Aspects of the present disclosure relates to biopsy procedures and systems. In particular, the disclosure relates to methods, systems, and apparatus useful for planning and performing guided and free-handed transperineal prostate biopsies.
A biopsy is a medical procedure that involves sampling and removing tissues or cells from a living body for further examination and analysis. A prostate biopsy may be performed by a care provider for diagnosis and treatment of a patient's prostate. For example, the vast majority of patients with an abnormal prostate specific antigen (PSA) or suspicious results from a digital rectal examination (DRE) undergo biopsy. Typical biopsy procedures include transrectal ultrasound-guided (TRUS) biopsies and transperineal ultrasound-guided (TPUS) biopsies.
TRUS involves obtaining tissue or cell specimens by passing a biopsy needle or other biopsy instruments through the rectal wall and into the prostate at various locations using a sagittal imaging plane. The biopsy needle or other biopsy instruments may be guided by ultrasound in a sagittal plane. There are disadvantages associated with TRUS. In particular, the patient may be required to take antibiotics prior to the procedure to reduce the risk of infections. Also, TRUS requires the patient to perform bowel preparation, which is a procedure usually undertaken before the biopsy, for cleansing the intestines of fecal matter and secretions. Further, the passage of the biopsy needle through the rectal wall may introduce bacteria from the rectum into the prostate, such as coliform bacteria that may lead to an infection or other complications. Additionally, many clinically significant prostate cancers are found in locations of the prostate that are often too difficult to access when using the transrectal approach.
TPUS includes obtaining tissue or cells specimens by passing one or more biopsy needles through the perineum and into the prostate. TRUS has been favored over TPUS. Unlike TRUS, TPUS does not require a patient to take antibiotics prior to the procedure or to undergo the bowel preparation for lowering the risk of bacterial issues. Further, TPUS uses a more effective route to access the prostate and is capable of accessing target locations that may be difficult to access utilizing the transrectal approach in comparison with TRUS. In addition, the needle does not pass through the rectal wall which eliminates the risk associated with TRUS of coliform bacteria entering the prostate or the bloodstream.
Systems configured for TPUS include a biopsy grid that may be fixed to, for example, a floor, platform, or table on which the patient receiving the biopsy lies. The biopsy grid may provide multiple apertures through which a biopsy needle or other biopsy instruments may be inserted. An ultrasound probe is fixed directly to the apparatus and is used to axially guide the biopsy needle or other instruments, for example other biopsy instruments. Thus, TPUS systems require imaging in an axial plane of the ultrasound or a transverse transducer for positioning the biopsy needle.
It is with these observations in mind, among others, that various aspects of the present disclosure were conceived and developed.
Aspects of the present disclosure involve a biopsy guide configured to couple with a transrectal probe and for use in guiding an access needle in a transperineal prostate biopsy procedure. The access needle may be configured to perforate and be positioned within subcutaneous tissue of a perineum at an access site of a target area of a patient. The biopsy guide may include a guide member and a displacement member supported by the guide member. The guide member may be configured to operably couple with the transrectal probe and including a distal end, a proximal end opposite the distal end, and a length extending along a longitudinal axis between the distal and proximal ends. The displacement member may be configured to support the access needle and displace the access needle along at least a portion of the length of the guide member between the distal and proximal ends. The access needle may be configured to extend into the subcutaneous tissue when the access needle is displaced to the distal end.
In certain embodiments, the biopsy guide may further include the access needle.
In certain embodiments, the biopsy guide may further include the transrectal probe.
In certain embodiments, the displacement member may be configured to displace along the at least a portion of the length of the guide member between the distal and proximal ends. In certain embodiments, the guide member may include a guide rail extending at least a portion of the length between the distal and proximal ends, and the displacement member may include a coupling mechanism to releasably couple with the guide member. In certain embodiments, the displacement member may be configured to displace relative to the guide member via interaction of the coupling mechanism and the guide rail.
In certain embodiments, the displacement member may be configured to slidingly displace relative to the guide member via interaction of the coupling mechanism and the guide rail.
In certain embodiments, the guide rail may include a first guide rail and a second guide rail opposed to the first guide rail, the displacement member releasably coupled between the first and the second guide rails.
In certain embodiments, the coupling mechanism may include: first upper and lower members which may be configured to sandwich the first guide rail; and second upper and lower members which may be configured to sandwich the second guide rail.
In certain embodiments, the coupling mechanism may include upper and lower members which may be configured to sandwich the guide rail.
In certain embodiments, the displacement member may include a plurality of needle receiving ports for positioning the access needle in a plurality of orientations relative to the transrectal probe. In certain embodiments, each of the plurality of needle receiving ports may be configured to align the access needle parallel with a longitudinal axis of the transrectal probe. In certain embodiments, the plurality of needle receiving ports may include five needle receiving ports.
In certain embodiments, the biopsy guide may include a lower mount releasably coupled to the guide member and including a probe coupling mechanism for releasably coupling with the transrectal probe.
In certain embodiments, the probe coupling mechanism extends at least partially around the transrectal probe, wherein the guide rail extends distally beyond the probe coupling mechanism.
In certain embodiments, the probe coupling mechanism extends at least partially around the transrectal probe, wherein the displacement member may be configured to distally displace beyond the probe coupling mechanism.
In certain embodiments, the guide member may include a slot extending a first length between the distal and proximal ends, the displacement member including a rail member may be configured to be received within the slot such that the displacement member is displaceable along the at least a portion of the length of the guide member between the distal and proximal ends. In certain embodiments, a longitudinal axis of the slot is generally parallel with a longitudinal axis of the transrectal probe when the guide member is secured to the transrectal probe. In certain embodiments, interaction between the slot and the rail member constrains lateral movement of the displacement member relative to the guide member. In certain embodiments, interaction between the slot and the rail member constrains the vertical tilting of the displacement member relative to the guide member. In certain embodiments, the displacement member may include a plurality of needle receiving ports oriented vertically or in a single plane relative to each other. In certain embodiments, the guide member may include a pair of guide rails, the displacement member may be configured to displace between the pair of guide rails.
In certain embodiments, the access needle may extend beyond the distal end of the guide member when the access needle is displaced to the distal end. In certain embodiments, the access needle may be configured to be locked into position at the distal end.
Aspects of the present disclosure may also involve a biopsy guide which may be configured to couple with a transrectal probe and for use in guiding an access needle in a transperineal prostate biopsy procedure. The access needle may be configured to perforate and be positioned within subcutaneous tissue of a perineum at an access site of a target area of a patient. The biopsy guide may include a guide member and a displacement member. The guide member may be configured to operably couple with the transrectal probe and may include a distal end, a proximal end opposite the distal end, and a length between the distal and proximal ends. The displacement member may be supported by the guide member and may be configured to support and displace the access needle along at least a portion of the length of the guide member between the distal and proximal ends while maintaining a fixed trajectory of the access needle.
