The present disclosure relates to devices, systems, and methods for patient support. More specifically, the present disclosure relates to devices, systems, and methods for surgical patient supports.
Patient supports, such as surgical support tables, provide support to various portions of a patient's body. Versatile positioning of table tops of the patient supports provides access to various parts of a patient's body. Positioning patient supports should be performed with consideration for the safety and security of the patient.
The present application discloses one or more of the features recited in the appended claims and/or the following features which, alone or in any combination, may comprise patentable subject matter:
According to an aspect of the present disclosure, a patient support device may comprise a patient support top for providing support to a patient's body, an end support configured to support the patient support top for selective rotation about a rotation axis, and a rotation lockout assembly operable between a locked state to block against free rotation of the patient support top about the rotation axis and unlocked state to permit free rotation of the patient support top about the rotation axis. The rotation lockout assembly may include a rotation disk rotatable between locked and unlocked positions corresponding respectively with the locked and unlocked states of the rotation lockout assembly, and a lever arm pinned at one end to the rotation disk for traversing an arced path upon rotation of the rotation disk between locked and unlocked positions.
In some embodiments, the rotation lockout assembly may include a safety latch assembly for blocking against inadvertent rotation of the rotation disk. The safety latch assembly may include a trigger for deactivation to permit rotation of the rotation disk. In some embodiments, the safety latch assembly may include a key operable between a latched position engaged with the rotation disk to block rotation and an unlatched position disengaged from the rotation disk to allow rotation. In some embodiments, the trigger may include an arm having a contact end for operation by a user's hand and an indicator end for communicating with an actuator to operate the lock arm between the latched and unlatched positions.
In some embodiments, the rotation lockout assembly may include a crank handle configured for operation by a user's hand. The crank handle may extend from the rotation disk to provide leverage in rotating the rotation disk between the locked and unlocked positions. In some embodiments, the rotation disk may include a light indicator arranged proximate to the crank handle adapted to indicate whether the rotation disk is in the locked position by at least one of presence, absence, and color of light emitted and to indicate a position other than the locked position of the rotation disk by another one of presence, absence, and color of light emitted.
In some embodiments, the end support may include a primary shaft for supporting rotation of the patient support top and a rotation control assembly for controlled rotation of the primary shaft. The rotation control assembly may include a rotation plate selectively fixed against rotation relative to the primary shaft by arrangement of the rotation disk in the locked position. In some embodiments, the rotation plate may be selectively fixed for rotation with the primary shaft by operation of a locking collar between locked and unlocked positions corresponding respectively with the locked and unlocked positions of the rotation disk.
In some embodiments, the locking collar may be attached with the lever arm and may include a collar body and a number of locking pins extending from the collar body. The locking collar may be movable according to the position of the lever arm between an engaged position in which the number of locking pins engage with each of the rotation plate and a flange of the primary shaft to rotationally fix the rotation plate and the flange together, and a disengaged position in which the number of locking pins are disengaged from the flange of the primary shaft to release the rotation plate and the flange for relative rotation. In some embodiments, the rotation control assembly may include an actuator configured to provide controlled rotation to the rotation plate for transmission to the primary shaft when selectively fixed for rotation with the rotation plate. In some embodiments, the system may include a lockout control system for controlling the operation of the rotation lockout assembly between the locked and unlocked states, the lockout control system including at least one sensor arranged to detect connection of the patient support top with the end support.
According to another aspect of the present disclosure, an end support of a patient support device for supporting a patient support top for selective rotation about a rotation axis may comprise a primary shaft extending along the rotation axis, a rotation control assembly including a rotation plate and an actuator adapted to provide controlled rotation to the rotation plate, and a rotation lockout assembly operable between a locked state to block against free rotation of the primary shaft about the rotation axis and unlocked state to permit free rotation of the primary shaft about the rotation axis. The rotation lockout assembly may include a rotation disk rotatable between locked and unlocked positions corresponding respectively to the locked and unlocked states of the rotation lockout assembly, and a lever arm pinned at one end to the rotation disk and at another end to the end support for traversing an arced path upon rotation of the rotation disk between locked and unlocked positions.
