The use of an operating room can present expensive medical service costs. It is estimated that operating room time can cost between about $30 to $100 per minute. An operating room must be sterilized before each operation and the medical staff must also prepare for the operation. Because each employee is usually paid for their time in the operating room, the operating room use costs can be very high. By increasing the efficiency of the employees within the operating room, the time for each procedure can be reduced and the cost of the surgery can also be reduced. Further, it is important to account for surgical objects such as needles and sponges during a surgical procedure. If a needle becomes lost during the surgery, steps need to be taken to ensure patient safety and that the needle has not been accidently left in the patient. Accounting for needles during a surgical procedure in an accurate manner can be time-consuming. Therefore, it would be desirable to provide improved ways to keep track of used needles in an operating room. Also, needle puncture through a surgical glove can present risks to operating room personnel.
The process of loading a needle holder is often carried out by those personnel assisting the surgeon in the process of surgery. A scrub technician or surgical assistant can pass the loaded needle holder to the surgeon. Both unused needles not yet having been used and those already used needles can be maintained on an instrument tray such as a Mayo stand, and an accounting of the needles is often made by the surgical assistant and circulating nurse during the course of surgery.
At the time of surgical incision wound closure, or other tissue repair, during which multiple armed sutures are to be utilized, the surgical assistant can be fully focused on the needs of the surgeon. The assistant passes the loaded needle holder to the surgeon's hand for use.
Used needles may be dispensed and accounted for in a less than optimal and safe manner. As a substitute for having the loaded needle driver passed to the surgeon, the surgeon may awkwardly load the armed suture himself. This often requires the surgeon turning to the instrument tray (e.g., Mayo stand), locating the suture package, and grasping and orienting the package such that the needle can be effectively and properly loaded onto the needle holder, which takes additional time and movement than would be ideal and undesirably directs the surgeons attention away from the patient.
In prior neutral zone approach, objects and instruments that are passed between a scrub tech and a surgeon must be placed in a neutral zone area. The process may require a scrub tech to place the object into the neutral zone and the surgeon cannot pick up the object until the scrub tech's hands are removed from the neutral zone. Similarly when the surgeon no longer needs a surgical object, it is placed in the neutral zone and the surgeon's hand removed. This system is less than ideal because the surgeon and scrub tech must often be very careful and clearly communicate and look at the neutral zone, away from the site of the operation, when any objects are passed. This can be particularly difficult when trying to perform actions quickly which can easily happen in an operating room procedure, for example when attempting to save a patient's life.
In many currently used suture handling methods and systems, the surgeon can be handed a needle driver with an armed suture needle. The surgeon may drive the needle through the flesh of the patient and then hands the needle driver with used needle to the scrub tech. The scrub tech then moves the used needle away from the surgical field and removes the used needle. The scrub tech then places a new armed needle in the needle driver and then hands the surgeon the needle driver. The described process is repeated, and results in more movement than would be ideal.
In addition to being highly inefficient, such systems can also have poor micro-ergonomics.
In light of the above, improved methods and apparatus are needed to improve operating rooms. Ideally such methods and apparatus would provide improved efficiency, outcomes, needle handling, counting, and safety.
The present invention relates to systems and methods for increasing operating room efficiency. Although specific reference is made to dispensing and securing needles, the embodiments described herein are well suited for use with many types of objects used in an operating room, such as sharp objects.
Systems and methods for improving operating room efficiency as described herein improve the manner in which surgeons' access and dispose of objects used in surgery such as sutures and needles. The methods and apparatus disclosed herein can improve safety by decreasing the number of needle passes between the surgeon and assistant, and by placing needles in a receptacle prior to being passed from the surgeon to the assistant.
Many embodiments relate to the dispensing and loading of surgical needles that can be facilitated and made more efficient and ergonomic by associating the needles, sutures and the packaging onto the surgeon's forearm, wrist, and/or hand. Furthermore and in many embodiments, the invention relates to the association of used needle temporary storage device as associated with the surgeon's forearm, wrist, and/or hand. The association of the surgeon's forearm wrist and/or hand can be accomplished in many ways, such as with mounting onto the surgeon's forearm wrist or hand, mounting to a surgical instrument such as forceps, or with a support extending into a near surgical field of the surgeon, and combinations thereof. Packaging and devices as described herein facilitate the safe and efficient dispensing of armed sutures in the proper orientation from the surgeon's forearm, wrist, and/or hand for use by the surgeon. Alternatively or in combination, the sutures can be dispensed from a support coupled to a surgical instrument such as forceps and the dispensed needles subsequently placed in the receptacle. The methods and apparatus disclosed herein allow the physician to self-load the needle into the needle driver, self-place the dispensed needle into a used needle receptacle, and optionally install the suture in the patient, which have the benefits of decreasing reliance on assistants, improving operating room efficiency and the safety of needle handling. In many embodiments, one or more needles can be secured in the receptacle prior to passing the needle to an assistant, which increases safety by placing the needle in the receptacle prior to passing to the assistant. A plurality of needles can be surgeon dispensed and surgeon placed in the container, such that the safety and efficiency can be increased by decreasing the number of passes between the surgeon and assistant.
In many embodiments, an “armed” suture comprises a suture that has a surgical needle attached. Furthermore, packages of armed sutures often contain more than one such suture and needle. The package may contain not only one, but also perhaps five and possibly more such as 8 or more sutures and needles. In the course of surgery, many such armed sutures can often be used, each needing to be “loaded” onto the needle holder or “needle driver”. The surgeon can hold the needle driver in his dominant hand and a tissue forceps in the non-dominant hand in order to manipulate and hold tissues to be sutured. Thus the surgeon can use both hands when suturing to self-dispense and self-secure the dispensed needles.
By associating the suture packaging and the enclosed armed sutures onto the surgeon's forearm, wrist or hand, the surgeon can more efficiently access armed sutures for loading onto the needle driver. Furthermore, the surgeon's forearm, wrist or hand can also provide a location for attachment of a used needle temporary or permanent storage device. In many embodiments, by associating the suture package to the volar or dorsal-radial region of the surgeon's non-dominant forearm, wrist, or hand, the mechanics of grasping the needle with the needle holder can be facilitated. Such an approach allows the surgeon to instantly reorient the suture pack and into a more appropriate position such that grasping the needles with the needle holder is facilitated. Associating the package with the surgeon's non-dominant extremity can allow the surgeon to, without significant body motion or without needing to grasp the package with his non dominant hand, reposition the needle package and needles in space such that they are readily accessible to be grasped with the needle driver.
In many embodiments a forearm-mounted system comprises a needle trap that can include an integrated suture pack mount that can be easily attachable to and detachable from a needle puncture resistant barrier worn on a forearm. The puncture resistant barrier provides a stable surface for dispensing of new sutures/needles from a standard suture pack and securement of contaminated needles after the stitch is completed. A benefit of the integration of the suture pack mount with the needle trap is that this configuration can enable real time proximity reconciliation within the near surgical field of used and unused needles. Integration of the suture pack mount with the needle trap within the near surgical field enables the surgeon to maintain focus on the incision closure process without having to divert visual attention to locate the needle securement container and deposit the used needles.
In many embodiments, the puncture resistant barrier provides protection to at least the volar surface of a forearm from inadvertent needle sticks and may also provide additional protection to the dorsal surface of a forearm. The puncture resistant barrier can also provide additional mounting surfaces for tool holders, running-suture spools, or other procedure specific materials that are optimally located in the near surgical field. The puncture resistant barrier can provide protection from sharps and can be comfortable, anatomically conformal, lightweight, unobtrusive, and quickly attachable to the surgeon's forearm with one hand.
The present disclosure provides multiple concepts, technologies and devices by which currently available armed sutures and the packages from which they are dispensed can be associated with the surgeon's forearm, wrist or hand for easier and more efficient loading by the surgeon, reducing the need for assistance from the scrub technician. Furthermore, disclosed herein are newly designed suture packages or modifications to currently available packages, which can incorporate concepts and technologies that allow for easy and efficient attachment of single or multiple suture packages to the support platform on the surgeon's forearm, wrist or hand or other support. The embodiments disclosed herein are well suited for use when the surgeon is gowned and gloved. The needle storage devices for dispensed used needles can also be associated with the surgeon's forearm, wrist or hand, as well as protective barriers and mechanisms that decrease the likelihood of needle stick to the surgeon.
The methods and apparatus disclosed herein allow a person who is closing an incision or wound with suture needles to reconcile needles dispensed from a suture pack with needles secured in a needle receptacle, in order to ensure that all needles used in a surgical procedure are accounted for. In many instances, the surgeon closing the incision can dispense suture needles from a suture pack in the near surgical field and place needles removed from the suture pack into a secure container within the near surgical field, and count the needles removed from the suture pack and the needles placed in the needle receptacle while the suture pack and needle receptacle remain in the near surgical field in order to reconcile the needles in the near surgical field. The reconciled needles secured in the receptacle and any remaining needles in the suture pack can then be passed from the near surgical field to another person outside the near surgical field or to a neutral zone. This needle reconciliation within the near surgical field allows the surgeon and others to act quickly if a needle is not accounted for and to take corrective action, for example by finding the missing needle. In many instances, needle reconciliation within the near surgical field also allows the surgeon to notice the missing needle sooner than reconciliation outside the near surgical field, and can make it easier to find the missing needle because the needle is missing for a shorter time. Needle reconciliation within the near surgical field also allows the surgeon or other person closing an incision or wound to have greater control over the surgical procedure, and also decreases the staffing requirements for surgery and associated costs. Although reference is made to needle reconciliation within the near surgical field outside of the patient, the methods and apparatus disclosed herein are well suited for needle reconciliation within the patient, for example within the patient during laparoscopic and robotic surgery.
Aspects of the present disclosure may provide barriers for placement on a forearm of a user. An exemplary barrier may comprise a curved shell defining a longitudinal axis extending between a proximal end and a distal end, with the curved shell extending with curvature about the longitudinal axis.
In many embodiments, the proximal end of the shell defines a cross-section with a long axis and a short axis, the distal end of the shell defines a cross-section with a long axis and a short axis, and the long axis of the proximal end is rotated about the longitudinal axis relative to the long axis of the distal end.
In many embodiments, the barrier long axis of the distal end is rotated relative to the long axis of the proximal end when placed on a forearm of a user, the proximal end is located toward an elbow of the user, and the distal end is located toward a wrist of the user when placed.
In many embodiments, the barrier comprises a pre-formed self-supporting barrier shaped to define the long axis on the proximal end and the short axis on the distal end as opposing edges of the barrier are urged toward each other.
In many embodiments, the long axis of the proximal end is longer than the long axis of the distal end.
In many embodiments, the proximal end comprises a short axis and the distal end comprises a short axis, and the short axis of the proximal end is longer than the short axis of the distal end. The long axis of the distal end may be shorter than the short axis of the proximal end.
In many embodiments, the barrier may comprise a thermoformed sheet of material having substantially uniform thickness.
In many embodiments, the barrier comprises a preformed self-supporting structure.
In many embodiments, the barrier comprises a dorsal aspect having a dorsal length extending between the proximal end and the distal end, a radial aspect having a radial length extending between the proximal end and the distal end, and a volar aspect having a volar length extending between the proximal end and the distal end. The radial aspect may be disposed between the dorsal aspect and the volar aspect. The radial length may be shorter than the dorsal length and the volar length. The barrier may comprise indicia on the radial aspect for a user to align the barrier with a radial ridge of the forearm of the user.
In many embodiments, the barrier may further comprise a proximal tab having a proximal tab length and a distal tab having a distal tab length, the proximal tab longer than the distal tab. The distal tab length may be within a range from about 25% to about 75% of the proximal tab length. The proximal tab and the distal tab may be preformed to have a curved shape extending around the longitudinal axis in a free standing configuration.
In many embodiments, the barrier is shaped to fit a left forearm of a user or a right forearm of a user.
In many embodiments, the barrier comprises a dorsal taper on a dorsal side between the proximal end and the distal end and a volar taper on a volar side between the proximal end and the distal end. The volar taper may be greater than the dorsal taper.
In many embodiments, the barrier comprises a placed configuration when opposite edges on opposite sides have been drawn toward each other.
In many embodiments, the barrier comprises a placed configuration when opposite edges on opposite sides have been drawn toward each other and wherein dorsal, volar and radial aspects of the barrier define a proximal center at the proximal end and a distal center at a distal end, an intermediate portion of the barrier defines an intermediate center with intermediate dorsal volar and radial aspects, and the center of the intermediate portion is located away from a straight line extending between the proximal center and the distal center. The plurality of intermediate dorsal, radial, and volar portions may define a plurality of intermediate centers. The proximal center, the intermediate center, and the plurality of intermediate centers may define a curved path extending between the proximal center and the distal center. A perpendicular cross-section of the proximal portion through the proximal point may define a plane and an orthogonal axis extending from the proximal center perpendicular to the plane. The distal center may be offset from the orthogonal axis by an amount within a range from about 1 cm to about 4 cm.
The barrier may be in a variety of dimensions. The barrier may comprise a thickness within a range from about 0.4 mm to about 5 mm. The may comprise a longitudinal length within a range from about 6 inches to about 11 inches. The barrier may comprise a ratio of the distance across the proximal end to the distance across the distal end within a range from about 1.1 to about 1.5.
In many embodiments, the barrier may comprises a pre-formed shaped barrier. The barrier may comprise a volar edge on a volar side and a dorsal edge on a dorsal side. The volar edge may separate from the dorsal edge when advanced over the forearm for placement. An amount of force to separate the volar edge from the dorsal by about one inch from a free standing configuration may be within a range from about 25 grams to about 400 grams, or from about 50 grams to about 150 grams.
In many embodiments, the barrier comprises a shell and an underlying foam which extends distally beyond the distal border of the shell of the barrier. The foam may curve over a leading distal edge of the shell to pad the interface of the shell when the barrier impinges on the wrist to provide comfort.
In many embodiments, the barrier comprises a shell and an underlying foam which extends distally beyond the distal border of the shell of the barrier to pad the interface of the shell when the barrier impinges on the wrist to provide comfort.
In many embodiments, the barrier may comprise a shell and an underlying foam which curves over a leading distal edge of the shell to pad the interface of the shell when the barrier impinges on the wrist to provide comfort.
In many embodiments, the barrier may comprise a shell and a distal edge of the shell has a curvature with a diameter equal to the thickness of the shell.
In many embodiments, the barrier may comprise a shell and a distal end of the shell curves away from the forearm of a user, such as with a radius of curvature of between 2 mm and 5 mm.
In many embodiments, the barrier comprises a shell having a radial curvature at a distal edge of shell with displacement within a range from about 3 mm to 1.5 cm to distribute a load of the barrier on a wrist of a user.
In many embodiments, the barrier comprises a shell and a foam padding the distal edge of the shell.
In many embodiments, the barrier may comprise a thickened distal edge.
In many embodiments, the barrier may be configured to distribute a load when device abuts the dorsal or radial or volar aspect of the wrist with motion of the wrist.
Aspects of the present invention include barriers for placement on a forearm of a user. An exemplary barrier may comprise a curved shell defining a longitudinal axis extending between a proximal end and a distal end. The curved shell may extend with a curvature about the longitudinal axis. The proximal end of the shell may define a cross-section. The distal end of the shell may define a cross-section. The barrier may comprise a pre-formed shaped barrier. The barrier may comprise a volar edge on a volar side and a dorsal edge on a dorsal side. The volar edge may separate from the dorsal edge when advanced over the forearm for placement. An amount of force to separate the volar edge from the dorsal by about one inch from a free standing configuration may be within a range from about 25 grams to about 400 grams, or from about 50 grams to about 150 grams.
Aspects of the present invention may provide a method comprising providing a barrier as disclosed herein.
Aspects of the present invention may provide needle receptacles. An exemplary needle receptacle may comprise a lower structure that has an entry zone and a secure zone, an upper structure that has a secure zone, a needle slot for receiving one or more suture needles between the lower structure and the upper structure, and an upper needle driver slot that extends through a portion of the upper structure and a lower needle driver slot that extends through portion of the lower structure. A lower protrusion on a bottom side of the lower structure may comprise a height sufficient to provide clearance for the needle driver when a needle grasped away from a tip of the needle driver advances along the needle slot. The lower protrusion may comprise a standout extending along the lower needle driver slot.
Another exemplary needle receptacle may comprise a housing comprising a lower structure and an upper structure. The upper structure may comprise an optically transmissive material and the lower structure may comprise an optically transmissive material in order to view needles within a secure zone of the receptacle with backlight illumination. The upper portion may comprise a transparent material to view the needles, and the lower portion may comprise a translucent material to pass backlight illumination light to the needles. The needle receptacle may further comprise a slot through the upper structure in order to view needles within a secure zone of the receptacle. The upper structure may have a longitudinal slot to receive a needle driver. The secure zone may comprise an elongate needle slot to receive a plurality of needles. The elongate needle slot may extend between the upper structure and the lower structure. The needles in the needle slot can be viewed through the top structure with backlight illumination through the lower structure.
Another exemplary needle receptacle may comprise a lower structure that has an entry zone and a secure zone, an upper structure that has a secure zone, and a needle slot for receiving one or more suture needles between the lower structure and the upper structure. A plurality of protrusions may extend along the needle slot with a periodicity in order to provide tactile feedback to a user to indicate a position of the needle along the needle slot.
Another exemplary needle receptacle may comprise a lower structure that has an entry zone and a secure zone, an upper structure that has a secure zone and a needle driver slot extending along the secure zone, and a needle slot for receiving one or more suture needles between the lower structure and the upper structure. A plurality of protrusions may extend along the needle driver slot to provide tactile feedback to a user as to the depth of the needle driver along the needle driver slot. The plurality of protrusions may comprise one or more of teeth, inclined teeth, ratchet teeth or circular cutouts. The plurality of protrusions may comprise one or more of teeth, inclined teeth, ratchet teeth or circular cutouts, flaps, bristles, or filaments. The plurality of protrusions may be arranged with periodicity to provide an indication of depth of the needle driver along the needle driver slot.
Another exemplary needle receptacle may comprise a lower structure that has an entry zone and a secure zone, an upper structure that has a secure zone, and a needle slot for receiving one or more suture needles between the lower structure and the upper structure. A plurality of asymmetric protrusions may extend along the needle slot in order to inhibit removal of the needle along the needle slot. Each of the plurality of asymmetric protrusions may comprise a base extending to a peak. The base may comprise a distal edge toward an entrance of the slot and a proximal edge toward a stop on a proximal end of the slot. The peak may be located closer to the proximal edge than the distal edge. The plurality of asymmetric protrusions may comprise one or more of bristles or fibers inclined proximally toward a stop in order to facilitate movement toward the stop and inhibit movement toward an opening of the slot through which the needle is passed for placement in the secure zone. The entry zone may be at a distal end of the needle receptacle and the secure zone may be at a proximal end of the needle receptacle. The plurality of asymmetric protrusions may comprise one or more of bristles or fibers inclined towards a stop in order to facilitate movement toward the stop and inhibit movement toward an opening of the slot through which the needle is passed for placement in the secure zone.
Another needle receptacle may comprise a structure to receive a needle with resistance or force to remove the needle, wherein an amount of resistance or force to remove the needle is within a range from about 5 grams to 250 grams, within a range from about 15 grams to about 150 grams, within a range from about 25 grams to about 100 grams, or within a range from about 30 grams to about 90 grams. The amount of force to remove the needle may be greater than the amount of force to insert the needle. The needle receptacle may comprise a needle slot, and the amount of force may comprise an amount of force to advance the needle along the needle slot. The needle receptacle may comprise a needle driver slot, and the amount of force may comprise an amount of force to advance the needle driver along the needle driver slot to secure the needle in the needle slot.
Aspects of the present invention may provide a method comprising a step of inserting a needle into a needle receptacle. The needle receptacle may resist insertion of the needle with an amount of force within a range from about 5 grams to 250 grams, within a range from about 15 grams to about 150 grams, within a range from about 25 grams to about 100 grams, or within a range from about 30 grams to about 90 grams. The amount of force to remove the needle may be greater than the amount of force to insert the needle.
Aspects of the present invention may provide needle traps. An exemplary needle trap may comprise a landing zone and a secure zone. The landing zone may be substantially coplanar with the secure zone.
Aspects of the present invention may provide a method comprising steps of moving a needle to a landing zone of a needle receptacle and sliding the needle from the landing zone into a secure zone of the needle receptacle.
Aspects of the present invention may provide a receptacle comprising a slotted structure that allows a tip and a tail of the needle to be substantially enclosed while suspending a mid-portion of the needle in the slot.
Aspects of the present invention may provide a needle receptacle comprising a slot along a secure zone. The slot may be sized smaller than a finger tip having a size of about 10 mm.
Aspects of the present invention may provide a needle receptacle comprising a needle groove having a thickness small enough to inhibit rotational movement of the needle out of the needle groove.
Aspects of the present invention may provide sterile barrier kits. An exemplary sterile barrier kit may comprise a sterile package and a sterile barrier contained within the package. The kit may be configured for one or more of regional anesthesia, spinal anesthesia, emergency room suturing, or intravenous (IV) line placement. The kit may be configured to one or more of regional anesthesia, spinal anesthesia, emergency room suturing, intravenous (IV) line, arterial line, or central line placement.
In the needle receptacles disclosed herein, the receptacle may be sized to a range of needles, and may optionally comprise a smaller slot for smaller needle drivers, in which the slot comprises a width of no more than a diameter of a largest needle for which the trap is designed to store.
A longitudinal slot for the needle driver may comprise a through and through slot, in which the slot extends though both sides of the receptacle.
A longitudinal slot or groove for the needle driver may comprise a lower solid wall, in which the wall is located at a sufficient depth to allow the tip of the needle driver to protrude beyond the needle securement slot plane. The needle driver groove or slot may extend beneath the needle slot by a distance within a range from about 0.1 mm to about 10 mm.
In the needle receptacles disclosed herein, the receptacle may comprise a longitudinal slot bounded by a structure to one or more sides of the slot that creates a varying resistance to translation as the needle is drawn along the slot. Optionally, the varying resistance may be provided with one or more of discrete or asymmetric features that protrude into the needle slot, in order to increase compression of the needle and provide tactile feedback as the needle is drawn along the slot.
The needle receptacle may comprise a secure zone, can be applied to the forearm, and may comprise a width of less than 12 cm and a length of less than 26 cm.
A compressive member may be configured to secure a needle and provide resistance to movement of the needle against an apposed surface. The foam structure may comprise a gap of less than 2 mm between the foam and the apposed surface.
Aspects of the present disclosure may provide a method of inserting a needle into a needle receptacle. The method may comprise steps of placing the needle at an entry zone of the needle receptacle coupled to a forearm and moving the needle along a plane of the forearm to secure the needle within a housing of the needle receptacle.
The barrier may comprise a recess in an outer surface of the barrier. The recess may be configured to receive at least a portion of a needle receptacle therein to couple the needle receptacle to the barrier in a low profile.
The barrier may comprise an integrated needle receptacle such that the needle receptacle is provided on the barrier in a low profile.
The needle receptacle may comprise a needle driver slot cover configured to at least partially cover a longitudinal needle driver slot of the needle receptacle to reduce risk of exposure of needle tips through the needle driver slot. The needle driver slot cover may comprise one or more flexible strips configured to elastically deform when a needle driver tip is translated along the needle driver slot. The needle driver slot cover may comprise a flexible strip disposed over the needle driver slot. The flexible strip may comprise a longitudinal slit positioned over the needle driver slot and extending longitudinally along the needle driver slot. The flexible strip may further comprise a plurality of vertical slits disposed over a length of the needle driver slot and extending orthogonally with respect to the longitudinal slit. The needle driver slot cover may comprise a transparent material. The needle driver slot cover may be slidably coupled to the needle receptacle and configured to slide to expose or cover the needle driver slot when the needle driver tip is translated along the needle driver slot. The needle driver slot cover may be configured to slide along a longitudinal axis of the needle driver slot. The needle driver slot cover may be configured to slide along an axis orthogonal to the longitudinal axis of the needle driver slot.
The needle receptacle may comprise a compressive member mounted laterally along a first longitudinal edge of a needle driver slot. The compressive member may be configured to be displaced by translation of a needle driver tip along the needle driver slot. Upon removal of the needle driver tip from the needle driver slot, exposed ends of a needle may be compressively pushed toward a second longitudinal edge of the needle driver slot opposite the first edge. The compressive member may be configured to provide a compressive force in a direction orthogonal to a longitudinal axis of the needle driver slot.
A housing of the needle receptacle may comprises a light guide. The needle receptacle may be coupled to a light source configured to transmit light to the light guide to provide backlighting.
A housing of the needle receptacle may comprise a light scattering material or surface to provide for non-uniform light transmission therethrough. The light scattering surface may comprise a surface of the lower or upper structure. The light scattering surface may comprise a roughened surface. The light scattering surface may comprise a sandblasted surface.
Aspects of the present disclosure may provide apparatuses for dispensing and securing a swaged needle. An exemplary apparatus may comprise a housing and a swaged needle. The housing may comprise a top portion, a bottom portion, and a side wall. The swaged needle may be coupled to the top portion of the housing. The swaged needle may comprise an attached suture. The attached suture may be wrapped around the side wall. A leading end of the swaged needle may be covered. The housing may comprise a spindle configured to allow rotation of the housing about a central axis of the housing. The apparatus may further comprise a mounting mechanism to mount the apparatus to a barrier. A height of the housing may be in a range from about 0.3 mm to about 15 mm, such as a range from about 1.5 cm to about 8 cm. The apparatus may be configured to couple to another identical apparatus in a stacked configuration. The housing may comprise a lid coupled to the top portion. The swaged needle may be covered by the lid. The top portion of the housing may comprise a slot to receive the leading end of the swaged needle and secure the swaged needle thereto.
Aspects of the present disclosure may provide apparatuses for dispensing and securing a swaged needle. An exemplary apparatus may comprise a housing, a plurality of spindles, and a swaged needle. The housing may comprise a bottom portion and a side wall extending from the bottom portion. The plurality of spindles may extend from a surface of the bottom portion. The swaged needle may be coupled to the housing. The swaged needle may comprise an attached suture. The attached suture may be wrapped around at least two of the plurality of spindles. The plurality of spindles may be arranged on the bottom portion in pairs and the suture may be wrapped around a first pair of spindles. The apparatus may further comprise a second swaged needle coupled to the housing. The second swaged needle may comprise an attached second suture. The second suture may be wrapped around a second pair of spindles.
Aspects of the present disclosure may provide needle receptacles for mounting to a surgical tool. An exemplary needle receptacle may comprise a housing, a tool-mounting interface, and a coupling mechanism. The housing may comprise a planar needle slot to receive a needle and secure the needle therein. The tool-mounting interface may be configured to couple to a distal end of the surgical tool. The coupling mechanism may be configured to couple the housing to the tool-mounting interface. The housing may be configured to receive at least 5 needles therein. The tool-mounting interface may comprise an elastomeric cap configured to fit over the distal end of the surgical tool. The housing may comprise a rigid enclosure configured to receive a plurality of needles in a planar array aligned along a length of the rigid enclosure. The housing may comprise a circular array of compartments. Each compartment may be configured to receive a single needle therein. The circular array of compartments may be configured to rotate about a central axis of the housing to allow access to each compartment.
A needle driver slot may comprise an upper groove and a lower groove. The upper groove and the lower groove may comprise rounded edges.
A needle driver slot may comprise an upper groove and a lower groove. A width of the upper groove may be greater than a width of the lower groove.
A needle driver slot may comprise an upper groove and a lower groove. The upper groove and the lower groove may comprise beveled edges.
A needle driver slot may comprise an upper groove and a lower groove. The edges of the upper groove and lower groove may be angled and collinear.
In the needle receptacles disclosed herein, the needle driver slot may comprise an upper groove and a lower groove. The edges of the upper groove and lower groove may correspond to a subsection of a prolonged curving plane.
Aspects of the present disclosure may provide needle handling systems. An exemplary needle handling system may comprise a needle dispensing unit, a needle receptacle, and a barrier mounting base. The needle dispensing unit may comprise a plurality of sterile needles secured therein. The needle receptacle may comprise a planar needle slot configured to receive a plurality of used needles in a planar array. The barrier mounting base may comprise a top side and a bottom side. The top side may be configured to couple to the needle dispensing unit and the needle receptacle. The bottom side may be configured to couple to a barrier. The barrier mounting base may comprise a first portion configured to couple to the needle dispensing unit and a second portion configured to couple to the needle receptacle. The barrier mounting base may further comprise a hinge disposed between the first portion and the second portion to allow the first portion to bend with respect to the second portion.
The needle receptacle may comprise a first compressive member and a second compressive member. The first compressive member may be configured to engage a leading end of a needle. The second compressive member may be configured to engage a trailing end of the needle so as to entrap the needle between the compressive members.
A needle receptacle as in any one of the preceding claims, the needle receptacle comprising one or more clips configured to receive and enclose one or more ends of a needle and apply compressive force to the one or more ends to secure the one or more ends therein.
Aspects of the present disclosure may provide a needle receptacle comprising a housing and a rotatable cover coupled to the housing. The housing may comprise a plurality of compartments. Each compartment may be configured to contain a single needle therein. The rotatable cover may be coupled to the housing. The rotatable cover may comprise a window. The rotatable cover may be configured to rotate about a central axis of the housing to align the window with a single compartment to allow access to the single compartment through the window.
The methods, apparatuses, receptacles, kits, and barriers disclosed herein may further comprise associating a combination of both dispensing unit and used needle repository on the forceps.
In the methods, apparatuses, receptacles, kits, and barriers disclosed herein more than one setup of a suture package and needle receptacle may be ready for use.
The methods, apparatuses, receptacles, kits, and barriers disclosed herein may further comprise a sterile disposable forceps, a needle and suture package in combination with a used needle receptacle.
In the methods, apparatuses, receptacles, kits, and barriers disclosed herein, a sterile disposable forceps, a needle, and suture package in combination with a used needle receptacle may be co-manufactured into a common package.
In the methods, apparatuses, receptacles, kits, and barriers disclosed herein, a balanced surgical forceps may have an attached needle retention device onto the forceps.
In the methods, apparatuses, receptacles, kits, and barriers disclosed herein, a configuration may comprise a back to back relationship of the suture package and needle receptacle on opposing sides.
In the methods, apparatuses, receptacles, kits, and barriers disclosed herein, the suture package and needle receptacle may be attached to the forceps to allow for containment, coverage, securement, of both tip and end (tail) of one or more needles.
In the methods, apparatuses, receptacles, kits, and barriers disclosed herein, a forceps mounted needle receptacle may promote an organized deposition or array of used needles to facilitate counting and reconciliation of needle count.
In the methods, apparatuses, receptacles, kits, and barriers disclosed herein, the needle receptacle may be configured with a size and shape for five needles and may comprise five zones, one for each needle.
The methods, apparatuses, receptacles, kits, and barriers disclosed herein may further comprise five tactile bumps to facilitate localization into individual zones.
The methods, apparatuses, receptacles, kits, and barriers disclosed herein may further comprise 2-20 tactile bumps to facilitate localization into individual zones.
The methods, apparatuses, receptacles, kits, and barriers disclosed herein may further comprise 5-8 tactile bumps to facilitate localization into individual zones.
The methods, apparatuses, receptacles, kits, and barriers disclosed herein may further comprise 3-10 tactile bumps to facilitate localization into individual zones.
The methods, apparatuses, receptacles, kits, and barriers disclosed herein may be further configured for back lighting to enhance needle profile contrast.
The methods, apparatuses, receptacles, kits, and barriers disclosed herein may further comprise five zone specific light sources and may be configured to provide one light source on per needle into the receptacle. Light sources may be located on the needle receptacle.
The methods, apparatuses, receptacles, kits, and barriers disclosed herein may further comprise five light sources or sensors on a trap in a receptacle. The light sources may be coupled with the barrier. The barrier may be configured with five lights sources that light up according to a number of needles in the trap in the receptacle.
The methods, apparatuses, receptacles, kits, and barriers disclosed herein may further comprise a translational slot cover with ratcheted counting mechanism.
Aspects of the present disclosure may provide a needle apparatus which may comprise a pair of opposing needle receptacles. Each needle receptacle may have a front side and a back side and an opening to receive needles on the front side. The back sides may be oriented toward each other and the front sides may be oriented away from each other.
Aspects of the present disclosure may provide a needle apparatus which may comprise a pair of opposing suture packages. Each suture package may have a front side and a back side. The front side may be open to access a plurality of needles therefrom. The back sides may be oriented toward each other and the front sides may be oriented away from each other.
Aspects of the present disclosure may provide a needle apparatus which may comprise a needle receptacle and a suture package. The needle receptacle may have a front side and a back side and having an opening to receive needles on the front side. The suture package may have a front side and a back side. The front side may be open to access a plurality of needles therefrom. The back sides may be oriented toward each other and the front sides may be oriented away from each other.
A needle apparatus as disclosed herein may further comprise an interface to mount the needle apparatus on a surgical instrument. The interface may optionally comprise a slot to receive a proximal end of the instrument.
A needle apparatus as disclosed herein may further comprise an interface to mount the needle apparatus on forceps and the interface may optionally comprise a slot to receive a proximal end of the forceps.
A needle apparatus as disclosed herein may further comprise an interface to mount the needle apparatus on tweezers. The interface may optionally comprise a slot to receive a proximal end of the tweezers. The interface may comprise an adhesive.
A needle apparatus as disclosed herein may have opposing back sides which are rotatable about a common axis.
A needle apparatus as disclosed herein may have opposing back sides which are independently rotatable about a common axis.
A needle apparatus as disclosed herein may further comprise a pair of disposable forceps.
A needle apparatus as disclosed herein may be sterile and contained within a sterile package.
A barrier as disclosed herein may comprise a padding layer and a mechanical barrier layer. One or more magnets may be coupled to a surface of the mechanical barrier layer facing the padding layer such that the one or more magnets are disposed between the padding layer and the mechanical barrier layer.
A barrier as disclosed herein may comprise a mechanical barrier layer comprising a polymer material.
A barrier as disclosed herein may barrier comprise a polymer material with a thickness in range from about 0.5 mm to about 5 mm.
Aspects of the present disclosure may provide methods for handling suture needles. In an exemplary method, a suture needle may be grasped with a needle driver to dispense the suture needle from a suture package mounted on a support. The dispensed suture needle may be placed into a needle receptacle mounted on the support. A tip of the dispensed suture needle may be oriented away from a surgeon during the grasping step and the placing step.
The dispensed suture needle may travel a variety of distances. The dispensed suture needle may travel less than two feet from the grasping step to the placing step. The suture needle may travel a round trip distance of less than four feet from the grasping step to the placing step. The suture needle may travel no more than two feet from the suture pack to a wound and no more than two feet from the wound to the needle receptacle.
In many embodiments, the dispensed suture needle remains within a near surgical field during the steps of grasping and placing. The near surgical field may be bounded by a length extending from a front side of a torso of a surgeon to an incision, a width extending between forearms of the surgeon in a neutral rotation position, and a height extending vertically from a height of the incision to shoulders of the surgeon.
In many embodiments, the suture package and the needle receptacle are arranged for the surgeon to dispense a plurality of needles from the suture package and place the plurality of needles in the needle receptacle without an external rotation of an arm of a surgeon with respect to an anatomical neutral plane of the arm.
In many embodiments, the suture package and the needle receptacle are arranged for the surgeon to dispense a plurality of needles from the suture package and place the plurality of needles in the needle receptacle without an external rotation of an arm of a surgeon beyond a coronal plane of the surgeon.
In many embodiments, the suture package and the needle receptacle are arranged for the surgeon to dispense a plurality of needles from the suture package and place the plurality of needles in the needle receptacle without an external rotation of an arm of a surgeon beyond a plane perpendicular to the coronal plane of the surgeon at the surgeon's shoulder.
In many embodiments, the suture package and the needle receptacle are arranged for the surgeon to dispense a plurality of needles from the suture package and place the plurality of needles in the needle receptacle without an external rotation of an arm of a surgeon beyond a sagittal plane that bisects the coronal plane at the surgeon's shoulder.
In many embodiments, the suture package and the needle receptacle are arranged for the surgeon to dispense a plurality of needles from the suture package and place the plurality of needles in the needle receptacle without an external rotation of an arm of a surgeon beyond a mid-sagittal plane of the surgeon.
In many embodiments, the near surgical field comprises a space disposed within one or more of about 2 feet of the incision, 1.5 feet of the incision or about 1 foot of the incision.
In many embodiments, the suture package and the needle receptacle are attached to the support.