In certain embodiments, may include the transrectal probe.
In certain embodiments, may include the access needle.
In certain embodiments, the displacement member may slidingly couple with the guide member via a coupling mechanism such that the displacement member is displaceable relative to the guide member. In certain embodiments, the guide member may include a first rail member, and the coupling mechanism may include upper and lower members that sandwich the first rail member. In certain embodiments, the guide member may further include a second rail member opposite the first rail member, the upper and lower members sandwiching the second rail member. In certain embodiments, the fixed trajectory is generally parallel to a longitudinal axis of the transrectal probe. In certain embodiments, the guide member may include a pair of guide rails extending the length, and the displacement member may be positioned between the pair of guide rails and slidingly couple with the pair of guide rails via a coupling mechanism. In certain embodiments, the coupling mechanism may include upper and lower members that sandwich each of the pair of guide rails.
In certain embodiments, the guide member may include a sheath in which the probe resides when the guide member is operably coupled with the transrectal probe.
In certain embodiments, the biopsy guide further includes a mechanical arrangement between the guide member and the displacement member that at least facilitates the displacement of the access needle along the at least a portion of the length of the guide member, wherein the mechanical arrangement may include at least one of a sliding arrangement, a lead screw, or a parallel bar linkage.
In certain embodiments, the guide member operably couples with the transrectal probe via at least one of a sheath arrangement, a ratchet arrangement, a biased collar arrangement, a flexible strap arrangement, a clamping arrangement, or a clamshell collar arrangement.
Aspects of the present disclosure also involve a biopsy guide which may be configured to couple with a transrectal probe and for use in guiding an access needle in a transperineal prostate biopsy procedure. The access needle may be configured to perforate and be positioned within subcutaneous tissue of a perineum at an access site of a target area of a patient. The transrectal probe may include a distal end, a proximal end opposite the distal end, and a longitudinal axis between the distal and proximal ends. The biopsy guide may include a displacement member which may be configured to be operably coupled with the transrectal probe and to support and displace the access needle along at least a portion of the transrectal probe. The displacement of the access needle may be along a trajectory that is parallel to the longitudinal axis of the transrectal probe.
In certain embodiments, the biopsy guide may further include a guide member operably coupled to the displacement member and by which the displacement member is operably coupled with the transrectal probe.
In certain embodiments, at least a portion of the displacement member displaces relative to the guide member when the access needle is displaced along the trajectory that is parallel to the longitudinal axis of the transrectal probe.
In certain embodiments, the biopsy guide may further include a mechanical arrangement between the guide member and the displacement member that at least facilitates the displacement of the access needle along the trajectory that is parallel to the longitudinal axis of the transrectal probe, wherein the mechanical arrangement may include at least one of a sliding arrangement, a lead screw, or a parallel bar linkage.
In certain embodiments, the guide member may operably couple with the transrectal probe via at least one of a sheath arrangement, a ratchet arrangement, a biased collar arrangement, a flexible strap arrangement, a clamping arrangement, or a clamshell collar arrangement.
In certain embodiments, the biopsy guide may further include a mechanical interface by which the displacement member is operably coupled with the transrectal probe and by which the displacement member displaces the access needle along the trajectory that is parallel to the longitudinal axis of the transrectal probe. In certain embodiments, the mechanical interface may include at least one of a sliding arrangement directly between the transrectal probe and the displacement member or a rolling arrangement directly between the transrectal probe and the displacement member.
In certain embodiments, the biopsy guide may further include the transrectal probe and wherein the transrectal probe may include a first portion of the sliding arrangement and the displacement member may include a second portion of the sliding arrangement directly engaged in sliding contact with the first portion. In certain embodiments, at least one of the first portion or second portion comprises a slot, a rail, or a bar.
In certain embodiments, the biopsy guide may further include the transrectal probe and wherein the sliding arrangement may include at least a portion of the displacement member being in direct sliding contact with an exterior surface of the transrectal probe.
In certain embodiments, the biopsy guide may further include the transrectal probe and wherein the rolling arrangement may include a roller bearing arrangement supported on the displacement member being in direct rolling contact with an exterior surface of the transrectal probe.
Related art systems and prostate biopsy TPUS methods do not allow free-hand movement of the ultrasound probe, and heavily rely on the axial ultrasound plane to confirm positioning of the biopsy needle or other instruments. Moreover, such systems and methods include extracting prostate tissue specimens by delivering separate punctures into the transperineal tissue. Also, a care provider executing TPUS procedure using related art systems may experience substantial difficulty in freely handling and positioning a biopsy needle at a desired target location of the prostate relying on the sagittal plane in using the TRUS methods.
An apparatus in accordance with an embodiment may include an upper mount and a lower mount. The lower mount may be configured to connect with the upper mount to secure a transrectal probe therebetween. The upper mount may be configured to support an access needle, the access needle configured for perforation of subcutaneous tissue of a perineum at an access site of a target area of a patient. The upper mount may be configured to guide the access needle whereby movement of the access needle is fixed relative to movement of the transrectal probe.
A system in accordance with an embodiment may include a biopsy guide and a transrectal transducer fixed to the biopsy guide. The biopsy guide may be configured to guide an access needle to perforate an access site in subcutaneous tissue of a perineum, whereby movement of the access needle is fixed relative to a movement of the transrectal transducer.
A method of performing a prostate biopsy in accordance with an embodiment may include imaging a prostate in an axial plane and a sagittal plane with a transducer providing a real-time image, locating a target area of the prostate, and positioning an access needle and an access site in subcutaneous tissue of a perineum wherein the access site is at a midpoint between a lateral edge of the prostate and a urethra along a first axis and a midpoint between an anterior capsule and a posterior capsule along a second axis. The method may include guiding a biopsy instrument along a sagittal plane to the target using the real-time image, and obtaining one or more specimens of the prostate through the access needle with a biopsy instrument.
Accordingly, there is a demand for transperineal biopsy methods, systems, and apparatus that enables a biopsy that is less burdensome for the patient and for the practitioner performing the biopsy, increased guidance of needle or other biopsy instruments, and with a higher rate of efficacy and lower rate of health risk than related art TPUS and TRUS systems and methods. Apparatus, systems, and methods disclosed herein satisfy these demands.
Other implementations are also described and recited herein. Further, while multiple implementations are disclosed, still other implementations of the presently disclosed technology will become apparent to those skilled in the art from the following detailed description, which shows and describes illustrative implementations of the presently disclosed technology. As will be realized, the presently disclosed technology is capable of modifications in various aspects, all without departing from the spirit and scope of the presently disclosed technology. Accordingly, the drawings and detailed description are to be regarded as illustrative in nature and not limiting.