In some embodiments, the rotation lockout assembly may include a safety latch assembly for blocking against inadvertent rotation of the rotation disk. The safety latch assembly may include a trigger for deactivation to permit rotation of the rotation disk. In some embodiments, the safety latch assembly may include a lock arm operable between a latched position engaged with the rotation disk to block rotation and an unlatched position disengaged from the rotation disk to allow rotation. In some embodiments, the trigger may include an arm having a contact end for operation by a user's hand and an indicator end for communicating with an actuator to operate the lock arm between the latched and unlatched positions.
In some embodiments, the rotation lockout assembly may include a crank handle configured for operation by a user's hand. The crank handle may extend from the rotation disk to provide leverage in rotating the rotation disk between the locked and unlocked positions. In some embodiments, the rotation lockout assembly may include a light indicator arranged proximate to the crank handle adapted to indicate whether the rotation disk is in the locked position by at least one of presence, absence, and color of light emitted and to indicate a position other than the locked position of the rotation disk by another one of presence, absence, and color of light emitted.
In some embodiments, the rotation plate may be selectively fixed for rotation with the primary shaft by operation of a locking collar between locked and unlocked positions corresponding respectively with the locked and unlocked positions of the rotation disk. The locking collar may be attached with the lever arm and includes a collar body and a number of locking pins extending from the collar body.
In some embodiments, the locking collar may be movable according to the position of the lever arm between an engaged position in which the number of locking pins engage with each of the rotation plate and a flange of the primary shaft to rotationally fix the rotation plate and the flange together, and a disengaged position in which the number of locking pins are disengaged from the flange of the primary shaft to release the rotation plate and the flange for relative rotation. In some embodiments, the actuator of the rotation control assembly may be configured to provide controlled rotation to the rotation plate for transmission of controlled rotation to the primary shaft when selectively fixed for rotation with the rotation plate. In some embodiments the end support may include a lockout control system for controlling the operation of the rotation lockout assembly between the locked and unlocked states, the lockout control system including at least one sensor arranged to detect connection of the patient support top with the end support.
According to another aspect of the present disclosure a patient support system may include at least one patient support top connected with at least one end support to support the at least patient support top above the floor for selective rotation about a rotation axis, a rotation lockout assembly operable between a locked state to block against free rotation of the at least one patient support top about the rotation axis and unlocked state to permit free rotation of the at least one patient support top about the rotation axis, and a lockout control system for controlling the operation of the rotation lockout assembly between the locked and unlocked states. The lockout control system may include at least one sensor arranged to detect connection of the at least one patient support top with the end support.
In some embodiments, the rotation lockout assembly may be adapted to block against free rotation of the patient support top unless the lockout control system indicates that least one patent support top is connected with the end support. In some embodiments, the at least one sensor may be arranged to communicate with the rotation lock assembly to indicate that the at least one patent support top is connected with the end support. In some embodiments, at least one patient support top may include two patient support tops. The at least one sensor may be arranged to communicate with the rotation lock assembly to indicate that the two patent support tops are connected with the end support.
In some embodiments, the rotation lockout assembly may be arranged blocked against operation out of the locked state unless the lockout control assembly indicates that the two patient support tops are connected with the end support and may permit operation into the unlocked state in response to communication from the lockout control assembly that the two patent support tops are connected with the end support.
In some embodiments, the rotation lockout assembly may include a rotation disk rotatable between locked and unlocked positions corresponding respectively to the locked and unlocked states of the rotation lockout assembly. In some embodiments, the rotation lockout assembly may include a lever arm pinned at one end to the rotation disk and at another end to the end support for traversing an arced path upon rotation of the rotation disk between locked and unlocked positions.
In some embodiments, the end support may include a primary shaft extending along the rotation axis to receive connection with the at least one support top. The end support may include a rotation control assembly having a rotation plate and an actuator adapted to provide controlled rotation to the rotation plate. The rotation plate may be selectively fixed for rotation with the primary shaft by operation of a locking collar between locked and unlocked positions corresponding respectively with the locked and unlocked positions of the rotation disk.
In some embodiments, the locking collar may be attached with the lever arm and may include a collar body and a number of locking pins extending from the collar body. The locking collar may be movable according to the position of the lever arm between an engaged position in which the number of locking pins engage with each of the rotation plate and a flange of the primary shaft to rotationally fix the rotation plate and the flange together, and a disengaged position in which the number of locking pins are disengaged from the flange of the primary shaft to release the rotation plate and the flange for relative rotation.