In many embodiments, the method further comprises repeating the steps of grasping and placing until a plurality of suture needles has been dispensed from the suture package and placed into the needle receptacle.
In many embodiments, the dispensed suture needle is attached to a suture, and the method further comprises installing the suture into a patient with the dispensed suture needle and the needle driver. The steps of grasping, installing, and placing may be repeated until a plurality of sutures have been installed in the patient.
In many embodiments, the suture pack and the needle receptacle are arranged for a surgeon to perform the steps of grasping and placing with one hand.
In many embodiments, the support comprises a movable support controlled by a surgeon.
In many embodiments, the needle receptacle comprises a structure located to place into a stable configuration one or more reels of suture coupled to a swaged on needle in order to dispense suture of the swaged needle from the one or more reels stably supported on the needle receptacle.
In many embodiments, the suture pack comprises a structure located to place into a stable configuration one or more reels of suture each coupled to a swaged on needle in order to dispense the one or more reels of suture and needle from the structure stably supported on the suture pack.
In many embodiments, the suture pack comprises a structure located to place into a stable configuration one or more reels of suture coupled to a swaged on needle in order to dispense suture of the swaged needle from the one or more reels stably supported on the suture pack.
In many embodiments, a suture attached to the dispensed suture needle is cut with one hand.
In many embodiments, the support comprises a barrier supported by a surgeon. The barrier may be coupled to a limb of the surgeon. The barrier may be releasably coupled to a limb of the surgeon. The suture package may be selected among a plurality of suture packages supported on a tray, and the suture package may be placed on the barrier. The needle receptacle may be selected among a plurality of needle receptacles supported on a tray, and the needle receptacle may be placed on the barrier.
In many embodiments, the suture package, the needle receptacle, and the support are sterile. One or more of the support or the barrier is configured for placement on a back portion of a hand of a surgeon with one or more structures extending from the barrier.
In many embodiments, the suture package and the needle receptacle comprise a self-contained package capable of being passed together from a surgeon to an assistant and vice versa with a plurality of innocuous needles supported with the suture package and the needle receptacle. The suture package may be attached to the needle receptacle. The suture package may be flexibly attached to the needle receptacle with a hinged support member. A combination of the suture package and needle receptacle may be attached to a support on an extremity of the surgeon. A combination of the suture package and needle receptacle may attach conformably to the support on an extremity of the surgeon.
The suture pack may comprise a planar suture package, and the needle receptacle may lie at an oblique angle of less than 45 degrees relative to the planar suture package. The suture package and the needle receptacle may each in contact with the support so as to decrease a profile of the needle receptacle. The suture package may be assembled together on the support.
The suture package and the trap may at least partially overlap in order to decrease size on barrier. The suture package and the trap may at least partially overlap in order to decrease a footprint of the suture package and the trap on barrier. The package and the needle receptacle trap may overlap in a proximal to distal direction. The suture package and the needle receptacle may overlap in a medial to lateral direction. The suture package and the needle receptacle may comprise an attachment mechanism. The suture package may comprise a standard commercially available needle package.
A needle receptacle attachment mechanism may allow attachment of the suture package to one or more of a lateral border or a distal border of the needle receptacle.
The step of coupling the barrier to a limb of the surgeon may comprise placing the barrier over a volar portion of a forearm of the surgeon.
The needle receptacle may be placed over a volar forearm of the surgeon. The needle receptacle may comprise a planar structure placed over the volar forearm. The needle receptacle may comprise a planar structure placed over the volar forearm and optionally the planar structure may be placed over a medial portion of the volar forearm. The needle receptacle may be arranged over the volar forearm to allow easy insertion of a used needle when a hand holding needle holder is slightly supinated. The needle may be placed in the receptacle with rotation of an arm holding a needle driver with shoulder joint rotation in order to align and place the used needle into an opening of the needle receptacle.
The needle receptacle may be arranged over the volar forearm to allow easy insertion of a used needle when a hand holding needle holder is slightly pronated. The needle may be placed in the receptacle with rotation of an arm holding a needle driver with shoulder joint rotation in order to align and place the used needle into an opening of the needle receptacle.
The needle receptacle may comprise a longitudinal length, a transverse width, and a height. The length may be greater than the width and the height. The width may be greater than the height. The length may be within a range from about 4 cm to about 15 cm, the width may be within a range from about 3 cm to about 6 cm, and the height may be within a range from about 0.5 cm to about 2 cm.
The step of coupling the barrier to the limb of the surgeon may comprise steps of providing legs that extend from sides of the barrier and engaging the legs on the limb of the surgeon to stabilize the barrier on the forearm of the surgeon. The step of engaging the legs on the limb of the surgeon may comprise a step of engaging one or more of a distal portion or a proximal portion of a forearm of the surgeon. The legs may comprise at least a plurality of legs for stable placement on one or more the first portion or the second portion. The legs may comprise slap bracelets. The legs may comprise a first leg and a second leg. The method may further comprise a step of securing a first coupling mechanism on the first leg to a second coupling mechanism on the second leg to secure the barrier to the limb of the surgeon.
The method may further comprise a step of coupling the suture package to the barrier. The method may further comprise a step of coupling the needle receptacle to the barrier. One or more of the support or the barrier may comprise a barrier layer configured to protect the limb of the surgeon from contact with the suture needles.
The support may comprise a surgical tool held by a surgeon. The surgeon may perform the steps of grasping and placing with one hand, while holding the surgical tool with the other hand.
A plurality of suture packages may be mounted on the support.
The step of placing the dispensed suture needle into the needle receptacle may comprise a step of rendering innocuous both ends of the dispensed suture needle within the needle receptacle.
The step of placing the dispensed suture needle into the needle receptacle may comprise a step of compressing a component of the needle receptacle against a tip of the dispensed suture needle.
The step of placing the dispensed suture needle into the needle receptacle may comprise a step of placing the dispensed suture needle in contact with a foam material in the needle receptacle.
The step of placing the dispensed suture needle into the needle receptacle may comprise placing a tip of the dispensed suture needle into a tapered structure that guides the dispensed suture needle into the needle receptacle.
The method may further comprise a step of actuating a lever coupled to a door of the needle receptacle to open the door. The method may further comprise a step of inserting the dispensed suture needle through the door in the needle receptacle. The method may further comprise a step of actuating the lever to close the door.
The method may further comprise a step of rotating the support so that the suture package faces the needle drive before grasping the suture needle with the needle driver.
The method may further comprise a step of rotating the support so that the needle receptacle faces the needle driver before placing the dispensed suture needle into the needle receptacle with the needle driver.
The needle receptacle may comprise a plurality of channels separated by dividers. The step of placing the dispensed suture needle into the needle receptacle may comprise a step of placing the dispensed suture needle into one of the plurality of channels. A plurality of suture needles may be dispensed from the suture package. The step of placing the suture needle into the needle receptacle may comprise placing each of the plurality of dispensed suture needles into a different one of the plurality of channels. The dividers may surround one or more of a proximal end or a distal end of the dispensed suture needle.
The needle receptacle may comprise a transparent structure.
The support may be coupled to a proximal portion of surgical forceps.
One or more of the suture package or the needle receptacle may be coupled to a proximal portion of surgical forceps.
The suture package and the needle receptacle may be arranged for a surgeon to count a plurality of undispensed needles and a plurality of dispensed needles within a near surgical field.
The suture package and the needle receptacle may be arranged for a surgeon to maintain a needle inventory within a near surgical field.
The suture package and the needle receptacle may be arranged for a surgeon to reconcile a needle inventory within a near surgical field.
The step of placing the dispensed suture needle into a needle receptacle mounted on the support may further comprise a step of securing the needle to the needle receptacle.
Aspects of the present disclosure provide apparatuses for handling suture needles. The apparatus may comprise a suture package, a needle receptacle, and a support. The suture package may be configured to dispense a plurality of suture needles. The needle receptacle may be configured to store a plurality of dispensed suture needles. The support may be configured to support one or more of the suture package or the needle receptacle.
In many embodiments, the needle receptacle is arranged to place the suture needle in the receptacle with a tip of the suture needle oriented away from the surgeon.
In many embodiments, the needle receptacle is arranged to place the suture needle in the receptacle with a tip of the suture needle oriented away from a direction of translation of the suture needle into the needle receptacle.
In many embodiments, the suture needle comprises a curved suture needle and the needle receptacle is arranged to place the suture needle in the receptacle with each end of the suture needle oriented away from the surgeon.
In many embodiments, the needle receptacle comprises a structure to receive the suture package and stably support the suture package.
In many embodiments, the suture package and the needle receptacle are arranged for the surgeon to dispense a plurality of needles from the suture package and place the plurality of needles in the needle receptacle without an external rotation of an arm of a surgeon with respect to an anatomical neutral plane of the arm.
In many embodiments, the suture package and the needle receptacle are arranged for the surgeon to dispense a plurality of needles from the suture package and place the plurality of needles in the needle receptacle without an external rotation of an arm of a surgeon outside a near surgical field of the surgeon.
In many embodiments, the needle receptacle comprises a structure located to place into a stable configuration one or more reels of suture coupled to a swaged on needle in order to dispense suture of the swaged needle from the one or more reels stably supported on the needle receptacle.
In many embodiments, the needle receptacle comprises a structure located to place into a stable configuration one or more reels of suture each coupled to a swaged on needle in order to dispense suture of the swaged needle from the one or more reels stably supported by a common base mounted to one of the group selected from: the a barrier on an arm of a surgeon, a drape over the patient, and a support.
In many embodiments, the apparatus further comprises a cutter arranged with the support in order to cut a suture of the suture needle with one hand.
In many embodiments, the apparatus further comprises a sterile tray having a plurality of suture packages supported thereon.
In many embodiments, the suture package, the needle receptacle and the support are sterile.
In many embodiments, one or more of the support or the platform is configured for placement on a back portion of a hand of a surgeon with one or more structures extending from the platform.
In many embodiments, the support is configured to attach to the suture package and to the needle receptacle in order to stably support the suture package and the needle receptacle on the support and in order to inhibit sliding or falling of the suture package and the needle receptacle from the support when the support is inverted or inclined and wherein the support is configured to release the suture package and the needle receptacle.
In many embodiments, the suture pack and the needle receptacle are arranged for a surgeon to perform the steps of grasping and placing with one hand.
In many embodiments, the support comprises a movable support configured to be controlled by a surgeon.
In many embodiments, the support comprises a platform configured to be supported by a surgeon.
In many embodiments, the support comprises a platform configured to be supported by one of the group selected from: a surgeon, a drape, and, a mount coupled to the surgical table, and a stable mount. The platform may comprise a coupling configured to couple the platform to a limb of the surgeon. The coupling may comprise one or more legs that extend from sides of the platform. The legs may be configured to engage the limb of the surgeon. The coupling may comprise slap bracelets. One or more of the support or the platform may comprise a barrier configured to protect the surgeon from contact with one or more ends of a dispensed suture needle.
In many embodiments, the support comprises a platform coupled to an adjustable support structure to place the platform within a near surgical field.
In many embodiments, the support comprises a platform is within a near surgical field and coupled to one of the group consisting of: an adjustable support structure, a stable mount, and a drape.
In many embodiments, the support is configured to couple to surgical forceps configured to engage tissue with pinching motion. The support may be configured to couple to a proximal end of the surgical forceps. The surgical forceps may comprise one or more of Adson forceps or Bonney forceps. The apparatus may weigh less than 45 grams. The apparatus may further comprise a coupling to couple the suture package and the needle receptacle to a proximal portion of the surgical tool. The apparatus may further comprise a suture package holder configured to support one or more suture packages. The suture package holder may be coupled to a proximal portion of the surgical tool. The needle receptacle and the suture package may be supported on opposite sides of the surgical tool. The suture package holder and the needle receptacle may be supported on a same side of the surgical tool. The coupling may comprise a tool attachment pocket and the proximal portion of the surgical tool may be placed in the tool attachment pocket. The tool attachment pocket may be coupled to the surgical tool with an adhesive layer. The apparatus may comprise two suture packages coupled to the proximal portion of the surgical tool. The needle receptacle may be sandwiched between the two suture packages.
In many embodiments, the apparatus further comprises a tool holder mounted on the support for holding a needle driver.
In many embodiments, the apparatus further comprises a tool holder mounted on the support for holding scissors.
In many embodiments, the needle receptacle is configured to contain both ends of a dispensed suture needle placed into the needle receptacle.
In many embodiments, the needle receptacle comprises a mechanism that compresses a component of the needle receptacle against a tip of a dispensed suture needle placed into the needle receptacle.
In many embodiments, the needle receptacle comprises a tapered structure that guides a tip of a dispensed suture needle into the needle receptacle.
In many embodiments, the needle receptacle comprises a tapered structure that guides a portion of a dispensed suture needle into the needle receptacle.
In many embodiments, the portion of the dispensed suture needle is a tip of the needle.
In many embodiments, the needle receptacle comprises a foam material shaped to contact a tip of a dispensed suture needle placed into the needle receptacle.
In many embodiments, the needle receptacle comprises a door coupled to a lever for opening and closing the door.
In many embodiments, the needle receptacle weighs less than 45 grams.
In many embodiments, the needle receptacle comprises a plurality of channels for storing the plurality of dispensed suture needles. The needle receptacle may further comprise a power source, a first conductor electrically coupled to the power source, and a first visual indicator electrically coupled between the power source and a second conductor. The first visual indicator may indicate the presence of a first dispensed suture needle in a first channel of the plurality of channels when the first dispensed suture needle is placed in contact with both the first conductor and the second conductor. The power source may comprise a battery. The first visual indicator may comprise a first light. The needle receptacle may further comprises a second visual indicator electrically coupled between the power source and a third conductor. The second visual indicator may indicate the presence of a second used needle in a second channel of the plurality of channels when the second used needle is placed in contact with both the second conductor and the third conductor. The second visual indicator may comprise a second light. The needle receptacle may further comprise numerical markings for the plurality of channels.
In many embodiments, the needle receptacle is configured to render innocuous both ends of the suture needle when placed in the receptacle. The needle receptacle may comprise a structure to view the needle with both ends rendered innocuous.
In many embodiments, the needle receptacle is configured to receive the suture needle and to stabilize the surgical needle within the needle receptacle on a needle receptacle support. The needle receptacle support may comprise one or more of a magnet, an adhesive, or a deflectable material to stabilize the suture needle.
In many embodiments, the needle receptacle is configured to receive the suture needle with sliding movement and corresponding resistance to the sliding movement in order to stabilize the surgical needle within the needle receptacle.
In many embodiments, the needle receptacle comprises a transparent cover to view a plurality of suture needles rendered innocuous therein. The needle receptacle may comprise an opening to place the plurality of suture needles within the suture needle receptacle.
In many embodiments, the needle receptacle comprises a structured array to arrange a plurality of needles along the array for counting.
Aspects of the present disclosure may provide methods for securing of a suture needle by a surgeon. A suture needle may be inserted into an opening of a needle receptacle with a needle driver. The suture needle may be rotated inside the needle receptacle to insert an end of the needle into a material. The suture needle may be released from the needle driver. With the inserting step, the needle may be translated away from a leading end. With the rotating step, a trailing end of the needle may be inserted into the deformable structure. The material may comprise one or more of a deformable material, an adhesive material or an elastic material. The material may comprise one or more of a foam, elastic membrane, or an adhesive.
Aspects of the present disclosure provide methods for securing of a suture needle by a surgeon. A suture needle may be inserted into an opening of a needle receptacle with a needle driver. The suture needle may be secured inside the needle receptacle. The suture needle may be released from the needle driver. The needle receptacle may be configured to store a plurality of suture needles.
In many embodiments, the needle receptacle is located within a near surgical field.
In many embodiments, the needle receptacle comprises an entry zone and a secure zone. The inserting step may comprise placing the suture needle on the entry zone of the needle receptacle. The securing step may comprise sliding the suture needle from the entry zone into a needle slot in the secure zone.
In many embodiments, the needle receptacle is coupled to a second needle receptacle. The method may further comprise steps of placing a second suture needle on a second entry zone of the second needle receptacle, and sliding the second suture needle from the second entry zone into a second secure zone of the second needle receptacle.
In many embodiments, the secure zone comprises a needle driver slot and the inserting step comprises moving a distal portion of the needle driver along the needle driver slot to place the suture needle in the secure zone.
In many embodiments, the secure zone comprises a compressive member that compresses against at least a portion of the suture needle during the securing step.
In many embodiments, the secure zone comprises a compressive member that applies a force against at least a portion of the suture needle during the securing step.
In many embodiments, secure zone comprises a plurality of protrusions that extend into the needle slot. The securing step may comprise moving the suture needle against a plurality of protrusions in the secure zone.
In many embodiments, the method may further comprise steps of detecting the suture needle placed into the needle receptacle, determining a number of suture needles disposed within the needle receptacle, and displaying the number of the sutures needles disposed within the needle receptacle on a visual display. The needle receptacle may comprise a first conductor and a second conductor that are electrically coupled to a power source. The suture needle may be disposed within the needle receptacle is in contact with both the first conductor and the second conductor. The detecting step may comprise measuring an electrical current through the first conductor and the second conductor.
In many embodiments, securing step may comprises a step of rotating a first suture needle within the needle receptacle so that an end of the suture needle is pressed into a first surface of a first structure mounted to the needle receptacle. The first structure may comprise one or more of a deformable material, an adhesive material or elastic structure, the first structure comprising one or more of a foam, elastic membrane, or an adhesive. The needle receptacle may comprise an offset zone between the opening and the first structure. During the insertion step, the first suture needle may be moved through the offset zone before performing the rotating step. The method may further comprise steps of inserting a second suture needle through the opening of the needle receptacle with the needle driver and rotating the second suture needle within the needle receptacle so that an end of the second suture needle is pressed into a second surface of the first structure mounted to the needle receptacle. The first suture needle may be rotated in a clockwise direction about a longitudinal axis of the needle driver. The second suture needle may be rotated in a counterclockwise direction about the longitudinal axis of the needle driver. The first structure may comprise one or more of a foam or an adhesive or a deformable material.
In many embodiments, the method further comprises steps of viewing the suture needle through a wall of the needle receptacle, wherein the wall is transparent, and counting suture needles disposed within the needle receptacle. The needle receptacle may be mounted on a proximal portion of a surgical tool.
Aspects of the present disclosure provide needle receptacles. An exemplary needle receptacle may comprise a lower structure, an upper structure, a needle slot, and a needle driver slot. The lower structure may have an entry zone and a secure zone. The upper structure may have a secure zone. The needle slot may be for receiving one or more suture needles between the lower structure and the upper structure. The needle driver slot may extend through a portion of the upper structure.
In many embodiments, the needle driver slot is perpendicular to the needle slot.
In many embodiments, a long axis of the needle driver slot is perpendicular to a long axis of the needle slot.
In many embodiments, the needle driver slot extends through a portion of the lower structure.
In many embodiments, the needle receptacle further comprises a compressible member that is adjacent to the needle slot.
In many embodiments, the needle receptacle further comprises a plurality of protrusions that are adjacent to the needle slot.
In many embodiments, the needle receptacle further comprises comprising a needle counting mechanism configured to detect a number of suture needles disposed in the secure zone of the needle receptacle.
In many embodiments, the needle receptacle further comprises a power source, a first conductor electrically coupled to the power source, a second conductor electrically coupled to control circuitry, and a visual display electrically coupled to the control circuitry. The visual display may indicate the number of suture needles disposed in the secure zone when the suture needles are placed in contact with both the first conductive element and the second conductive element.
In many embodiments, the needle receptacle is coupled to a second needle receptacle through a coupling in direct contact with both the needle receptacle and the second needle receptacle. The coupling may comprise a tool slot adapted to fit over a proximal end of a surgical tool.
In many embodiments, the needle receptacle further comprises a camera for obtaining a photographic image of the suture needle in the secure zone. The needle receptacle may further comprise a transmitter for transmitting the photographic image of the suture needle to a receiver.
In many embodiments, the needle receptacle may further comprise a camera for obtaining a photographic image for the presence of the suture needle in the secure zone. The needle receptacle may further comprise a transmitter for transmitting the photographic image for the presence of the suture needle to a receiver.
Another exemplary needle receptacle may comprise a housing having an opening and an interior volume and a first elongated member coupled to an interior surface of the housing. The first elongated member may have a needle insertion surface that extends inward from the interior surface of the housing.
In many embodiments, the first member comprises one or more of a deformable material, an adhesive material, or elastic structure. The deformable material may comprise one or more of a foam, elastic membrane, or an adhesive. The interior volume may be substantially cylindrical. The first deformable member may extend from the interior surface substantially radially inward into the interior volume.
In many embodiments, the needle receptacle may further comprise a second elongated member coupled to the interior surface of the housing. The first member and the second deformable member may be on opposite sides of the interior surface of the housing. The second member may comprise one or more of a deformable material, an adhesive material, or elastic structure. The first member may comprise one or more of a foam, elastic membrane, or an adhesive.
In many embodiments, the opening comprises an elongated slot that is longer than a length of the needle.
In many embodiments, the housing is transparent.
Aspects of the present disclosure provide apparatuses for protecting a limb of a surgeon from contact with a needle. An exemplary apparatus may comprise a barrier having a curved cross section and a coupling to couple the barrier to the limb of the surgeon. The barrier may be configured to support one or more of a suture package or a needle receptacle.
In many embodiments, the apparatus further comprises a barrier mount. The barrier mounting base may be configured to support one or more of a suture package or a needle receptacle. The barrier may be configured to support the barrier mount.
In many embodiments, the barrier comprises a sterile barrier and the coupling comprises a sterile coupling.
In many embodiments, the barrier comprises an extension sized to extend over a dorsal side of a hand of a surgeon. The extension may comprise a stiffness to support one or more of a suture package or a needle receptacle.
In many embodiments, the barrier comprises an extension sized to extend over a dorsum of a hand of a surgeon. The extension may comprise a deflection to allow movement of the hand to a dorsal radial side of the surgeon.
In many embodiments, the barrier comprises an extension sized to extend over a hand of a surgeon.
In many embodiments, the coupling comprises one or more of a first leg or a second leg.
In many embodiments, the coupling comprises a first leg and a second leg. The first leg may extend outward from a distal portion of the barrier in a first direction. The second leg may extend outward from the distal portion of the barrier in a second direction that is opposite to the first direction.
In many embodiments, the coupling comprises a plurality of proximal legs.
In many embodiments, the coupling comprises one or more slap bracelets.
In many embodiments, the coupling comprises a strap configured to wrap around a portion of a forearm of the surgeon. The strap may be coupled to opposite edges of the barrier.
In many embodiments, the coupling comprises a thumb loop disposed on a distal portion of the barrier. The thumb loop may be configured to couple to a thumb of the surgeon. The thumb loop may be made of a flexible material. The thumb loop may be formed in the barrier.
In many embodiments, the barrier may comprise a malleable material configured to deform to curve around the limb. The barrier may comprise a plurality of grooves extending in a parallel to a length of the limb. The barrier may comprise an inner foam layer configured to be compressed against the limb. The barrier may be configured to support a needle receptacle on a volar portion of the barrier. The barrier may be configured to support a suture package with one or more of a volar or a radial portion of the barrier. The dorsal portion of the barrier may comprise a tool holder.
In many embodiments, the barrier comprises the curved cross section in a free standing configuration.
In many embodiments, the barrier comprises a curved thermoformed barrier material.
Aspects of the present disclosure may provide a method comprising the steps of providing a needle receptacle comprising a housing having a needle slot and a needle driver slot wherein the needle driver slot intersects a side portion of the needle slot, grasping an end portion of a suture needle with a needle driver, moving the suture needle along the needle slot by sliding the needle driver along the needle slot, and releasing the suture needle within the needle slot.
In many embodiments, the needle driver moves through the needle driver slot in a straight path or a spiral path.
In many embodiments, the needle driver moves through the needle driver slot in a circular path.
In many embodiments, the method further comprises steps of providing a compressive member adjacent to the needle slot and compressing the compressive member against the needle.
In many embodiments, the method further comprises steps of applying a rotational torque about a center axis to the needle driver.
In many embodiments, the method further comprises steps of viewing the end portion of the needle within the needle driver slot and determining a number of the needles within the needle receptacle based upon the viewing step.
In many embodiments, the method further comprises steps of detecting the suture needle placed into the needle slot, determining a number of the needles within the needle receptacle, and displaying the number of the needles within the needle receptacle on a visual display.
In many embodiments, the method further comprises steps of providing a barrier and coupling the needle receptacle to the barrier.
In many embodiments, the barrier is adapted to be placed on a limb of a surgeon.
In many embodiments, the coupling of the needle receptacle to the barrier is via a magnetic coupling or a hook and loop coupling.
In many embodiments, the method further comprises steps of providing one or more straps that extend from the barrier. The straps may be adapted to secure the barrier to a limb of a surgeon.
Aspects of the present invention may provide needle receptacles. An exemplary needle receptacle may comprise a housing, a needle slot, a first needle driver slot, and a second needle driver slot. The housing may have a cross section having a width and a thickness. The needle slot may be for storing used suture needles within the cross section of the housing. The first needle driver slot may extend through the thickness of the housing. The first needle driver slot may intersect a side portion of the needle slot. The needle driver slot may extend through a portion of the upper structure.
In many embodiments, the needle driver slot is substantially perpendicular to the needle slot.
In many embodiments, the needle driver slot has a circular portion or a spiral portion.
In many embodiments, the needle receptacle further a compressible member that is adjacent to the needle slot.
In many embodiments, the needle receptacle further comprises a needle counting mechanism for detecting a number of needles in the needle receptacle. The needle receptacle may further comprise a power source and a visual display electrically coupled to needle counting circuitry. The visual display may indicate a number of needles in the needle receptacle.
In many embodiments, the needle receptacle further comprises a barrier, and the needle receptacle is attached to the barrier. The needle receptacle may further comprise a suture pack holder for holding suture packs attached to the barrier. The needle receptacle may further comprise one or more straps that extend from side of the barrier adapted to secure the barrier to a limb of a surgeon.
Aspects of the present disclosure may provide an apparatus for handling suture needles, the apparatus comprising a support configured to receive a suture package and a needle receptacle.
Aspects of the present disclosure may provide an apparatus for handling suture needles, the apparatus comprising a platform to attach a suture package and a used needle holder.
Aspects of the present disclosure may provide an apparatus for handling suture needles, the apparatus comprising a platform to attach a suture package and a used needle receptacle.
Aspects of the present disclosure may provide an apparatus for receiving a plurality of contaminated surgical suture needles, each needle having a tip, a trailing end and a needle body extending between the tip and the trailing end. The apparatus may comprise a housing having a top and a bottom, at least one opening between the top and the bottom configured and dimensioned to receive a contaminated surgical needle inserted therethrough, a window, and an innocuous zone within the housing to hold the plurality of contaminated surgical needles in an arrangement for counting through the window with each tip and trailing end.
Aspects of the present disclosure may provide an apparatus for receiving a contaminated surgical suture needle, the needle having a tip, a trailing end and a needle body extending between the tip and the trailing end. The apparatus may comprise a housing having a top and a bottom, at least one opening between the top and the bottom configured and dimensioned to receive a contaminated surgical needle inserted therethrough, and a secure zone within the housing to hold the contaminated surgical needle in an orientation with the needle tip secured.
In many embodiments, the orientation comprises a predetermined orientation.
In many embodiments, the at least one opening is configured and dimensioned to receive the contaminated surgical needle in a lateral orientation.
In many embodiments, wherein the at least one opening is configured and dimensioned to receive the contaminated surgical needle in a transverse orientation.
In many embodiments, the surgical needle is a curved needle and at least a portion of the curved needle body enters the opening before the tip or the trailing end thereof.
In many embodiments, the apparatus further comprises a first side connected to and extending between the top and the bottom, a second side connected to and extending between the top and the bottom, a first end, and a second end. The at least one opening may be disposed in the first end.
In many embodiments, the top and bottom are circular in shape.
In many embodiments, the secure zone is configured and dimensioned to receive a plurality of contaminated surgical needles.
In many embodiments, at least a portion of the top is sufficiently transparent to permit visualization of contaminated needles disposed in the secure zone.
In many embodiments, the apparatus includes a window permitting inspection and counting of a plurality of contaminated surgical needles contained therein. The plurality of contaminated surgical needles may comprise at least five surgical needles.
In many embodiments, the housing top includes a slot configured and dimensioned to receive a tip of a needle driver, facilitating insertion of the contaminated surgical needle into the housing under control of the needle driver.
In some embodiments, the slot is offset to view a trailing end of the needle.
In some embodiments, the slot is linear.
In some embodiments, the slot is curved.
In some embodiments, the slot is straight and is oriented along the center of the top.
In some embodiments, the slot is straight and is oriented off the longitudinal axis of the top.
In some embodiments, the apparatus comprises a plurality of slots.
In some embodiments, the slot is configured and dimensioned to orient the needle driver into a specific orientation relative to the slot.
In many embodiments, the secure zone includes needle retention features to hold a plurality of contaminated surgical needles in a predetermined orientation.
In many embodiments, the apparatus further comprises needle retention features to hold the contaminated surgical needle between the top and bottom. The needle retention features may comprise foam disposed between the top and bottom, such as urethane foam.
In some embodiments, the needle retention features comprise loop and hook fasteners disposed between the top and bottom.
In some embodiments, the needle retention features comprise a plurality of protrusions extending from one or both of the top and bottom. The plurality of protrusions may comprise dimples, protuberances, or filaments. The plurality of protrusions may be angled away from the at least one opening to permit the needle to pass into the secure zone and to resist movement of the needle toward the at least one opening. The needle retention features may comprise flaps disposed between the top and bottom.
In some embodiments, the needle retention features comprise gel disposed between the top and bottom.
In some embodiments, the needle retention features comprise hemispherical nubs disposed between the top and bottom.
In some embodiments, the needle retention features comprise angled bristles disposed between the top and bottom.
In many embodiments, the apparatus further includes a sterile mounting member attached to the housing for mounting the apparatus in the near surgical field.
In many embodiments, the top and bottom are injection molded.
In many embodiments, the top and bottom snap fit together.
In many embodiments, the top and bottom are welded together, such as ultrasonically welded together.
In many embodiments, the top and bottom are adhesively connected.
In many embodiments, the top surface is comprised of clear polycarbonate.
In many embodiments, the top and bottom are comprised of polycarbonate.
In many embodiments, the apparatus further comprises a slot through the top surface.
In many embodiments, the top and bottom are flexible.
In many embodiments, the top and bottom are rigid.
In many embodiments, one or both of the top and bottom define an entry zone, a transition zone, and a secure zone. The entry zone may define a landing zone which is wider than the entry zone to facilitate movement of the needle toward the entry zone. The entry zone may include at least one structure to urge a needle driver holding a contaminate needle toward a slot in the top surface. The structure may include a V-shaped entry edge of the entry zone.
In many embodiments, the apparatus may further comprise a sterile package containing the apparatus.
In many embodiments, the apparatus may further include a sterile mounting member attached to the housing for mounting the apparatus in the near surgical field. The mounting apparatus may comprises a barrier configured and dimensioned to be mounted to a forearm of a surgeon. The barrier may be configured and dimensioned to support a sterile package of surgical needles and sutures.
In many embodiments, the innocuous zone within the housing is configured to hold the plurality of contaminated surgical needles in an arrangement for counting through the window with either of each tip and trailing end beneath the window.
Aspects of the present disclosure may provide an apparatus comprising one or more of a sterile surgical gown, a sterile glove, or a sterile cover configured with a barrier to inhibit needle sticks and a surface configured to stably support one or more of a suture pack or a needle receptacle over one or more of a hand, a radial forearm or a volar forearm.
Aspects of the present disclosure may provide an apparatus comprising one or more of a sterile surgical gown, a sterile glove, or a sterile cover configured with a barrier to inhibit needle sticks and a surface configured to stably support one or more of a suture pack or a needle receptacle over one or more of a hand, a radial forearm, a volar forearm, a dorsal forearm, a ulnar forearm, and wrist.
Aspects of the present disclosure may provide an apparatus comprising one or more of a sterile cover or a sterile drape configured with a barrier to inhibit needle sticks and a surface configured to stably support one or more of a suture pack or a needle receptacle in a near surgical field.
Aspects of the present disclosure may provide a surgical suturing kit comprising a sterile enclosure that may contain a sterile package of sterile sutures and a sterile apparatus for receiving at least one contaminated surgical suture needle.
Aspects of the present disclosure may provide a surgical suturing kit comprising a sterile enclosure that may contain a sterile package of sterile sutures and a sterile apparatus for receiving at least one contaminated surgical suture needle. The needle may have a tip, a trailing end, and a needle body extending between the tip and the trailing end. The sterile apparatus may comprise a sterile housing having a top and a bottom, at least one opening between the top and the bottom configured and dimensioned to receive a contaminated surgical needle inserted therethrough, and a secure zone within the housing to hold the contaminated surgical needle in a predetermined orientation with the needle tip secured.
The surgical kit may further comprise a barrier configured and dimensioned to support the package of sterile sutures and the apparatus for receiving the at least one contaminated surgical suture needle.
The barrier layer may be configured and dimensioned to be mounted to a forearm of a surgeon.
Aspects of the present disclosure may provide a method comprising a step of placing a needle in a used needle holder.
Aspects of the present disclosure may provide an apparatus comprising a used needle holder.
Aspects of the present disclosure may provide an apparatus comprising means for securing a used needle.
Aspects of the present disclosure may provide an apparatus for handling sutures, comprising a sterile housing, a suture dispensing portion disposed within the housing, the suture dispensing portion configured to support one or more sterile suture needles, and a needle receptacle portion disposed within the housing, the needle receptacle portion configured to secure a plurality of dispensed suture needles.
Aspects of the present disclosure may provide an apparatus comprising needle receptacle means for stabilizing and rendering innocuous a dispensed needle.
Aspects of the present disclosure may provide an apparatus comprising needle receptacle means for stabilizing and rendering innocuous a dispensed needle and barrier means for supporting the needle receptacle means in order to place dispensed needles in the needle receptacle means.
Aspects of the present disclosure may provide an apparatus comprising needle receptacle means for stabilizing and rendering innocuous a dispensed needle and a barrier means for supporting the needle receptacle means in order to place dispensed needles in the needle receptacle means.
Aspects of the present disclosure may provide an apparatus for use in a sterile operating room. The apparatus may comprise a dispensed needle receptacle, a suture package, and a barrier to support one or more of the dispensed needle receptacle or the suture package and inhibit needle penetration through the barrier. The dispensed needle receptacle, the suture package, and the barrier may be arranged within a near surgical field of a surgeon.
The apparatus may comprise a barrier mounting base to support one or more of the dispensed needle receptacle or the suture package and inhibit needle penetration through the barrier. The barrier may be to support the barrier mounting base.
Aspects of the present disclosure may an apparatus for use in a sterile operating room comprising a dispensed needle receptacle comprising five or more dispensed surgical needles. The dispensed surgical needles may be stabilized and innocuous within the needle receptacle. The needle receptacle may comprise one or more of an opening, a window, or a transparent material for counting the stabilized innocuous dispensed needles. The needles may be arranged for counting within the receptacle.
Aspects of the present disclosure may provide a method of securing dispensed needles, comprising a step of receiving a dispensed needle receptacle comprising five or more dispensed surgical needles from a neutral zone. The dispensed surgical needles may be stabilized and innocuous within the needle receptacle. The needle receptacle may comprise one or more of an opening, a window, or a transparent material for counting the stabilized innocuous dispensed needles. The needles may be arranged for counting within the receptacle.
Aspects of the present disclosure may provide a method of securing dispensed needles comprising a step of receiving a dispensed needle receptacle comprising five or more dispensed suture needles from a neutral zone. The dispensed surgical needles may be stabilized and innocuous within the needle receptacle. The needle receptacle may comprise one or more of an opening, a window, or a transparent material for counting the stabilized innocuous dispensed needles. The needles may be arranged for counting within the receptacle.
Aspects of the present disclosure may provide a method of securing dispensed needles comprising a step of receiving a dispensed needle receptacle comprising five or more dispensed suture needles from a near surgical field. The dispensed surgical needles may be stabilized and innocuous within the needle receptacle. The needle receptacle may comprise one or more of an opening, a window, or a transparent material for counting the stabilized innocuous dispensed needles. The needles may be arranged for counting within the receptacle.