The apparatus, systems, and methods provided herein enable real-time visualization, free-handed, guided, and multi-sample transperineal methods for performing a biopsy. The methods, systems, and apparatus provided herein also enable a complete biopsy of the prostate with only one perforation, or with minimal perforations of a patient's skin by way of an initial access site, such that the access needle is freely moveable. The biopsy guide may be placed on or fitted to an assortment of ultrasound probes of different sizes and shapes due to an adjustable mounting system. The guide may be configured to fit to the probe using any suitably configured fastening system. For example, the guide may be configured as a sleeve that is formed to slide over an end of a probe and into an operable position. Alternatively, the guide may be configured to fit to a probe using screws, flanges, zip ties, or other temporary, permanent, or semi-permanent fastening systems.
In one embodiment, the guide allows biopsies of one or more tissue or cell samples to be obtained through an initial access needle, while providing direct, real-time ultrasound visualization by, for instance, fixing a position of the access needle relative to an ultrasound probe to provide. For example, the guide is fixed to an ultrasound probe that is not fixed and may be freely moveable in operation. Stabilization bars that are built into the guide facilitate the positioning and holding of the perineal skin and subcutaneous tissue to allow positioning of the access needle. The position of the access needle is facilitated by locking the access needle into the subcutaneous tissue of the perineum using a sliding platform that allows a user, such as a medical practitioner or patient caregiver, to place the access needle along a sagittal transducer plane at optimal positions for obtaining prostate biopsies. In some embodiments, upon placement of the access needle into a locked position, for example, in the pelvic floor, a user may then pass a biopsy needle through the access needle to a desired location of the prostate. In yet further embodiments, the passing of the biopsy needle through the access needle and to the prostate may be facilitated by direct sagittal plane visualization based on the alignment of the access needle.
Methods and systems provided herein do not require a patient to take antibiotics at any point prior to the biopsy procedure, nor do they require a patient to undergo bowel preparation in advance of the procedure. Methods, systems, and apparatus can reduce or eliminate multiple skin perforations by using a single access location or access site, while allowing multiple extractions of tissue or cell specimens from the prostate. Methods, systems, and apparatus in accordance with embodiments allow for real-time visualization during a free-handed, guided, transperineal approach, while also facilitating a complete assessment of the prostate with, for example, only one perforation of the patient's skin wherein the access needle is freely moveable in each plane.
Methods, systems, and apparatus of embodiments may include and facilitate treatment that uses a cryoablation probe for focal therapy of prostate cancer, a radiofrequency instrument, a thermotherapy instrument, any instrument for treatment of the cancerous area, or a combination of any of these instruments.
Methods, systems, and apparatus of embodiments enable planning and performing the free-hand transperineal prostate biopsies under the guidance of a device and of a real-time transducer in the sagittal imaging plane.
The biopsy is performed using a system that includes a biopsy guide, a transducer, an access needle, and a biopsy instrument. The access needle may allow the anesthesia to be injected into the patient, and the tissue or cell specimens of the prostate to be extracted. If anesthesia is used, a syringe may be included in the system. The transducer may be an ultrasound probe or any other type of device that is capable of causing a visualization of the prostate in a display device. In embodiments, the biopsy guide may be disposable. In embodiments, the biopsy guide may be formed of materials intended for a single use. In other embodiments, the biopsy guide is reusable. In some embodiments, the biopsy guide may be formed of materials intended for multiple uses.
The guide may include a sliding platform, stabilization bars, one or more upper and lower mounts, and a fastener. The upper and lower mounts may be curvilinear in shape. The upper and lower mounts may be positioned proximally or distally along an ultrasound probe, such as a transrectal ultrasound probe. The configuration and positioning of the upper and lower mounts are adjustable based on the shape of the ultrasound probe and the patient's body habitus.
The guide may be made of any material such as a plastic or metallic material. The guide may be disposable and made of a biodegradable plastic material. In other embodiments, the guide may be reusable and made of stainless steel. The dimensions, for example, the length, width, height, depth, and breadth of the sliding platform, stabilization bars, upper and lower mounts, and the fastener may vary and may be adjustable. The variable and adjustable dimensions, for example, of the stabilization bars, provide a user with flexibility in achieving and maintaining the guide in an appropriate ultrasound plane while performing biopsy procedures, while the user's patients may vary in size and levels of perineal subcutaneous tissue and fat. In a patient with an excessive amount of perineal subcutaneous tissue and fat, a larger stabilization bar will assist in locking the guide in the proper ultrasound plane.
The adjustable stabilization bars and mounts may be curvilinear in shape, allowing the guide to be placed proximally or distally along any cylindrical instrument, such as the transrectal ultrasound probe, which is determined by the surgeon based on the shape of the probe and the patient's body habitus. This allows the guide to be mounted to any assortment of ultrasound probes. Similarly, the platform may, for example, have various thicknesses.
The stabilization bars may be fixed to a top portion of the upper curvilinear mounts of the guide, and may extend beyond the front edge of the upper mounts. The stabilization bars may extend beyond the front edge of the upper curvilinear mount by approximately 8 mm. The guide may be approximately 60 mm wide, or the guide may be approximately 50 mm long, for example. The stabilization bars may have grooves for accommodating a sliding platform that is shorter in length than the stabilization bars. The grooves being configured to allow the platform to slide forward and backward along the stabilization bars.
An inner portion of the stabilization bars may have built-in grooves. The grooves accommodate a sliding platform which is shorter in length than the stabilization bars. This allows the sliding platform to slide from the back to the front of the stabilization bars. The stabilization bars may include a resistance as to prevent the sliding bar to freely move back and forth on the stabilization bar. This resistance may be introduced by the sliding platform or both the stabilization bar and the sliding platform. The resistance may be provided by a strip of rubber or any other material capable of providing friction or other. The strip may be curvilinear. The resistance may be generated by a mechanical system, such as a spring mechanism.
The sliding platform may have a hole through the platform. In some embodiments, the hole is drilled in the center of the platform. The hole can accommodate various types of needles, including access needles having various diameters, for example, spinal needles having a gauge in the range of 14-18. The hole can also accommodate needles having various lengths. The lengths of the needle may depend, in part, on the body habitus. The needle may be a reusable needle, such as a reusable spinal needle. The needle may be a disposable needle, such as a disposable spinal needle.
A flange of the guide secures the placement of the access needle to the guide. The flange may be configured to snap into the guide to secure the needle. The flange may be secured to the guide by other securing mechanisms. The flange can be of various shapes and configurations. For example, the flange may be u-shaped. As another example, the flange may have a thin or slim configuration. The guide assists in providing the appropriate angle of penetration and direction of the access needle, or other instruments that may be used in combination with the guide.