Aspects of the present disclosure may provide a method of securing dispensed needles comprising steps of inserting a suture needle into an opening of a needle receptacle with a needle driver and releasing the dispensed needle from the needle driver. The needle receptacle may be configured to store a plurality of five or more dispensed needles. The dispensed needle may be stabilized, innocuous, and arranged with four or more stabilized innocuous dispensed needles for counting in the container though one or more of a channel, an opening, a window, or a transparent material.
Aspects of the present disclosure may provide an apparatus for handling needles. The apparatus may comprise a suture package configured to dispense a plurality of needles, a needle receptacle configured to store a plurality of dispensed needles, and a support configured to support one or more of the suture package or the needle receptacle.
Aspects of the present disclosure may provide a method for handling suture needles. The method may comprise steps of grasping a needle with a needle driver to dispense the needle from a suture package mounted on a support and placing the dispensed needle into a needle receptacle mounted on the support.
The apparatuses or method disclosed herein may comprise a barrier comprising a weight of no more than about 6 ounces (170 grams) and a needle receptacle comprising a capacity of at least about 5 needles, an overall thickness of no more than about 0.5 inches (12.5 mm), a length of no more than about 5″ (127 mm), and a width of no more than about 2.5″ (63.5 mm) to receive and store the at least about 8 needles in a linear array.
The apparatuses or method disclosed herein may comprise a barrier comprising a weight of no more than about 6 ounces (170 grams) and a needle receptacle comprising a capacity of at least about 5 needles, an overall thickness of no more than about 0.5 inches (12.5 mm), a length of no more than about 5″ (127 mm), and a width of no more than about 2.5″ (63.5 mm) to receive and store the at least about 5 needles in a linear array or an arcuate array.
The apparatuses or method disclosed herein may comprise a barrier comprising a weight of no more than about 6 ounces (170 grams) and a needle receptacle comprising a capacity of at least about 8 needles, an overall thickness of no more than about 0.5 inches (12.5 mm), a length of no more than about 5″ (127 mm), and a width of no more than about 4″ (101.6 mm) to receive and store the at least about 8 needles in an arcuate array.
The apparatuses or method disclosed herein may comprise a barrier comprising a weight of no more than about 6 ounces (170 grams) and a needle receptacle comprising a capacity of at least about 8 needles, an overall thickness of no more than about 0.5 inches (12.5 mm), a length of no more than about 5″ (127 mm), and a width of no more than about 4″ (101.6 mm) to receive and store the at least about 8 needles in a linear array.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may comprise a channel having an elongate cross section sized to receive a plurality of suture needles in an ordered array and a slot extending into the channel to receive a needle driver and advance a suture needle of the plurality along the channel for placement among the plurality of needles of the ordered array.
The apparatuses, methods, and needle receptacle disclosed herein may further comprise one or more of a sterile surgical gown, a sterile glove, or a sterile cover configured with a barrier to inhibit needle sticks and a surface configured to stably support one or more of a suture pack or a needle receptacle over one or more of a hand, a radial forearm or a volar forearm.
In the apparatuses, methods, and needle receptacle disclosed herein, one or more of a sterile cover or a sterile drape may be configured with a barrier to inhibit needle sticks and a surface configured to stably support one or more of a suture pack or a needle receptacle.
The apparatuses, methods, and needle receptacle disclosed herein may enable passing of a plurality of suture needles into and out of a near surgical field, thereby eliminating passing of individual suture needles between a surgeon and a surgical assistant.
The apparatuses, methods, and needle receptacle disclosed herein may enable passing of a plurality of secured into and out of a near surgical field, thereby eliminating passing of individual suture needles between a surgeon and a surgical assistant.
The apparatuses, methods, and needle receptacle disclosed herein may enable passing of a plurality of innocuous needles into and out of a near surgical field, thereby eliminating passing of individual suture needles between a surgeon and a surgical assistant.
The apparatuses, methods, and needle receptacle disclosed herein may enable passing of a plurality of used needles into and out of a near surgical field, thereby eliminating passing of individual suture needles between a surgeon and a surgical assistant.
The apparatuses, methods, and needle receptacle disclosed herein may comprise a step of dispensing of a suture needle by a surgeon from a near surgical field.
The apparatuses, methods, and needle receptacle disclosed herein may comprise a means for mounting one or more suture needle packages within a near surgical field.
The apparatuses, methods, and needle receptacle disclosed herein may comprise a needle resistant barrier mounted on a surgeon's arm. The needle resistant barrier may be configured to provide a mounting surface for one or more suture needle packages.
In the apparatuses, methods, and needle receptacle disclosed herein, a needle resistant barrier may comprise a light weight material and may be configured to conform to one or more of a surgeons arm, wrist, or hand.
In the apparatuses, methods, and needle receptacle disclosed herein, a needle resistant barrier may comprise a thin, puncture-resistant material integrated with a flexible web.
In the apparatuses, methods, and needle receptacle disclosed herein, a needle resistant barrier may be configured to adjust in order to accommodate a range of forearm sizes.
In the apparatuses, methods, and needle receptacle disclosed herein, a needle resistant barrier may comprise a plurality of bi-stable springs connected by a flexible web.
In the apparatuses, methods, and needle receptacle disclosed herein, a needle resistant barrier may comprise a malleable metal material having one or more grooves to control bending of the malleable metal material.
In the apparatuses, methods, and needle receptacle disclosed herein, a needle resistant barrier may comprise a plastic material having one or more hinges.
In the apparatuses, methods, and needle receptacle disclosed herein, a needle resistant barrier may be configured to be donned and doffed quickly with one hand.
In the apparatuses, methods, and needle receptacle disclosed herein, a needle resistant barrier may comprise a plurality of stacked bi-stable springs to adjust a compressive force.
In the apparatuses, methods, and needle receptacle disclosed herein, a needle resistant barrier may be configured to provide a modular mounting surface on a dorsal side of one or more of a forearm or a wrist. The modular mounting surface may be configured to support one or more surgical tools or materials.
In the apparatuses, methods, and needle receptacle disclosed herein, a suture needle package may be configured to mount on one or more of a surgeon's arm, wrist, or a back of a hand.
In the apparatuses, methods, and needle receptacle disclosed herein, a suture needle package may be configured to mount on the needle receptacle.
In the apparatuses, methods, and needle receptacle disclosed herein, a needle resistant barrier may be configured to provide protection to a volar side of one or more of a forearm or a wrist.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may be configured to couple to a surgical drape.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may be configured to couple to a needle resistant barrier mounted on a surgeon's forearm.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may be configured to attach and detach from a needle resistant barrier with one hand.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may be configured to attach to a surgical tool
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may be configured to attach to a surgical tool, and the needle receptacle may be configured to accommodate a variety of handle widths and thicknesses of a surgical tool.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may be configured to couple to a needle resistant barrier integrated into a surgical apparel.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may be configured to couple to a needle resistant barrier integrated into a surgical gown, a gown sleeve, or an extended glove.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may be configured to provide protection from both leading and trailing ends of a plurality of used suture needles by one or more of encapsulating or covering.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may be configured to inhibit one or more of unintentional removal or dislodgment.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may be configured to facilitate needle insertion into the needle receptacle by allowing needles to be inserted with minimal hand-eye precision.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may be configured to facilitate needle insertion into the needle receptacle by allowing needles to be inserted with gross motor movement.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may be configured to facilitate needle insertion into the needle receptacle by allowing needles to be inserted with only articulation or rotation of the shoulder and elbow joints.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may comprise means for counting needles during and after the procedure.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may comprise means for reconciling needles during or after the procedure.
In the methods disclosed herein, a first set of needles from a first suture pack may be reconciled before a second suture pack enters the near surgical field.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle is low-profile and lightweight.
In the apparatuses, methods, and needle receptacle disclosed herein the needle receptacle may be configured to receive needles held in needle drivers in various positions.
In the apparatuses, methods, and needle receptacle disclosed herein the needle receptacle may be is configured to inhibit magnetizing the needle driver.
In the apparatuses, methods, and needle receptacle disclosed herein the needle receptacle may be is configured to receive at least about 5 needles.
The apparatuses, methods, and needle receptacle disclosed herein may further comprise a step of cutting of a suture by a surgeon using a cutter disposed in a near surgical field.
In the apparatuses, methods, and needle receptacle disclosed herein, a cutter may be mounted on a surgeon's finger.
In the apparatuses, methods, and needle receptacle disclosed herein, a cutter may be mounted on a needle resistant barrier.
In the apparatuses, methods, and needle receptacle disclosed herein, a cutter may comprise retractable scissors on a cable with take up spool.
In the apparatuses, methods, and needle receptacle disclosed herein, a cutter may comprise an integrated and recessed blade.
In the apparatuses, methods, and needle receptacle disclosed herein, a cutter may be mounted on a surgical tool.
In the apparatuses, methods, and needle receptacle disclosed herein, a cutter may comprise may be integrated with a needle receptacle.
In the apparatuses, methods, and needle receptacle disclosed herein, a cutter may comprise may be configured to prevent unintentional damage to a surgeon's glove.
In the apparatuses, methods, and needle receptacle disclosed herein, the needle receptacle may be arranged over the volar forearm to allow easy insertion of a used needle when a hand holding needle holder is slightly pronated. The needle may be placed in the receptacle with rotation of an arm holding a needle driver with shoulder joint rotation in order to align and place the used needle into an opening of the needle receptacle. The needle may comprise a curved needle having a tip and a tail, and the length may be defined as a straight-line distance between the tip and the tail.
In many embodiments of the barrier, curved shell conforms to the shape of a volar surface of the forearm.
In many embodiments of the barrier, the curvature of the curved shell extending with curvature about the longitudinal axis conforms to a shape of a volar surface of the forearm.
In many embodiments of the barrier, the pre-formed shaped barrier conforms to the shape of a volar surface of the forearm.
In many embodiments of the barrier, the pre-formed shaped barrier is straight along the dorsal edge.
In many embodiments of the barrier, the curved shell is straight along the dorsal edge.
Aspects of the present disclosure may provide needle receptacles. An exemplary needle receptacle may comprise a lower structure and an upper structure above the lower structure to define a needle slot between the upper structure and the lower structure. The needle slot may comprise a secure zone to secure needles. The upper structure may comprise a first edge and a second edge arranged to define a deformable needle driver slit that extends through a portion of the upper structure, wherein the slit deforms to receive a needle driver.
Another exemplary needle receptacle may comprise a housing having a cross section having a width and a thickness, a needle slot for storing used suture needles within the cross section of the housing, and a deformable needle driver slot that extends through a portion of the upper structure.
Another exemplary needle receptacle may be for receiving a surgical suture needle, the needle having a tip, a trailing end and a needle body extending between the tip and the trailing end. The needle receptacle may comprise a housing, at least one opening, a secure zone, and a deformable driver needle slit. The housing may have a top and a bottom. The at least one opening between the top and the bottom may be configured and dimensioned to receive a surgical needle therethough. The secure zone within the housing may be configured to hold the surgical needle in an orientation with the needle tip secured. The secure zone may be in communication with the opening. The deformable needle driver slit may extend through the top of the housing and within the secure zone.
In many embodiments, the first edge separates from the first edge to receive the needle driver.
In many embodiments, the deformable needle driver slit includes a first edge and a second edge opposite the first edge.
In many embodiments, the first edge and the second edge contact each other in a non-deformed free standing state without a needle driver extending therebetween.
In many embodiments, the first edge and the second edge are spaced apart from each other in a non-deformed state, with a gap being defined between the first edge and the second edge.
In some embodiments, the gap is less than 1 mm.
In some embodiments, the gap is less than 2 mm.
In some embodiments, the gap is less than 0.5 mm.
In some embodiments, the upper structure comprises a stiff portion and a deformable portion, with the deformable portion being proximate to and including the needle driver slit.
In some embodiments, the upper structure is deformable.
In some embodiments, the lower structure is deformable.
In some embodiments, the upper structure and lower structure are both deformable.
In some embodiments, the lower structure comprises a landing zone, and the upper and lower structures define an entry zone and a second zone, the entry zone located between the landing zone and the secure zone and wherein separation of the slit increases proximate a needle driver when the needle driver advances along the slit.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, a portion of a needle body is visible through the needle driver slot.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, a mid-body portion a needle body is visible through the needle driver slot.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, a portion of a needle body is visible through the needle driver slot in the upper structure.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, a mid-body portion a needle body is visible through the needle driver slot visible through the needle driver slot in the upper structure.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, a portion of a needle body is visible through the needle driver slot in the lower structure.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, a mid-body portion a needle body is visible through the needle driver slot visible through the needle driver slot in the lower structure.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, a portion of a needle body is visible through both the needle driver slot in the lower structure and the needle driver slot in the upper structure.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, a mid-body portion a needle body is visible through the needle driver slot visible through both the needle driver slot in the lower structure and the needle driver slot in the upper structure.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the lower structure provides for non-uniform light transmission therethrough.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the lower structure comprises a translucent material.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the lower structure comprises a light scattering material selected from the group consisting of a translucent material, a diffuse material, a rough material, and light scattering particles.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the lower structure is semi opaque.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the lower structure is opaque.
In many embodiments, the apparatuses, methods, and needle receptacles disclosed herein may be configured to non-uniformly transmit light.
In many embodiments, the apparatuses, methods, and needle receptacles disclosed herein may be configured to non-uniformly transmit backlight illumination.
In many embodiments, the apparatuses, methods, and needle receptacles disclosed herein may be configured to diffuse light from backlight illumination in order to provide more uniform backlight illumination of suture needles.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the lower structure is dyed.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the lower structure is colored.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the lower structure provides includes a roughened surface for non-uniform light transmission therethrough.
In many embodiments, the apparatuses, methods, and needle receptacles disclosed herein may further comprise a flap extending into or along the needle driver slot from an edge of the needle driver slot.
In many embodiments, the apparatuses, methods, and needle receptacles disclosed herein may further comprise flaps extending into or along the needle driver slot from an edge of the needle driver slot.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the flaps are deformable.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the needle driver slot includes a first edge and a second edge opposite the first edge, and the flaps extend from one of the first and second edges.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the needle driver slot includes a first edge and a second edge opposite the first edge, and the flaps extend from both the first edge and the second edge.
In many embodiments, the apparatuses, methods, and needle receptacles disclosed herein may further comprise flaps extending into the needle driver slit from an edge of the needle driver slot.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the flaps are deformable.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the needle driver slit includes a first edge and a second edge opposite the first edge and wherein the flaps extend from one of the first and second edges.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the needle driver slit includes a first edge and a second edge opposite the first edge, and wherein the flaps extend from both the first edge and the second edge.
In many embodiments, the apparatuses, methods, and needle receptacles disclosed herein may further comprise flaps extending into the needle driver slit from an edge of the needle driver slit.
In many embodiments, the apparatuses, methods, and needle receptacles disclosed herein may further comprise protrusions that extend into the needle driver slot from an edge of the needle driver slot.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the needle driver slot includes a first edge and a second edge opposite the first edge, and wherein the protrusions extend from one of the first and second edges.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the needle driver slot includes a first edge and a second edge opposite the first edge, and wherein the protrusions extend from both the first edge and the second edge.
In many embodiments, the apparatuses, methods, and needle receptacles disclosed herein may further comprise that extend into the needle driver slit from an edge of the needle driver slot.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the needle driver slit includes a first edge and a second edge opposite the first edge, and wherein the protrusion extend from one of the first and second edges.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the needle driver slit includes a first edge and a second edge opposite the first edge, and wherein the protrusions extend from both the first edge and the second edge.
In many embodiments, the apparatuses, methods, and needle receptacles disclosed herein may further comprise protrusions that extend into the needle driver slot from an edge of the needle driver slit.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the resistance of the needle driver along the needle driver slot is less than the resistance of the needle along the needle slot when the needle is advanced along the slot with a needle driver.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the resistance of the needle receptacle against the needle driver is less than the resistance of the needle receptacle against the needle.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the force imparted by the needle driver slot against movement of the needle driver is less than the force imparted by the needle slot against movement of the needle.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the force imparted by the needle receptacle against movement of the needle driver is less than the force imparted by the needle receptacle against movement of the needle.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the friction force between the needle driver slot or slit and the needle driver is less than the friction force between needle slot and the needle.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the friction force between the needle receptacle and the needle driver is less than the friction force between the needle receptacle and the needle.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, a width of the needle driver slot varies along the length of the needle driver slot.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the needle driver slot includes a first edge and a second edge that is opposite the first edge, the first edge and the second edge being separated by a width, and wherein the width varies along the length of the needle driver slot.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the needle driver slot includes a first edge and a second edge that is proximate the first edge, the first edge and the second edge being separated by a width, and wherein the width varies along the length of the needle driver slot.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the needle driver slot has a first end and a second end along a length of the needle driver slot and a width of the needle driver slot at the first end is greater than a width of the needle driver slot at the second end.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the first end is closed and the second end is open for receiving a needle driver therethough.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the needle driver slot has a first end and a second end along a length of the needle driver slot and a width of the needle driver slot at the second end is greater than a width of the needle driver slot at the first end.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the first end of the needle driver slot is closed and the second end of the needle driver slot is open for receiving a needle driver therethough.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the first end of the needle driver slot is proximate the secure zone and the second end of the needle driver slot is proximate the transition zone.
In many embodiments of the apparatuses, methods, and needle receptacles disclosed herein, the first end of the needle driver slot is a greater distance from the entry zone than the second end of the needle driver slot.
In many embodiments, the methods, apparatuses, receptacles, kits, and barriers disclosed herein may further comprise 2-20 tactile bumps along the needle driver slot or the needle slot to facilitate localization into a plurality of zones. The tactile bumps may be sized to engage the needle driver moving along the needle driver slot or the needle moving along the needle slot. Each of the plurality of tactile bumps may define a boundary between adjacent zones in order to decrease bunching of a plurality needles when placed.
In many embodiments, the methods, apparatuses, receptacles, kits, and barriers disclosed herein may further comprise 5-8 tactile bumps along the needle driver slot or the needle slot to facilitate localization into individual zones.
In many embodiments, the methods, apparatuses, receptacles, kits, and barriers disclosed herein may further comprise 5 tactile bumps to facilitate localization into individual zones.
In many embodiments, the methods, apparatuses, receptacles, kits, and barriers disclosed herein may further comprise 3-8 tactile bumps to facilitate localization into individual zones.
In many embodiments, the methods, apparatuses, receptacles, kits, and barriers disclosed herein may further comprise 3-6 tactile bumps to facilitate localization into individual zones.
In many embodiments of the methods, apparatuses, receptacles, kits, and barriers disclosed herein, the tactile bumps are pairs of tactile bumps.
In many embodiments of the methods, apparatuses, receptacles, kits, and barriers disclosed herein, the tactile bumps are arranged along a length of the needle receptacle.
In many embodiments of the methods, apparatuses, receptacles, kits, and barriers disclosed herein, the tactile bumps are arranged along a length of the needle driver slot or needle driver slit.
In many embodiments of the methods, apparatuses, receptacles, kits, and barriers disclosed herein, the tactile bumps are arranged along a length of the needle slot.
In many embodiments of the methods, apparatuses, receptacles, kits, and barriers disclosed herein, the tactile bumps are arranged a first distance from each other along the length. The first tactile bump or bumps may be a second distance from an entrance to the needle slot, the second distance being greater than the first distance.
In many embodiments of the methods, apparatuses, receptacles, kits, and barriers disclosed herein, the needle receptacle is configured to be mounted on a barrier mounting base and the barrier mounting base is configured to be mounted on a barrier. The apparatus, method, or needle receptacle may further comprise a suture pack mounted to the barrier mounting base. The apparatus, method, or needle receptacle may further comprise a suture pack mounted to the needle receptacle. The apparatus, method, or needle receptacle may further comprise a suture pack mounted to the needle receptacle and the barrier mounting base.
In many embodiments of the apparatuses, methods, or needle receptacles disclosed herein, the suture pack is mounted to a barrier mounting base and the barrier mounting base is mounted to a barrier.
In many embodiments, the apparatuses, methods, or needle receptacles disclosed herein may further comprises a needle receptacle mounted to the barrier mounting base.
In many embodiments, the apparatuses, methods, or needle receptacles disclosed herein may further comprise a needle receptacle mounted to the suture pack.
In many embodiments, the apparatuses, methods, or needle receptacles disclosed herein may further comprise a needle receptacle mounted to the suture pack and the barrier mounting base.
In many embodiments, adhesion of the needle receptacle to the mounting base is greater than the adhesion of the mounting base to the barrier.
In many embodiments, adhesion of the mounting base to the barrier is sufficiently weak to allow manual removal of the mounting base from the barrier.
In many embodiments, the adhesion of the needle receptacle to the mounting base is sufficiently weak to allow removal of the needle receptacle from the mounting base.
In many embodiments, adhesion of the suture pack to the mounting base is greater than the adhesion of the mounting base to the barrier.
In many embodiments, adhesion of the suture pack to the needle receptacle is greater than the adhesion of the mounting base to the barrier.
Aspects of the present disclosure may provide a method comprising the steps of orienting a needle with respect to a needle receptacle with the tip of the needle directed away from a direction of translation of the needle and moving a needle in the direction of translation to an entry zone of a needle receptacle and into a secure zone of the needle receptacle.
Aspects of the present disclosure may provide a method of inserting a needle into a needle receptacle. The method may comprise the steps of placing the needle at an entry zone of the needle receptacle coupled to a forearm and moving the needle along the needle receptacle in the direction of translation to secure the needle within a housing of the needle receptacle. The needle may be oriented with respect to a needle receptacle with tips of the needle directed away from a direction of translation of the needle into the needle receptacle.
Aspects of the present disclosure may provide a method for securing of a suture needle by a surgeon. The method may comprise the steps of orienting a suture needle with respect to a needle receptacle with tips of the needle directed away from a direction of translation of the needle, inserting the suture needle into an opening of a needle receptacle with a needle driver by moving the needle in the direction of translation, securing the suture needle inside the needle receptacle, and releasing the suture needle from the needle driver.
In many embodiments, the body of the needle leads the needle tip in the direction of translation.
In many embodiments, wherein the needle receptacle inhibits translation of the needle into the needle slot when the needle tip leads the needle body in the direction of translation.
In many embodiments, a translation force to translate the needle within the needle slot is twice a great when translating the needle with the tip leading the body as compared to translating the needle with the body leading the tip.
In many embodiments, a translation force to translate the needle within the needle slot is greater when translating the needle with the tip leading the body as compared to translating the needle with the body leading the tip.
In many embodiments, a translation force to translate the needle within the needle slot is greater when translating the needle with the tip leading the body as compared to translating the needle with the body leading the tip.
In many embodiments, the direction of translation extends between an entry zone of the needle receptacle and a secure zone of a needle receptacle.
In many embodiments, the direction of translation along a longitudinal axis of a needle receptacle.
In many embodiments, the direction of translation is along a length of a needle driver slot.
In many embodiments, the direction of translation is along a length of a needle driver slit.
In many embodiments, the direction of translation is along a length of a user's forearm.
In many embodiments, the direction of translation extends between a wrist and an elbow of a user's arm.
In many embodiments, the direction of translation is parallel to a length of a needle driver slot or slit.
In many embodiments, the direction of translation starts proximate a user's wrist in a direction towards a user's elbow.
In many embodiments, the direction of translation is towards a secure zone.
In many embodiments, the direction of translation is towards a closed end of a needle driver slot or slit.
In many embodiments, the direction of translation is towards a proximal end of a needle driver slot or slit.
In many embodiments, the direction of translation is away from a landing zone.
In many embodiments, the direction of translation is away from a entry zone.
In many embodiments, the direction of translation is away from transition zone.
Aspects of the present disclosure provide needle receptacles. An exemplary needle receptacle may comprise a flexible upper structure, a flexible lower structure, and a needle driver receiving slot. The flexible upper structure and the flexible lower structure may be coupled to each other to define a needle slot to receive needles. The needle driver receiving slot may be formed through the flexible upper structure extending from the perimeter of the upper flexible sheet material.
Another exemplary needle receptacle may comprise a sheet material, a needle slot, and a needle driver. The sheet material may extend between a first end and a second end and may be folded onto itself at a fold to form an upper structure and a lower structure, the upper structure and lower structure having substantially parallel planar surfaces in a narrow profile configuration. The substantially parallel planar surfaces can extend within about ten degrees of each other, and can extend within about five degrees of parallel to each other. The needle slot may be defined between the upper structure and the lower structure. The needle driver receiving slot may be formed though the upper structure and extending from the first end towards the fold.
Another exemplary needle receptacle may comprise a first flexible sheet material forming an upper structure, a second flexible sheet material forming a lower structure, and a slot formed through the first flexible sheet material and extending from the perimeter of the first flexible sheet material. The first flexible sheet material and the second flexible sheet material may be coupled to each other at their respective perimeters.
In many embodiments, the needle receptacle is mounted to a rigid structure.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 1 pound force applied to the needle tip. The needle may be selected from the group consisting of a tapered suture needle and a cutting suture needle. The force may be selected from the group consisting of at least 2 pounds, at least 3 pounds and at least 4 pounds.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 0.3 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation GS-21 needle.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 0.3 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation CV-23 needle.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 0.3 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation thin bodied half-circle needle.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 0.3 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation medium bodied half-circle needle.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 0.5 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation GS-21 needle.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 0.5 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation CV-23 needle.
In many embodiments, upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 0.5 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation thin bodied half-circle needle.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 1 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation medium bodied half-circle needle.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 1 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation GS-21 needle.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 1 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation CV-23 needle.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 1 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation thin bodied half-circle needle.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 1 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation medium bodied half-circle needle.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 3 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation GS-21 needle.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 3 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation CV-23 needle.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 3 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation thin bodied half-circle needle.
In many embodiments, the upper structure and lower structure comprise sufficient strength to resist puncture with a sharp tip of a needle with at least 3 pound force applied to the tip of the needle. The needle may comprise a United States Surgical Corporation medium bodied half-circle needle.
In many embodiments, the upper structure and lower structure are configured to flex together in order to increase a distance of the needle slot between the upper structure and the lower structure from a first distance in a narrow profile configuration for placement inside sterile packaging to a second distance in an expanded profile configuration outside the sterile packaging with the second distance greater than the first distance in order to receive the needles.
In some embodiments, the first structure contacts the second structure in the narrow profile configuration.
In some embodiments, the first structure contacts the second structure in the narrow profile configuration.
In some embodiments, the first structure and the second structure comprise sufficient thickness to hold the needles between the first structure and the second structure.
In some embodiments, the first structure and the second structure comprise sufficient thickness to secure the needles in a secure zone between the first structure and the second structure.
In some embodiments, the upper structure and lower structure are substantially flat in the narrow profile configuration. The upper structure and lower structure may be curved in the expanded profile configuration.
In some embodiments, the needle receptacle comprises a length, a width, and a height, the length being greater than width and the width being greater than the height. The thickness in the narrow profile configuration may be selected from the group consisting of no more than 5 mm, no more than 4 mm, no more than 3 mm, no more than 2 mm, no more than 1 mm, and no more than 0.5 mm. A difference between the first distance and the second distance may be selected from the group consisting of no more than 3 mm, no more than 2 mm, no more than 1 mm, and no more than 0.5 mm.
In some embodiments, the upper structure and the lower structure each comprise a thickness within a range selected from the group consisting of 0.1 mm to 2.5 mm, 0.2 mm to 2 mm, 0.25 mm to 2 mm and 0.5 mm to 1 mm.
In some embodiments, the receptacle comprises a first side and a second side opposite the first side. The upper structure may be connected to the lower structure at a first coupling region along the first side and a second coupling region along the second side. The needle slot may extend between the first coupling region and the second coupling region. A distance between the first coupling region and the second coupling region may define a width of the needle slot.
In some embodiments, first surface is connected to the second coupling surface along a third coupling region defining an end of the needle slot.
In some embodiments, the needle receptacle comprises a first open end and a second open end opposite the second open end with the needle slot extending between the first open end and the second open end. The first structure and the second structure may comprise sufficient stiffness to secure the needles in the needle slot between the first region and the second region.
In some embodiments, the needle receptacle may further comprise a strip of material along a lower surface of the lower structure to adhere the needle receptacle to a support. The strip of material may be oriented along a long axis with a long axis of the needle slot to allow the lower structure to flex with the upper structure when the distance increases from the first distance to the second distance.
Aspects of the present disclosure may provide sterile kits. An exemplary sterile kit may comprise a sterile packing comprising a sterile barrier, a plurality of needles, and a needle receptacle. The plurality of needles may be contained within a needle package. A tip to tip distance of each of the plurality of needles may be less than a width of the needle slot. The plurality of needles and the needle receptacle may be sterile and contained within the sterile barrier of the sterile kit.
In many embodiments, the tip to tip distance of each of the plurality of needles is within a range selected from the group consisting of 75% to 100% of the width of the needle slot, 80% to 99% of the width of the needle slot, and 85% to 98% of the width of the needle slot and 90 to 97% of the width of the needle slot.
In many embodiments, the tip to tip distance of each of the plurality of needles is within a percentage of the width of the needle slot in the expanded configuration, the percentage within range selected from the group consisting of 75% to 100% of the second width of the needle slot, 80% to 99% of the second width of the needle slot, and 85% to 98% of the second width of the needle slot and 90 to 97% of the second width of the needle slot. The needle slot may comprise a length, a width, and a height, the length being greater than the width and the width being greater than the height.
In many embodiments, the upper structure and the lower structure each comprise a needle driver slot to receive a needle driver.
In many embodiments, the upper structure and lower structure are connected to each other at their respective perimeters.
In many embodiments, the upper structure and lower structure are parallel to each other at their respective perimeters.
In many embodiments, the upper structure and lower structure are adhered to each other at their respective perimeters.
In many embodiments, the upper structure forms an upper portion of a secure zone and a transition zone of the needle receptacle.
In many embodiments, the lower structure forms a lower portion of the secure zone and the transition zone of the needle receptacle.
In many embodiments, the lower structure forms a landing zone of the needle receptacle.
In many embodiments, the lower structure that forms the landing zone of the needle receptacle extends from the transition zone away from the secure zone.
In many embodiments, the needle receptacle has a length that extends between a first end and a second end. The entry zone may include the first end and the secure zone may include the second end. The transition zone may be between the first end and the second end.
In many embodiments, the lower structure of the entry zone is a landing zone configured to receive a needle and a needle driver tip.
In many embodiments, the needle driver slot extends from an edge of the upper structure in the transition zone into the secure zone, partitioning the upper structure and the edge into separate first and second portions within the transition zone.
In many embodiments, first and second portions of the upper structure within the transition zone are deformed towards the lower structure, displacing the upper structure from the lower structure and forming an opening in the needle slot therebetween.
In many embodiments, first and second portions of the upper structure within the transition zone are folded towards the lower structure, displacing the upper structure from the lower structure and forming an opening in the needle slot therebetween.
In many embodiments, first and second portions of the upper structure within the transition zone are folded away from the lower structure, displacing the upper structure from the lower structure and forming an opening in the needle slot therebetween.
In many embodiments, the first and second sheet material is flexible.
In many embodiments, the first and second sheet material chosen from the group consisting of: ABS, polycarbonate, polyethylene, polypropylene, thermoformable plastic, and PETG.
In many embodiments, the kit further comprises at least one needle.
In some embodiments, the needle has a length and the needle slot has a width, the length of the needle being substantially similar to, but less than the width of the needle slot.
In some embodiments, the needle has a length and the needle receptacle has a width, the length of the needle being substantially similar to, but less than the width of the needle receptacle.
In some embodiments, the length of the needle and the width of the needle slot are such that the needle deforms the needle slot when the needle is in the needle slot.
In some embodiments, the length of the needle and the width of the needle slot are such that the upper structure and the lower structure of the needle receptacle apply a compressive force on the needle when the needle is in the needle slot.
In some embodiments, the length of the needle and the width of the needle slot are such that the needle deforms the upper structure and the lower structure when the needle is in the needle slot.
In some embodiments, the needle is a curved needle having a tip and a tail, and the length is defined as a straight-line distance between the tip and the tail.
In some embodiments, the length of the needle is the defined as a straight-line distance between the two ends of the needle.
In some embodiments, the lower structure includes a flap that is foldable over the upper structure to close the needle slot.
In some embodiments, the lower structure includes a flap that is foldable over the upper structure to seal the needle slot.
In some embodiments, the flap includes at least a portion of the lower structure extending beyond the transition zone away from the secure zone.
In some embodiments, the flap includes at least a portion of the entry zone of the lower structure.
In some embodiments, the kit further comprises an adhesive on the flap.
In some embodiments, the adhesive on the flap adheres to the upper structure to close the needle slot.
In some embodiments, the adhesive on the flap adheres to the upper structure to seal the needle slot.
In many embodiments, the apparatuses, methods, needle receptacles, and kits disclosed herein may further comprise a stiff structure configured to receive the needle receptacle. The stiff structure may include an open side shaped to receive the needle receptacle. The stiff structure may include a needle driver slot that aligns with a needle driver slot of the needle receptacle when the needle receptacle is within the stiff structure. The stiff structure may be in the shape of a hexahedron. The stiff structure may include an upper structure coupled to a lower structure, with the stiff structure configured to receive and hold the needle receptacle between the upper structure and the lower structure. The stiff structure may include an upper structure coupled to a lower structure, with the upper structure and lower structure configured to exert a clamping force on the needle receptacle to hold the needle receptacle to the stiff structure. The stiff structure may include an upper structure, a lower structure, and a wall structure, with the wall structure coupling the upper structure and the lower structure together. The stiff structure may comprise a receiver configured to receive the needle receptacle.
The stiff structure may include a first stiff member having first and second ends, a second stiff member extending from the first end of the first stiff member, and a third stiff member extending from the second end of the first stiff and in a same plane as the second stiff member. The stiff structure may be configured to receive a needle receptacle of any of the preceding claims between the second and third stiff members.
In some embodiments, the distance between the second and third member at an end proximate the first member is less than a distance between the second and third member at a distal end such that when the needle receptacle is received within the stiff structure. The second and third members may impart a force on the needle receptacle, deforming the needle receptacle and enlarging an entry to the needle slot of the needle receptacle.
In some embodiments, a width of the needle receptacle at an entry zone is greater than a width of the needle receptacle at a secure zone such that when the needle receptacle is received within the stiff structure. The second and third members may impart a force on the needle receptacle, deforming the needle receptacle and enlarging an entry to the needle slot of the needle receptacle.
Aspects of the present disclosure provide needle receptacles. An exemplary needle receptacle may comprise a first sheet of stiff material forming an upper structure, a second sheet of stiff material forming a lower structure, and a slot formed through the second stiff sheet material and extending from the perimeter of the second stiff sheet material. The first sheet stiff material and the second stiff sheet material may be coupled to each other at their respective perimeters.
In many embodiments, the upper structure and lower structure are parallel to each other at their respective perimeters.
In many embodiments, the upper structure and lower structure are adhered to each other at their respective perimeters.
In many embodiments, the upper structure and lower structure are coupled to each other via walls that extend from the perimeter of the lower structure to the perimeter of the upper structure.
In many embodiments, the lateral opening is configured to receive a needle therethrough.
In many embodiments, the upper structure forms an upper portion of a secure zone and a transition zone of the needle receptacle.
In many embodiments, the lower structure forms a lower portion of the secure zone and the transition zone of the needle receptacle.
In many embodiments, the lower structure forms a landing zone of the needle receptacle.
In many embodiments, the lower structure that forms the landing zone of the needle receptacle extends from the transition zone away from the secure zone.
In many embodiments, the needle receptacle has a length that extends between a first end and a second end. The entry zone may include the first end and the secure zone may include the second end. The transition zone may be between the first end and the second end.
In many embodiments, the lower structure of the entry zone is a landing zone configured to receive a needle and a needle driver tip.
In many embodiments, the needle driver slot extends from an edge of the upper structure in the transition zone into the secure zone, partitioning the upper structure and the edge into separate first and second portions within the transition zone.
In many embodiments, first and second portions of the upper structure within the transition zone are deformed towards the lower structure, displacing the upper structure from the lower structure and forming an opening in the needle slot therebetween.
In many embodiments, first and second portions of the upper structure within the transition zone are folded towards the lower structure, displacing the upper structure from the lower structure and forming an opening in the needle slot therebetween.
In many embodiments, the lower structure includes a flap that is foldable over the upper structure to close the needle slot.
In many embodiments, the lower structure includes a flap that is foldable over the upper structure to seal the needle slot.
In many embodiments, the flap includes at least a portion of the lower structure extending beyond the transition zone away from the secure zone.
In many embodiments, the flap includes at least a portion of the entry zone of the lower structure.
In many embodiments, the needle receptacle further comprises an adhesive on the flap.
In many embodiments, the adhesive on the flap adheres to the upper structure to close the needle slot.
In many embodiments, the adhesive on the flap adheres to the upper structure to seal the needle slot.
In many embodiments, the needle receptacle further comprises one or more needle retainers within the needle slot.
In many embodiments, the needle retainers include at least one magnet.
In many embodiments, the at least one magnet is coupled to one or both of the upper structure and the lower structure.
In many embodiments, the at least one magnet is within one or both of the upper structure and the lower structure.
In many embodiments, the needle retainers include at least one adhesive tab.
In many embodiments, the at least one adhesive tab is coupled to one or both of the upper structure and the lower structure.
In many embodiments, the at least one adhesive tab extends into the needle slot from one or both of the upper structure and the lower structure.
In many embodiments, the at least one adhesive tab includes opposite first and second sides, the first side facing an opening in the needle slot and being non-adhesive and the second side facing away from the opening in the needle slot and being adhesive.
In many embodiments, the needle retainer include a compliant material within the needle slot.
In many embodiments, the compliant material includes a first foam structure that extends from the lower structure towards the upper structure and applies a retention force to the upper structure through a needle within the needle slot to retain the needle within the slot.
In many embodiments, the compliant material includes a first foam structure that extends from the upper structure towards the lower structure and applies a retention force to the lower structure through a needle within the needle slot to retain the needle within the needle slot.
In many embodiments, the compliant material includes a first foam structure that extends from the upper structure towards the lower structure and a second foam structure that extends from the lower structure towards the upper structure. A gap may be defined between the first foam structure and the second foam structure. The first foam structure and the second foam structure may exert a force on each other through a needle within the gap to retain the needle within the needle slot.
In many embodiments, the needle retainers include a mechanical divider that allows needles to enter the needle slot and resists needles exiting the needle slot.
In many embodiments, the needle retainers include at least one mechanical divider. The divider may comprise a leading structure, a following structure, and a pivot structure. The pivot structure may couple the leading structure to the following structure. The divider may be configured to permit needles to move into the needle slot, but resist movement of needles out of the needle slot.
In many embodiments, the at least one divider separates one needle from another needle in an ordered array within the needle slot.
In many embodiments, the leading structure and the following structure extend from the pivot structure at a right angle to each other.
In many embodiments, the leading structure and the following structure extend from the pivot structure at an obtuse angle to each other.
In many embodiments, in an initial configuration, the following structure rests against the lower structure of the needle receptacle and the leading structure extends into the needle slot from the pivot structure, the pivot structure being coupled to the lower structure of the needle receptacle.
In many embodiments, the pivot structure includes a spring that holds the following structure against the lower structure of the needle receptacle.
In many embodiments, the spring is a helical spring.
In many embodiments, in a retention configuration, the following structure extends into the needle slot form the pivot structure forming a barrier between a needle within the needle slot and the entry zone of the needle receptacle.
In many embodiments, the needle retainers retain the needles in a planar array within the needle slot.
In many embodiments, the needle retainers retain the needles in such that they do not overlay with each other within the needle slot.
In many embodiments, the needle retainers retain the needles in an array within the needle slot.
In many embodiments, the needle retainers retain the needles in an unstacked configuration within the needle slot.
In many embodiments, the needle retainers retain the needles within the needle slot such that each of the needles is separated for each other of the needles.
In many embodiments, the retaining features are magnetic.
In many embodiments, the one or more clips extending along the length of the needle slot and facing the lateral opening of the needle slot, the one or more clips coupled to the needle receptacle at the lateral opening, such that a needle placed into the needle slot is directed into the one or more clips, and held securely between the upper and lower portions of the clips as the needle is translated away from the lateral opening and towards the closed end.
In many embodiments, each clip comprises an upper portion, a lower portion, and a hinge portion that connects the upper and lower portions, wherein the clip is configured to apply a compressive force against a needle placed between the upper and lower portions.
In many embodiments of the needle receptacle disclosed herein, the upper structure and the lower structure are separated by a first distance at a first end of the secure zone proximate the transition zone and a second distance at a second end of the secure zone distal the transition zone, the first distance being less than the second distance such that the upper and lower structures exert a clamping force on a plurality of needles arranged between the first and the second end within the needle slot.
In many embodiments of the needle receptacle disclosed herein, the needle receptacle further comprises a ratcheting cover, engaged with the needle receptacle and configured to translate longitudinally in a first direction towards the entry zone and resist translation away from the entry zone.
In many embodiments of the needle receptacle disclosed herein, the ratcheting cover covers the needle driver slot as the cover translates towards the entry zone.
In many embodiments of the needle receptacle disclosed herein, the needle receptacle further comprises a needle receiver, the needle receiver comprising an elongated body having an upper surface and shaped to be received within the secure zone of a needle receptacle, and receiving tabs extending from the upper surface of the elongated body.
In many embodiments of the needle receptacle disclosed herein, the receiving tabs are configured to be engaged with a needle.
In many embodiments of the needle receptacle disclosed herein, the needle engages one or more receiving tabs and translates into the secure zone of the needle slot, the needle pulls a portion of the needle receiver into the needle slot.
In many embodiments of the needle receptacle disclosed herein, the needle receptacle further comprises an aperture though the lower structure and within the entry zone or transition zone, the needle receiver configured to pass from underneath the lower structure, though the aperture, and into the needle slot.
In many embodiments of the needle receptacle disclosed herein, the receiving tabs are affixed to the upper surface of the needle receiver.
In many embodiments of the needle receptacle disclosed herein, the receiving tabs are formed by cutting a slit though the needle receiver and plastically deforming the receiving tab formed by the slit in a direction though the upper surface of the needle receiver.
In many embodiments of the needle receptacle disclosed herein, the receiving tabs are formed by cutting a slit though the needle receiver and deflecting the receiving tab formed by the slit in a direction though the upper surface of the needle receiver.
In many embodiments of the needle receptacle disclosed herein, the needle receiver is configured to ratchet into the needle slot.
In many embodiments of the needle receptacle disclosed herein, the needle receiver is configured to permit movement of the needle receiver into the needle driver slot and resist movement of the needle receiver out of the needle slot.
In many embodiments of the needle receptacle disclosed herein, the receiving tabs are configured to hold the needles within the needle slot in a spaced-apart array.
In many embodiments of the needle receptacle disclosed herein, the array is an ordered array.
In many embodiments of the needle receptacle disclosed herein, the array is a planar array.
In many embodiments of the needle receptacle disclosed herein, the needle receptacle further comprises blocking tabs extending from a respective one or both of the upper surface or lower surface towards the other of the upper surface or lower surface and being configured to permit entrance of a needle under load provided by a needle driver but retain the needles within the needle slot when not under load.
In many embodiments of the needle receptacles, apparatuses, barriers, and methods disclosed herein, the stiff portion comprises a rigid portion.
In many embodiments of the needle receptacles, apparatuses, barriers, and methods disclosed herein, the stiff structure comprises a rigid structure.
In many embodiments of the needle receptacles, apparatuses, barriers, and methods disclosed herein, the stiff material comprises a rigid material.
In many embodiments of the needle receptacles, apparatuses, barriers, and methods disclosed herein, the slot comprises a slit.
Aspects of the present disclosure may provide a method comprising providing an apparatus, needle receptacle or barrier as disclosed herein.
Aspects of the present disclosure may provide needle receptacles. An exemplary needle receptacle may comprise a lower structure and an upper structure above the lower structure to define a needle slot between the upper structure and the lower structure. The needle slot may comprise a used needle secure zone to secure used needles and a new needle secure zone to secure new needles. The needle slot may extend from a first end of the needle receptacle at an entry to the needle slot to a second end of the needle receptacle at the new needle secure zone. The upper structure may comprise a first edge and a second edge arranged to define a needle driver slot that extends through the upper structure from the new needle secure zone to the used needle secure zone.
Aspects of the present disclosure provide needle receptacles. An exemplary needle receptacle may comprise an upper structure, a lower structure, and a slot. The upper structure and the lower structure may be coupled to each other at their respective perimeters. The slot may be formed through the upper structure and may extend from the perimeter of the upper structure at a first end to the perimeter of the upper structure at a second end.
In many embodiments, the first end of the upper structure is at an entry to the used needle secure zone and the second end of the upper structure is at an exit to the new needle secure zone.
In many embodiments, new needles are secured in the new needle secure zone and dispensed through the exit to the new needle secure zone.
In many embodiments, used needles are secured in the used needle secure zone and received through the entry to the new needle secure zone.
In many embodiments, the needle receptacle may further comprise a stop between the new needle secure zone and the used needle secure zone. The stop may be configured to resist translation of needles between the new needle secure zone and the used needle secure zone. The stop may extend from the lower structure and into the needle driver slot.
In many embodiments, the lower structure of the entry zone is a landing zone configured to receive a tip of a needle driver.
Aspects of the present disclosure may provide a sterile kit. The sterile kit may comprise a sterile packing comprising a sterile barrier, a suture pack, a needle receptacle of as disclosed herein, and a barrier mounting base. The suture pack and needle receptacle may be coupled to the barrier mounting base. The sterile kit may further comprise a sheet structure. The barrier mounting base may be coupled to the sheet structure.
Aspects of the present disclosure may provide a sterile kit. The sterile kit may comprise a sterile packing comprising a sterile barrier, a suture pack, a needle receptacle as disclosed herein, a barrier mounting base, and a sheet structure. The suture pack, needle receptacle, and the barrier mounting base may be coupled to the sheet structure. The barrier mounting base or the sheet structure may include a living hinge.
The needle receptacles disclosed herein may further comprise needle retention features within the needle slot to hold contaminated surgical needles therein.
In many embodiments, the needle retention features comprise foam disposed between upper and lower surfaces within the needle slot.
In many embodiments, the foam comprises urethane foam.
In many embodiments, the needle retention features comprise loop and hook fasteners disposed between upper and lower surfaces within the needle slot.
In many embodiments, the needle retention features comprise a plurality of protrusions extending from one or both of upper and lower surfaces within the needle slot.
In some embodiments, the plurality of protrusions comprise dimples.
In some embodiments, the plurality of protrusions comprise protuberances.
In some embodiments, the plurality of protrusions comprise filaments.
In some embodiments, the plurality of protrusions are angled away from the at least one opening to permit the needle to pass into the secure zone and to resist movement of the needle toward the at least one opening.
In some embodiments, the needle retention features comprise flaps disposed between upper and lower surfaces within the needle slot.
In many embodiments, the needle retention features comprise gel disposed between upper and lower surfaces within the needle slot.
In many embodiments, the needle retention features comprise hemispherical nubs disposed upper and lower surfaces within the needle slot.
In many embodiments, the needle retention features comprise angled bristles disposed upper and lower surfaces within the needle slot.
In many embodiments of the barrier disclosed herein, the barrier may includes a ferrous metal or magnet to magnetically couple to a needle receptacle.
In many embodiments of the needle receptacles disclosed herein, the needle receptacle includes a ferrous metal or magnet to magnetically couple to a barrier.
In many embodiments of the methods disclosed herein, the support is mounted to a drape over the over a patient.
In many embodiments of the methods disclosed herein, the support is mounted within the near surgical field.
In many embodiments of the methods disclosed herein, the support is mounted to a table within the near surgical field.
In many embodiments of the methods disclosed herein, the support is mounted to a stand within the near surgical field.
In many embodiments of the methods disclosed herein, the support is mounted at a location opposite the surgeon from an incision.
In many embodiments of the methods disclosed herein, the support is mounted proximal the incision of the patient.
In many embodiments of the methods disclosed herein, the support is mounted distal the incision of the patient.
In many embodiments of the methods disclosed herein, the support is mounted superior the incision of the patient.
In many embodiments of the methods disclosed herein, the support is mounted inferior the incision of the patient.
In many embodiments of the barrier mounting base disclosed herein, the barrier mounting base includes a flat surface for coupling one or more of a needle receptacle and a suture pack either directly or indirectly.
In many embodiments of the barrier mounting base disclosed herein, the barrier mounting base includes a concave surface shaped to receive a barrier therein.
In many embodiments of the barrier mounting base disclosed herein, the concave surface is opposite the flat surface.
In many embodiments of the barrier mounting base disclosed herein, the barrier mounting base further comprises torsional stiffeners extending from a surface of the barrier mounting base and is configured to increase the torsional rigidity of the barrier mounting base as compared to the barrier mounting brace without the torsional stiffeners.
In many embodiments of the barrier mounting base disclosed herein, the barrier mounting base further comprises first and second extensions along respective first and second sides of the barrier mounting base and configured to couple with a barrier. A lower surface of the barrier mounting base may contact a curved surface of the barrier at a first location and the first and second extensions may contact the curved surface of the batter at respective second and third locations.
In many embodiments of the support disclosed herein, the support comprises a sheet structure including a first hinge separating a base of the support from a mounting surface of the support.
In many embodiments of the support disclosed herein, the base is configured to couple the support to a surgical drape and the mounting surface is configured to couple to a needle receptacle.
In many embodiments of the support disclosed herein, the base is configured to couple the support to a surgical drape and the mounting surface is configured to couple to a needle receptacle.
In many embodiments of the support disclosed herein, the mounting surface is at an angle with the base of between 30 degrees and 90 degrees.
In many embodiments of the support disclosed herein, the mounting surface is at an angle with the base of between 60 degrees and 75 degrees.
In many embodiments of the support disclosed herein, the mounting surface is at an angle with the base of between 45 degrees and 75 degrees.
In many embodiments of the support disclosed herein, the mounting surface is at an angle with the base of between 45 degrees and 90 degrees.
In many embodiments of the support disclosed herein, the support comprises a sheet structure including a first hinge separating a base of the support from a mounting surface of the support.
In many embodiments of the support disclosed herein, the support comprises a sheet structure including a second hinge separating the mounting surface of the support from a adjustment structure that extends from the hinge and engages with the base.
In many embodiments of the support disclosed herein, the support comprises a plurality of stops that extend from a surface of the base and are engagable by the adjustment structure to adjust an angle of the mounting surface.
In many embodiments of the support disclosed herein, the support further comprises a third hinge between the adjustment structure and a fourth section, the fourth section coupleable to the base.
In many embodiments of the support disclosed herein, the hinge is a living hinge.
In many embodiments of the apparatus disclosed herein, the top and bottom of the spindles may include a coupling the top coupling having a first shape and the bottom coupling being shaped to receive the top coupling.
In many embodiments of the apparatus disclosed herein, the top and bottom of the spindles may include a coupling the top coupling having a first shape and the bottom coupling may be shaped to engage with the first shape of the top coupling.
In many embodiments of the apparatus disclosed herein, the top of the spindle may include an extension and the top of the spindle includes a recess shaped to receive the extension.
Aspects of the present disclosure may provide a needle receptacle comprising a lower structure that has a secure zone, an upper structure that has an entry zone and a secure zone, a needle slot for receiving one or more suture needles between the lower structure and the upper structure, a ramp structure that forms a lower entry zone, and an upper needle driver slot that extends through a portion of the upper structure and a lower needle driver slot that extends through portion of the lower structure and the ramp structure. The ramp structure may include a surface that is angled away from the needle slot and the upper structure. The entry zone of the upper structure may be angled away from the needle slot and the ramp structure. The needle receptacle may further comprise a compliant structure within the needle slot. The compliant structure may apply a holding force against a needle within the needle slot and the secure zone to resist translation of the needle out of the needle slot and the secure zone. The upper structure may apply a holding force against a needle within the needle slot and the secure zone to resist translation of the needle out of the needle slot and the secure zone.
Aspects of the present disclosure may provide needle receptacles. An exemplary needle receptacle may comprise first and second elongated members, a first needle retention slot, and a second needle retention slot. The first and second elongated members may have a first end coupled to a wall, the first and second members being parallel to each other and extending from the wall, the first elongated member having a first surface that faces the second elongated member and the second elongated member has a second surface that faces the first elongated member. The first needle retention slot may be formed in the first surface of the first elongated member and may extend along the length of the first elongated member. The second needle retention slot may be formed in the second surface of the second elongated member and may extend along the length of the second elongated member. The first and second needle retention slots may together form a secure needle zone for securing used suture needles therein.
The first and second elongated members may apply a compressive force to the used suture needles.
A needle driver slot may be formed between the first and second elongated members.
Aspects of the present disclosure may provide needle receptacles. An exemplary needle receptacle may comprise a housing and a cavity. The housing may have an upper portion and a lower portion coupled together by a hinge portion. The upper portion, lower portion, and hinge portion may form a u-shape. The cavity formed between the upper portion and the lower portion may be configured storing a plurality of needles.
In many embodiments of the needle receptacle disclosed herein, the hinge portion is spring-loaded to bias the upper and lower portion of the housing towards one another, such that the needles can be secured within the needle slot by the compressive forces exerted by the upper and lower portions.
In many embodiments of the needle receptacle disclosed herein, each of the upper portion and the lower portion comprises a first arm and a second arm and forming a needle driver slot therebetween.
In many embodiments of the needle receptacle disclosed herein, the lower portion further comprises an extension that extends away from hinge.
In many embodiments of the needle receptacle disclosed herein, the extension forms a landing zone for a needle to be secured in the housing. The needle may be placed in contact with an upper surface of the extension with the needle driver tip aligned with the needle driver slot.
In many embodiments of the needle receptacle disclosed herein, the needle driver slot in the lower portion extends into the extension.
In many embodiments of the needle receptacle disclosed herein, the needle driver slot in the lower portion extends through the extension.
In many embodiments of the needle receptacle disclosed herein, the needle driver slot is closed at an end of the first or second portion proximate the hinge and open at an end of the first or second portion away from the hinge.
In many embodiments of the needle receptacle disclosed herein, the needle receptacle may further comprise blocking tabs extending from a respective one or both of the upper portion or lower portion towards the other of the upper portion or lower portion and being configured to permit entrance of a needle under load provided by a needle driver but retain the needles within the needle slot when not under load.
In many embodiments of the needle receptacle disclosed herein, the needle receptacle may further comprise lateral walls disposed over outer lateral edges of housing.
In many embodiments of the needle receptacle disclosed herein, the lateral walls are integrated with the housing.
In many embodiments of the needle receptacle disclosed herein, the lateral walls are be removably coupled to outer lateral edges of housing.
Aspects of the present disclosure provide needle receptacles. An exemplary needle receptacle may comprise a lower structure having a channel formed in an upper surface thereof, an upper structure formed from a stiff material and a flexible material, a needle slot formed between the upper structure and the lower structure for securing used suture needles therein, and a needle driver slot formed by the upper structure between the stiff material and the flexible material and being above the channel of the lower structure.
In many embodiments, the needle receptacle further comprises a compliant material within the needle slot between the stiff material of the upper structure and the lower structure. The compliant material may comprise foam.
In many embodiments, the needle driver slot formed in the upper structure is parallel to the channel formed in the upper surface of the lower structure.
In many embodiments, the needle driver slot includes a first edge and a second edge opposite the first edge.
In many embodiments, the flexible material includes the first edge of the needle driver slot and the stiff material includes the second edge of the needle driver slot
In many embodiments, the first edge separates from the second edge to receive the needle driver.
In many embodiments, the first edge and the second edge contact each other in a non-deformed free standing state without a needle driver extending therebetween.
In many embodiments, the first edge and the second edge are spaced apart from each other in a non-deformed state, a gap being defined between the first edge and the second edge.
In many embodiments, a portion of the lower structure extends beyond an end of the upper structure, forming a landing zone. The needle may be placed in contact with an upper surface of the extension with the needle driver tip aligned with the needle driver slot.
In many embodiments, receiving a needle receptacle comprises receiving five or more dispensed surgical needles from a surgeon, wherein the dispensed surgical needles are stabilized and innocuous within the needle receptacle when received from the surgeon.
In many embodiments, receiving a needle receptacle comprises receiving five or more reconciled dispensed surgical needles from a person who reconciled the surgical needles when the needles were within a near surgical field, and wherein the dispensed surgical needles are stabilized and innocuous within the needle receptacle when received. In many instances, the needles were within the needle receptacle when reconciled and reconciled with surgical needles of a needle pack within the near surgical field.
All publications, patents, and patent applications mentioned in this specification are herein incorporated by reference to the same extent as if each individual publication, patent, or patent application was specifically and individually indicated to be incorporated by reference.
The novel features of the invention are set forth with particularity in the appended claims. A better understanding of the features and advantages of the present invention will be obtained by reference to the following detailed description that sets forth illustrative embodiments, in which the principles of the invention are utilized, and the accompanying drawings of which:
FIGS. 392A1-392A12 illustrate exemplary embodiments of devices for securing a plurality of needles, in accordance with many embodiments.
FIGS. 392B1-392B5 illustrate exemplary embodiments of devices for securing a plurality of needles, in accordance with many embodiments.
The present invention is directed towards systems and methods for improving the efficiency of operating rooms. The embodiments disclosed herein are well suited for combination with many prior systems and methods, such as prior suture packs, prior needle holders, and prior operating rooms and personnel.
Although specific reference is made to the placement of used needles in a used needle container, the embodiments disclosed herein are well suited for use with needles dispensed from a suture pack and placed in a used needle container without suturing the patient, for example.
Secure—The needle is secure means that the tip of the needle is prevented from compromising sterility or coming into contact with skin of the patient or surgical staff. When used with the sharps container, the used needle is physically secured from falling out of container. Sharps can include needles and tools or other objects which have one or more sharp surfaces that can puncture the skin of the patient or surgical staff.
In many embodiments, a secure needle as described herein is secured to prevent both the leading and trailing ends or tips of the needle from coming into contact with skin, gloves, surgical apparel of the surgical staff, surgical drape, or patient.
As used herein like characters such as letters and numerals refer to like elements.
As disclosed herein, a used suture needle encompasses a suture needle dispensed from a suture pack.
As used herein the terms “needle driver” and “needle holder” are used interchangeably.
As used herein the terms “armed sutures” and “armed needles” are used interchangeably.
As used herein the terms “used needle holder”, “needle receptacle”, “used needle receptacle”, “used suture needle receptacle”, “sharps container”, “needle trap”, and “needle receptacle means” are used interchangeably.
As used herein the terms “suture package”, “suture pack” and “suture package means” are used interchangeably.
As used herein the terms “barrier” and “barrier means” are used interchangeably.
As used herein the terms “support” and “support means” are used interchangeably.
As used herein the terms “platform” and “platform means” are used interchangeably.
As used herein “secure” means fixed or fastened so as not to give way, become loose, or be lost.
As used herein “innocuous” means incapable of contact with a human finger.
One approach for improving operating room efficiency is to reduce the dependence of the surgeon on the surgical assistant. For example, a surgical procedure can include performing a surgical procedure and then closing a patient's surgical incisions after the procedure is completed. The closing generally includes installing surgical sutures to hold the patient's body tissue together after the surgery. This surgical suture procedure can include needles loaded with sutures that are stored in a needle package and a needle driver. When needed, the surgeon uses a needle driver to grasp and remove a needle from the suture package. The needle point is pressed into the flesh, advanced along the trajectory of the needle's curve until it emerges, and pulled through. The trailing thread is then tied into a knot, usually a square knot or surgeon's knot. Ideally, sutures bring together the wound edges, without causing indenting or blanching of the skin, since the blood supply may be impeded and thus increase infection and scarring. Placement varies based on the location, but the distance between each suture generally is equal to the distance from the suture to the wound edge. The most common stitch is a simple interrupted stitch with the suture thread cut between each individual stitch. Because each stitch may require a separate needle and the patient may require many stitches, the surgeon may need to handle many different needles. The size and shape of the needles may also vary depending upon the patient's needs.
An embodiment, the present invention is directed towards a system for improving efficiency by eliminating the need for the assistant to provide needles to the surgeon when closing a patent's surgical wounds. Eyed or reusable needles are needles with holes or eyes, which are supplied separate from their suture thread. The suture must be threaded on site, as is done when sewing at home. The advantage of this is that any thread and needle combination is possible to suit the job at hand. Swaged, or atraumatic, needles with sutures comprise a pre-packed eyeless needle attached to a specific length of suture thread. The suture manufacturer swages the suture thread to the eyeless atraumatic needle at the factory. The chief advantage of this is that the doctor or the nurse does not have to spend time threading the suture on the needle, which may be difficult for very fine needles and sutures. Also the suture end of a swaged needle is narrower than the needle body, eliminating drag from the thread attachment site. In eyed needles, the thread protrudes from the needle body on both sides, and at best causes drag. When passing through friable tissues, the eye needle and suture combination may thus traumatize tissues more than a swaged needle, hence the designation of the latter as “atraumatic”.
There are several shapes and sizes of surgical needles. These include: Straight, ¼ circle, ⅜ circle, ½ circle, ⅝ circle, compound curve, half curved (also known as ski), half curved at both ends of a straight segment (also known as canoe), etc. Subtypes of the ½ circle needle shape include, from larger to smaller size, CT, CT-1, CT-2 and CT-3. The ski and canoe needle design allows curved needles to be straight enough to be used in laparoscopic surgery, where instruments are inserted into the abdominal cavity through narrow cannulas. Needles may also be classified by their point geometry, examples include: taper (needle body is round and tapers smoothly to a point), cutting (needle body is triangular and has a sharpened cutting edge on the inside curve), reverse cutting (cutting edge on the outside), trocar point or tapercut (needle body is round and tapered, but ends in a small triangular cutting point), blunt points for sewing friable tissues, side cutting or spatula points (flat on top and bottom with a cutting edge along the front to one side) for eye surgery, etc. Atraumatic needles may be permanently swaged to the suture or may be designed to come off the suture with a sharp straight tug. These “pop-offs” are commonly used for interrupted sutures, where each suture is only passed once and then tied.
In an embodiment, operating room efficiency can be improved by allowing the surgeon to load suture needles to a needle driver. A surgeon may use a dominant hand to hold the needle driver and one or more suture packets can be attached to the non-dominant limb of the surgeon. The surgeon can then grasp the new suture needles from the suture packet on the non-dominant limb.
For example, if the user is right handed, the surgeon may attach the suture package to the left arm or hand and use the right hand to handle a needle driver. The user can grasp a portion of a needle with the needle driver and remove the needle from the suture package. The user can then use the needle driver to press the needle point into the flesh of the patient. The needle is advanced along the trajectory of the needle's curve until it emerges from the flesh, and the needle and suture are pulled through. The trailing thread is then tied into a knot, usually a square knot or surgeon's knot.
It has been estimated that there are over one billion passages of needles per year in the US. This high needle use results in a serious risk of injury. The inventive system reduces this risk because the needles are only handled by the surgeon. Because there is a reduced number of passes of sharp needles between surgical personnel there are fewer chances of having accidentally dropped needles, drape penetration or retained foreign objects within the patient.
A “surgical field” can include a space within an operating room where the patient and surgeon are located during surgery. A “near surgical field” 313 can be a much smaller space that is in close proximity to the incision 317 on the patient 315 and the surgeon. The near surgical field 313 may comprise a space disposed between the surgeon 319 and the incision 317. For example, the near surgical field can comprise a length 316 extending between a surgeon and an incision of a patient and a width 318 extending transverse to the length, the width comprising no more than about 24 inches (61 cm) across. The entire near surgical field can also be within the field of view 311 of the surgeon 319.
The near surgical field may be conceptualized as the space bound by the neutral planes 320 of the surgeon's arms, such that no external rotation of the arms or the shoulders beyond a position of neutrality is necessary for the surgeon to reach an object positioned within the near surgical field. For example, the near surgical field can comprise a space wherein the surgeon's arms retain some degree of bending and can rotate internally from the neutral planes 320 (in the direction shown by arrows 322 in
As shown in
In many embodiments, a needle trap or needle receptacle as described herein is configured such that a user can slide a needle into the receptacle and have the needle be secured the moment the needle is released from the needle driver. The needle can be released using a single maneuver, and the needle can be immediately secured within the needle receptacle.
In addition to the improved safety, the inventive system improves the efficiency of surgical procedures, which can result in reduced time for procedures in the operating room. For example, the time of the surgical procedures can be reduced because the scrub tech no longer needs to assist the surgeon with needle loading/unloading, providing needle holders and scissors. Rather than assisting the surgeon, the scrub tech can perform other tasks reduce the time needed in the operating room. For example, the scrub tech can perform a sponge count with the circulating nurse or begin the breakdown of the back table to facilitate a faster operating room turnover thereby decreasing the time spent between surgical procedures. This extra free scrub tech time may also lead to more accurate and reliable sponge count thereby decreasing the risk of retained foreign object. The overall effect of the inventive system and apparatus is faster time of closures (room turnover from one surgical case to the next) because the scrub tech is also now free to begin “breaking down” the back table where instruments are kept). The work flow in the operating room is more efficient because there are fewer steps and no reliance on the support of a scrub tech. Rather than coordinating the movement of the needles and tools, the surgeon can simply reach for the needed objects without having to wait for anyone else. There is no need to reach for tools and there is no transfer of sharp objects. The platform can be configured with the proper instruments and/or with needles in an optimum position for removal from the suture packs.
Because the surgeon does not need to worry about the coordination of transferring tools and needles, the surgeon can maintain eye contact on surgical field. Time lost to looking away from the surgical field or refocusing the eyes to see where the tools and needles are located during an object transfer can be reduced. Body rotation of the surgeon can be decreased, as well as crossover of one forearm over the other. The movements can be more circular, of lesser excursion. Thus, the micro-ergonomics can be improved.
Further, the present embodiments can allow the surgeon to track his own needle usage and inventory, since the surgeon himself can dispense fresh needles and secure used needles. When needles are passed back and forth between a surgeon and an assistant, it can be difficult for the surgeon to know how many more suture needles remain inside an opened suture pack, how many suture packs are opened, etc., while it can be similarly difficult for the assistant to know how many and/or what types of needles have been used by the surgeon. Such lack of clarity regarding the inventory of available needles can necessitate an ongoing dialogue between the surgeon and the assistant, which can be distracting, inefficient, and prone to producing errors. By contrast, when the surgeon is able to track his own needle usage, as with the methods described herein, he can easily determine when a particular suture pack needs to be replaced, and communicate his needs to his assistant in a more precise manner. Referring again to
With reference to
With reference to
With reference to
With reference to
In an embodiment shown in
In an embodiment shown in
The needle storage unit 133 can hold the used needles 104 after the suture has been knotted and the needle is no longer needed. The needle storage unit 133 eliminates the need to place the used needle 104 in the neutral zone and picked up by the surgical staff after it has been used. The user can simply complete the suture stitch, cut the suture and place the used needle 104 in the needle storage unit 133 with the needle driver. The user can then grasp the next needle 103 from the suture package 101. The needle storage unit 133 can greatly increase the efficiency of the surgical procedure. In an embodiment, the needle storage unit 133 can include an internal volume and internal walls with a hole or slot for inserting the used needles 104. The housing may be transparent so the user can see that the used needles 104 are fully inserted and trapped within the needle storage unit 133.
With reference to
In an embodiment, the suture package 101 can be held in a pocket 137 in the glove 107 as shown in
In an embodiment shown in
As discussed above with reference to
In an embodiment, the tools 151 can be needle drivers that have handle at a proximal end and a thin tip at a distal end. The tool holders 147 can be holes or slots that are wider than the distal portion of the tool 151. The distal ends of the tools 151 can be inserted into the holders 147 in the platform but the handle portions of the tools 151 can be wider than the holes or slots. The center of balance of the tools 151 can be inserted through the holes or slots so that when the platform is upright, the tools 151 will be held in the tool holders 147. In an embodiment, the slots can be between about 0.5 to about 2.0 inches in width.
A surgeon can use a platform for holding suture packages during a medical procedure. The suture holders can be attached to a platform 145 that is secured to the glove 107 around the hand/arm 143 of the user. In an embodiment, the platform 145 can be much larger than a single suture package 101. In these embodiments, multiple suture packages 101 can be attached to different areas of the platform 145. A surgeon can have a plurality of suture packages 101 on the dorsal surface of the left hand glove 107. The right hand is holding a needle driver, which is holding a needle. The right hand is also holding a tool. The surgeon can complete a stitch and then release the needle. The needle driver can grasp a new needle from the suture package 101.
Different structures can be mounted on the platforms 145 depending upon the preference of the surgeon. For example with reference to
As discussed above, the surgeon can place used needles 104 into the needle container 149 and then use a second tool as needed.
In an embodiment, a platform can be used by the surgeon to hold tools, sutures, needles, suture packs, sharps container, etc. The platform can be secured to a forearm and/or hand and/or forearm and/or fingers on one or more dorsum surfaces of the surgeon so that the objects can be easily accessed without the need for any interaction with anyone else such as a scrub technician. Thus, when using the platform, the surgeon does not need to interact with anyone else. The surgeon can remove objects from the platform that are needed and place and store objects on the platform that are no longer needed. The elimination of interaction between multiple individuals to handle the sharp objects simplifies the surgical procedure and reduces the chances of cuts or other injuries such as lacerations, punctures, abrasion, break in the skin, etc.
In an embodiment with reference to
In addition to providing a stable platform 145 for tools and objects, the structural layer 169 can also provide a protective barrier for the surgeon from sharp objects. If a surgeon accidentally directs a sharp object towards the dorsum of the forearm, the structural layer 169 of the platform 145 will block the sharp object and prevent any injury to the portions of the forearm and wrist and hand covered by the platform 145. Aluminum is a material that is softer than steel. Thus, a tool or sharp object that is pressed against the structural layer 169 will tend to not be scratched or otherwise damaged by the contact with the softer structural layer 169 material.
As shown in
With reference to
Although the inner elastic foam layer has been described as being bonded to the structural layer, there can be portions of the inner foam layer that are not bonded to the structural layer. For example, in some embodiments, the platform can include tool holders that are located at holes formed in the structural layer. The tools such as needle drivers can be placed in the holes with the thin body of the needle driver distal to the tool finger holes. The thin body can be placed through the hole while the handle finger holes of the needle driver cannot pass through the hole because it is wider than the diameter of the hole. Thus, the handle will hold the tool in place and prevent it from passing completely through the hole. The holes can be oriented such as to properly orient the tools for easy grasping by the contralateral hand. For example the holes may be oriented as slots with the long axis parallel or at a specific angle to the long axis of the forearm such that the finger loops of the needle holder can be easily grasped by the contralateral hand without the need for contralateral forearm motion. In an embodiment, the tools are held in the tool holders of the platform with the structural layer between the center of gravity of the tool and the handle or finger hole portion of the tool. As discussed, the inner and/or outer foam layers that are bonded to the structural layer can provide friction which can prevent the movement of the tool. Thus, the tools can be held in the tool holders by a combination of gravity and friction.
In some embodiments, the upper and lower foam material adjacent to the holes is removed. However, in other embodiments, the foam layers can be left over the holes. For example with reference to
It is also possible to have a smaller hole 178 (
In other embodiments the inventive surgical platform can include another outer elastic foam layer that is bonded to the outer surface of the structural layer opposite the inner surface. The outer foam layer can have different physical properties than the inner foam layer. As discussed above, the platform can be used to hold tools, sutures, suture packs, needles, sharps containers, etc. The sharps containers can include various embodiments including: sponges, enclosures, magnetized surfaces and/or combinations of different embodiments. In an embodiment the outer foam layer can have physical characteristics that will improve the connection between the objects and the platform. For example, the outer surface of the outer foam layer can have a greater surface area for better anti-slip surface that provides a high static coefficient of friction with the objects that effectively grip the contact surfaces of the object.
In an embodiment with reference to
It can be very important to hold objects 108 in a secure manner to the platform 145. In an embodiment, the outer foam layer 173 can be a high friction material that prevents or resists movement between the object 108 and the outer layer 173. The friction force between the objects 108 and the outer surface of the outer foam layer 173 can be described or quantified based upon the static coefficient of friction (COF), which can be symbolized by the Greek letter μS. The static COF is a dimensionless scalar value that describes the ratio of the force of friction between two bodies and the force pressing them together. The coefficient of friction depends on the materials used. For example, slippery materials such as Teflon on smooth surfaces can have a low coefficient of friction, while rubber on a suture package surface can have a higher coefficient of friction. Coefficients of friction range from near zero to greater than one. In an embodiment, the static coefficient of friction between the outer surface of the outer layer 173 of foam and the object 108 coupled to the platform is greater than 0.3. The friction force is quantified by the static friction=μS×compression force.