The hole in the guide is placed so that once the guide is mounted to the ultrasound probe, the drilled hole will be parallel to the sagittal transducer. The drilled hole may also accommodate the tip of a biopsy gun, or any other biopsy instrument. The sliding platform may be interchangeable and may be removed to allow placement of another sliding platform with a different sized to permit different sizes of needles and other instruments. The hole may be configured to accommodate a cryoablation instrument, a radiofrequency instrument, thermotherapy instrument, or any other instrument for diagnosis and treatment of a bodily tissue, including a cancerous area of a prostate.
The platform may have or define a predrilled hole in the center of the platform that can accommodate various sizes of needles and instruments. For example, the hole may be configured to accommodate a needle having a range of 14-18 gauges, such as a reusable 14 gauge spinal needle. Central hole placement on the platform enables alignment of the hole with a sagittal transducer when the guide is mounted to an ultrasound probe. The platform may have multiple holes to accommodate various applications and body habitus. Further, the platform may be of various thicknesses.
Once the one or more upper curvilinear mounts are placed at the desired location on the transrectal ultrasound probe, the access hole for a needle, such as a 14 gauge reusable spinal needle, will remain a fixed distance from the ultrasound probe. In embodiments, having one or more lower curvilinear mounts, the mounts may be positioned to cradle an upper aspect of the ultrasound probe.
At least two lower mounts are provided and may be individually positioned to accommodate various types of probes, which may have variable diameters along their shafts. In embodiments, a probe, such as a transrectal ultrasound probe, may have one or more diameters along the probe's shaft. In yet further embodiments, one end of the guide may be fixed at a location of the probe having a different diameter than the location where the other end of the guide is fixed. The separate lower mounts allow for the fixation of the guide, even with varying probe diameters.
The lower mount of the guide may include a lower right mount and a lower left mount connected by an adjustable mid-joint or fastener. The adjustable mid-joint or fastener allows the guide to be secured to the probe even if the diameter of the shaft of the probe is longer than the width of the lower mount. The mid-joint or fastener may be flexible to allow the right lower mount to form an acute angle with the left lower mount. This also allows for fixation of the guide to a probe shaft that is not circular in shape.
The lateral edges on both ends of the lower mounts may contain a notched post. Corresponding locations of the upper mounts contain holes, such as square shaped holes, to accommodate the notched post of a corresponding lower mount. An upper aspect of each hole includes a flange for locking the notched post in a fixed position. This configuration allows the lower mounts and the upper mounts to be secured to each other and to the probe.
Methods may include locating a suspicious area, positioning an access needle, and obtaining one or more tissue or cell specimens from an accurate point in the prostate. The method allows for multiple tissue or cell specimens to be obtained from a bodily organ, such as the prostate, and permits access to the prostate from different angles through a single initial access needle. The method may include calculating the volume of the prostate by positioning the access needle at a mid-point in the x axis from the lateral edge of the prostate to the urethra.
Methods may be performed using no anesthesia. Alternatively, an anesthetic may be used. For example, the anesthetic may be lidocaine, or any type of local anesthetic. The lidocaine may include 1 or 2% of a lidocaine solution.
The suspicious area or bodily organ may be located by using a transducer. The transducer may be any type of probe for accessing and viewing a targeted site or object, such as an ultrasound probe, or any type of transducer capable of providing visualization of the prostate and/or instruments and devices for diagnosis and treatment of the tissue. The biopsy may be performed using a biopsy gun, a suction device, or any type of instrument that is small enough to be introduced through the access needle and capable of extracting the tissue or cell specimen. The biopsy may be performed while the patient is in a dorsal lobothy position, prone position, or any position that allows for access to the perineal area.
Methods may include applying an antiseptic solution to the perineal area. The antiseptic solution may include betadine, or any other substance that reduces the possibility of infection, sepsis, or putrefaction. Methods may include applying bacitracin to the skin at the puncture site or any other type of topical preparation for preventing the possibility of infection.
Methods may include attaching a needle to a luer lock syringe, which may contain an anesthetic, or any other type of device capable of retaining its contents and dispensing its contents through the needle. A biopsy gun or any other instrument that may be attached to the needle and used for inserting or extracting any substance thru the lumen of the access needle.
Methods may include releasing the syringe from the needle after the anesthetic is injected. Methods may include dividing the prostate in three different regions and designating lateral, mid, apical prostate, and may include labeling the tissue or cell specimen containers, which will identify the tissue or cell specimens.
Methods may include securing the guide to the probe. This will permit the practitioner to take the biopsy gun as many times as necessary using his/her other hand, and, consequently, extract multiple tissue or cell specimens. It is contemplated that this can be done without assistance of any other person, and that the biopsy gun may also be attached to the guide in order to permit the surgeon to, for example, label the container with the tissue or cell specimen while performing the biopsy. Methods may also include monitoring all the actions in the prostate by way of a display device that provides images captured by the probe.
Methods may include moving the needle in x, y, and z planes. By being able to move the needle in x, y, and z planes, the surgeon is capable of extracting tissue or cell specimens from several different areas of the prostate without having to retrieve the needle and preventing other perforation of the patient's skin. In embodiments, movement of the needle within the patient's body is facilitated by using a display device.
Methods may include removing the access needle from the perineal area. This may be done while the biopsy gun is secured to the access needle or after the biopsy gun has been detached from the access needle.
Methods may include realigning the needle in the desired prostate region. If the surgeon wishes to start at the right lateral prostate region and notices that the needle tip is not directed at the lateral region, the surgeon rolls the ultrasound probe slightly and to note that the needle tip is directed to the desired region, then the surgeon may realign the needle to obtain tissue or cell specimen. The surgeon may realign the needle using one hand while having the needle attached to the biopsy gun, which may be attached to the probe through the guide.
Methods may include identifying the areas in which biopsy have already been performed. After each extraction of tissue or cell specimen during the biopsy, a hyperechoic streak remains visible on ultrasound display. This allows the surgeon to identify the area of the prostate and that an extraction has been made, as to allow the surgeon to prevent overlap of extractions.
In another embodiment, the method includes identifying the path of the urethra. This allows the surgeon from preventing passing the biopsy needle thru or into this path.
In one embodiment, the fastener (e.g., via the aperture 201, flange 203, and/or the teeth 202) can be configured to fasten the guide 100 to the probe 103 with, e.g., varying levels of tension to provide for adjustments of the relative positions of the guide 100 and the probe 103 even after the guide 100 has been mounted to the probe 103. For example, the fastener 102 can provide a first level of tension sufficient to hold the position of an access needle (e.g., introduced through a hole or other needle mount of the guide 100) rotationally fixed to the probe 103 while still allowing for a forward or reverse sliding of the probe 103 with respect to the guide 100. By way of example, the forward or reverse sliding adjustment can be performed to adjust the penetration depth of the probe 103 with respect to the patient depending on a size of the patient. Once the final adjustment is made, the fastener can be actuated to final position or tension that will then lock further adjustments of the positioning of the guide 101 relative to the probe 103.