The compression force can be applied by a clamp, a tab 181, elastic material, a clip, a spring and/or any other suitable mechanical device. The compression force can also be provided by the foam. The compression force can be stored in the foam material by manually bending the tab 181 over and onto the suture packet. The compressed foam will try to expand and this foam expansion force can help to hold the suture packet in place. The compression force can prevent any vertical movement of the suture packet and the friction force can prevent any horizontal movement relative to the platform surface. In an embodiment, the compression mechanism is attached to the platform and applies a force to compress the object against the outer foam layer. The compressive force results in a friction force that prevents a sliding movement of the object over the surface of the outer foam layer.
With reference to
The described sharps container 255 can provide various benefits to the users. The sharps container 255 is easily accessed and secured to any portion of the platform 145 over the forearm and hand. The used needles 104 are highly visible in the repository for easy used needle 104 counting. The demarcations can assist in the counting of the used needles 104. The foam 173 in the sharps container securely holds the tips of the needles 104. The tips are also adjacent to the structural layer 169 and cannot cause damage even if the needles 104 are accidentally contacted or pressed further into the foam 173. The used needles 104 can be secured, treated and maintained in control of the surgeon until a “group transfer” occurs. More specifically, the used needles 104 are secured to the sharps container 255. The used needles 104 can also be treated by mechanically cleaning the distal portions and chemically disinfected. The securing of the used needles 104 can be in constant contact and can be maintained in control of the surgeon until a “group transfer” occurs. The “group transfer” can include the transfer of a group of surgical tools from the surgeon to the scrub tech. The surgical tools in the group transfer can include: the needle driver, the forceps, the used sharps container, the sharps container and other objects.
In an embodiment, outer foam layer 173 can include different areas that have different physical properties. For example, first area may be designed to support suture packs 101 and a second area may be designed to function as a sharps container 255 as described above. The first area that supports the suture packs 101 can be made of a thinner less elastic foam material with a higher COF exposed surface than the second area. The suture packs 101 can be compressed against the first area and the high COF can prevent movement of the suture packs. This feature can be important because the surgeon must manually place the proximal ends of the needles 103 in needle driver. Any unwanted movement of the needles 103 can make this task more difficult.
With reference to
With reference to
In the illustrated embodiment, the tabs 181 hold one or more of the suture packs 101 to the platform 145. Some of the tabs 181 are oriented to be substantially perpendicular to the edges of the suture packets 101 while other tabs 181 can be oriented at various other angles. In the illustrations, the tabs 181 on the lower right are oriented to be about 45 degrees to the side edges of the suture packets 101.
In an embodiment, the multi-layer platform can have a suture pack carrier.
In the illustrated embodiments, the suture pack retaining structures can adapt to wide range of suture pack 101 sizes. Suture packs 101 can vary in size from about 1″×3″ to about 3″×4″. The suture packs 101 can have a “flat” conformation. The tabs 181 can provide an easy and secure system for attaching or locking the suture packs 101 onto the barrier platform. The platform can accommodate multiple suture packs 101 and the packs can also be easily removed from the platform.
With reference to
With reference to
The inventive platform has been described with various system components: tool holders, tools, suture pack holders, suture packs, armed needles, used and sharps containers, all mounted on a platform. Although these components can be set at predetermined locations on the platform, in other embodiments, the inventive system can have a modular configuration. In these embodiments, the system components: tool holders, tools, suture pack holders, suture packs, armed needles 103, sharps container can be independent and modular. The user can mix and combine these individual components and place them in any desired positions on the apparatus and platform. The individual components can have various connection mechanisms such as: hook and loop (Velcro), snaps, tack features, screw fasteners, tabs, or any other suitable connection mechanisms such as elastic bands and adhesives. Once the surgical procedures are completed, the system components can be removed from the inventive platform. It may be possible to clean and sterilize the platform, attach new modular components and reuse the platform.
The present platform invention can address several operating room issues including improved safety and efficiency. As discussed, the structural layer of the platform can create a barrier that prevents needle sticks to forearm and dorsum of hand. Thus, both the surgeon's hand and forearm can be protected. The platform can be held against the forearm but can be spaced away from the hand, which may allow for full movement of the surgeon's (wrist, hand, fingers) hand. The platform also does not interfere with the elbow range of motion.
The inventive platform system provides various benefits. The bendable legs allow the platform to adapt readily and securely to variable forearm sizes. The platform allows the surgical tools and needles to be oriented in any desired position. Ideally, the system can minimize unnecessary forearm motion. The suture pack(s) can be placed on any portion of the platform including the radial border of forearm and the volar forearm. The platform provides a protective barrier to the hand and forearm while still allowing full hand range of motion. The angle of the hand cover portion of the platform relative to forearm portion can be about 10-45 degrees. However, the hand element can be flexible and the angle and shape of the hand element can be adjusted to any desired shape. The inflection point may be: a living hinge, a mechanical hinge or any other suitable articulation movement mechanism.
For example, with reference to
In preferred embodiments, the sharps container can be physically adjacent to or in close proximity with the suture packet holder and the suture packets. The sharps container and the suture packets can be on the same support structure such as a platform. This configuration facilitates improved surgical work flow and condenses several complex coordinated motions into more streamlined simplified actions performed by the surgeon. As discussed, the platform with the suture packet holders secured to suture packets and the sharps container can be on the same platform apparatus mounted on a non-dominant arm of the surgeon. When a suture is required, the surgeon can grasp an armed needle having an attached suture from the suture packet and use the suture on the patient. When the stitch is completed, the surgeon can then place the used needle in the sharps container and then easily grasp a new armed needle from the suture packet.
Various sharps container designs can combine with the inventive system. In an embodiment, the sharps container can be a soft open or closed cell elastic material such as foam or a sponge which can be marked with a sequence of numbered regions. The used needles can be inserted into the soft cell material which will hold the used needles in place. In an embodiment, the sharps container cell material can be adjacent or bonded to one or more layers of a thin elastic homogeneous material such as a soft plastic or rubber that can be easily pierced by the used needles without substantially deforming the soft elastic cell material. The homogeneous material can provide a friction force that can increase the resistance to inserted needle movement that can further prevent the accidental removal of the used needles from the sharps container. It can also be easier to print the number markings on a solid rubber material than on a soft elastic cell material such as foam.
A potential problem with used needles is their ability to transmit viruses when a used needle accidentally breaks the skin on an operating room surgical member. However, if the used needle is cleaned and/or disinfected the used needles are much less likely to spread viruses. In yet another embodiment, the soft open or closed cell elastic material can be coated and/or saturated with a disinfectant such as bleach or other antimicrobial materials. The disinfectants can be in the form of a high viscosity gel that can be held within the foam material but will not easily be removed from the elastic cell material. In an embodiment, a portion or all of the soft open or closed cell elastic material of a sharps container can be surrounded by a layer(s) of the thin elastic homogeneous material in order to help retain a disinfectant liquid within the soft cell sharps container material (may need to elaborate, clarify).
With reference to
With reference to
In the illustrated embodiment, the door 237 mechanism is coupled to a pair of rotational members 246 on opposite sides of the sharps container 235. A lever 243 can extend away from the receptacle housing. When no force is applied to the lever 243, a torsional spring 245 or any other suitable spring mechanism can exert a counter clockwise torque about one or both of the rotational members 246. This torque can hold the door 237 in the closed position against a stop 247. When a downward force is applied to the lever 243, a clockwise torsional force can be applied to the door 237 mechanism that is greater than the counter clockwise spring 245 force. The door 237 mechanism can rotate clockwise and open to allow used needles 104 to be deposited in the receptacle 235. Once the used needle 104 is captured, the use can release the lever 243 and the door 237 can return to the closed position against the stop 247.
The manually controlled door configuration can allow the user to carefully control the door 237 to prevent used needles from escaping the sharps container 235. The repository housing can include an opening at the top surface and the door 237 mechanism can be mounted on two rotational members 246 on opposite sides of the housing that define a rotational axis. The doors 237 can be above the rotational axis 246 and a spring 245 can normally hold the door 237 in a closed position against a rotational stop 247. The lever 243 can be coupled to the door 237 mechanism and exit a side of the housing that is easily accessible to the user such as the side of the housing closest to the user. Actuating the lever 243 can cause the door 237 mechanism to rotate about the rotational axis and open. When the lever 243 is released, the spring 245 will rotate the door 237 mechanism back to the closed position.
With reference to
Alternatively the position of the door can be automatically controlled by gravity. When the sharps container is used on a forearm-mounted platform, the door can be at the top of the repository and open when the repository is in an upright position. However, when the sharps container is rotated, the doors can close to prevent used needles from exiting.
Because the suture packets and the sharps container are in close proximity, the surgeon's movement of releasing a used needle 104 and picking up a new needle is simple and short. Thus, this configuration has micro-ergonomic benefits over other suture packet and sharps container methods. As discussed above, the sharps container can be an elastic foam or other material into which used needles 104 are inserted with the sharp points directed towards a structural layer which blocks the needle from further movement and protects the surgeon's forearm from the used needle. It has also been found that mounting the used needle 104 on the dorsum on the forearm can also resist injury to the surgeon from the exposed suture ends of the needles. The dorsum of the forearm can rotate with the hand. However, the forearm is not easily moved into a position where the dorsum of the forearm faces the body. The forearm is inherently configured with the volar and palmar surfaces facing the body while the dorsum faces away from the body. This human anatomy limitation provides another safety feature for the inventive forearm mounted platform with sharps container.
With reference to
With the used sharps container on a dorsal side and suture packs 101 on the volar side, the movement and micro-ergonomics are slightly different because the surgeon will rotate the forearm 143 after the used needle is placed in the sharps container and while the new armed needle is being grasped. However, because the suture packet 101 and sharps container are still in close proximity, for example within less than 7 inches, the movement of the surgeon is still very efficient. This configuration also has the benefit of a safe used needle 104 position and a more adjustable suture packet 101 position.
The described process used with a medical apparatus on a forearm of a user can be illustrated with reference to flow chart shown in
The sutures and needles can remain within the near surgical field during the installation of the sutures.
In yet another embodiment, the suture packet holder (with a suture packet) and a sharps container can be mounted on a surgical tool on the same plane, facing the same direction, or on opposite planes. The suture packet holder and the sharps container can be held by the surgeon's non-dominant hand. In the illustrated examples shown in
An embodiment of this process can be illustrated with reference to the flow chart shown in
In other embodiments, various types of sharps containers can be used to hold used needles. For example with reference to
With reference to
With reference to
In an alternative embodiment, the back surfaces of the suture packets can be attached to a foam needle repository and the opposite side of the needle repository can be attached to the tool. In yet another embodiment of a needle receptacle and suture pack assembly 205 as shown in
With reference to
In other embodiments a solid platform is secured to the surgical drape on the fringe of the surgical incision. In an embodiment the device is mounted opposite the surgeon if the surgeon has no assistance or on the adjacent side to the surgeon's dominant hand. In an embodiment illustrated in
A common feature among the inventive devices described above is that they combine armed and/or unarmed needle and/or suture pack(s) with a used needle retention device on the same structure. The armed and/or unarmed needle and/or suture pack(s) with a used needle retention device can be fixed to the structure permanently and/or in frangible association. This configuration allows for improved micro-ergonomics. The surgeon can hold a needle driver in one hand and another tool such as forceps in the second hand. The surgeon does not have to let go of the needle driver or the forceps when needles are removed from the suture packs or when the used needles are placed in the used needle retention device. Since the surgeon does not have to remove the fingers from the instruments, the procedures can be a more efficient and safer since there is much less likelihood of accidentally dropping an instrument.
The use of the forearm for needles and used retained needles can provide improved efficiency, safety, and better micro-ergonomics. Using such a system, the surgeon always knows where used needles are located. It is also is very difficult to accidentally jab the surgeon's body with the used needles unless the surgeon crosses forearms to appose the dorsum of non-dominant forearm to another part of your body. If used needles are on the surgical field it is much easier for the surgeon's hand to accidentally be placed on them. Having the new and used needles on the in close proximity allows for apposition. The installation of sutures in a patient is done with a circular motion by the surgeon. The surgeon can more easily, drop a used needle off in the sharps container and grab the next new needle.
As illustrated in the top view of an embodiment of the inventive platform shown in
In some of the illustrated embodiments, the used needles are inserted into a foam sharps container coupled to a planar mounting surface such as a platform with the lengths of the needle approximately perpendicular to the mounting surface as shown in
In other embodiments, suture packs 101 can be placed on the upper surface of the sharps container 257. With reference to
In an embodiment with reference to
In an embodiment with reference to
With reference to
In other embodiments, the suture packet 101 and used needle receptacle 257 can be configured in a diagonal manner like layered shingles. In the illustrated example shown in
With reference to
When a needle 104 is placed in the sharps container 255, the surgeon can drive the sharp tip of the needle 104 through the elastic material 251. The needle 104 can be covered with body fluids and may be contaminated with bacteria and/or viruses. The used needle 104 tip can pass through the elastic material 251 and into the antimicrobial material 266 in the container 264 portion. Since the container material can be transparent, the user to see the used needle 104 tips in the antimicrobial material 266. The elastic material 251 may create a tight seal around the perimeter of the used needle 104 which can prevent the antimicrobial liquid 266 from escaping from the fluid container 264 portion of the needle receptacle 257.
The portions of the used needles 104 that are inserted into the antimicrobial material 266 are cleaned and disinfected. Thus, these used needles 104 are properly treated by the act of inserting the used needles 104 into the receptacle 257. These disinfected treated needles 104 pose much less of a threat of transferring an infection or disease in the event of subsequent human contact. If the used needle 104 is accidentally removed from the used needle receptacle 257, the surface of the needle 104 will slide against the elastic material 251 which will further clean the needle 104 as it is removed from the needle receptacle 257 further reducing the risk of spreading an infection or disease compared to untreated used needles 104.
After sutures are used to close a patient, the surgical team must perform a needle count to insure that none of the used needles 104 are in the patient. In an embodiment the used needle receptacle 257 can have a sequential series of number markings 259. The numeric markings 259 can be on the elastic material 251 or on any other suitable portions of the receptacle 257. The surgeon can place the used needles 104 in the numbered spaces in the marked sequence. During the needle count, the counter can easily perform the count by looking at the last numbered area of each receptacle 257 having an inserted used needle 104.
The used needles 104 should be placed as far as possible into the used needle receptacle 257. However, the proximal end will normally be exposed after the used needle 104 is inserted into the receptacle 257. These proximal ends are not as sharp as the distal ends but can still be sharp enough to cause injury to people. With reference to
The suture needles 104 are generally curved in shape. Thus, it may be easier to insert the used needles 104 into the used needle receptacle if the channels are also curved or angled as shown in
In some embodiments, multiple used needle sharps containers can be used together to hold a greater number of used needles 104. In an embodiment shown in
In some embodiments of the present invention, locking mechanisms 265 can be used with the sharps containers 255 as shown in
In other embodiments with reference to
In an embodiment, the sharps containers 255 can have indicators that indicate that the needle is properly placed in the channel 277 of the sharps container 255. In the illustrated example, foam indicator blocks 279 can be mounted just below each of the cams 275. The friction force of the foam 279 against the sides of the channel 277 can hold the blocks 279 in place. After the needle 104 tip passes through the cams 275, it contact the upper surface of the foam indicator block 279 and the downward force of the needle 104 can move the foam block 279 to a lower portion of the channel 277. Eventually, the foam block 279 may contact the bottom of the channel 277 and the used needle 104 can be further inserted into the foam block 279 without any additional movement of the block 279. In an embodiment the foam block 279 can be concealed in the upper position and visible in the lower position so that users can easily see if the channel 277 of the sharps container 255 is filled with a used needle 104.
In other embodiments, other types of locking mechanisms and indicators can be used with the sharps container. In an embodiment illustrated in
In the illustrated embodiment, the lower circuit turns on the electromagnet 273 when the tip of the needle 104 is adjacent to the electromagnet. In this embodiment, the lower circuit is completed when the needle 104 which is in contact with the middle conductor 270 also touches the lower conductor 271. This electrical connection between the middle conductor 270 and lower conductor 271 completes the circuit and causes the electromagnet to energize pulling the needle against the electromagnet 273. It would be easy to slide the needle 104 against a charge electromagnet 273 so it should be energized once the needle 104 is in the proper position. In this embodiment, the electromagnet 273 provides a locking mechanism that prevents the needle 104 from being removed from the sharps container 255. The electromagnetic 273 locking mechanism can be used alone or in combination with other locking mechanisms.
In other embodiments, the sharps container 255 can have battery 269 and control electronics that senses presence of needle 104 and keeps ongoing count and has indicator lights 267 or display that lets operator know the relative or absolute absence of needle same device can contain transmitter to communicate wirelessly with other devices and electronics including via Bluetooth or low frequency low energy transmitter including tablets, computers, mobile phones etc. Sensors may sense impedance changes, weight, electrical resistance, volumetric, etc. The sensor information can be used to indicate the number of used needles 104 in the sharps container for the purpose of providing an accurate used needle 104 count. The electromagnet 273 can work through a plastic layer. Therefore in some embodiments, the used needles 104 are not in direct contact with the electromagnets 273. When the used needles 104 need to be removed from the sharps container 255, the electromagnets 273 can be turned off. In an embodiment, electromagnet 273 can be used to secure the sharps container 255 to a magnetic forearm platform.
As discussed above, the needle receptacle and suture packet assembly can be placed on the end of a surgical tool. The prior example illustrated suture packets on the exposed sides and a used needle receptacle along the edge of the assembly. In other embodiments as illustrated in
The surgeon can grasp a proximal end of a new needle 103 from the used needle receptacle and suture pack assembly 258 and install the suture. The surgeon can then insert the used needle 104 in the next sequential space in the used needle receptacle 257. The surgeon can then grasp another new needle 103 and repeat the process. This process is more efficient because the surgeon does not need to reply upon a scrub tech to handle needles and needle drivers. This process is also safer because there is limited, or no coordinated handling of needles between the surgeon and the scrub tech reducing the risk of mishandling.
Embodiments of the present invention are directed towards sharps containers that can provide a lightweight structure that securely store between about 2-20 used needles in the immediate proximity of the surgeon. The sharps container can be less than approximately 4 inches in height or length, 4 inches in width and 3 inches in thickness and can be held on a surgical tool, a platform supported by the surgeon or any other movable structure controlled by the surgeon. The inventive sharps container can have an internal volume for storing the used sharps and in an embodiment, the container can have a movable door that can be open to insert the used sharps and closed to prevent the used sharps from escaping. The shape of the sharps container can be cylindrical, box shaped or any other suitable shape that has an internal volume that is large enough to store about 2-20 used needles 104. Because the used sharps container can be on the end of a surgical tool, the weight of the used sharps container is preferably less than 0.100 lbs. or 45 grams.
In many embodiments, the surgeon takes responsibility for securing the needle or group of needles prior to passing to the assistant. The suture needles can be curved solid needles that pass through tissue. Thus, these needles pass through very small holes in the tissue and the needles cannot have adaptions on the back end of the needle to slide over the needle to safely secure the sharp used needle tip in at least some embodiments.
In an embodiment, the present invention provides a means for safely securing the used surgical needle in the surgical field with the shortest route for the contaminated needle from tissue to a used sharps container. The process is substantially shorter because the needle only travels a short distance that is normally less than one foot, for example within the near surgical field.
The design and use of the inventive sharps container as described and illustrated has physical properties that do not interfere with the surgeon's workflow in closing patient wounds. Work in relation to embodiments suggests that securing used needles to a sharps container positioned on the instrument or on the surgeon's forearm or hand actually expedites the procedure, in addition to making the procedure safer. There can be no shorter physical path for the needle to a sharps container that is attached to hand/forearm or back of surgical tools on the surgeon's anatomy. Thus, the inventive system also minimizes the distance that the used needles must travel and eliminates unnecessary movement of the used needles, which increases the efficiency and reduces the required time. The inventive process has the benefits of only requiring the surgeon to perform the entire task, which minimizes the handling of a used sharp needle which increases the safety of the inventive system.
In some embodiments, the integrated suture packet and sharps container 308 share a housing 309, with the new armed needles 103 accessible from a first side 303 of the housing, and the sharps container 257 disposed on a second side 304 of the housing. For example, in a first embodiment the surgeon may use a needle driver to grasp an armed needle from a first side of the housing. The surgeon can use the suture and place the used needle in the sharps container through a door in a second side, such as the top surface, of the housing. The user can open the door to insert the used needle and then close the door to prevent the used needle from escaping.
In other embodiments, a protective door can be closed to shield the armed needles. This can be useful if the integrated suture packet and sharps containers are placed in storage to protect the needles. In different embodiments, the protective doors can be opened in various different ways. In an illustrated embodiment, the door may slide side to side or up/down so that the surgeon can easily open the door to access new armed needles. In other embodiments, multiple doors can open to allow access to the armed needles. In some embodiments, the protective door can be manually operated. In other embodiments, an actuator can be used to control the position of the protective door. The housing can also have an outer surface which can be used for labels or markings to provide needle and/or housing information.
Such an integrated configuration of a suture pack and a needle receptacle can provide improved safety and efficiency benefits described herein. Sharps containers can have many different varieties including: foam with demarcations that allow for multiple needles, foam encased in an outer shell such that needles cannot pass out the sides of the shell, foam encased in the outer shell having an aperture for introducing the used needles, the aperture is more narrow that the width of the housing such that with the bend of the needle, the housing will capture the needle tip. The foam represents a reservoir type vehicle for capturing needles in which the surgeon has flexibility on the orientation and location to place the used needles.
Another sharps container embodiment includes specific holes into which the needles are place by the surgeon. The used needles can go in but the mechanism captures the needle and does not allow removal of the used needles 104. Such mechanisms can include a cone with tapered tip and malleable leaves that bend to allow needle passage but prevent removal-similar in shape to lobster trap. Another mechanism is a cam or several cams with ratchet. As a used needle is introduced the cams rotate and compress the tip of the needle. Rotation of the cams can also expose side of the cam with a color change indicating the presence of the needle. There many potential mechanisms for capturing individual needles at fixed location.
In an embodiment, the cartridge can include an attachment mechanism(s). The attachment mechanism can be used to couple the cartridge to another object such as a tool or a platform. In an embodiment the attachment mechanism can be a slot or slots or holes in the cartridge into which the non-surgical end of the pickup attaches, or can incorporate and adaption of the surgical pickup. In other embodiments, the attachment mechanisms can include permanent magnets which can be used to secure the cartridge to the tool. With reference to
In other embodiments, a pure mechanical locking mechanism can be used to secure the cartridge to another object. In an illustrated example
In different embodiments, the fresh needle side of the cartridge can have a protective cover or door that moves or slides to expose the armed needle. The protective cover or door mechanism can be actuated in any direction, up down or sideways.
The cartridge can have an oval cross section with the fresh needles recessed from the face. Once the cover or door is open, the fresh needles are accessible to the surgeon.
The sharps container can be closed cell foam on the contralateral side that also is marked and has an aperture on the face. The foam may extend to the full border of the face to facilitate the capture and retention of the used needles 104. The walls of the cartridge are not penetrable by the needle to protect the needle from coming out of the side of the housing.
The sharps container can have a magnetic base that can help to prevent used sharps from accidental removal and the sharps container can also be a clear transparent structure that can allow the used needles 104 to be more easily counted. The sharps container can have a dome coverage that allows used needles 104 to pass through by rotating the needle through a small aperture so needle can enter the sharps container at any angle. The sharps container may include a magnetic base with covers that lock in place as needle placed in the container. Locking or closing the sharps container lid may expose the next new armed needle(s) or actuate and open the door covering the new needles.
With reference to
Forces on the proximal aspect of the needle 104 do not need to be very large to cause the needle 104 to be further advanced through the foam 263 layer or rotate the needle 104 within the foam 263. The foam 263 can also allow for low force angulatory displacement of the needle 104 relative to the plane of the foam 263. Thus, if a side force is applied to the exposed proximal portion the needle 104 will simply bend relative to the plane of the foam 263. Under the foam 263, there is a sufficient volume for the distal tip of the needle 104 to move around within the sharps container housing 295. Because the foam 263 can allow for movement of the needle 104 even after it has been inserted, there is a reduced risk of injury to human skin by the proximal aspect of the needle 104. As discussed, a downward force on the needle 104 will cause it to be pushed further through the foam 263 into the sharps container and a horizontal force will cause the needle 104 to rotate about the foam 263 entrance point.
In different embodiments, the hole 293 size and the foam 263 thickness can both be variable. The size and physical properties of the foam 263 and hole 293 can be selected to provide optimized functionality based upon the types of needles 104 being used. Smaller needles 104 are lighter weight can use thinner lower density foam 263 over a smaller hole 293 while longer needles 104 may need thicker higher density foam 263 over a larger hole 293. The shape of the underlying volume of the container will need to be optimized to allow for maximal needle 104 tip excursion.
In an embodiment, the position of the holes 293 can be indicated by corresponding circular markings 297 on the exposed side of the foam 263 so that the user can easily locate the holes 293 under the foam 263 layer. The holes 293 can be numerically marked 259 so to help with needle 104 counts. The hole 293 can be part of a tubular structure that extends into the housing 295 as shown in
With reference to
In other embodiments with reference to
In an embodiment, a modular medical device comprising a forearm-mounted puncture barrier functions as a platform upon which one or more used needle repositories and/or one or more suture packs or suture pack carriers can be mounted. The used needle repositories and the suture packs/carriers can be coupled to the forearm mounted puncture barrier by any of the coupling mechanisms described above or by any other suitable method. The used needle repositories can include various needle trap devices and the suture pack carriers can include a clip for holding a suture pack to the forearm mounted puncture barrier. The needle trap can be removable from the forearm mounted puncture barrier and is intended for replacement when the device has secured the intended number of contaminated needles.
An embodiment of a used needle trap is illustrated in
In an embodiment, the entry zone 333 of the used needle container 331 can be a partially circular flat zone or area in the X-Y plane that is an exposed part of the lower structure 341. The surgeon can hold the used needles 104 with a needle driver and place the used needles 104 on an upper surface of the entry zone 333. The contact and/or force of the needle 104 against the entry zone 333 can cause the curvature of the used needles 104 to be moved into a planar orientation flat against the landing zone surface X-Y plane with the convex mid-portion of the curved needle 104 facing or pointing towards the transitional zone 335.
The entry zone 333 can be wider (y-axis) relative to needle slot 349 and the perimeter around the entry zone 333 can have a contrasting color to aid visual recognition. The upper surface of the entry zone 333 surface can include a low friction material. Graphic guides on the entry zone 333 surface can help to reinforce needle 104 rotational orientation. The needle driver slot 343 can extend into the entry zone 333 and the width of the needle driver slot 343 can be greater or oversized in the entry zone to facilitate fast location of the entrance to the needle trap with the needle driver. The needle driver slot can taper as it extends through the transition zone 335 towards the secure zone 337, to provide a self-centering close fit with the tip of the needle driver in the transition zone 335 and secure zone 337.
The transition zone 335 is disposed between the entry zone 333 and the secure zone 337. In the transition zone, the compressive side load on the needles ends may be increased and the depth (z-axis) of the needle slot can narrowed as the secured needles are translated through the transition zone, constraining the needles to a single needle deep array extending longitudinally along the secure zone 337.
The secure zone 337 comprises the region adjacent to the transition zone 335, in which full compressive side loading is applied to the needle ends to prevent unintentional removal or dislodging of the needles.
The boundary 345 may be concave, wedge or “V” shaped, with the apex of the “V” shape pointing towards the secure zone 337 to promote proper orientation of the needles 104.
In an embodiment, the transition zone 335 can include a concave, wedge or “V” shaped boundary on a side of the entry zone 333 in the upper structure 339 with the apex of the “V” shaped boundary pointing towards the secure zone 337 to promote proper orientation of the needles 104. The secured needle 104 in the needle trap 331 can be configured to have the convex side of the needle 104 facing the secure zone 337 and the concave side, sharp point and tail of the needle 104 facing towards the entry zone 333. Thus, the needle trap 331 can be configured to have the sharp leading and trailing ends of the needle 104 pointing away from the direction of motion, thereby reducing the risk of needle-stick injury. The transition zone 335 can have a flared cowling over a portion of the landing zone and tapered surfaces in both the Y-axis and the Z-axis, to reduce the width and height from the entry zone 337 to a single needle height and width in the used needle slot 349 as the needle 104 is moved along the longitudinal X-axis path from the transition zone 335 to the secure zone 337. The needle driver slot 343 can intersect a portion of the needle slot 349, such as a middle portion of the needle slot, and can be in the midline of the used needle trap 331 in the X-axis such that the distal tip of the needle driver can translate the needle 104 along the X-axis of the used needle trap 331. Alternatively, the needle driver slot 343 can intersect the needle slot 349 off the midline or asymmetrically, such that the needle driver slot extends along an axis substantially parallel to, but not overlapping, the X-axis of the used needle trap 331. The needles 104 can slide within the needle slot 349 deeper into the secure needle zone 337 without excessive resistance or sensitivity as to how the needles 104 are grasped by the needle holder. In an embodiment, the secure zone 337 can prevent used needles 104 from being removed from the used needle trap 331.
In a preferred embodiment, the needle 104 is moved into contact with the entry zone 333 of the lower structure 341 by the surgeon manipulating the tip of the needle driver in the needle driver slot 343. The needles 104 can be pushed against the entry zone 333 and become aligned with the X-Y plane of the used needle trap 331. The needles 104 can then be moved in translation along the longitudinal X-axis of the used needle trap 331 from the entry zone 333 into the transition zone 107 where the needles 104 slide into the used needle slot 349 with the convex side facing the secure zone 337 and the sharp tip and tail of the needle 104 facing the entry zone 333. The needle driver can move the used needles 104 into the used needle slot 349 in the secure zone 337 until the needle driver runs into the end of the needle slot 349 or the last inserted used needle 104, or the needle 104 contacts the end stop 363 of the needle slot 349.
In an embodiment, the distal tip of the needle driver holding a needle 104 can have an elongated cross section and the width of the needle driver slot 343 can narrow in the secure zone 337 so that the distal tip of the needle driver must be oriented with the longer cross section dimension aligned with the needle driver slot 343. This needle driver orientation can also cause the needle 104 properly aligned across the width of the secure zone 337 within the needle trap 331. Thus, the narrowing of the needle driver slot 343 can force the needle driver to properly orient the needles 104 in the secure zone 337 as the needle driver slides against the sides of the needle driver slot 343 in the secure zone 337.
In the secure zone 337 the Z-axis depth of the needle slot 349 narrows so as to compress against and orient the used needles 104 in parallel alignment with the needles 104 positioned across the width of the needle slot 349 and center portions of the used needles 104 spanning across the needle driver slot 343. Once the needle 104 has been fully inserted into and can proceed no further in the X direction the surgeon can release the used needle 104 in the secure zone 337 and this process can be repeated for the next used needle. The tip and trailing ends of the used needles 104 can be secured within the used needle slot 349 in the secure zone 337 between the lower structure 341 and the upper structure 339. Once the surgery is completed or when the used needle trap 331 is full or during a medical procedure, the used needles 104 stored in the needle trap 331 can be easily counted. In
The upper structure or front cover shell 339 comprises the top half portion of the needle slot 343, and can be joined to the lower structure 341 by adhesive bonding or ultrasonic welding. The upper structure may comprise an injection molded clear polycarbonate, or other optically transparent material. The inner surface of the upper structure may have protrusions or nubs 361, also referred to as tactile bumps, intended to provide separation between secured needles, to increase resistance against the removal of secured needles, and to provide tactile feedback during translation of needles from entry or transitional zone into the secure zone. The upper structure may includes 2-20 tactile bumps, 5-8 tactile bumps, or 3-10 tactile bumps. The inner surface of the upper structure may have a protruding needle stop 363, intended to prevent needles from being translated beyond the needle driver slot which would prevent accurate visual counting. The upper structure that covers the transition zone 335 is flared at the boundary 345 toward the entry zone 333 to present a deeper (z-axis) spatial target for fast location of the entrance to the trap with the needle driver.
The lower structure or rear shell 341 comprises the bottom half portion of the needle slot 343, and can be joined to the upper structure 339 by adhesive bonding or ultrasonic welding. The inner surface of the lower structure may have wells or recesses 359 within which the compressive members 347 may be adhesively attached. The recesses may decrease in depth within the transition zone from the entry zone to the secure zone to increase compressive side load on needle ends. The deeper recesses at the boundary of the entry and transition zones can prevent the end of the compressive members from being displaced by the needles during translation. The outer surface of the lower structure can incorporate recesses within which the foam connectors 357, adhesive pad 355, and secure zone suture pack holder 351 may be adhesively attached. The walls of the recesses can provide a standoff to provide separation between the needle trap and barrier mounting surface for the needle driver tip. The lower structure may comprise injection molded colored polycarbonate, or a material similar in composition to the material of the upper structure.
Compressive members 347 can comprise open cell urethane foam strips adhesively bonded to the lower structure 341. The compressive members can provide side load compression on the ends of the used needles along the secure zone.
The foam connectors 357 can provide an attachment interface between the needle trap 331 and a barrier or platform as described herein. The foam connectors may be adhesively attached within recesses to the outer surface or underside of the lower structure 341. Loop connectors may be adhesively attached to the exposed foam surface, which can extend above the recess walls and provide a means of attachment to corresponding hook connector adhesively attached on the exterior barrier surface.
The secure zone suture pack holder 351 can provide a means to permanently attach a suture pack 101 next to the needle trap 331, providing a means for proximity reconciliation in real time by both the surgeon and operating room assistants in the near surgical field. The suture pack holder may comprise a closed cell foam pad, adhesively bonded to the outer surface of the lower structure 341. The exposed top surface of the holder may be covered with pressure sensitive adhesive for attachment to the rear surface of a suture pack. Loop connectors can be adhesively attached to a raised surface 344 on the bottom surface of the suture pack holder, and provide a means to attach to a hook connector on a barrier or platform as described herein.
The suture pack holder can be configured to flex between the needle trap and attached suture pack to enable the combined assembly to assume a lower profile when mounted on the forearm by “tenting”. Alternatively or in combination, the suture pack holder can be coupled to the needle trap via a hinge 346, as shown in
The adhesive pad 355 can be attached to the outer surface or underside of the lower structure 341, underneath the entry zone. For example, the adhesive pad may be attached to the lower structure with pressure sensitive adhesive. The exposed surface of the adhesive pad can be covered with pressure sensitive adhesive providing a means to attach a suture pack 353 under the entry zone of the needle trap, along the longitudinal axis of the forearm (x-axis). An additional piece of loop connector may be attached to the underside of the suture pack 353, to enable additional stabilization of the suture pack by attaching to a hook connector on a barrier or platform as described herein.
The used needles 104 can be held in the needle slot 349 between an upper structure 339 and a lower structure 341. Compressive members 347 can be placed on the lower structure 341 below the needles 104 in the secure zone 337. In an embodiment, an elastic and/or compressible member 347 material can be foam, rubber, elastic plastic or any other suitable material or mechanisms that can be attached to the inner surfaces of the lower structure 341 facing the needle slot 349. In the illustrated example, compressible member 347 can have a uniform thickness and leading edges of the compressive members 347 can be bend downward at the leading edge (towards the entry zone 333). In the illustrated embodiments, the compressive members 347 can fit within recesses 359 in the lower structure 341. The leading edges of the recesses 359 can be deeper than the other portions of the recesses 359 and this curvature of the compressible member 347 can provide a gradual narrowing of the needle slot 349 as the used needles 104 slide over the compressible member 347 into the secure zone 337.
With reference to
In different embodiments, the secure zone 337 can incorporate other types of retention systems. For example, the retention system can include a compressible member 347 which can be fabricated from: foam, Velcro loop or any other suitable media. The compressible member 347 can be compliant and can compress the needles 104 against the bottom side of the upper structure 339 between retention features. The compressible member 347 can have a dimensional interference with the protrusions 361. In an embodiment, the density of the retention media material can be less than or equal to 4 lb. For example, the retention media material can be polyethylene or polyurethane foam which can provide a low coefficient of friction against a sliding needle 104.
In the illustrated embodiment, a suture pack 101 can be attached to a suture pack holder 351 that can be can be attached to the secure zone 337 portion of the needle trap 331 with an adhesive. In another embodiment, another suture pack 353 with sutures 103 can be attached to the entry zone 333 with an adhesive 355. The suture pack holder 351 and/or suture pack 353 can provide a rigid base under the suture pack 101 which can prevent the suture pack 101 from being bent while attached to a forearm barrier or any other structure. Bending of the suture pack 101 can result in loosening of needles 103 in their mounts which can potentially result in a lost needle 103. The suture pack holder 351 and/or suture pack 353 can is designed to either extend from or be attach as separate pieces to the needle trap 331. In an embodiment, the suture pack holder 351 and/or suture pack 353 and the trap 331 can be manipulated into a compact or flat space saving configuration for shipping and storage and then expanded into the illustrated configuration prior to use.