It is noted that the guide's fastener as described above is one example embodiment among other possible example fasteners that are applicable to various embodiments of the guide 100. Accordingly, it is contemplated that various embodiments of the guide 100 may use any now known or later developed fastening system that can secure the guide 100 to the probe 103.
By way illustration and not limitation, examples of two fasteners are discussed with respect to
In another embodiment, as shown in
The urethra should be avoided in any part of the procedure, but it is mostly important when extracting cell or tissue specimens from the apical region of the prostate, when the chances of perforation is greater. After several extractions, the practitioner is able to see the blood streak from where the cell or tissue specimen was taken so as to avoid overlapping.
After this procedure, the patient may be put with restriction for no more than 1 day. If the patient is put on restriction for 1 day, after the one-day-restriction, no restriction is made.
In an embodiment, the biopsy system performs the processes 2400 of
At 2402, a target area or object, such as the prostate, is imaged. Imaging may be performed with a transducer, such as an ultrasound probe. Imaging of a target area may be in a sagittal and/or axial plane and may be performed in real-time with direct visualization. Utilizing the real-time image, a user can identify areas of interest, e.g. suspicious areas or the target area or object at 2403.
The user may determine an access site for positioning an access needle. At 2404, an access needle is positioned at an access site in subcutaneous tissue of the perineum. The access site may be at a midpoint between a lateral edge of the prostate and the urethra along an x axis, and a midpoint between an anterior capsule and a posterior capsule along a y axis. The access needle is guided and positioned at the access site by using the guide.
At 2405, a biopsy instrument is guided to the target or suspicious areas or object. The biopsy instrument may include a biopsy needle. The guiding of the biopsy instrument can be facilitated by using the real-time visualization provided by the transducer. Real-time visualization also facilitates obtaining tissue or cell specimens from an accurate point in the prostate, for example. The method allows for one or more tissue or cell specimens to be obtained from a bodily organ, such as the prostate at 2406, and permits access to the prostate from different angles through a single initial access needle.
At 2407, the biopsy instrument may be retrieved and removed from the patient. The method may include calculating the volume of the prostate by positioning the access needle at a mid-point in x axis from the lateral edge of the prostate to the urethra.
The guide 2600 includes a sliding platform 301. The guide is fitted to the probe 103 by a sleeve 2607. The sleeve 2607 is formed by the lower mount 104 and the upper mount 105. The sleeve 2607 may be configured to slide over an end of the probe 103 into an operable position as shown in
The sliding platform 301 of the guide 2600 may be pivotably mounted to enable movement in a direction perpendicular to a longitudinal axis of the probe 103, as shown in
For example,
In another embodiment, the method may be performed without the patient taking antibiotics or undergoing bowel preparation before having the procedure. During the procedure, the practitioner may administer an anesthetic to the patient, for example, lidocaine, or any type of local, anesthetic. The lidocaine may be included in a solution having 1% of lidocaine.
In an embodiment, the suspicious area is located by using a transducer. The transducer may be any type of transrectal robe for prostate cancer, such as an ultrasound probe, or any type of transducer capable of imaging the prostate and the extraction device. The biopsy may be performed using a biopsy gun, a suction-mechanism, or any type of instrument that is small enough to be introduced through the access needle and capable of extracting the tissue or cell specimen. The biopsy may be performed while the patient is in a lithotomy position, prone position, or any position that allows for access to the perineal area.
In another embodiment, methods may include applying an antiseptic solution to the perineal area such as betadine, or any other substance that reduces the possibility of infection, sepsis, or putrefaction.
In another embodiment, the ultrasound probe may be a B&K 8848 transrectal ultrasound probe, or any other ultrasound capable of causing visualization of the prostate and the extraction device. The frequency range may be 5-12 MHZ, and the focal range may be 3-60 mm. The ultrasound probe may be able to cause the visualization of the prostate and extraction devices at least in the axial plane, sagittal plane, or a combination thereof.
In another embodiment, methods may include attaching a needle to a luer lock syringe, which may contain an anesthetic, or any other type of device capable of retaining its contents and to dispense its contents through the needle. A biopsy gun or any other instrument may be attached to the needle for inserting or extracting any substance through the lumen of the access needle.
In another embodiment, the method includes releasing the syringe from the needle after the anesthetic is injected. The method may include dividing the prostate in three different regions and designating lateral, mid, apical prostate, and may include labeling the tissue or cell specimen containers, which will identify the tissue or cell specimens.
In another embodiment, a biopsy gun may be an 18 gauge biopsy gun, or any other size that is capable of being coaxially inserted thru the lumen of the access needle.
In another embodiment, methods may include securing the guide to the probe. This will permit the practitioner to take the biopsy gun as many times as necessary using his or her other hand, and, consequently, extract multiple tissue or cell specimens. It is contemplated that this can be done without assistance of any other person, and that the biopsy gun may also be attached to the guide in order to permit the surgeon to e.g. label the container with the tissue or cell specimen while performing the biopsy. The method may also include monitoring all the actions in the prostate thru a display device, which will transmit images captured by the probe.
In another embodiment, methods may include moving the needle in x, y, and z planes. By being able to move the need in x, y, and z planes, the surgeon is capable of extracting tissue or cell specimens from several different areas of the prostate without having to retrieve the needle and preventing other perforation of the patient's skin.
Methods may further include removing the access needle from the perennial area. Removal of the access needle may be performed while the biopsy gun is secured to the access needle or after the biopsy gun has been detached from the access needle.
Methods may include realigning the needle in the desired prostate region. If the surgeon wishes to start at the right lateral prostate region and notices that the needle tip is not directed at the lateral region, the surgeon rolls the ultrasound probe slightly and to note that the needle tip is directed to the desired region, then the surgeon may realign the needle to obtain tissue or cell specimen. The surgeon may realign the needle using one hand while having the needle attached to the biopsy gun, which may be attached to the probe through the guide.
Methods may include identifying the area in which a biopsy has already been performed. After each extraction of tissue or cell specimen during the biopsy, a hyperechoic streak remains visible on ultrasound display. This allows the surgeon to identify the area of the prostate and that an extraction has been made, as to allow the surgeon to prevent overlap of extractions.
In another embodiment, methods may include identifying the path of the urethra. This allows the surgeon from preventing passing the biopsy needle thru or into this path. In another embodiment, the method includes pressuring the perineum. In yet another embodiment, the method includes applying bacitracin to the skin at the puncture site or any other type of topical preparation for preventing the possibility of infection. In another embodiment, positioning the access needle is performed without the need of a biopsy grip, wherein the guide provides the precise point for the biopsy.
An apparatus and system in accordance with embodiments discussed above is used to carry out these methods. In an alternative embodiment of apparatus and systems, a guide may not include a lower mount, and may include an access needle. The guide includes a stabilization bar, sliding platform, a hole located in approximately the center of the platform, an upper mount, teeth, aperture, arms, and a connector. The access needle includes a hub and is secured to the guide. The teeth may be part of, or may be attached to, a lower mount. The teeth may be inserted into the aperture in order to secure the guide to a probe, for example. It is contemplated that the combination of the aperture and the teeth may form a fastener mechanism. In embodiments, connector is part of, or may be attached to, an access needle, and may be secured to the upper mount in order to provide stabilization of the access needle and to allow the practitioner to move the access needle by merely moving, for example, a probe that may be secured to the guide.
A connector and a hub permit the use of various other instruments such as, for example, a non-biopsy instrument, to be secured. A biopsy instrument may be inserted into the access needle in order to reach a targeted area. The upper mount may include arms. In embodiments, the arms may be shorter, longer, or may not exists, in which case the aperture is disposed directly in the upper mount. When the aperture is directly in the upper mount, upper mount may be longer, thicker, or a combination thereof.
In some embodiments, the guide may include lower mounts that have teeth. Arms may extend from the upper mount to allow the height of the guide to be adjusted and to be placed farther from or closer to the probe. The arms permit the access needle to be maintained at a certain distance from a probe. In embodiments, the material of the guide may be a plastic or any other material, including other plastic materials, or any other material that is cost effective. In embodiments, the guide may be reusable and may be formed with a stainless steel. The lower mount may be curvilinear and flexible to allow the lower mount to bend if necessary to secure the guide to the probe.
Reference is made to
To begin, reference is made to
The upper mount 2702 may couple with the lower mount 2704 and may include a guide member 2708 and a displacement member, translating member, or sliding platform 2710. The displacement member 2710 may couple with an access needle 2712 and be supported by the guide member 2708. More particularly, the displacement member 2710 may slidingly couple with the guide member 2708 such that the displacement member 2710 and the access needle 2712 are guided along a trajectory that is fixed relative to the guide member 2708 and the transrectal probe. The trajectory of the access needle 2712 may be generally parallel with a longitudinal axis of the transrectal probe when the biopsy guide 2700 is coupled with the probe.
Reference is made to
As seen in the figures, the guide member 2708 includes a distal end 2716, a proximal end 2718 opposite the distal end 2716, and a longitudinal axis 2720 extending through the distal and proximal ends 2716, 2718. As described herein locational orientations of distal and proximal are relative to the patient or, more particularly, the perineum of the patient. As such, distal generally refers to towards the patient and proximal refers to away from the patient.
Referring back to the figures, the guide member 2708 further includes a base platform 2722 extending substantially perpendicularly between a pair of vertical extension members 2724. Atop each of the vertical extension members 2724 is a guide rail or stabilization bar 2726 that is adapted to slidingly engage with and allow the displacement member 2710 to translate along a trajectory that is parallel with the longitudinal axis 2720 of the guide member 2708.
As best seen in
As seen in
As seen in
As seen in
As seen in
Reference is made to
As seen in the figures, the displacement member 2710 includes a central vertically extending member 2760 having five needle receiving ports 2768 formed therein. Each needle receiving port 2768 includes an opening 2770 extending from a distal end 2772 to a proximal end 2774 of the displacement member 2710. Each of the openings 2770 of the needle receiving ports 2768 are generally vertically aligned with each other and each includes a trajectory axis 2776 defining a trajectory of the access needle 2712 when positioned within the opening 2770. The trajectory axis 2776 is generally parallel to the longitudinal axis 2720 of the guide member 2708 when the displacement member 2710 is coupled with the guide member 2708. The trajectory axis is also generally parallel with a longitudinal axis of the probe when the biopsy guide 2700 is coupled with the probe. Thus, the trajectory axis 2776 of the access needle 2712 may be generally fixed or constant, in a generally parallel orientation to the previously described axes, as the displacement member 2710 displaces distal-proximal relative to the guide member 2708.
A particular needle receiving port 2768 may be chosen based on a desired distance from the probe. Thus, if a physician desires that the access needle 2712 should be positioned nearer the probe, a particular needle receiving port 2768 may be chosen that is at the bottom of the displacement member 2710. In certain embodiments, the openings 2770 of the needle receiving ports 2768 may be vertically spaced apart about 5 mm. In certain embodiments, the openings 2770 of the needle receiving ports 2768 may be vertically spaced apart about 3 mm. In certain embodiments, the openings 2770 of the needle receiving ports 2768 may be vertically spaced apart about 4 mm. In certain embodiments, the openings 2770 of the needle receiving ports 2768 may be vertically spaced apart at any interval between about 2 mm to about 6 mm, among other distances.
While the vertically extending member 2760 includes five needle receiving ports 2768, it is foreseen that more or less ports may be included in the displacement member 2710 without limitation.
The displacement member 2710 further includes a coupling mechanism 2778 to displaceably couple the displacement member 2710 and the guide rails 2726. The coupling mechanism 2778 includes a pair of lower tab members 2780 extending laterally out and away from the vertically extending member 2760. When coupled with the guide rails 2726, the lower tab members 2780 may abut or be positioned adjacent the bottom surface 2730 of the rectangular member 2728. The tab members 2780 include a planar top surface 2782 that may provide sliding contact with the bottom surface 2730 of the rectangular member 2728. The planar contact between the surfaces may contribute to stability of the displacement member 2710 relative to the guide rails 2726 by reducing vertical tilt of the displacement member 2710.
The coupling mechanism 2778 further include an upper member 2784 positioned above the lower tab members 2780. A bottom surface 2786 of the upper members 2784 may abut or be positioned adjacent the top surface 2744 of the rectangular member 2728 when the displacement member 2710 is coupled with the guide rails 2726. The bottom surface 2786 of the upper members 2784 is planar and, thus, the planar contact between the surfaces may contribute to stability of the displacement member 2710 relative to the guide rails 2726 by reducing vertical tilt of the displacement member 2710. The upper members 2784 and the lower tab members 2780 operate to sandwich the rectangular members 2728 of the guide rails 2726 when the displacement member 2710 is coupled with the guide member 2708.