In an embodiment, the needle trap 331 and suture pack holder 351 and/or suture pack 353 can be attached to another structure such as a protective barrier worn on a forearm of a surgeon using various different types of connection mechanisms. For example, the needle trap 331, suture pack holder 351, and suture pack 353 can be attached to another structure such as a protective barrier with a hook and loop connection mechanism. At least a portion of the protective barrier can be covered with a hook material which can be adhesively bonded to the protective barrier and back portions of the needle trap 331, suture pack holder 351, and suture pack 353 can be adhesively bonded to a loop material. In another embodiment, the needle trap 331 can be attached to a barrier or any other object with adhesive backed foam 357. In an embodiment the needle trap 331 can include one or more pieces coupled to a back surface of the lower structure 341.
Although the needle trap has been described and illustrated as having a specific configuration, in other embodiments various other configurations of components can be used to hold the needles in the needle trap. For example in an embodiment, the compressive members 347 illustrated in
In other embodiments, other mechanisms can be used to keep the used needles in the secure zone of the needle trap. For example, the used needle container can include magnets mounted on the upper structure and/or the lower structure on opposite sides of the needle driver slot. The needle driver can be used to move the used needles into the needle slot and when the needles are released, the magnets can hold and secure the needles within the secure zone.
With reference to
Although the elastic material 365 is illustrated as having flat inner surfaces, in other embodiments, the elastic material 365 can have various surface features. For example with reference to
With reference to
A feature of the needle trap 331 is the ability to easily count needles that are placed in the secure zone 337. As illustrated in
Housing 340 defines needle slot 349, which comprises channel slot 349 having an elongate cross section sized to receive the plurality of needles. The housing 340 comprises an overall length L, an overall thickness T, and a first width W1 comprising an overall width, and a second width W2. The needle driver slot 343 comprises a width S to receive needles. The driver needle slot comprises a length dimensioned larger than a width of the slot to allow placement of a plurality of needles in the secure zone. The needle driver slot comprises a guide to guide the needle driver as the needle driver and needle are advanced along the slot. An upper flange portion F1 and a lower flange portion F2 extend from the housing 340. The upper flange portion F1 can be flared upward to facilitate needle placement in the slot. Alternatively or in combination, the lower flange portion can be flared downward. The upper and lower flange portions may define a landing zone to receive needles from a needle driver.
The transition zone of the needle slot is dimensioned larger than the secure zone to facilitate placement of the needles in the needle slot. The elongate needle channel slot comprises a first elongate width CW1 near an opening of the needle slot 349, and a second elongate width CW2 in an interior secure zone of the needle slot. The elongate needle channel slot comprises a first thickness CT1 near an opening of the needle channel slot 349, and a second thickness CT2 in an interior secure zone of the needle slot. The first thickness CT1 can be at least about twice as thick as the second thickness CT2, for example.
The transition zone of the needle slot comprises a guide in order to facilitate placement of the needles in the needle slot. The first channel width CW1 is dimensioned larger than the second channel width CW2 in order to provide a larger entry zone to receive needles and facilitate placement of needles in the secure zone. The second channel width CW2 is dimensioned to receive the plurality of needles arranged in a row in the secure zone. The needle slot channel comprises a first thickness CT1 and a second thickness CT2. The first channel thickness CT1 is dimensioned larger than the second thickness CT2 in order to facilitate placement of needles in the secure zone comprising second thickness CT2. The second thickness CT2 can be dimensioned smaller than a thickness of the needles as described herein in order to contain the needles with at least some mechanical resistance and deformation of one or more interior structures, such as a surface or protrusions of the interior surface. The first thickness CT2 is dimensioned larger than the thickness of the needles placed therein in order to easily place the needles in the transition zone.
In many embodiments, the needle trap is configured to provide at least some resistance to the needle sliding along the needle slot in the secure zone, in order to stabilize and render innocuous the needle in the secure zone, such that the needle is secured. One or more of the upper or lower structures of the needle slot can be configured to deflect when the needle is advance into and placed in the secure zone, for example. Alternatively or in combination, the interior of the needle slot channel may comprise structures configured to one or more of deflect, deform, stretch or bend within the secure zone in order to stabilize the needles within the secure zone.
In some embodiments, the resistance of the needle driver along the needle driver slot is less than the resistance of the needle along the needle slot when the needle is advanced along the slot with a needle driver.
In some embodiments, the resistance of the needle receptacle against the needle driver is less than the resistance of the needle receptacle against the needle.
In some embodiments, the force imparted by the needle driver slot against movement of the needle driver is less than the force imparted by the needle slot against movement of the needle.
In some embodiments, the force imparted by the needle receptacle against movement of the needle driver is less than the force imparted by the needle receptacle against movement of the needle.
In some embodiments, the friction force between the needle driver slot or slit and the needle driver is less than the friction force between needle slot and the needle.
In some embodiments, the friction force between the needle receptacle and the needle driver is less than the friction force between the needle receptacle and the needle.
Although reference is made to dimensions of the needle trap having a substantially flat configuration, the needle trap can be configured in many ways. For example, the needle trap 331 may comprise a conformal material that allows the needle trap to be bent or curved, for example.
In other embodiments, additional devices can be used with the needle trap 331 to facilitate remote counting and tracking of needles. With reference to
The electrical counter mechanism can comprise an electrical circuit with electrical current flowing through the needles 104 in the secure zone and the control circuitry 375. The electrical resistance changes based upon the number of needles 104 stored in the secure zone in contact with both of the conductive elements 371. The electrical circuit can have a higher electrical resistance with fewer needles 104 in the secure zone. The electrical resistance can decrease with more needles 104 in the secure zone. Each of the used needles 104 can each have an electrical resistance between the conductive elements 371 that is substantially the same. Thus, each of the used needles 104 can function as a resistor in the electrical circuit and multiple used needles 104 in the secure zone can function as a plurality of parallel resistors.
The basic electrical circuit equation is V=I R where V is voltage, I is current and Rtotal is the cumulative needle resistance. The cumulative electrical resistance can decrease with each additional stored needle in the secure zone. The equation for parallel resistors is 1/Rtotal=1/R1+1/R2+1/R3 . . . . However, the resistances of the needles can all be substantially equal, i.e. R1=R2=R3 where R1 is the electrical resistance of each used needle. The cumulative electrical resistance needles equation becomes 1/Rtotal=N/R1 or Rtotal=R1/N where N=number of needles. Thus, the number of needles can be calculated with the electrical circuit by V=I R1/N or N=I R1/V. Changes in the cumulative resistance and impedance of the parallel needles can alter the electrical current flowing through the electrical circuit. The voltage V and R1 values can be substantially constant. Thus, changes in the electrical current (I) are based upon the number of parallel needles in the secure zone. The control circuitry 375 can include an ammeter that measures the electric current (I) in the circuit and based upon the measured current, the control circuitry 375 can calculate the number of needles in the secure zone. The control circuitry 375 can output a signal to the visual display 377 that corresponds to the number of needles in the secure zone. In an embodiment, the number of needles N can be displayed on the visual display 377. With reference to
With reference to
As discussed, the middle portions of each of the needles in the secure zone 337 of the needle container 201 are visible through the needle driver slot 343 which can also function as a window. Counting of needles 104 can be improved by fabricating a needle container 201 from a clear casing and clear foam materials an embodiment of which is shown in
In another embodiment, a visible red dot can appear wherever a needle is present in the secure zone and each dot can represent a different needle in the secure zone. In other embodiments, different color dyes can be used with some or all of the needle depressions. It can be easier to count different colored dye markings or alternatively, if the dyes are arranged in a repeating sequence. For example a first needle position depression can be red, a second needle depression can be blue, a third needle depression can be green, a fourth needle depression can be purple and a fifth needle depression can be yellow. This color sequence can repeat for all subsequent depressions in groups of five or any other numeric interval of depressions. Thus, a sixth needle and eleventh needle depressions can be red, a seventh and twelfth needle depressions can be blue, etc.
In an embodiment with reference to
With reference to
With reference to
With reference to
The camera can face the needle trap 331 and also possibly the suture pack(s) 101. The images of the needle trap 331 can be transmitted to the visual display(s) 337 which can be visible to another person. For example, the remote visual display(s) 337 can be a video display mounted on an operating room wall. As discussed, a portion of each of the needles 104 is visible from the upper surface of the needle trap 331 through at least the needle driver slot 343. Thus, a displayed image of the needle trap 331 on the surgeons forearm can show the number of used needles 104 in the needle trap 331 and new suture needles 103 in the suture pack 101. A surgical assistant can view the display 337 and see the suture pack(s) 101 and the needle trap 331 with the secured needles 104 to track in real time. The surgical assistant can then provide additional suture packs 101 if additional needles 103 are required and provide new empty needle traps 331 as the barrier mounted needle traps 331 become full of used needles 104 and needs to be replaced. Also, if a needle 104 is lost the error can immediately be detected by someone monitoring the surgical procedures or by the processor which can detect the sequential removal of new needles 103 from the suture pack and the deliver of the used needles 104 to the needle trap 331. Although an exemplary set of system components has been described, in other embodiments, the needle count components can include but are not limited to: dedicated receivers, electronic watches, smartphones, tables, computers, headsets, earpieces, displays, or any other suitable device for the purpose of tracking the needles.
As discussed, mid-bodies of needles 104 are visible through the needle driver slot 349 in the needle trap 331. In an embodiment, the processor 393 can run a software program that can interpret the visual display signals from the needle sensor 389 (camera) and determine the number of needles 104 in the needle trap 331 as well as the needles 103 in the suture pack 101. The processor 393 can then output this needle count number on the visual display 377 which can help with the needle counting process. In other embodiments, the needles 104 can include markings 397 or transmitters that can help track the needles 104. In an embodiment, the markings can visual codes such as bar codes, quick response (QR) codes, color codes, numeric markings or any other markings which can provide at least some identification information about the needles 104. The markings can be placed on the middle body portion of the needles 104. When the needles 104 are placed in the needle trap 331, the markings can be visually detected through the needle driver slot 349 in the needle trap 331 by an optical sensor such as a scanner or a camera. In an embodiment, an optical needle sensor 389 can detect the markings and the processor 383 can interpret the markings and determine the identifications of the needles 104 based upon the markings. This identification information can then be used for needle tracking and needle reconciliation. The identification information can also be output to the visual display 377.
In other embodiments, other mechanisms can be used for needle tracking. For example, in an embodiment the needles 104 can include embedded electronic components such as a radio frequency transmitter such as a radio frequency identification tag (RFID) which can transmit an RF identification signal in response to exposure to an interrogating radio wave. In an embodiment with reference to
In other embodiments, the suture packs 101 can also have integrated tracking mechanisms. For example, the suture packs can include an active electronic sensor that can be activated when suture pack is opened. This active signal can be transmitted to a processor off the surgical field that can monitor the use of the suture packs and know which needles must be reconciled after the suture pack is used. In an embodiment, these active signals can be transmitted wirelessly from a suture pack or a suture pack sensor to a remote receiver. These active signals can be processed by a processor as described above. This feature can allow the needles to be tracked from the suture packs to the needle trap in a closed loop manner to further insure that all needles are accounted for.
In another embodiment, the tracking of the needles can be done more locally on the barrier which can be mounted on the forearm of the surgeon. In this embodiment, a processor can be mounted on the barrier and the processor can keep track of the locations of all needles through out the surgical procedure. An active signal can identify a suture pack that is being opened and the identities of all of the needles in the newly opened suture pack. The system can identify the movement of each of the needles from the suture pack through a patient and into the needle trap. If a needle is lost the processor that can output an error signal to an output device such as a visual display or audio output device can immediately detect the error. If possible, the surgical procedure can be temporarily stopped until the lost needle is found. The described needle tracking can also provide useful needle tracking information that can be stored in a data center and the number of needles in the near surgical field can be automatically reconciled in real time. As needles are secured in the needle trap, the system can broadcast correlation information for needle reconciliation.
In another embodiment, the suture dispenser and needle trap can be combined onto a single mount that attaches to the proximal end of a surgical tool such as forceps. Such configurations can allow attachment to the slotted shape of the forceps with adequate mechanical integrity such as to avoid displacement with the mechanical forces anticipated during manipulation of the tools against the needle trap.
In an embodiment the suture dispenser and needle trap can be attached to the surgical tool with a mechanical clip that secures a sufficient length of the suture dispenser and needle trap to the tool (forceps) base to provide rotational and translational stability. In another embodiment, the clip can contain adhesive mounts. In another embodiment, magnets can augment the secure attachment of the suture dispenser and needle trap to the forceps.
In other embodiments, the needle trap and/or suture dispenser can be attached to the surgical drapes covering the patient and can be positioned adjacent to the wound. In an embodiment the suture dispenser and needle trap are mounted on a protective platform that secures position on drapes and the platform can be secured to the drapes with an adhesive or any other suitable coupling mechanism.
The suture pack dispensers can have multiple configurations and designs. In an embodiment, suture pack dispensers can secure existing suture packs to the barrier. In other embodiments, needles with attached suture are secured in a structured array for easy access by the surgeon. In another embodiment, non pop-off suture needles are compatible with the suture packs and suture pack dispensers. The non pop-off needles can include but are not limited to swaged on needles, running suture needles, barbed running suture needles, etc. These needles can be used for creating multiple surgical knots and/or for running suture application that can be dispensed as single or double needles.
In an embodiment, a spool can be attached to the forearm mount or barrier for securing the running needle. This embodiment can include multiple spool mounts attached to the barrier for the forearm configuration, or to the instrument clip construct for the forceps attached device. In an embodiment the suture spools can be stack together for lower profile. In another embodiment the spool can allow for rotation for easier dispensing of the suture. Multiple mechanisms for securing the needle, which is attached to the thread wound around the spool, can includes mechanical, adhesive, magnetic mechanisms and multiple needle enclosure designs.
Used Needle Receptacles
In many embodiments, various types of used needle receptacles can be mounted on any of the disclosed barriers and platforms. With reference to
In an embodiment with reference to
In an embodiment, the box 260 with transparent dome 262 could be mounted on a platform or barrier on a forearm of a surgeon. When the used needle 104 is used to install a suture and is then placed in the used needle receptacle 257, the surgeon can hold the used needle 104 with a needle driver, place the needle 104 into the used needle receptacle 257 though an opening under the dome 262. The surgeon can then insert the needle 104 into the foam 263 and rotate the needle driver and needle 104 to fully insert the needle 104. The initial motion of inserting the needle 104 can be tangential to the forearm and there can be a lower likelihood of missing the foam 263 and causing injury. However, there can be problems with this configuration. Because the dome 262 makes the foam 263 less accessible, it can be difficult to properly place the needles 104 in an organized manner unless significant effort and attention to needle 104 placement is performed by the surgeon. Also, the needles 104 placed closest to the dome 262 opening may possibly project the proximal ends out of the needle receptacle 257 from the opening which can potentiate injury since they may not be covered by the dome 262.
In another embodiment as illustrated in
With reference to
With reference to
In other embodiments, a used needle receptacle 257 can include both magnets 287 and foam 263. In an embodiment with reference to
With reference to
With reference to
The used suture needle receptacle 257 can be mounted on a platform with the opening facing away from the platform. The cylindrical geometry of the used suture needle receptacle 257 enables the housing 295 to be rotated in the mounting plate to present the foam 263 at optimal angle for both forehand and backhand needle driver rotation which can be easily used by both left and right handed users. The size of the opening may provide safety features. A hand or a fingertip is less likely to be accidentally inserted into a smaller opening than a larger opening and injury is less likely. In an embodiment, it is possible to have a larger number of smaller containers with each container limited to 5 needles per housing 295. The illustrated design of the housing 295 can allow either end of the needle 104 to be inserted into the foam 263.
With reference to
With reference to
With reference to
With reference to
With reference to
The needle traps 331 illustrated and described with reference to
With reference to
With reference to
In other embodiments, the needles 104 can be inserted into different surfaces of the used suture needle receptacles 257. For example, with reference to
With reference to
With reference to
With reference to
With reference to
With reference to
With reference to
With reference to
With reference to
Barrier
As discussed, the efficiency of suture installation processes can be improved by placing used suture needles in a used needle receptacle or a used needle trap within the near surgical field. In an embodiment with reference to
The barrier can function as a protective layer for a user and can be made of various materials and can have various different shapes. The barrier can be worn over a limb of the user and can be made of any material that can prevent needles from passing through the barrier and contacting the covered limb of the user. With reference to
When the barrier 403 is used, a user can wrap the barrier around the limb to be protected. In this example, the barrier 403 is designed to protect a forearm. With reference to
With reference to
With reference to
In addition to providing protection, the barriers can also provide mounting surfaces for various surgical components. With reference to
With reference to
With reference to
In an embodiment, the barrier 403 is needle puncture resistant, unobtrusive and conformal. The barrier 403 design and fabrication can be an optimized combination of hardness and thickness. More specifically, the barrier 403 can be hard enough to resist puncture and thin enough to remain adequately flexible to be comfortable during use. In a an embodiment, the barrier 403 can be fabricated from extruded Poly ethylene terephthalate glycol-modified (PETG) or polycarbonate which can be between about 0.010-0.04 inch in thickness. The hardness of the barrier 403 can have a hardness between about 45 A and 65 D (Shore hardness scale A and D, respectively). In an embodiment, the barrier 403 can be die cut from flat sheet of puncture resistant material. In another embodiment, the barrier 403 can be thermo-formed in an anatomically conformal, semi-conical shape that can be attached to the forearm and adjusted to optimize fit with a single hand. In an alternative embodiment the barrier 403 can be blow-molded and rotationally laser cut into the designed shape. In different embodiments, barriers 403 can be fabricated using various other manufacturing processes. In an embodiment, a conformal foam layer can be mounted on inner surface of the barrier 403. This foam forearm interface surface added to the barrier can improve comfort. In some embodiments, the barriers 403 can be packaged in a flat form. However, in other embodiments, the barriers 403 can be packaged in a rolled up configuration. The barriers 403 can be packaged with one or more needle traps.
With reference to
With reference to
The suture pack mounts can be integrated with or coupled to the needle trap. In different embodiments, the suture pack mounts can be positioned in two orientations. A suture pack mount 183 can be positioned above the needle trap 331 towards the radial aspect of the forearm. In another embodiment, a suture pack mount 183 can be positioned under the needle trap 331 in a longitudinal configuration. In an embodiment, a die cut foam mount can be attached to an underside of the needle trap 331 with PSA. A hook or loop fastener on an underside of the foam mount can be attached to a mating fastener on the barrier 403 to increase stability of a suture pack 101. Alternatively, the suture pack 101 can be attached to the needle trap 331 by means of PSA on underside of needle entry zone 333. In an embodiment, a hook or loop fastener can be attached by to the bottom of the suture pack 101 which in turn attaches to a mating fastener on the outer surface of the barrier 403.
Legs 175 or straps can extend outward from the barrier 403 at a distal portion and loop material 129 can be attached to an upper surface of one of the legs 175. With reference to
With reference to
In other embodiments a needle receptacle 257 and/or a needle trap 331 can be attached to a surgical tool 201. With reference to
The needle receptacle 257 and suture pack clip 115 assembly 206 can also include a tool mounting interface 433 illustrated in
In other embodiments, other types of needle receptacles can be attached to surgical tool 201. An embodiment of needle trap 331 attached to a proximal end of a surgical tool 201 is illustrated in
With reference to
In the illustrated embodiments, the needle traps 331 can be configured in a back-to-back orientation. The needle traps 331 can be positioned at right angles to each other, 45 degrees off set from an axis of the surgical tool 201. Although the tool mounting interface 433 illustrates a tool slot 439 attached to the surgical tool 201, in other embodiments the needle trap assembly 332 can be connected with any other types of connection mechanisms such as but not limited to: hook and loop, tabs, adhesives or foam etc. These various mechanisms can be used to secure the needle trap assembly 332 to various forceps geometry.
For clarity, all components of the needle traps 331 are not illustrated in
The weight of the combined needle traps and mounting structure can be within a range from about 5 grams to about 80 grams, for example within a range from about 10 grams to about 40 grams, for example. The weights within these ranges can provide balance to the surgical tool on which one or more needle traps are placed.
The needle trap as shown in
Alternatively, a pair of opposing suture packs can be mounted on the instrument, and used needles stored elsewhere such as the volar forearm as described herein, and for example as described with reference to
Surgical Gown
In an embodiment, a surgical gown can be constructed with barrier or multiple barriers built into the sleeves of the gown. Typically the sleeves of the gown are manufactured of lightweight fabric that is impenetrable to fluids to protect surgeon and patient from cross contamination. These gown materials however may not protect a surgeon from needle or sharps penetration or tearing. In an embodiment, the gowns can be created with barrier zones on the forearms that can be impenetrable to needle perforation and can prevent tearing.
In an embodiment with reference to
In another embodiment with reference to
In another embodiment the barrier 403 can be a flexible plastic shield that is substantially flat or slightly curved and conforms to the arm when the barrier 403 is attached to the forearm over the surgical gown 401. In other embodiments, additional straps and/or tabs can be additionally used to augment the coupling of the forearm sleeve 413 to the barrier 403 and improve the connection security. For example, Velcro, wet and dry adhesives, magnets and mechanical locks or any other suitable types of connection mechanisms such tabs and straps can be used to secure the sleeve 413 and barrier 403 to the user's forearm.
In an embodiment, the surgical gowns can be constructed of multiple pieces, panels and/or sheets of thermoplastic materials. These pieces can be seamlessly welded together to create the surgical gowns. Such thermoplastics gown materials can be used to create zones of increased material thickness that can act as barrier zones. In an embodiment, the barrier is comprised of a thickened layer and/or multiple layers of the gown material that can be thermally heated and compressed such that the material properties of the barrier prevent needle penetration with forces that one reasonably may anticipate in surgery.
With reference to
With reference to
In other embodiments, the barriers 403 illustrated in
In other embodiments, various mechanisms can be used to mechanically attach one or more suture packages to the barrier mounted on the forearm of a surgeon. With reference to
In different embodiments, the surgical gowns with barrier zones can be disposable gowns or reusable fabric gowns. Alternatively, the gown can be constructed of a disposable gown material with the barrier device attached to the forearm of the gown. However, after use, the barrier can be removed from the disposable gown and reused. In these embodiments, the barrier can be attached to the sleeve with an adhesive, hook and loop coupling, or any other suitable releasable attachment components.
In an operating room, sterile sleeves 413 as illustrated in
Glove Extensions
In the operating room the surgeon can wear an operating gown that extends to the wrist or palm of the surgeon. The surgeon can then place a glove or multiple layers of gloves on the fingers and hand can then pulled proximally to cover the distal extent of the sleeve of the gown. Thus, a distal portion of the sleeve of the gown can be covered a proximal portion of the gloves.
Embodiment of the present invention can include surgical gloves 481 designed to extend proximally up the surgeon's forearm. Gloves 480 may include a glove portion 481, a glove extension 483 and a barrier 403. The glove portion 481 can be fabricated with latex or latex like polymers such as but not limited to: nitrile, isoprene, or vinyl. In an embodiment, a sleeve extension 483 can be coupled to the glove portion 481 and the sleeve extension 483 can be made of a material that is different than the glove portion 480 material covering the fingers. More specifically, the fingers of the glove 481 can be made of a different material than the rest of the glove. Such glove finger materials can include but are not limited to materials usually encountered in the sleeves of gown. Such materials include fabrics and thermoplastic materials.
In an embodiment, a glove can have a proximal extension 483 that includes a barrier 403 zone having a barrier material that can resist and/or prevent sharps from penetrating the barrier 403 and contacting the flesh under the barrier 403. In an embodiment the glove barrier can also allow any of the described components to be attached. For example, needle trap(s) and/or suture pack(s) can be attached to the glove barrier using any of the described attachment mechanisms such as but not limited to: adhesives, hook and loop connectors, magnets, mechanical couplings, etc.
In an embodiment, the glove with an integrated barrier can cover the hand and further comprise a proximal extension that extends over at least a portion of the forearm and may possibly extend to the elbow. The proximal extension can contain a barrier that can orient to the radial border of the forearm. Such a barrier can also contain one or more zones for attachment of a needle trap(s) and/or suture pack(s).
In an embodiment, the barrier 403 on the forearm and integrated with the glove can comprise one or more devices that can function to provide a barrier 403 for the wearer of the glove 480. The barrier 403 material integrated with the glove 480 can be made of plastic, metal, fabric, or any other suitable material(s). In an embodiment the barrier 403 can be attached to an inside portion of the glove 480 which can be along the forearm. In another embodiment the barrier 403 sandwiches the glove between an inner and outer layer of the glove material.
Surgeon-Controlled Suture Cutting
Sutures are sometimes swaged into the trailing end of the needle and must be cut at the conclusion of a stitch. A scrub technician may traditionally cut the sutures from the needles. However, enabling the surgeon to cut the sutures can eliminate the need for a third party scrub technician to cut the suture. This procedural change can improve efficiency and safety. Ideally, the suture can be cut without imparting tension on the suture during the cutting.
In an embodiment with reference to
With reference to
With reference to
In an embodiment with reference to
With reference to
With reference to
With reference to
In other embodiments with reference to
In other embodiments, the scissors can be actuated with a pneumatic pressure. In these embodiments, the scissors can be coupled through a pneumatic hose to a control button which can be a valve and a pneumatic pressure source. The scissors can be normally open when the control button is not actuated. For example, when the control button is pressed the air pressure can be directed through a hose to actuate the pneumatic scissors and cut an object between the blades of the scissors. When the control button is released, the air pressure can be vented and the pneumatic scissors can open the blades of the scissor.
In another embodiment with reference to
With reference to
In various embodiments the actuation of the described cutters and scissors can be accomplished by manually squeezing the scissors as discussed above, or by other means such as but not limited to: pneumatic foot pedal coupled to a piston, electronic signal from foot pedal, proximity sensing of suture within cutting zone.
Needle Traps
Surgeons often pull the needle from the tissues after the “last throw” of the needle by grasping the tip portion of the needle. This practice is common as the tip is the portion of the needle showing from the tissues and therefore the needle tip is the easiest portion of the needle to grasp. The needle may not need to be regrasped (in a center portion) after the last throw and therefore grasping of the tip of the needle with the needle driver can provide the safety benefit of securing the tip of the needle within the jaws of the needle driver. If the needle driver and needle are handed to a scrub tech, the needle tip may not be exposed and the needle handling can be less dangerous to the scrub tech and the surgeon. However, in embodiments, the used needles can also be deposited in needle traps that can be configured to receive needles held by their tips by a needle driver.
With reference to
With reference to
With reference to
Another embodiment of a needle trap 311 is illustrated in
In another embodiment with reference to
Another embodiment of a circular needle trap is illustrated with reference to FIGS. 303-306. In this embodiment, the width of the needle driver slot 343 can prevent free rotation of the needle driver 198. The needle driver slot 343 can be slightly wider than the width of the tip of the needle driver 198. This configuration can allow a torque to be applied between the housing 295 and the needle driver 198 which can drive the needle driver 198 through the circular portion of the needle driver slot 343. With reference to
For all of the needle trap embodiments illustrated in
In the illustrated embodiments, the number of needles stored in the needle slot 349 can be determined by counting the needles within the needle driver slot 343. In an embodiment, some or all of the housing 295 components can be made of a transparent material so that a larger portion of the trapped needles 104 can be visible. In still other embodiments, any of the compatible needle counting systems disclosed with reference to
In many embodiments, the needle trap 331 embodiments illustrated in
The materials and structures to stabilize needles as described herein can be configured in many ways. The materials and structures may comprise one or more one or more of a deformable material, an adhesive material or an elastic material, and the material may comprise one or more of a foam, elastic membrane, or an adhesive, for example.
In many embodiments, a needle resistant barrier as described herein can comprise a thin, puncture-resistant material integrated with a flexible web. The barrier can comprise a plurality of bi-stable springs connected by a flexible, in order to accommodate a range of different forearm sizes. The plurality of bi-stable springs can comprise a plurality of stacked bi-stable springs, to adjust a compressive force.
Although the suture handling systems and methods as described herein are presented in the context of a surgeon closing a patient's wound, the systems and methods can be used in any situation involving the handling of suture needles. For example, the systems and methods may be used to safely dispense and dispose of suture needles when the dispensed suture needle is not used to install a suture in a patient. For example, a surgeon may dispense a fresh suture needle, and then decide that he does not want to use the dispensed needle. The surgeon may decide that a needle of a different size would be more appropriate, or that the dispensed needle is not needed after all, for example. The surgeon may accidentally contaminate a freshly dispensed needle before the needle is used (e.g., by touching the tip of the fresh needle against an unsterile surface), and may therefore have to dispose of the needle without using it. A need to attend to another matter may arise after the surgeon has already dispensed a fresh suture needle (e.g., blood splashed on surgeon's gloves necessitating a change of gloves), necessitating the disposal of the fresh needle before it can be used.
As used herein the terms “needle trap” and “needle receptacle” are used interchangeably.
As used herein the terms “shell” and “shell structure” are used interchangeably.
As used herein the terms “panel” and “shell” are used interchangeably.
The present inventors have conducted several experimental studies to determine needle receptacles and barriers that work well in the surgical environment. Several prototypes have been built and tested, and performance metrics measured.
In many instances the needle receptacle is referred to with reference to the receptacle as placed on the volar forearm of the user such as a surgeon. In this regard, the term “distal” may refer to the opening of the needle receptacle that receives the needle from outside the receptacle, and the term “proximal” may refer to the secure zone into which the needle is placed after moving through the distal opening.
The needle receptacle may comprise a front (upper) and back (lower) panel that houses the needles with a secure zone. The needle receptacle may comprise a planar needle slot or groove along which needles are conveyed and within which the needles are housed, partially encased in a parallel, back to back, single layer array, for example. A needle driver slot in the back (lower) panel allows the needle and needle driver to become aligned with the needle slot. The back (lower) needle driver slot can be located distally to the needle slot with an enlarged opening, such that the needle driver can be aligned with the needle slot prior to entry into the needle slot. The experiments of the present inventors have suggested that a back panel landing zone and needle slot having substantially planar configurations may be preferred. For example, the needle slot can be substantially parallel (e.g. generally within about ten degrees) with the front surface of the landing zone, for example coplanar. The inventors have tested a trumpet or funnel shaped landing zone having a tapered concave section, and these experiments indicated that a planar landing zone may provide improved performance. The landing zone can have a distance transverse to the longitudinal axis that defines the width of the landing zone. The maximum distance across of the width of the landing zone can be within a range from about 20 mm to about 60 mm, for example within a range from about 30 mm to about 50 mm. The width of landing zone can taper from the maximum distance to a lesser distance near the needle entry slot, for example adjacent the needle entry slot. The distance across the landing zone near the needle entry slot can be within a range from about 20 mm to about 60 mm, for example within a range from about 20 mm to about 50 mm.
The entry zone of the needle slot can be sized larger than the secure zone of the needle slot. As described herein, the elongate needle channel slot may comprise a first elongate width CW1 near an opening of the needle slot 349, and a second narrower width CW2 within the secure zone of the needle slot. The height of the needle slot above the landing zone can be within a range from about 4-10 mm, for example from about 5-8 mm. The width CW1 can be within a range from about 20 to about 60 mm, for example from about 30 mm to about 50 mm. The entry zone of into the needle receptacle may comprise an upward flare near the edges to provide sufficient clearance for the needle. The upward flare can provide height to the distal opening of the needle slot. The flare can be within a range from about 50 degrees to about 90 degrees relative to the surface of the landing zone. For example, within a range from about 60 degrees to about 80 degrees.
The needle driver slot width is designed to be sufficient to accommodate a needle driver various orientations. The needle driver slot depth of the lower slot is dimensioned to allow protrusion of the needle driver jaws when the needle driver grasps the needle away from the ends.
In accordance with these experiments and contemplated embodiments, the landing zone front face may be substantially planar, and needle slot of the secure zone substantially planar, for example substantially parallel to each other. In some embodiments, the landing zone and needle slot can be substantially parallel with each other. In many embodiments, a plane defined by the landing zone extends through the secure zone of the needle receptacle.
The needle receptacle can suspend the needle/s while protecting the tip and tail end of the needle in a stiff protective container, for example a hard container. The landing zone and secure zone can be arranged to guide the needle and provide tactile feedback to the user.
The needle receptacle may maintain needles along a plane and provides the suspension of the needles such that tip and ends are between the protective stiff cover in front and stiff cover in back, for example hard cover in front and hard cover in back. This can suspend the middle of the needle in air. This configuration allows for counting and allows for access to manipulate and position the needles for counting by visual assessment. The planar orientation can be orthogonal to a user's line of sight when counting and can display the needle in full profile for easy visual assessment. Other planar organization may comprise a needle magnet or a flat adhesive strip, although these do allow for access to the needle, the needle may not be grasp and manipulated as easily.
The thickness of that needle slot in which the needle is housed can be dimensioned appropriately. If the needle slot is too wide, the needle could rotate/twist or come loose. The present inventors have made a limited needle slot groove width between the hard plastic shells and then further reduced this space by using foam compression, which also provides friction component. The arc of the needle can facilitate capture, although straight needles can also be captured. In many embodiments, the needle tip and end are secured within planar recesses such as grooves. Other structures are contemplated and described herein that allow for the suspension or “floating” of the mid portion of the needle, for example in air.
In many embodiments, a slotted structure is configured to allow the tip and tail of the needle to be substantially enclosed while suspending in the slot the mid portion of the needle.
A needle could be contained in the planar recess (Groove) on one end only with the needle tip for instance residing in the longitudinal slot as described herein. The needle tip can be recessed from the frontal surface of the receptacle to provide improved safety.
The lower trap slot can be configured with depth to accommodate the tip of the needle driver that may well extend beyond the needle slot plane. The lower or back slot may comprise a groove of sufficient depth to allow the needle driver to advance the needle along the slot.
The present inventors have conducted experiments to determine suitable amounts of force to advance the needle along the slot or other structure to secure the needle. Structures can be provided to provide a greater amount of force to remove the needle than insert the needle.
While the thickness profile of the needle receptacle can be configured in many ways, the thickness can be less than 2 cm in preferred embodiments, in which the needle receptacle comprises a longitudinal length and a cross-sectional width dimensioned greater than the thickness. The thickness profile can be especially helpful on the volar side of the forearm and other surfaces on the forearm as well. The needle retention device may have a profile above the surface of the barrier of less than 4 cm, for example. The profile can be further reduced by creating a recess in the barrier to accommodate the trap. A cutout can be provided in the barrier, in which the footprint of the cutout corresponds to the trap. Alternatively or in combination when the trap has a solid back wall to the slot and the trap fit with the barrier, the trap can be recessed. The recess may comprise a depth 2 to 5 mm, for example.
The barrier may comprise the receptacle as described herein in order to decrease the profile.
The trap can be configured to facilitate safe handling or transfer between personnel in many ways. The needle landing zone can be used to grasp the needle receptacle. The needle receptacle can be held up to a light source, such that the needles are not obscured by the fingers or hand of the user. The needle receptacle may comprise a material or dye having an orange color, red or other color, for example. The backlight illumination can highlight the profile of the needle when needle visualized through the front face, which can be transparent. The well-defined profile can be helpful for counting, for example by a person or an automated needle counter, such as a video camera coupled to a processor with appropriate software. Any needle receptacle as disclosed herein can be configured with a landing zone that can be used for dual purpose of safe handling and needle placement.
The needle receptacle can be configured with various amounts of resistance in many ways. In many instances, the needle receptacle comprises an amount of force for insertion of the needle and a greater amount of force to remove the needle. The needle receptacle comprises a structure to receive a needle with resistance. The amount of resistance to insertion can be within a range from about 5 grams to 250 grams, for example. The amount of force can be within one or more of the following ranges: about 25 grams to about 100 grams; or about 30 grams to about 90 grams, for example. The needle receptacle may comprise a needle slot, and the amount of force may comprise an amount of force to advance the needle along the needle slot. Alternatively or in combination, the needle receptacle may comprise a needle driver slot, and the amount of force may comprise an amount of force to advance the needle driver along the needle driver slot to secure the needle in the needle slot.
The needle receptacle may be configured to provide an increasing amount of resistance as the needle is advanced along the needle slot. The varying resistance is provided with one or more of a discrete or asymmetric features that protrude into the needle slot, in order to increase compression of the needle and provide tactile feedback as the needle is drawn along the slot.