The coupling mechanism 2778 further includes a lateral brace mechanism 2788 at lateral ends of the upper members 2784. The lateral brace mechanism 2788 includes an upside-down U-shaped member 2790 having three inner surfaces 2792 that define a longitudinal extending channel 2794 therein. The channel 2794 may receive the side members 2732 therein when the displacement member 2710 couples with the guide rails 2726. In this way, the lateral brace mechanism 2788 may contribute to stability of the displacement member 2710 relative to the guide rails 2726 by reducing lateral tilt of the displacement member 2710. It is foreseen that the displacement member 2710 may not include the lateral brace mechanism 2792 and may instead only include the upper member 2784 and the lower tab members 2780. Alternatively, it is foreseen that the displacement member 2710 may not include the upper member 2784 and the lower tab members 2780, but may only include the lateral brace mechanism 2792. Additionally and alternatively, other mechanisms are possible to facilitate the displacement member 2710 displacing between the proximal and distal ends 2718, 2716 of the guide member 2708. For example, the guide member 2708 could include longitudinally extending rods (not shown) and the displacement member 2710 may include a sleeve that engages and is guided by the rods. In such an embodiment, the rods may be adapted to slide within the openings 2770 of the needle receiving ports 2768 with or without modification to the displacement member 2708.
Still referring to
Reference is made to
In operation, a transrectal probe is positioned within the opening between the first and second clamping structures 2810, 2816. The physician may determine a desired position on the probe based on the patient's anatomy, the particular transrectal probe, or the particular procedure to be performed, among other possible criteria. Once a position for the lower mount 2704 is chosen, the physician may cause the first and second arm members 2804, 2806 to be contracted relative to each other by pushing on the outer ends 2822 of the clamping structures 2810, 2816, respectively. As the clamping structures 2810, 2816 converge relative to each other, the lower row of teeth 2820 on the second clamping structure 2806 is received within an opening 2824 formed between the upper row of teeth 2812 and the lower smooth surface 2814. The upper row of teeth 2812 are caused to engage with the lower row of teeth 2820. Additionally, the upper smooth surface 2818 is caused to slide on an inner smooth surface 2826 of the first arm member. And, the lower smooth sliding surface 2814 is caused to slide on a lowest smooth surface 2828 on the second clamping structure 2816. The teeth of the upper and lower row 2812, 2820 are arranged in a saw tooth like manner such that when they are increasingly engaged with each other the teeth grip each other and resist moving in the opposite direction. Once engaged, the teeth may be disengaged by pulling on a tab 2830 on a bottom portion of the first clamping structure 2810. Pulling on the tab 2830 allows the teeth 2812, 2820 to disengage with each other and the flexible nature of the first and second arms 2804, 2806 are caused to spring back into the shape shown in
Reference is made to
The following discussion will focus on use of the biopsy guide 2700 and will refer to
As seen in
As seen in
As seen in
As seen in
In the orientation shown in
In certain embodiments where the bevel 2840 of the access needle 2712 does not extend past the distal face 2740 of the distal member 2734, the physician may use the distal member 2734 to manipulate the perineal skin and subcutaneous tissue of the patient while having the displacement member 2710 coupled to the guide member 2708, but while not having the bevel 2840 of the access needle 2712 contact the patient's skin.
While
As further seen in
Once the access needle 2712 is in position in the patient's skin and subcutaneous tissue, the biopsy procedure may continue, as described previously, with the physician extending a biopsy needle through the lumen 2844 of the access needle 2712 and into the patient's prostate. Once procedure is complete, the physician may remove the access needle 2712 from the patient's body by proximally displacing the displacement member 2710 and the access needle 2712 by pulling or pushing on the displacement member 2710 or access needle. Alternatively, the access needle 2712 may be disengaged with the displacement member 2710 while the displacement member 2710 is in the distal-most position.
The discussion will now focus on additional and alternative embodiments of the biopsy guide. As seen in
The lower mount 2704, as described herein, may take many forms without departing from the scope of the present disclosure. Other mechanisms to couple the upper mount 2702 to the probe are possible and contemplated herein. For example, the upper mount 2702 may couple with or be integrally formed with a thin sheath or sleeve of latex, polyurethane, or other materials, such as a male condom. The sheath may be fitted over the probe in a tight fitting manner such that the upper mount 2702 is secured in position relative to the probe.
Additional or alternative embodiments of the lower mount 2704 may include rubber or rubber-type cinch straps that are coupled with or integral with the upper mount 2702.
The upper mount 2702, as described herein, may take many forms without departing from the scope of the present disclosure. Other mechanisms to guide the access needle 2712 are possible and contemplated herein. For example, the displacement member 2710 supporting the access needle 2712 may be coupled to a platform on a coupler side of a four-bar linkage (e.g., parallelogram linkage) where the fixed portion of the linkage may be coupled with the base platform 2722 of the guide member 2710. The platform may be displaceable distal-proximal by urging the platform distally or proximally, while displacing in an arcuate path. In the case of a parallelogram linkage, the trajectory of the access needle 2712 may remain parallel to the longitudinal axes of the probe and guide member 2710 while vertically displacing. In this way, such a linkage may be used for distal-proximal displacement as well as vertical displacement or adjustment, as needed for a particular biopsy procedure. This type of displacement member 2710 may be used with the guide member 2708 as described herein with or without modification.
As another example, the displacement member 2710 supporting the access needle 2712 may be coupled to a carriage or lead screw nut that is displaced relative to the guide member 2708 (and probe) via rotation of a lead screw. The lead screw may be positioned parallel to the longitudinal axis of the guide member 2708 and the probe such that displacement of the lead screw nut and, thus, the displacement member 2710 and access needle 2712 displace or translate distal-proximal while maintaining a trajectory of the access needle 2712 that may be fixed. A bottom side of the lead screw nut may include a feature or protrusion that extends into a channel formed in the base platform 2722 of the guide member 2708 such that the lead screw nut does not rotate, but, rather, displaces or translates linearly distal-proximal in response to rotation of the lead screw. The lead screw may be rotatable by hand via, for example, a handle at the proximal end of the lead screw.
Reference is now made to
As seen in
As seen in the figures, a bottom end 3716 of the vertically extending member 3712 is coupled to a distal end 3718 of a rail member 3720 that may slidingly engage with the guide member 3710. The rail member 3720 includes a flange member 3722 and a web member 3724 arranged in a T-beam shape. That is, the flange member 3722 is wider than the web member 3724, which projects upward and substantially perpendicularly from a central portion of the flange member 3722. From the distal end 3718, the rail member 3720 extends proximally to a proximal end 3726. At the proximal end 3726 is an end plate member 3728, which prevents distal displacement of the displacement member 3706 past a certain point.