The needle receptacle may comprise a compressive member configured to secure a needle and provide resistance to movement of the needle against an apposed surface, and wherein the foam structure comprises a gap of less than 2 mm between the foam and the apposed surface.
The needle receptacle comprises a secure zone and can be applied to the forearm and comprises a width of less than 12 cm, and a length of less than 26 cm. The appropriately sized receptacle can be applied to the forearm or a barrier as described herein.
The needle receptacle can also be configured to easily view the needles with various types of illumination. For example, the housing containing the needles may comprise an optically transmissive material. A lower portion of the housing may comprises an optically transmissive material in order to view needles within a secure zone of the receptacle with backlight illumination. Alternatively or in combination, the upper portion may comprise a transparent material to view the needles. The lower portion may comprise a transparent or a translucent material to pass backlight illumination light to the needles. The upper portion may comprise the upper shell, and the lower portion may comprise the lower shell as described herein, for example.
The needle receptacle trap may comprise a landing zone and a secure zone, in which the landing zone is substantially coplanar with the secure zone. The landing zone coplanar with the secure zone can make it easier for a user to place the needles in the trap. The needle can be placed by moving the needle to the landing zone of the needle receptacle and sliding the needle from the landing zone into the secure zone of the needle receptacle.
The needle receptacle may comprise a slotted structure that allows a tip and a tail of the needle to be substantially enclosed while suspending a mid-portion of the needle in the slot.
The needle receptacle may comprise a slot along a secure zone, in which the slot is sized smaller than a finger tip having a size of about 10 mm.
A needle receptacle comprising a needle groove having a thickness small enough to inhibit rotational movement of the needle out of the needle groove.
The needle receptacle may comprise an upper shell structure and a lower shell structure. The upper shell structure may comprise the top needle driver groove and the undulations in the elevated flange, the needle stop, and a portion of the arrow tip. The lower portion may comprise the entry zone, the lower needle driver slot, the arrow tail, and the bevel. The upper shell structure and the lower shell structure may comprise coupling structures 3109 to couple the upper shell structure with the lower shell structure.
The needle receptacle can be placed on the volar forearm of the user on a barrier as described herein. The needle receptacle can be arranged over the volar forearm to allow easy insertion of a used needle when a hand holding needle holder is slightly supinated or slightly pronated. The needle can be placed in the receptacle with rotation of an arm holding a needle driver with shoulder joint rotation in order to align and place the used needle into an opening of the needle receptacle, for example.
While the needle receptacle can be dimensioned in many ways, the needle receptacle may comprises a longitudinal length, a transverse width and a height. The length may be greater than the width and the height, and the width is greater than the height. The length can be within a range from about 4 cm to about 15 cm, the width is within a range from about 3 cm to about 6 cm, and the height is within a range from about 0.5 cm to about 2 cm, for example. The needle receptacle may comprise an opening to receive the needle, and the opening can be sized larger than the secure zone of the receptacle, such that the opening comprises the maximum height and width of the receptacle.
The compressive members are dimensioned to allow the needle to be readily advanced into the secure zone with decreased amounts of resistance. In this regard the cross-sectional dimensions of the compressive members are sized to provide appropriate amounts of resistance. For example, the compressive members may not extend fully outward toward the full width of the bottom shell structure. The compressive members comprise a generally cross-sectional shape having a rectangle. The rectangular shape of the cross-section may comprise a height and a width from with the height is dimensioned to urge the needle upward toward the upper shell structure and the width dimensioned with the cross-section to provide appropriate amounts of resistance. The wider the compressive member the greater the amount of force to the needle. The narrower the compressive member the less the force.
The receptacle can be sized to a range of needles, and may comprise a smaller slot for smaller needle drivers, in which the slot comprises a width of no more than a diameter of a largest needle for which the trap is designed to store.
The longitudinal slot for the needle driver may comprise a through and through slot, in which the slot extends though both sides of the receptacle.
The longitudinal slot may comprise a lower solid wall, in which the wall has a recess or groove of sufficient depth to allow the tip of the needle driver to protrude beyond the needle securement slot plane, in which the needle driver groove or slot extends beneath the needle slot plane by a distance within a range from about 0.1 mm to about 10 mm.
The receptacle may comprise a longitudinal slot bounded by a structure to one or more sides of the slot that creates a varying resistance to translation as the needle is drawn along the slot. The varying resistance can be provided in many ways, and may comprise a discrete or asymmetric features that protrude into the needle slot, in order to increase compression of the needle and provide tactile feedback as the needle is drawn along the slot
The inner surfaces of the needle driver slot can be configured in many ways to provide the user with feedback as the needle driver is being advanced toward the proximal end. For example, one or more of the upper shell or the lower shell may comprise undulating surface structures or protruding surface structures to provide this feedback. For example, small dimples can be provided in one or more of the upper slot or the lower slot to provide the user with tactile feedback. The protrusions and/or recesses provided along the inner surfaces of the needle driver slot are generally symmetrically arranged along either side of the needle driver slot to provide the user with a sense of depth within the slot as the needle is advanced. While the size of the structures that are used can be varied in many ways, in many embodiments the structures generally extend inwardly toward the needle driver slot at least about a quarter of a millimeter, for example at least a millimeter and generally within a range for about a 1/10 of a millimeter to about a millimeter on either side of the needle driver slot.
Referring again to
The chiral barrier can be located along a coordinate reference system, in which the origin corresponds to a central point 3321 of the proximal forearm. The +X direction extends toward the volar side of the forearm; the +Y direction extends in a direction toward the radius of the forearm; and the −Z axis extends toward the distal end of the forearm near the wrist.
The barrier comprises proximal tabs 3285a and distal tabs 3285b configured to allow the user an ergonomic fit. The proximal tab comprises the proximal tab length 3288a and the distal tab comprises the distal tab length 3288b. The distal tab length is generally shorter than the proximal tab length to provide improved comfort. The distal tab length generally comprises a length that is within a range from about 20% to about 80% of the proximal tab length. The proximal tab may comprise a length within a range of about ½ inch to about 2 inches for example. The barrier may comprise one or more tab couplings 3295 for securing the barrier about the arm of the user. For example, the proximal tab and/or the distal tab, extending from the dorsal aspect 3282 of the barrier, may comprise one or more tab couplings configured to engage corresponding tab couplings disposed at the volar aspect 3281 of the barrier.
The barrier generally comprises a generally elliptical cross-section in the preformed shape on the proximal end 3283 and it also comprises a generally elliptical shape on the distal end 3284. Although reference is made to an elliptical shape, the shape may comprise non-elliptical shapes having the first dimension across longer than the second dimension across perpendicular to the first dimension across. For example, the shape may correspond to an oblong shape along one dimension or an egg shaped profile for example.
The self-supporting barrier may comprise a primary axis 3303a having a substantially vertical orientation on the proximal end and a primary axis 3304a on the distal end rotated relative to the primary axis within an angle α as shown in
A person of ordinary skill and art will recognize that various adaptations can be made of the self-supporting thermal-formed barrier as shown in
The inventors have conducted experiments with many shapes of pre-formed barriers and determined that the chiral barrier as shown with reference to
The distal end can also be offset relative to an axis of the proximal end. A path can extend from the center 3321 of the proximal end 3283 to the center 3322 of the distal end 3284. The path can be defined with the center of the barrier at locations between the proximal end and the distal end. As the forearm comprises musculature and other chiral structures, the shape profile of the forearm may comprise chirality. The chiral barrier is shaped to generally correspond to the chirality of the forearm. The center points of the forearm define a curved chiral path 3323 extending between the elbow and the wrist. At the proximal end, the barrier is shaped to correspond to the shape of the forearm and the curved central path of the forearm. The proximal end of the forearm can be defined with a plane extending perpendicular to the path corresponding to the center of the forearm. The plane defines a z-axis 3324 orthogonal to the cross-section through the forearm at the proximal end. The barrier is shaped similarly to the forearm. The proximal cross-section of the barrier comprises a central point 3322 and a plane 3325 that extends substantially perpendicular to the barrier surface on the proximal end. The z-axis 33224 from the center point of the barrier on the proximal end can be projected to the distal end. The inventors have learned that the distal end is offset from this projection of the z-axis by an extending between the proximal end and the distal end. The center of the forearm can be placed between the proximal end and the distal end. The offset can be within a range from about 0.25 inches to about 0.75 inches, for example.
The barrier comprises a shape memory material as described herein, which may comprise a thermoformed material. The thermoformed barrier material comprises a free standing self-supporting configuration with the geometrical features as shown in
As noted above with reference to
+X=volar aspect
+Y=radial aspect
Distal offset can be (8 mm, 20 mm)=(x,y)
Range from (0.2, 0.4) to about (2 cm, 4 cm) for example.
X offset (volar) can be within a range from about 0.2 cm to about 2 cm, for example within a range from about 0.5 cm to about 1.5 cm. The y offset (radial) can be within a range from about 0.4 to 4 cm, for example within a range from about 0.8 cm to about 3 cm. Although offsets are described, these are optional and in some embodiments the preformed barrier may comprise no offset, while still being chiral, for example with rotations of the long axes on the ends of the barrier as described herein.
The barrier as described herein can be configured with or without chirality.
The barrier can be configured with a shape memory material as described herein, and configured with force characteristics suitable for placement on the forearm of the user. The barrier comprises a volar edge on a volar side and a dorsal edge on a dorsal side. The volar edge can separate from the dorsal edge when advanced over the forearm for placement. An amount of force to separate the volar edge from the dorsal by about one inch from a free standing configuration can be within a range from about 25 grams to about 400 grams, for example. The range can be from about 50 grams to about 150 grams, for example. The masses provide correspond to the amount of force to separate based on the force of gravity, which will be readily understood by a person of ordinary skill in the art.
The barrier may comprise a mass within a range from 10 grams to about 250 grams, for example within a range from about 20 grams to about 75 grams. The barrier may comprise a preformed thermoplastic shell having a weight within a range from about 20 grams to about 60 grams, for example.
The barrier may comprise foam on an underlying surface beneath the shell. The weight of the barrier with foam can be within a range from about 35 grams to about 500 grams. The weight of the barrier with foam can be a range from 20 grams to about 260 grams, for example within a range from about 20 grams to about 85 grams. The barrier may comprise a preformed thermoplastic shell and foam beneath having a weight within a range from about 30 grams to about 70 grams, for example.
The barrier may comprise a weight as described herein and the weight of the barrier can be less than the amount of force required to separate the volar and distal ends for placement on the forearm of the user.
The barrier may comprise a longitudinal length within a range from about 6 inches to about 11 inches. The barrier may comprise a ratio of the distance across the proximal end to the distance across the distal end within a range from about 1.1 to about 1.5.
The barrier may comprise a shell wherein an underlying foam extends distally beyond the distal border of a shell of the barrier and wherein the foam curves over a leading distal edge of the shell to pad the interface of the shell when the barrier impinges on the wrist to provide comfort.
The barrier may comprise a shell having a radial curvature at a distal edge of shell with displacement within a range from about 3 mm to 1.5 cm to distribute a load of the barrier on a wrist of a user.
The barrier may comprise a shell, and inner foam padding may extend beyond distal edge of the shell. The foam layer can extend beyond a distal end of the shell by a distance within a range from about 1 mm to about 15 mm. The inner foam layer may comprise a thickness within a range from about 1 mm to about 15 mm.
The barrier may comprise a thickened distal edge.
The barrier can be configured to distribute a load when device abuts the dorsal or radial or volar aspect of the wrist with motion of the wrist.
The barrier can be configured to allow movement of proximal or distal ends of the barrier so as to allow greater amounts of movement of the wrist of the user relative to the barrier. For example, the barrier may comprise extensions on the proximal end that allow the barrier to be substantially fixed in relation to the proximal forearm of the user. Alternatively the barrier can be tighter on the proximal strap than the distal strap in order to allow the user's distal forearm to move more than the proximal forearm in relation to the barrier.
The barrier can be configured to couple to the proximal forearm in order to move with the proximal forearm more than the distal forearm. For example, the barrier may comprise a distal strap that can be tightened more than the proximal strap, in order to allow the barrier to move with rotation of the wrist of the user, for example.
The barrier can comprise a layer of padding on the bottom and a layer of mechanical barrier on the top, with magnets placed on the undersurface of the mechanical barrier between layer of padding and the layer of mechanical barrier. The mechanical barrier can comprise a polymer material, and can have a thickness in the range of about 0.5 mm to about 5 mm.
A swaged needle device as described herein may be stackable with another swaged needle device. For example, as shown in
As described herein, a needle receptacle may be coupled to a distal end of a surgical tool, such as forceps, for the securing of needles by a surgeon within the near surgical field without requiring the passing of needles out of the near surgical field. A tool-mounted needle receptacle may be particularly well-suited for the securing of small needles. The tool-mounted needle receptacle can be configured to removably couple to various surgical tools without requiring the use of coupling tools (e.g., screwdrivers). A tool-mounted needle receptacle may be configured to couple to a range of surgical tool sizes, for example via an elastic cap that fits onto the distal ends of tools of various sizes. In use, one or more suture packs containing suture needles with pop-off sutures may be supported by the surgeon on a non-dominant hand, wrist, or arm, as described herein. The tool-mounted needle receptacle may be coupled to the distal end of a tool held by the surgeon with the surgeon's non-dominant hand. The surgeon may dispense a suture needle from the suture pack, install the suture, and secure the used needle in the tool-mounted needle receptacle, using the surgeon's dominant hand. Preferably, a tool-mounted needle receptacle is configured to support at least 5 suture needles, in order to accommodate the minimum number of needles provided in a single suture pack. Ideally, a tool-mounted needle receptacle is symmetric for left and right hand use.
As best seen in the close-up view of
In use, the tool-mounted needle receptacle may be coupled to a tool held in the non-dominant hand of a user with the rotatable assembly facing the opposite (dominant) hand of the user. The notch of the housing may be aligned with a needle driver slot of an unoccupied cell of the rotatable assembly. To secure a needle, the user may align the tip of a needle driver holding the needle with the notch of the housing, and translate the needle driver radially inwards along the needle driver slot to place the needle within the cell, between the compressive member and the cover. The user may then release the needle from the needle driver, and rotate the rotatable assembly to align the notch of the housing with the needle driver slot of the next unoccupied cell in the rotatable assembly. For example, the user may push the needle driver upwards or downwards against the needle driver slot to rotate the rotatable assembly about the central axis via the central hinge.
In many embodiments, the present disclosure provides systems and devices for securing one or more needles. The systems devices for securing one or more needles described herein can be used to secure used needles (e.g., serve as a needle receptacle), used to dispense unused needles (e.g., serve as a suture package), or combinations thereof.
In many embodiments, the systems and devices provided herein utilize one or more clips to physically secure a needle or other sharp surgical instrument. A clip can include any device used to hold an object at a certain position and/or orientation relative to the clip and/or another object. For example, a clip can be used to hold one or more needles in place within a needle receptacle or suture package so as to prevent the needle(s) from falling out or becoming dislodged. A clip can constrain the movement of the object, e.g., with respect to up to six degrees of freedom of movement such that the object cannot move relative to the clip and/or another object. Optionally, a clip can constrain movement of the object along certain directions while permitting movement along other directions. In many embodiments, a clip is configured to compress an inserted object or portion(s) thereof in order to secure the physically object. The compressive forces can be applied using a spring or other flexible element that is sufficiently compliant to permit insertion of the object into the clip and sufficiently stiff to secure the object in place.
Optionally, the first arm portion 3463a and second arm portion 3463b can be spaced apart from each other so as to form a gap 3466 between the first and second arm portions 3463a, 3463b, such that a middle portion of the needle 3462 is exposed. In such embodiments, the received needle 3462 is secured only at its ends and not at its middle portion. The size of the gap 3466 can be selected based on geometry (e.g., length and/or curvature) of the needle 3462 in order to ensure that the ends of the needle 3462 will not protrude from the first and second arm portions 3463a, 3463b. The gap 3466 can be used to accommodate the tip of a needle driver or other instrument for inserting the needle 3462 into the clip 3461 and/or removing the needle 3462 from the clip 3461.
The device 3460 can include any suitable number of clips, such as one, two, three, four, five, six, seven, eight, nine, ten, or more clips. The clips can be arranged in a linear array along a longitudinal axis of the device 3460 so as to form a rack of clips. The plurality of clips can be integrally formed with each other so as to form a single continuous device. Alternatively, the clips can be removably coupled so as to permit adjustments to the size of the device 3460.
In many embodiments, the device 3470 is used to dispense unused needles as well as secure used needles, without requiring distinctly separate sections for each needle type. Used and unused needles can be differentiated from each other based their orientation within the device 3470. For example, an unused needle 3473 can be positioned within the device 3470 in a “concave down” configuration with the ends of the needle 3473 pointing downwards, as shown in
Optionally, the first clip 3483a and second clip 3483b can be spaced apart from each other so as to form a gap 3485 between the first and second clips 3483a, 3483b, such that a middle portion of the needle 3481 is exposed. In such embodiments, the received needle 3481 is secured only at its ends and not at its middle portion. The size of the gap 3485 can be selected based on the geometry (e.g., length and/or curvature) of the needle 3481 in order to ensure that the ends of the needle 3481 will not protrude from the first and second clips 3483a, 3483b.
By providing a plurality of such clip assemblies, the device 3480 can be used to hold a plurality of needles in a planar array. The device 3480 can include any suitable number of clip assemblies, such as one, two, three, four, five, six, seven, eight, nine, ten, or more clip assemblies. The clip assemblies can be arranged in a linear array along a longitudinal axis of the device 3481 so as to form a rack of clip assemblies. The plurality of clip assemblies can be integrally formed with each other so as to form a single continuous device. Alternatively, the clip assemblies can be removably coupled so as to permit adjustments to the size of the device 3480.
In many embodiments, the slot 3492 extends to the upper surface of the housing 3491 so as to define an elongate opening 3495 is formed along the length of the housing 3491. Optionally, the slot 3492 can extend below the plane of the needle 3493 towards the bottom surface of the housing 3491. As can be seen in
In many embodiments, the first arm portion 3502a and second arm portion 3502b can be spaced apart from each other so as to form a gap 3507 between the first and second arm portions 3502a, 3502b, such that a middle portion of the needle 3504 is exposed. In such embodiments, the received needle 3504 is secured only at its ends and not at its middle portion. The size of the gap 3507 can be selected based on the geometry (e.g., length and/or curvature) of the needle 3504 in order to ensure that the ends of the needle 3504 will not protrude from the first and second arm portions 3502a, 3502b. The gap 3507 can be shaped to accommodate insertion of a needle driver tip into the gap 3507, e.g., in order to grasp the exposed middle portion of the needle 3504. For example, the needle driver can be used to deposit a used needle into the device 3500, e.g., by aligning and sliding the needle along the slot 3503 from, the back portion 3508a of the housing 3501 towards the front portion 3508b of the device 3501. Optionally, the housing 3501 can be closed at the front portion 3508b so as to “trap” the received needles within the housing 3501.
In many embodiments, the housing 3511 includes lateral walls 3517 arranged to capture and enclose the ends of the needle 3516 when the needle 3516 is received within the slot 3515. In the depicted embodiment, the lateral walls 3517 are joined to the upper wall 3512 such that the lower wall 3513 is positioned between the lateral walls 3517. In alternative embodiments, the lateral walls 3517 can joined to the lower wall 3513, and the upper wall can be positioned between the lateral walls 3517.
In many embodiments, the upper wall 3512 includes an opening 3519 connected to the slot 3515 such that a middle portion of the inserted needle 3516 is exposed. In such embodiments, the received needle 3516 is secured only at its ends and not at its middle portion. The gap 3519 can be shaped to accommodate insertion of a needle driver tip into the gap 3519, e.g., while grasping the exposed middle portion of the needle 3516 in order to insert and/or remove the needle 3516 from the device 3510.
Each clip 3521 permits insertion of a needle 3524 along a horizontal orientation. Horizontal may be used herein to refer to an orientation in which the plane of the slot of the clip is aligned with and/or substantially parallel to the ground, such that the needle is inserted along a direction aligned with and/or substantially parallel to the ground (e.g., as indicated by arrow 3526). A device configured for horizontal needle insertion may in some instances be safer than devices configured for insertion along other directions (e.g., vertical direction), and may also provide a lower profile for securing a plurality of needles.
In many embodiments, the plurality of clips 3521 of the device 3520 are configured to be stacked with each other.
The stackable clips 3521 of the device 3520 can be removably coupled to each other, e.g., using snap fits, interference fits, interlocking structures, and the like. In embodiments where removably coupled clips are used, the number of clips in the device 3520 can be varied as desired by removing or adding clips in order to accommodate a corresponding number of needles. Alternatively, the clips 3521 of the device 3520 can be permanently affixed to each other in a stacked configuration, e.g., using adhesives, fasteners, and the like, or by being integrally formed with each other.
In many embodiments, the clips 3532, 3533 are each oriented at an oblique angle relative to the insertion direction 3536 for the needle 3531, such that the sides 3534a, 3534b, 3535a, 3535b of each clip 3532, 3533 are not parallel or orthogonal to the insertion direction 3536. The oblique angle can be selected based on the geometry (e.g., length and/or curvature) of the needle 3531 such that when the needle 3531 is inserted along the insertion direction 3536 convex side first, as illustrated in
In many embodiments, the upper wall 3542 includes a plurality of slits or fenestrations 3547. Alternatively or in combination, the plurality of fenestrations can be formed in the lower wall 3543. The fenestrations 3547 can be arranged substantially parallel to each other along the longitudinal axis of the device 3540. The spacing between fenestrations 3547 can be used to modulate the overall stiffness of the upper wall 3542 and/or lower wall 3543. For example, widely spaced fenestrations may result in a higher stiffness, while closely spaced fenestrations may result in a lower stiffness. The portions of the upper wall 3542 and/or lower wall 3543 between each adjacent pair of fenestrations can be considered to act as an individual “clip” for securing a respective needle. Accordingly, the plurality of fenestrations 3547 can be used to define a linear array of “clips” for securing a plurality of needles within the device 3540.
The upper wall 3542 and lower wall 3543 can be formed from and/or include spring materials that apply compressive force against the ends of the needle within the slot 3544 in order to secure the needle in place. Accordingly, the lateral portions 3548 of the housing 3541 joining the upper wall 3542 and lower wall 3543 can act as a spring-loaded hinge that biases the upper wall 3542 and lower wall 3543 towards each other. The design of the lateral hinge portion 3548 can be used to tune compressive forces applied to the received needle. For example, as illustrated in
In many embodiments, the interior surfaces of the upper wall 3542 and lower wall 3543 are arranged substantially parallel to each other, as illustrated in
The upper wall 3552 and lower wall 3553 can be formed from and/or include spring materials that apply compressive force against the ends of the needle within the slot 3554 in order to secure the needle in place. In many embodiments, one or more fenestrations or slits 3557 are formed in the upper wall 3552 so as to define a corresponding one or more tabs 3558 in the upper wall 3552. For example, as shown in
Alternatively or in addition to the use of clips, the systems and devices described herein can use other mechanisms to physically secure one or more needles. For example, deformable materials such as foam can be used to entangle the end(s) of a needle in order to render it innocuous. Entanglement can occur when the needle is pierced or tacked into the deformable material. The deformable material can encapsulate the needle end so as to protect the user from injury due to needle sticks, etc. Additionally, once entangled by the deformable material, the movement of the needle may be constrained so as to reduce the risk of the needle becoming loosened or dislodged. As another example, adhesive materials can be used to physically secure one or more needles within a device. The adhesive materials can be used to cover and/or encase the needle so as to constrain its movement, as well as to encase the ends of the needle to render them innocuous.
In many embodiments, the housing 3561 includes lateral walls 3566 arranged to capture and enclose the ends of the needle 3566 when the needle 3566 is received within the slot 3565. In the depicted embodiment, the lateral walls 3567 are joined to the upper wall 3562 such that the lower wall 3563 is positioned between the lateral walls 3567. In alternative embodiments, the lateral walls 3567 can joined to the lower wall 3563, and the upper wall can be positioned between the lateral walls 3567.
In many embodiments, the upper wall 3562 and lower wall 3562 can be formed from and/or include spring materials that apply compressive force against the ends of the needle 3565 within the slot 3564 in order to secure the needle 3565 in place. Alternatively or in combination, the device 3560 can include a pair of elongate blocks 3566a, 3566b formed from foam or any other deformable material suitable for entangling the ends of the needle 3565 as it is inserted into the slot 3564. The blocks 3566a, 3566b can be formed from the same material or from different materials. The blocks 3566a, 3566b can be positioned between the upper wall 3562 and lower wall 3563 and be aligned with the longitudinal axis of the device 3560. The distance between the blocks 3566a, 3566b can be determined based on the geometry (e.g., length and/or curvature) of the needle 3565 so as to be sufficiently far apart to allow the needle 3565 to be advanced within the slot 3564 in a convex-first orientation, while also being sufficiently close together to cause deformation of the foam by the ends of the needle 3565 as the ends are positioned within the outer limits of the blocks 3566a, 3566b. In many embodiments, the foam can be used to retain the needle 3565 within the device 3560 through one or more of the following mechanisms: deformation of the foam by the needle ends, piercing of the foam by the needle ends, entanglement and/or entrapment of the needle ends within the foam, or indirect tacking of the needle ends within the foam (e.g., tacking that occurs when the needle ends are drawn across the foam substantially in an orthogonal relationship relative to the surfaces of the foam blocks). For example, advancing the needle 3565 within the slot 3564 in an convex-first orientation may result first in deformation of the foam, followed by a passive piercing of the foam as a secondary effect. In many embodiments, the amount of force to remove an inserted needle 3565 from within the device 3560 is greater than the amount of force to introduce the needle into the device 3560.
In many embodiments, the upper and lower compression elements 3571, 3572 are shaped based on the geometry (e.g., length and/or curvature) of the needle 3574 such that when the needle 3574 is inserted into the device 3570, the ends of the needle 3574 protrude outward from the outer edges of the compression elements 3571, 3572. The exposed ends of the needle 3574 can be rendered innocuous through the use of adhesive casings 3577. The adhesive casings 3577 can be attached to the outer edges of the first and second arm portions 3573a, 3573b spanning the “boundary zone” where the exposed needle ends are located. In many embodiments, the adhesive casing 3577 can be connected to both the upper compression element 3571 and lower compression elements 3572 so as to enclose the exposed needle ends, as illustrated in
In many embodiments, each foam block 3602 also includes a tail 3604 at the end of the block 3602 away from the end where the needle 3603 is inserted. Alternatively, the user can tack each needle 3603 into the foam block 3602 using a needle driver 3604. The tail 3604 can enable handling of the secured needle without requiring the user to directly touch the needle itself, thereby improving safety. For example, a user (e.g., a surgeon) can tack the needle 3603 into the foam block 3602 using a needle driver 3605, and a second user (e.g., a scrub tech) can handle the secured needle 3603 using the tail 3604. Optionally, the tail 3604 can be used to hang the secured needle 3603 onto a wall or other surface 3606, as shown in
The device 3600 can be used to secure only the sharp leading end of the needle 3603 via the foam block 3602 without also securing the blunt trailing end of the needle 3603. While an unsecured trailing end may be hazardous within the surgical field due to the potential for ripping gloves, catching on surgical garments, etc., it may not be necessary to secure the trailing end in the embodiments where the needle 3603 is immediately transferred to a scrub tech outside of the near surgical field. In alternative embodiments, the embodiment of
Optionally, the integrated needle dispensing and securing apparatus may be provided with a hinge 3665 (e.g., a living hinge) between the dispensing portion and the securing portion, to allow the apparatus to be folded or collapsed along the hinge axis 3665a as shown in
Optionally, the barrier mounting base may be provided with a hinge 3696 between the first portion and the second portion, such as a living hinge. The hinge may allow at least partial folding of the base along the hinge, such that the plane of the first portion may be positioned at an angle with respect to the plane of the second portion.
The lateral opening 3803 may have a width 3803a that is greater than the height 3803b, in order to constrain the orientation of the needles being inserted through the opening into a substantially lateral orientation. The lateral opening 3803 may be oversized with respect to a needle to be placed into the needle receptacle, in order to facilitate the insertion of the needle through the lateral opening. For example, the width 3803a of the lateral opening may be greater than the length of the needle (or, in the case of a curved needle, the straight-line distance between the two ends of the needle), and the height 3803b of the lateral opening may be greater than the thickness or wire diameter of the needle. For example, the height may be greater than 10 times the thickness of the needle, such that a user could easily insert the needle through the lateral opening without having to carefully align the needle with the opening.
The needle slot 3802 may have a width 3802a, height 3802b, and length 3802c, wherein the width 3802a and height 3802b may be similar or equal to the width 3803a and height 3803b of the lateral opening. Alternatively, the dimensions of the needle slot may be different from the dimensions of the lateral opening, as described herein in reference to
The housing may be substantially box-shaped as shown in
Optionally, the needle receptacle 3800a or 3800b may be provided with one or more internal retaining mechanisms to securely hold the needles in place within the needle slot 3802. For example, the needle receptacle 3800a or 3800b may comprise a spring member 3806 as shown in
Optionally, the needle receptacle 3810a or 3810b may further comprise one or more internal retaining mechanisms as described in reference to
Optionally, as shown in
The needle receiver 3855 may be translated into the needle trap 3850 by conveyance. The needle receiver, initially without needles, may be slide along the underside of the lower structure 3852 of needle trap 3850, through opening 3859 of the needle trap 3850, and then onto the upper side of lower structure 3852 of needle trap 3850. In this configuration, the needle receiver 3855 may present surface 3856 between adjacent needle receiving tabs 3857a/b for receiving a needle 3858 at the entry zone 3850a of needle trap 3850. Through the motion of placing a needle onto surface 3856 of the needle receiver 3855 and against needle receiving tabs 3857a/b, and translating the needle from the entry zone 3850a through to the secure zone 3850c of needle trap 3850, the needle receiver 3855 translates into the needle trap 3850 and presents the next adjacent pair of needle receiving tabs 3857a/b and surface 3856 for subsequent needle placement and disposal (i.e, no separate action is required to advance the needle receiver 3855 into the needle trap 3850). The needle receiver may prevent bunching of subsequently placed needles, may allow for easy segregation of adjacent needles, and thereby may allow for easy needle counting.
In different embodiments, the needle trap 3850 and needle receiver 3855 may have different dimension depending upon the size of the needles 3858 being stored. Thus, a small needle receiver and complementary needle trap used to store small needles may have smaller dimensions than a large needle receiver and complementary needle trap used to store larger needles.
In many embodiments, the tip to tip distance of each of the plurality of needles is within a range selected from the group consisting of 75% to 100% of the width of the needle slot, 80% to 99% of the width of the needle slot, and 85% to 98% of the width of the needle slot and 90 to 97% of the width of the needle slot.
In many embodiments, the tip to tip distance of each of the plurality of needles is within a percentage of the width of the needle slot in the expanded configuration, the percentage within range selected from the group consisting of 75% to 100% of the second width of the needle slot, 80% to 99% of the second width of the needle slot, and 85% to 98% of the second width of the needle slot and 90 to 97% of the second width of the needle slot. The needle slot may comprise a length, a width, and a height, the length being greater than the width and the width being greater than the height.
The needle receiver 3855 may be comprised of a flexible material that allows the needle receiver to bend through the opening 3859 as shown in
The needle receiver 3855 may comprise a series of through openings to receive a needle driver tip, the through openings located along the longitudinal axis of the needle receiver 3855 and located between adjacent needle receiving tabs 3857a/b. This series of through opening may be sized to match the needle driver slot 3853 of the needle trap 3850, such that a needle 3858 can easily be placed into the needle receiver 3855 and translated with the needle driver from the entry zone 3850a through to the secure zone 3850c of the needle trap 3850.
The needle receiver 3865 may be comprised of a flexible material that allows the needle receiver to bend through the opening 3869 as shown in
In some embodiments, each internal filament 3897a/b may be attached within the needle trap 3893 as described above via a torsion spring, a helical torsion spring, or similar. In these embodiments, the internal filaments may comprise a rigid or semi-rigid material. In some embodiments, each internal filament 3897a/b may be attached within the needle trap 3893 as described above via an adhesive, a weld, or similar permanent attachment. In these embodiments, the internal filaments may comprise a flexible material capable of deforming.
At rest, the internal filaments 3897a/b may be configured such that the ends of the internal filaments opposite their respective attachment points are forced down or touch against the internal surface of lower structure 3892 (e.g., by the force of their respective springs at their attachment points, or by deforming, see
In some embodiments (as shown in
In some embodiments (as shown in
In the illustrated embodiments of
In an embodiment, the entry zone 3920a of the needle trap 3920 may comprise a partially rectangular flat zone or area in the X-Y plane that is an exposed part of the lower structure 3922. A surgeon can hold used needles 3928 with a needle driver and place the used needles 3928 on an upper surface of the entry zone 3922 (i.e., surface in the positive Z-axis). The contact and/or force of the needle 3928 against the entry zone 3928 may cause the curvature of the used needle 3928 to be moved into a planar orientation flat against the entry zone upper surface in the X-Y plane with the convex mid-portion of the curved needle 3928 facing or pointing towards the transition zone 3920b.
The entry zone 3920a may be the same width (Y-axis) relative to needle slot 3924 and the perimeter around the entry zone 3920a may have a contrasting color to aid visual recognition. The upper surface of the entry zone 3920a may comprise a low friction material. The upper surface of the entry zone 3920a may include graphic guides to indicate proper needle orientation to the surgeon. The entry zone 3920a may be folded over upper structure 3921 to secure needles deposited within the needle trap 3920.
The transition zone 3920b may be disposed between the entry zone 3920a and the secure zone 3920c. In some embodiments, in the transition zone, edges 3925 of the upper structure 3921 where the upper structure intersects with the needle driver slot 3923 at the entry zone/transition zone may be folded inward into the needle slot 3924 as shown in FIG. 392A5-392A6. In a folded inward configuration, edges 3925 may increase the depth (Z-axis) of the needle slot at the entry zone/transition zone intersection and facilitate loading of needles into the needle trap, as exemplified in the longitudinal cross-sectional view of FIG. 392A6. Additionally, the inward-folded edges 3925 may prevent needles 3928 from exiting back out of the needle trap 3920 by blocking any egress (e.g, the inward folded edges may catch the needles). In the transition zone, the compressive side load on the needles ends may be increased and the height (Z-axis) of the needle slot may be decreased as the secured needles are translated through the transition zone, thus constraining the needles to a single needle deep array extending longitudinally along the secure zone 3920c. In some embodiments, in the transition zone, edges 3925 of the upper structure 3921 where the upper structure intersects with the needle driver slot 3923 at the entry zone/transition zone may be folded outward as shown in FIG. 392A7-392A8. In a folded outward configuration, edges 3925 may help guide a needle driver into the needle driver slot 3923. In some embodiments, edges 3925 may not be folded, and the height (Z-axis) of the needle slot 3924 may remain constant from the transition zone 3920b through the secure zone 3920c. In some embodiments, the width (Y-axis) of the entry zone 3920a, transition zone 3920b, and secure zone 3920c may be the same.
The secure zone 3920c may be disposed adjacent the transition zone 3920b, and comprise the region in which full compressive side loading is applied to the needle ends to prevent unintentional removal or dislodging of the needles 3928.
The needle trap 3920 may be configured to promote needles, upon entry, to assume an orientation where the convex side of the needle 3928 faces the secure zone 3920c, and the concave side, sharp point, and tail of the needle 3928 face the entry zone 3920a. Thus, the needle trap 3920 may be configured to have the sharp point and tail end of the needle 3928 pointing away from the direction of motion, thereby reducing the risk of needle-stick injury. The needle driver slot 3923 may intersect a portion of the needle slot 3924, such as a middle portion of the needle slot, and may be disposed in the midline of the needle trap 3920 in the X-axis such that the distal tip of the needle driver can translate the needle 3928 along the X-axis of the needle trap 3920. Alternatively, the needle driver slot 3923 may intersect the needle slot 3924 off the midline or asymmetrically, such that the needle driver slot extends along an axis substantially parallel to, but not overlapping, the X-axis of the needle trap 3920. The needles 3928 may slide/translate within the needle slot 3928 deeper into the secure zone 3920c (i.e., away from the entry zone 3920a) without excessive resistance or sensitivity as to how the needles 3928 are grasped by the needle holder. In an embodiment, the secure zone 3920c can prevent used needles 3928 from being removed from the needle trap 3920.
In a preferred embodiment, the needle 3928 is moved into contact with the entry zone 3920a of the lower structure 3922 by the surgeon manipulating the tip of the needle driver holding the needle. The needle 3928 can be pushed against the entry zone 3920a and become aligned with the X-Y plane of the needle trap 3920. The needle 3928 can then be moved in translation along the longitudinal X-axis of the needle trap 3928 from the entry zone 3920a into the transition zone 3920b where the needle 3928 slides into the needle slot 3924 with the convex side facing the secure zone 3920c and the sharp point and tail of the needle 3928 facing the entry zone 3920a. The needle driver can be translated to move the needle 3928 into the needle slot 3924 in the secure zone 3920c until the needle driver runs into the end of the needle slot 3924 or the last inserted used needle 3928.
In some embodiments, the needle driver slot 3928 may comprise a linear cut through the upper and lower surfaces of the upper structure 3921 as exemplified in FIG. 392A3. In these embodiments, inherent flexibility of the needle trap material may allow the linear edges of the needle driver slot to deform and allow translation of the needle driver. In some embodiments, the needle driver slot 3928 may comprise a width in the Y-axis configured to receive the distal tip of the needle driver holding a needle 3928. In these embodiments, this width may narrow in the secure zone 3920c so that the distal tip of a needle driver with an elongated cross section must orient with the needle driver slot 3923 such that the held needle 3928 is properly aligned across the width of the secure zone 3920c within the needle trap 3920. In some embodiments, the needle driver slot 3928 may comprise a width in the Y-axis that is constant throughout its length in the X-axis, as exemplified in FIG. 392A4.
In many embodiments, the needle trap 3920 comprises a deformable, flexible, and/or compliant material. In many embodiments, the needle trap 3920 comprises a deformable, flexible, and/or compliant material that can provide compressive force to secure the one or more needles 3928 within the needle slot 3924. Alternatively or in combination, and as exemplified in FIG. 392A12, the needle trap 3920 may comprise magnetic strips, foam, surface coatings, gel, and the like identified as 3924a within the needle slot 3924 as described herein to prevent needles from exiting the envelope.
In many embodiments, and as shown in FIG. 329A9, needle trap 3920 may assume a planar configuration wherein the lower surface of upper structure 3921 and the upper surface of the lower structure 3922 rest against one another without the presence of any needles in the needle slot 3924 (i.e., without needles in the needle trap, the needle trap lays flat against its mounting surface). As shown in FIG. 329A10, as a needle 3928 is loaded into the needle trap 3920 through needle slot 3924 by the needle driver 327, the inherent flexibility of the needle trap material may allow the edges 3925 of the upper structure 3921, the linear edges of the needle driver slot 3923 of the upper structure 3921, and the upper structure 3921 to deform and conform to the needle 3928 and needle driver 327 as the needle driver 327 holding needle 3928 is translated into the needle trap 3920 for placement of needle 3928. As shown in FIG. 392A11, after the needle 3928 has been placed into the needle slot 3924 of the needle trap 3920, the inherent flexibility of the needle trap material may allow the edges 3925 of the upper structure 3921, the linear edges of the needle driver slot 3923 of the upper structure 3921, and the upper structure 3921 to conform to the needle 3928. In some embodiments, the conforming of the edges 3925 of the upper structure 3921, the linear edges of the needle driver slot 3923 of the upper structure 3921, and the upper structure 3921 may apply a compressive force to the needle 3928 within the needle trap 3920, thereby securing needle 3928 in place. In some embodiments, the conforming of the edges 3925 of the upper structure 3921, the linear edges of the needle driver slot 3923 of the upper structure 3921, and the upper structure 3921 may be limited to the location of the needle 3928 (i.e., remote from needle 3928, the lower surface of upper structure 3921 and the upper surface of the lower structure 3922 rest against one another). In some embodiments, the lower structure 3922 may additionally deform and conform to the needle 3928. In some embodiments, the lower structure 3922 may additionally deform and conform to the needle 3928 and needle driver 327.
In many embodiments, the needle trap 3920 may comprise a deformable, flexible, and/or compliant material that can prevent the one or more needles 3928 from puncturing through the lateral and longitudinal walls of the needle trap (i.e., puncture resistant material). The thickness of the material used to construct the needle trap 3920 may be in the range of 0.008 inches to 0.030 inches. The material used to construct the needle trap 3920 may comprise PTFE, Tyvek, polycarbonate, polyamide, Kevlar, PVC, and PETG; preferably PETG. The material used to construct the needle trap 3920 may have a puncture resistance of with strength to resist puncture with a sharp tip of a needle with at least 0.3 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation GS-21 needle or to resist puncture with a sharp tip of a needle with at least 0.3 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation CV-23 needle, or to resist puncture with a sharp tip of a needle with at least 0.3 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation thin bodied half-circle needle, or to resist puncture with a sharp tip of a needle with at least 0.3 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation medium bodied half-circle needle, or to resist puncture with a sharp tip of a needle with at least 0.5 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation GS-21 needle, or to resist puncture with a sharp tip of a needle with at least 0.5 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation CV-23 needle, or to resist puncture with a sharp tip of a needle with at least 0.5 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation thin bodied half-circle needle, or to resist puncture with a sharp tip of a needle with at least 1 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation medium bodied half-circle needle, to resist puncture with a sharp tip of a needle with at least 1 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation GS-21 needle, or to resist puncture with a sharp tip of a needle with at least 1 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation CV-23 needle, or to resist puncture with a sharp tip of a needle with at least 1 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation thin bodied half-circle needle, or to resist puncture with a sharp tip of a needle with at least 1 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation medium bodied half-circle needle, or to resist puncture with a sharp tip of a needle with at least 3 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation GS-21 needle, or to resist puncture with a sharp tip of a needle with at least 3 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation CV-23 needle, or to resist puncture with a sharp tip of a needle with at least 3 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation thin bodied half-circle needle, or to resist puncture with a sharp tip of a needle with at least 3 pound force applied to the tip of the needle, wherein the needle is a United States Surgical Corporation medium bodied half-circle needle.
In different embodiments, the needle trap 3920 may have different dimensions depending upon the size of the needles 3928 being stored. Thus, a small needle trap used to store small needles may have smaller dimensions than a large needle trap used to store larger needles. Needles may include the needles sizes listed above or other available needles, such as surgical needles available from United States Surgical Corporation.
In some embodiments, the needle trap 3920 may be constructed out of one sheet of material as shown in FIG. 392A1. In these embodiments, the needle driver slot 3923 may be cut through the needle trap 3920 and dimensioned as described herein (e.g., the needle driver slot may comprise a single cut, forming a linear cut through the material, or may comprise a through cut with a width 3923b as shown herein). Further, the single sheet of material may be folded over on itself and the outer perimeter along the longitudinal axis of the needle trap may be sealed so as to create the needle trap 3920 with a needle slot 3924 bounded by closed-in walls as described herein. In some embodiments the needle trap 3920 may be constructed out of two separate sheets of material as shown in FIG. 392A2. In these embodiments, the needle driver slot 3923 may be cut through one sheet of material that will form the upper structure 3921 of the needle trap 3920 (i.e., the top sheet shown in FIG. 392A2) and dimensioned as described herein (e.g., the needle driver slot may comprise a single cut, forming a linear cut through the material, or may comprise a through cut with a width 3923b as shown herein). Further, this one sheet of material that will form the upper structure 3921 may then be adhered to another sheet of material that will form the lower structure 3922 of the needle trap 3920 (i.e., the bottom sheet shown in FIG. 329A2) so as to seal the outer perimeter along the longitudinal axis of the needle trap and the lateral perimeter of the needle trap opposite the entry zone. In many embodiments, sealing the outer perimeter may comprise the use of an adhesive, a glue, a weld, a stitch, or any other joining means.
In some embodiments, the lower surface of lower structure 3922 of needle trap 3920 may comprise adhesive, velcro, or other bonding means to releasably attach the needle trap 3920 to a mounting surface, such as the barrier mounting base, barrier, or base as described herein. In some embodiments, the lower surface of lower structure 3922 of needle trap 3920 may comprise adhesive, or other bonding means to permanently attach the needle trap 3920 to a surface.
In some embodiments, the needle trap 3920 as described herein may be placed/inserted into a re-usable secondary structure 3926 (as shown in
The needle trap receiving slot 3926e of the secondary structure 3926 may be configured so as to receive the needle trap 3920. Thus, in different embodiments, the secondary structure may have different dimensions depending upon the size of the needle trap 3920. The fit of the needle trap 3920 within the needle trap receiving slot 3926e may be loose or tight, and rely on friction or surface treatments to accomplish the desired fit. In some embodiments, the secondary structure provides a compressive force to the needle trap within.
The needle driver slot 3926d of the secondary structure 3926 may be configured to match the dimensions of the needle driver slot 3923 of the needle trap 3920. Alternatively, the needle driver slot 3926d may be oversized (i.e., has greater width in the Y-axis) than the needle driver slot 3923.
The lateral wall 3926c of the secondary structure 3926 may serve as a stop for the needle trap 3920 (i.e., the needle trap is fully seated/inserted into the secondary structure when the needle trap abuts the lateral wall). Optional longitudinal walls 3926f may additionally serve to constrain the needle trap 3920 from lateral movement during use.
In some embodiments, the needle driver slot 3926d of the secondary structure 3926 may extend through both the upper structure 3926a (as shown in
In further detail the secondary structure 3926 of FIG. 392B1 may include a first stiff member 3926j having first and second ends and a second stiff member 3926h extending from the first end of the first stiff member and third stiff member 3926i extending from the second end of the first stiff and in a same plane as the second stiff member 3926h. The stiff structure 3926 may be configured to receive a needle receptacle 3920 of any of the preceding claims between the second and third stiff members 3926h, 3926i.
In some embodiments, the distance 3926d between the second and third members 3926h, 3926i at an end proximate the first member 3926j is less than a distance 3926k between the second and third member 3926h, 3926i at a distal end such that when the needle receptacle is received within the stiff structure, the second and third members impart a force, such as a lateral compressive force on the needle receptacle 3920, deforming the needle receptacle and enlarging an entry to the needle slot of the needle receptacle.
As shown in
In many embodiments, the longitudinal runners 3927, by providing needle driver space 3929, allow for the distal tip of the needle driver to deflect the lower structure 3922 of needle trap 3920 downward (as shown in
In some embodiments, the needle trap 3290 and the secondary structure 3926 may be configured to provide a compressive lateral force on the needle trap 3290 so as to promote spreading open of the needle slot 3924 (i.e., to facilitate easy placing of needles into the needle trap). FIGS. 392B2-392B3 and FIGS. 392B4-392B5 illustrate exemplary embodiments of such configurations. In these exemplary embodiments, the needle trap 3290 may have a lateral width 3920d at the end of the needle trap opposite the needle slot 3924, and a lateral width 3920k at the needle slot 3924. Further, in these exemplary embodiments, the inner grooves 3926g of the secondary structure 3926 may have an inner lateral width 3926d within the secondary structure opposite the needle trap receiving slot 3926e entrance, and an inner lateral width 3926k at the entrance of the needle trap receiving slot 3926e. In the embodiments shown in FIGS. 392B2-392B3, the inner lateral widths 3926d and 3926e of the secondary structure 3926 may be the same, while the lateral width 3920d of the needle trap may be less than the lateral width 3920k of the needle trap 3290. Further, the lateral widths 3926d and 3926e of the secondary structure may be sized complementarily to the lateral width 3920d of the needle trap 3290. Thus, the lateral width 3920k of the needle trap 3920 is greater than the lateral widths 3926d and 3926e of the secondary structure. Dimensioned as such, when the needle trap 3290 is placed into the secondary structure 3926, the secondary structure 3926 may provide a compressive lateral force on the needle trap 3290 so as to promote spreading open of the needle slot 3924, as shown in FIG. 392B3. Alternatively, in the embodiments shown in FIGS. 392B4-392B5, the lateral widths 3920d and 3920k of the needle trap 3290 may be the same, while the inner lateral width 3926k of the secondary structure may be less than the inner lateral width 3926d of the secondary structure 3296. Further, the inner lateral width 3926d of the secondary structure 3926 may be sized complementarily to the lateral width 3920d of the needle trap 3290. Thus, the inner lateral width 3296k of the secondary structure is less than the lateral widths 3920d and 3920k of the needle trap 3290. Dimensioned as such, when the needle trap 3290 is placed into the secondary structure 3926, the secondary structure 3926 may provide a compressive lateral force on the needle trap 3290 so as to promote spreading open of the needle slot 3924, as shown in FIG. 392B5. In some embodiments, the lateral dimensions 3920d and 3920k of the needle trap, and inner lateral dimensions 3926d and 3926k of the secondary structure, may be configured as necessary to provide a compressive lateral force on the needle trap 3290 so as to promote spreading open of the needle slot 3924.
Optionally, the lower portion of the housing may comprise an extended portion 3937 that extends beyond the front end of the upper portion of the housing. In use, the extended portion 3937 can provide a landing zone for a needle to be secured in the device, wherein the needle may be placed in contact with the upper surface of the extended portion with the needle driver tip aligned with the needle driver slot. The landing zone can facilitate the insertion of the needle into the needle slot by eliminating the need for a user to carefully align the needle with the plane of the needle slot. Optionally, the housing may further comprise blocking tabs 3938a, 3938b located at the front end of the housing, extending from the front outer edge of the lower housing portion to the front outer edge of the upper housing portion. The blocking tabs can prevent a needle from entering the needle slot with one or both ends of the needle exposed beyond the arms of the u-shaped housing, thus reducing the risk of needle stick injury by ensuring that both ends of the needle are secured between the upper and lower portions of the housing.
Optionally, to further reduce the risk of an exposed needle end extending beyond the arms of the u-shaped housing 3931, the device 3930 may be provided with lateral walls 3939 disposed over the outer lateral edges of the u-shaped housing, as shown in
As shown in
In the illustrated embodiments of
In many embodiments, and as exemplified in
The planar base 3991, two or more posts 3992, and two or more post receivers 3995 may comprise any material suitable to provide a rigid or semi-rigid swaged needle dispenser 3990, for example plastic, metal, or similar. In many embodiments, the swaged needle dispenser 3990 comprises materials capable of being sterilized.
The planar base 3991 of swaged needle dispenser 3990 may comprise any shape desired, and with any number of posts 3992, post receivers 3995, and needle receivers 3993 as necessary to hold any number of swaged needles 103 with attached sutures 3994. For example, the planar base 3991 may assume a circular, square, oval, rectangular, multi-faceted, or any other shape. In many embodiments, two or more swaged needle dispensers may be stacked upon one another.
In the illustrated embodiments of
In many embodiments, and as exemplified in
The planar base 4001 and two or more posts 4002 may comprise any material suitable to provide a rigid or semi-rigid swaged needle dispenser 4000, for example plastic, metal, or similar. In many embodiments, the swaged needle dispenser 4000 comprises materials capable of being sterilized.
The planar base 4001 of swaged needle dispenser 4000 may comprise any shape desired, and with any number of posts 4002 and needle receivers 3993 as necessary to hold any number of swaged needles 103 with attached sutures 3994. For example, the planar base 4001 may assume a circular, square, oval, rectangular, multi-faceted, or any other shape.
In some embodiments, the top and bottom of the spindles include a coupling the top coupling having a first shape and the bottom coupling being shaped to receive the top coupling. In some embodiments, the top and bottom of the spindles include a coupling. The top coupling having a first shape and the bottom coupling being shaped to engage with the first shape of the top coupling. In some embodiments, the top of the spindle includes an extension and the top of the spindle includes a recess shaped to receive the extension.
Base 4011 may comprise a planar structure 4010c, a planar structure 4010a, in some instances a planar structure 4010b, and in some instances a planar structure 4010d. Planar structure 4010c may be considered the base planar structure of base 4010 (i.e., in use it primarily lays in the horizontal), and may be placed on or coupled to surgical drapes, tables, stands, and the like via coupling means at its underside (e.g., Velcro, adhesive, magnets, mechanical joining means, and the like). Planar structure 4010c may comprise a rectangular configuration with a length and width as appropriate to provide stability to base 4010. Planar structure 4010a, including a mounting surface, may be coupled to planar structure 4010c at a living hinge 4011a, with an interior angle 4012 defining the angle between the planar structure 4010c and planar structure 4010a. Planar structure 4010a may be considered the planar surface or may include a planar surface that is a mounting surface whereon the needle dispensers, needle receptacles, and various tools as described herein may be coupled for use during surgical procedures. Thus, planar structure 4010a may comprise a surface configured to couple to the needle dispensers, needle receptacles, and various tools as described herein (e.g., may comprise Velcro, adhesive, magnets, mechanical joining means, and the like). Further, planar structure 4010c may comprise a rectangular configuration with a length and width as appropriate for coupling the needle dispensers, needle receptacles, and various tools as described herein thereto. In some embodiments (as shown in
In some embodiments, the living hinge 4011a, the living hinge 4011b (if present), and living hinge 4011c (if present) may comprise passive hinges. In some embodiments, the living hinge 4011a, the living hinge 4011b (if present), and living hinge 4011c (if present) may comprise active hinges. In some embodiments, the living hinge 4011a, the living hinge 4011b (if present), and living hinge 4011c (if present) may comprise a passive or active hinge.
In some embodiments, the base 4010 may be configured for infinite adjustability of interior angle 4012. In some embodiments, the base 4010 may be configured for finite adjustability of interior angle 4012. In many embodiments, the base 4010 may be configured to present the surface of planar structure 4010a configured to couple to the needle dispensers, needle receptacles, and various tools as described herein (e.g., via Velcro, adhesive, magnets, mechanical joining means, and the like) at an angle desired by the surgeon by adjustability of interior angle 4012. In preferred embodiments, the interior angle 4012 may be adjustable between 30 degrees and 90 degrees, between 60 degrees and 75 degrees, between 45 degrees and 75 degrees, or between 60 degrees and 90 degrees.
In many embodiments, the coupling of base 4010 to surgical drapes, tables, stands, and the like via coupling means located at the underside of planar structure 4010c may be releasable. In many embodiments, the coupling of base 4010 to surgical drapes, tables, stands, and the like via coupling means located at the underside of planar structure 4010c may be releasable and may not pull, tear, or otherwise damage the surgical drapes, tables, stands, or the like it is coupled thereto. In many embodiments, the strength of the coupling of base 4010 to surgical drapes, tables, stands, and the like via coupling means located at the underside of planar structure 4010c may be stronger than the coupling of needle dispensers, needle receptacles, and various tools as described herein to the surface of planar structure 4010a.
As shown in
In various embodiments, the support, also called a base 4010, may be mounted to a drape over the over a patient, within the near surgical field, to a table within the near surgical field, to a stand within the near surgical field, at a location opposite the surgeon from an incision, proximal the incision of the patient, distal the incision of the patient, superior to the incision of the patient, or inferior the incision of the patient.
As shown in
As shown in
As shown in
As shown in
In many embodiments, the kit 4060 may be planar or substantially planar (e.g., to facilitate easy shipping and/or storing). In many embodiments, the top and bottom surfaces of kit 4060 contents may touch the internal walls of kit 4060 packaging. In many embodiments, the contents of kit 4060 may be sterilized. In many embodiments, the length 4061h and width 4061w of kit 4060 may be minimized so as to minimize the overall size of the kit 4060.
Each of the components of the kits 4060, including for example, the needle dispenser 101 with needles 103, the needle receptacle 3920 and the barrier mounting base may be contained together within an sterile package for distribution.
In the illustrated embodiment, the needle receptacle 4070 may be a substantially planar device comprised of an entry zone 4071 and a secure zone 4072, as described herein. The needle receptacle 4070 may include an upper structure 4073, an upper structure 4074, a lower structure 4075, and a compliant structure 4076. The upper structure 4073 may comprise a ramp structure 4073a that couples to and forms a part of the lower structure 4075 and forms an entry way located below a needle slot 4077, a needle driver slot 4073b that intersects the ramp structure 4073a and extends at least partially through the upper structure 4073, and a window 4073c defined by an opening through the upper structure 4073 bound by the continuous upper structure inner wall 4073d and the ramp structure 4073a. The window 4073c may be configured to complementarily receive a raised planar surface 4074a of upper structure 4074, such that when the upper structure 4073 receives the upper structure 4074 from below the raised planar surface 4074a fits into window 4073c, and a recessed planar surface 4074b of upper structure 4074 stops against the underside of upper structure 4073. The upper structure 4074 may comprise a needle driver slot 4074c that extends partially therethrough and in line with the needle driver slot 4073b of upper structure 4073. The upper side of lower structure 4075 may comprise a ramp structure 4075a and a recess 4075b partially along its perimeter to complementary receive and couple to the underside of the ramp structure 4073a and a lower protrusion 4073e of upper structure 4073. The lower structure 4075 may also comprise a needle driver slot 4075c that extends partially therethrough and in line with the needle driver slot 4073b of upper structure 4073 and needle driver slot 4074c of upper structure 4074. The compliant structure 4076 may be configured to be received by the lower structure 4075 from above, wherein a lower surface of the compliant structure stops against a planar surface 4075d of the lower structure 4075. The compliant structure 4076 may also comprise a needle driver slot 4076a that extends partially therethrough and in line with the needle driver slot 4073b of upper structure 4073, the needle driver slot 4074c of upper structure 4074, and the needle driver slot 4075c of lower structure 4075. The compliant structure 4076 may also comprise bevels 4076b at the entrance of needle driver slot 4076a to aid in guiding of a needle driver therethrough. When assembled, the needle receptacle 4070 may comprise the planar needle slot 4077 formed by the empty vertical space between an upper planar surface 4076c of compliant structure 4076 and the lower surface of upper structure 4074, and closed in at the sides by the inner wall 4073d of upper structure 4073, thus the needle slot 4077 may be configured for receiving one or more needles 104. To aid in placement of one or more needles into the needle slot 4077 of needle receiver 4070, upper structure 4074 may comprise tabs 4074d within the entry zone 4071 that may angle vertically away from the opposing and angled down ramp structure 4073a.
The needle driver slots 4073b, 4074c, 4075c, and 4076a of needle receiver 4070 may align and be configured to provide clearance for a needle driver along the entire length of the needle translation from entry zone 4071 to secure zone 4072. The needle slot 4077 of needle receiver 4070 may constrain needles 104 placed therein into a single needle depth array, to minimize overall depth profile and facilitate needle counting. In many embodiments, the compliant structure 4067 may apply a holding force against one or more needles 104 within the needle slot 4077 and the secure zone 4072 to resist translation of the needle out of the needle slot 4077 and the secure zone 4072. In many embodiments, the compliant structure 4067 may comprise foam. In many embodiments, the compliant structure 4067 may comprise a compliant element. In many embodiments, the upper structure 4074 may apply a holding force against one or more needles 104 within the needle slot 4077 and the secure zone 4072 to resist translation of the needle out of the needle slot 4077 and the secure zone 4072.
In a preferred embodiment, the needle 104 is moved into contact between the ramp structure 4073a and the tabs 4074d of upper structure 4074 at entry zone 4071 of needle receptacle 4070 by the surgeon manipulating the tip of the needle driver in the needle driver slots of needle receptacle 4070 as described herein. The needles 104 can be pushed into the entry zone 4071 towards the needle slot 4077 and become aligned with the needle slot 4077 of needle receptacle 4070. The needles 104 can then be moved in translation along the longitudinal axis of the needle receptacle 4070 (i.e., the axis of orientation of the needle driver slots) from the entry zone 4071 into the secure zone 4072 where the needles 104 slide into the needle slot 4077 with the convex side facing the secure zone 4072 and the sharp tip and tail of the needle 104 facing the entry zone 4071. The needle driver can move the used needles 104 into the needle slot 4077 in the secure zone 4072 until the needle driver runs into the end of the needle slots of needle receptacle 4070 or the last inserted used needle 104.
In different embodiments, the needle receptacle 4070 can have different dimension depending upon the size of the needles 104 being received. Thus, a small needle receptacle 4070 used to receive smaller needles 104 can have smaller dimensions than a large needle receptacle 4070 used to store larger needles.
Structural components of needle receptacle 4070 may be joined as described herein (e.g., adhesive, mechanical fits, welds). The underside of needle receptacle 4070 may be configured to attach and/or couple (e.g., by hook and look couplings, adhesive) to many of the structures described herein, including barriers, barrier mounting bases, bases, and the like. In many embodiments, needle receptacle 4070 may be configured to releasably attach to many of the structures described herein.
In the illustrated embodiment, the needle receptacle 4140 may be a substantially planar device comprised of a secure zone 4142, as described herein. The needle receptacle 4140 may also comprise a landing zone 4141, as described herein. The needle receptacle 4140 may include an upper structure 4143, a lower structure 4146, and a needle slot 4149 disposed between the upper structure 4143 and the lower structure 4146. The needle slot 4149 may be configured for securing one or more needles, as described herein. The needle slot 4149 of needle receiver 4140 may constrain needles placed therein into a single needle depth array, to minimize overall depth profile and facilitate needle counting as described herein. The needle slot 4149 may be enclosed at all sides except at end 4143a of the upper structure 4143, in accordance with many embodiments described herein. The lower structure 4146 may comprise a channel 4146a formed in the upper surface thereof. The channel 4146a may be sized to receive a needle driver tip. The upper structure 4143 may comprise a stiff structure 4144, a flexible structure 4145, and a needle driver slot 4148 formed between the stiff structure 4144 and the flexible structure 4145.
The needle driver slot 4148 may be formed between an edge 4145a of the flexible structure 4145 and an edge 4144a of the upper structure. In many embodiments, edge 4145a of the flexible structure may separate from edge 4144a of the stiff structure to receive a needle driver, as described herein. In many embodiments, edges 4145a and 4144a may contact each other in a non-deformed free standing state without a needle driver extending therebetween. In some embodiments, edges 4145a and 4144a may be spaced apart from each other in a non-deformed state, a gap being defined therebetween.
The needle receptacle 4140 may comprise a compliant structure 4147 disposed between the upper surface of the lower structure 4146 and the lower surface of the stiff structure 4144. In many embodiments, the compliant structure 4147 may apply a holding force against one or more needles within the needle slot 4149 and the secure zone 4142 to resist translation of the needle out of the needle slot 4149 and the secure zone 4142. In many embodiments, the upper structure 4143 may apply a holding force against one or more needles within the needle slot 4149 and the secure zone 4142 to resist translation of the needle out of the needle slot 4149 and the secure zone 4142. In many embodiments, the compliant structure 4147 may comprise foam. In many embodiments, the compliant structure 4147 may comprise a compliant element.
In many embodiments, the needle driver slot 4148 may be disposed parallel to channel 4146 of the lower structure 4146. In many embodiments, the needle driver slot 4148 may be disposed parallel to and above channel 4146 of the lower structure 4146.
In many embodiments, a portion of the lower structure 4146 may extend beyond end 4143a of the upper structure 4143, forming a landing zone 4141. In some embodiments, the needle may be placed in contact with the upper surface of the extended portion of the lower structure 4146 with the needle driver tip holding the needle aligned with the needle driver slot 4148 of needle receptacle 4140. In some embodiments, channel 4146 may extend into the landing zone 4141. In some embodiments, the needle may be placed in contact and within channel 4146 of the upper surface of the extended portion of the lower structure 4146 with the needle driver tip holding the needle aligned with channel 4146 of the lower structure 4146 and needle driver slot 4148 of needle receptacle 4140.
In some embodiments, stiff upper structure 4143 and flexible upper structure 4145 may comprise beveled edges 4144b and 4145b, respectively, at opposing sides of needle driver slot 4148. The beveled edges 4144b and 4145b may facilitate easy locating of the needle driver into the needle driver slot 4148 when placing needles in needle receptacle 4140.
In different embodiments, the needle receptacle 4140 can have different dimension depending upon the size of the needles being received. Thus, a small needle receptacle 4140 used to receive smaller needles can have smaller dimensions than a large needle receptacle 4140 used to store larger needles.
Structural components of needle receptacle 4140 may be joined as described herein (e.g., adhesive, mechanical fits, welds). The underside of needle receptacle 4140 may be configured to attach and/or couple (e.g., by Velcro, adhesive) to many of the structures described herein, including barriers, barrier mounting bases, bases, and the like. In many embodiments, needle receptacle 4140 may be configured to releasably attach to many of the structures described herein. In some embodiments, needle receptacle 4140 may be configured to be received by a receiving element or other structure as described herein.
Forceps Mounted Receptacle: The dispenser, trap and forceps may comprise an all in one sterile configuration. These can be manufactured together, with each being disposable. The forceps could contain the suture material, for example.
The needles can be packaged with the barrier as a unit. The needles can be arrayed for deployment from the barrier wall with the barrier having an area available for suture coiling.
Alternatively, suture coiling may not be provided. The packaging can be configured to be dispensed from the barrier or the forceps.
It can be easier to load a trap onto a forceps along with the suture pack and have five or so such “set ups” ready on the Mayo stand. When one has been used up, it can be placed the Mayo and the next one grabbed.
The combination of both dispensing unit (suture package) and used needle repository can be associated together on the forceps.
More than one setup of a suture package and needle receptacle can be combined and ready for use.
The sterile packaging may comprise disposable single use forceps, needle and suture dispenser in combination with a used needle receptacle. These can be co-manufactured.
The forceps mounted receptacles may comprise one or more of many different shapes and sizes. The weight can be sufficiently low in order to provide balance to the forceps mounted instrument. The needle receptacles configured for mounting on the forceps can be configured to provide a balanced surgical instrument with the attachment of needle retention device onto the forceps.
Any design weighing less than 250 grams.
The needle receptacle can be located on one side of forceps, dispensing unit (suture pack) on the other side to save space and volume. The forceps can be easily be rotated to gain access to one or other side when the suture package and needle receptacle are mounted on opposing sides of the forceps.
The needle receptacle may comprise adhesive and can be placed on the back of suture pack or vice versa.
The needle receptacle and suture package can be configured to use a back to back on opposing sides relationship of needle dispensing device and needle receptacle.
The suture packs and needle receptacles as described herein can be configured to coupled to, for example attach, to the forceps that allows for containment, coverage, securement, of both tip and end (tail) of one or more needles.
The needle arrangement in the receptacle may not need to be planar, and can be stacked into trough, side by side, for example.
The forceps mounted needle receptacle as described herein can promote an organized deposition or array of used needles to facilitate counting and reconciliation of needle count.
Needle Count Reconciliation: The scrub assistant and circulator often to maintain an ongoing count of needles (needles in use, needles in the field, needles on the mayo stand, needles on the back table). The receptacle can be specifically designed to hold five needles for easy counting by the surgeon and staff. This can facilitate reconciliation and communication with the rest of the team. The trap or securement, containment device can be specifically designed for five needles, and sized and shaped accordingly. The needle receptacle as described herein may comprise five zones, one for each needle. For example five tactile protrusions as described herein can be used to facilitate localization into each of the five individual zones.
One or more of the needle receptacle, the barrier or the suture package may comprise light sources to indicate needle status. Five light sources, one for each needle entry into the trap, can be provided, for example. Five light sources on could mean five needles in in the receptacle. This configuration could be easier to see from a distance. These sources could be in the trap (receptacle) or there could be a means of communication between trap and barrier with light sources on the barrier. Lighting could be anywhere on the barrier, but be preferred if lighting is dorsal for ease of visualization by the assistant such as a scrub nurse, for example when the trap is on the volar surface and perhaps less visible for the assistant to see. Both volar lighting and dorsal lighting could be provided, for example. There could be five zone specific light sources with one light on per needle into the trap, for example with light sources on the trap. Five light sources on the trap could be in communication with the barrier, and the five lights on the barrier light up according to number of needles in the trap.
This longitudinal receptacle that receives needles with sliding could have five stops with each stop representing an additional needle added to the slot. The longitudinal sliding cover can be spring loaded. Each time the needle driver is abutted against the leading edge of the cover, it triggers a unit translational movement. This movement can be repeated with each needle entry until the slot is fully covered. Each translational unit movement can be numbered 1 through five.
The needle receptacle (for example having a slot to receive needles and the driver) can be configured with ratcheted counting mechanism. There can be an active count of needles to be dispensed as well. A user can start with five needles in the dispenser and zero in the trap (0:5). The user would end with (5:0), when needles are reconciled. The apparatus can be configured with five light sources on the dispenser and count down to zero. This reconciliation by lighting can be helpful.
In some embodiments, the needle receptacle comprises means for reconciling needles during or after the procedure.
In some embodiments, a first set of needles from a first suture pack are reconciled before a second suture pack enters the near surgical field.
In some embodiments, a dispensed needle receptacle comprising five or more dispensed surgical needles is received from a surgeon, wherein the dispensed surgical needles are stabilized and innocuous within the needle receptacle, the needle receptacle comprising one or more of an opening, a window or a transparent material for counting the stabilized innocuous dispensed needles, wherein the needles are arranged for counting within the receptacle.
In some embodiments, a dispensed needle receptacle comprising five or more dispensed surgical needles is received from a person who reconciled the surgical needles, wherein the dispensed surgical needles are stabilized and innocuous within the needle receptacle, the needle receptacle comprising one or more of an opening, a window or a transparent material for counting the stabilized innocuous dispensed needles, wherein the needles are arranged for counting within the receptacle.
The kits shown in
In some embodiments of needle receptacles disclosed herein, a housing of a needle receptacle may include a light scattering material or a light scattering surface for non-uniform light transmission therethrough. In some embodiments the upper or lower structure or surface of the upper or lower structure may be the light scattering surface or material. The light scattering surface or material may be a roughened surface or a sandblasted surface.
With respect to
With reference to
In some embodiments, the needle receptacle or suture pack may be placed such that dispensing or securing a needle from or to the suture pack or needle receptacle does not require external rotation 3345a of the arm or shoulders with respect to a sagittal plane that bisects the coronal plane at the surgeon's shoulders, therefore allowing the user to engage only fine motor control, rather than gross motor control, to perform movements related to the dispensing and securing of needles.
In some embodiments, the needle receptacle or suture pack may be placed such that dispensing or securing a needle from or to the suture pack or needle receptacle does not require external rotation 3345a of the arm or shoulders with respect to a mid sagittal plane of the surgeon, therefore allowing the user to engage only fine motor control, rather than gross motor control, to perform movements related to the dispensing and securing of needles.
In some embodiments, the needle receptacle may be placed or otherwise configured such that securing a needle into the needle receptacle uses only gross motor movement of the surgeon.
In some embodiments, the needle receptacle may be placed or otherwise configured to facilitate needle insertion into the needle receptacle using only articulation or rotation of the shoulder or elbow joints of a surgeon.
In some embodiments, the resistance of the needle driver along the needle driver slot is less than the resistance of the needle along the needle slot when the needle is advanced along the slot with a needle driver.
The systems and methods as described herein may be used to safely handle sutures during procedures involving non-living subjects, such as during the performance of autopsies on cadavers, wherein the person operating on the subject may still be exposed to blood-borne pathogens. Alternatively or in combination, the systems and methods described herein may be used to safely handle sutures during procedures involving non-human subjects, such as during the performance of an operation of an animal (e.g., in a veterinary practice or in animal studies).
While preferred embodiments of the present invention have been shown and described herein, it will be obvious to those skilled in the art that such embodiments are provided by way of example only. Numerous variations, changes, and substitutions will now be apparent to those skilled in the art without departing from the invention. It should be understood that various alternatives to the embodiments of the invention described herein may be employed in practicing the invention. It is intended that the following claims define the scope of the invention and that methods and structures within the scope of these claims and their equivalents be covered thereby.
This application is a continuation of PCT Application No. PCT/US16/59599, filed on Oct. 28, 2016, entitled “Systems and Methods for Increased Operating Room Efficiency”, which claims the benefit of U.S. Provisional Application No. 62/248,029, filed on Oct. 29, 2015, entitled “Systems and Methods for Increased Operating Room Efficiency”, the entire disclosure of which is incorporated herein by reference. The subject matter of the present application is related to U.S. application Ser. No. 14/697,050, filed on Apr. 27, 2015, entitled “Systems and Methods for Increased Operating Room Efficiency”, and PCT/US2015/027659, filed Apr. 24, 2015, entitled “SYSTEMS AND METHODS FOR INCREASED OPERATING ROOM EFFICIENCY”, the entire contents of which are incorporated herein by reference.
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Number | Date | Country | |
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20180185025 A1 | Jul 2018 | US |
Number | Date | Country | |
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62248029 | Oct 2015 | US |
Number | Date | Country | |
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Parent | PCT/US2016/059599 | Oct 2016 | US |
Child | 15895896 | US |