As seen in
As seen in
It is noted that the guide rail members 3746 and, more particularly, the distal members 3744 may be used by the physician to manipulate the perineal skin and subcutaneous tissue of the patient, as described previously. And while the embodiment of the biopsy guide 3700 in
As seen in
As seen in
As seen in
Reference is now made to
That is, the needle receiving ports 4006 may align a trajectory of an access needle in any of the ports 4006 such that a trajectory of the access needle may be generally parallel to a longitudinal axis of the probe. The needle receiving ports 4006 may be integrally formed with the guide member 4002. Or, the vertical member 4008 including the needle receiving ports 4006 may be releasably coupled to the guide member. In a releasable arrangement, the vertical member 4008 may be coupled with the guide member via any coupling mechanism described herein or known in the art. As seen in the figure, the needle receiving ports 4006 are cylindrical and extend generally from a proximal end 4010 to a distal end 4012 of the guide member 4002. The distal tip 4014 of the needle receiving ports 4006 may be about coplanar with a distal face 4016 of the distal members 4018 of the guide rails 4004.
Reference is made to
The inner surface 4116 may include roller bearings or similar structures to permit the collar 4112 to roll, translate, or displace relative to the probe 4118. While the channel 4120 is described as being formed in the probe 4118, the channel 4120 may be formed in a separate member that is coupled to the probe 4118. In this case, a specialized probe having a channel may not be needed; rather, any off-the-shelf ultrasound probe may be used with the separate member having the channel 4120 to utilize the biopsy guide 4100 of the present embodiment.
Reference is made to
As seen in
As seen in
Reference is made to
Reference is made to
Reference is made to
As with many of the embodiments of the biopsy guide described herein, there may be a particular type of mechanical arrangement between the guide member and the displacement member that at least facilitates the displacement of the access needle along at least a portion of the length of the guide member. As discussed in relation to each of the embodiments, the mechanical arrangement may include at least one of a sliding arrangement, a lead screw, or a parallel bar linkage. And, as described with reference to the various embodiments of the biopsy guide, the guide member may operably couple with the transrectal probe via at least one of a sheath arrangement, a ratchet arrangement, a biased collar arrangement, a flexible strap arrangement, a clamping arrangement, or a clamshell collar arrangement.
Reference is now made to
As described previously, the probe or transducer provides imaging in axial and sagittal planes so as to provide real-time images of the prostate. As seen in
When the prostate is viewed, as seen in
Identifying the urethra may be accomplished via a number of methods. First, as seen in
Additionally or alternatively, the marking device 3824 may include markers 3830 such as physical or chemical markers that are visible in an ultrasound environment (e.g., pellets of polylactic and polyglycolic acids containing carbon dioxide, polyglycolic acid pads) along the length of the catheter 3826 so that the physician can view the path of the urethra 3804 as viewed in transverse or sagittal planes. Thus, the physician may be able to position a trajectory of the access needle 2712 to be adjacent and not intersecting with the path of the urethra as indicated by the markers 3830 on the catheter 3826. The markers 3830 may be positioned on the catheter at certain intervals so as to provide a way to estimate the size or volume of the prostate 3800. Additionally or alternatively, the catheter 3826 may include a contrast medium (e.g., dye) for visualization purposes and may otherwise function similarly to markers 3830 positioned on the catheter 3826.
The biopsy guides and devices described herein may additionally include markers or sensors positioned on the biopsy guide or access needle such that movement of the guide or needle, or any device/material placed through the access needle, may be visualized via the markers/sensors by ultrasound equipment (e.g., probe) or other equipment using different imaging modalities (e.g., MRI, CT). In this way, for example, a marker positioned at a distal end of the access needle may provide visual guidance as to the location of the tip of the access needle relative to the boundaries of the prostate.
Although various representative implementations have been described above with a certain degree of particularity, those skilled in the art could make numerous alterations to the disclosed embodiments without departing from the spirit or scope of the inventive subject matter set forth in the specification. All directional references (e.g., distal, proximal, front, back, side, top, bottom, fore, aft, right, left, etc.) are only used for identification purposes to aid the reader's understanding of the implementations, and do not create limitations, particularly as to the position, orientation, or use of the embodiments described herein unless specifically set forth in the claims. Joinder references (e.g., attached, coupled, connected, and the like) are to be construed broadly and may include intermediate members between a connection of elements and relative movement between elements. As such, joinder references do not necessarily infer that two elements are directly connected and in fixed relation to each other.
It is believed that the present disclosure and many of its attendant advantages will be understood by the foregoing description, and it will be apparent that various changes may be made in the form, construction and arrangement of the components without departing from the disclosed subject matter or without sacrificing all of its material advantages. The form described is merely explanatory, and it is the intention of the following claims to encompass and include such changes.
While the present disclosure has been described with reference to various embodiments, it will be understood that these embodiments are illustrative and that the scope of the disclosure is not limited to them. Many variations, modifications, additions, and improvements are possible. More generally, embodiments in accordance with the present disclosure have been described in the context of particular implementations. Functionality may be separated or combined in blocks differently in various embodiments of the disclosure or described with different terminology. These and other variations, modifications, additions, and improvements may fall within the scope of the disclosure as defined in the claims that follow.
The present application is a continuation-in-part of U.S. application Ser. No. 17/314,845 filed May 7, 2021, which application is a continuation of U.S. application Ser. No. 16/115,180 filed Aug. 28, 2018, now U.S. Pat. No. 11,096,762, which application is a continuation of U.S. application Ser. No. 14/677,286 filed Apr. 2, 2015, now U.S. Pat. No. 10,064,681, which claims priority under 35 U.S.C. § 119 to U.S. Provisional Patent Application No. 61/974,826 filed Apr. 3, 2014. The present application is also a continuation-in-part of U.S. application Ser. No. 16/991,150 filed Aug. 12, 2020, which application is a continuation of U.S. application Ser. No. 14/874,104 filed Oct. 2, 2015, now U.S. Pat. No. 10,743,909, which application is a continuation-in-part of U.S. patent application Ser. No. 14/677,286 filed Apr. 2, 2015, now U.S. Pat. No. 10,064,681, which claims priority under 35 U.S.C. § 119 to U.S. Provisional Patent Application No. 61/974,826 filed Apr. 3, 2014. All the above-referenced applications are hereby incorporated by reference in their entireties.
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20220022996 A1 | Jan 2022 | US |
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61974826 | Apr 2014 | US |
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Child | 17314845 | US | |
Parent | 14874104 | Oct 2015 | US |
Child | 16991150 | US | |
Parent | 14677286 | Apr 2015 | US |
Child | 16115180 | US |
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Parent | 17314845 | May 2021 | US |
Child | 17494962 | US | |
Parent | 16991150 | Aug 2020 | US |
Child | 17314845 | US | |
Parent | 14677286 | Apr 2015 | US |
Child | 14874104 | US |