In some embodiments, the actuator of the rotation control assembly may be configured to provide controlled rotation to the rotation plate for transmission of controlled rotation to the primary shaft when selectively fixed for rotation with the rotation plate. In some embodiments, the lockout control system may include a display for indicating at least one of whether the two patient support top are connected with the end support and whether the rotation lockout assembly is in the unlocked state. In some embodiments, the display may include a user input for receiving a selection from a user to provide controlled rotation to the primary shaft.
In some embodiments, the rotation lockout assembly may include a safety latch assembly for blocking against inadvertent rotation of the rotation disk. The safety latch assembly may include a lock arm operable by an actuator between a latched position engaged with the rotation disk to block rotation and an unlatched position disengaged from the rotation disk to allow rotation of the rotation disk out of the locked position. In some embodiments, the safety latch assembly may include a trigger for deactivation to unlatch the lock arm to permit rotation of the rotation disk. In some embodiments, the trigger may include an arm having a contact end for operation by a user's hand and an indicator end for communicating with the actuator to operate the lock arm between the latched and unlatched positions.
In some embodiments, the lockout control system may be adapted to communicate with the rotation lock assembly to indicate whether the two patient support tops are connected with the end support. The actuator may arranged to maintain the lock arm in the latched position unless the lockout control system indicates that the two patient support tops are connected with the end support.
In some embodiments, the rotation lockout assembly may include a crank handle configured for operation by a user's hand. The crank handle may extend from the rotation disk to provide leverage in rotating the rotation disk between the locked and unlocked positions.
In some embodiments, the rotation lockout assembly may include a light indicator arranged proximate to the crank handle. The light indicator may be adapted to indicate whether the rotation disk is in the locked position by at least one of presence, absence, and color of light emitted and to indicate a position other than the locked position of the rotation disk by another one of presence, absence, and color of light emitted.
In some embodiments, the lockout control system may include a display for indicating at least one of whether the at least one patient support top is connected with the end support and whether the rotation lockout assembly is in the unlocked state. The display may include a user input for receiving a selection from a user to permit rotation of a rotation disk out of a locked position to permit free rotation of the at least one patient support top. In some embodiments, the user input may be a touch screen of the display and the user selection may operate an actuator to disengage a lock arm from the rotation disk to permit the rotation disk to move out of the locked position.
Additional features, which alone or in combination with any other feature(s), including those listed above and those listed in the claims, may comprise patentable subject matter and will become apparent to those skilled in the art upon consideration of the following detailed description of illustrative embodiments exemplifying the best mode of carrying out the invention as presently perceived.
The detailed description particularly refers to the accompanying figures in which:
For the purposes of promoting an understanding of the principles of the disclosure, reference will now be made to a number of illustrative embodiments illustrated in the drawings and specific language will be used to describe the same.
In performance of various surgical procedures, providing surgical access to surgery sites on a patient's body can promote favorable surgical conditions and can increase the opportunity for successful results. Patient support devices can assist in positioning the patient's body to provide a surgical team preferred and/or appropriate access to particular surgical sites. Patient supports devices can include patient support tops which are supported above the floor by support structures. Such support structures can provide enhanced maneuverability to assist in positioning the patient's body by permitting selective movement of the patient support top.
In the illustrative embodiment as shown in
As shown in
As shown in
Referring to
Referring now to
As shown in
As best shown in
As shown in
The disk 132 is illustratively secured with and receives rotational force from a manual interface 124. The manual interface 124 is illustratively embodied to include a base 134 formed as a disk connected concentrically with the rotation disk 132 and a grip 136 illustratively extending from the base 134 for engagement with a user's hand to apply rotational force to the base 134. The base 134 is selectively rotatable under the force from the grip 136 to rotate the disk 132 about an axis 135.
The grip 136 is illustratively formed ergonomically for grasping, embodied as a generally cylindrical extension having a tapered portion 136a proximate to the connection with the base 134. The grip 136 is illustratively arranged as a foldable grip having a hinged connection with the base 134 to fold from a perpendicular position relative to the base 134 (as shown in
Referring to
Referring to the illustrative embodiment as shown in
The offset connection of the end 144 of the lever arm 142 with the disk 132 traverses the lever arm 142 along an arced path 137 as the disk 132 rotates about the axis 135 as suggested in
As shown in
In the illustrative embodiment, the collar 150 is slidingly and rotatably mounted on the shaft 30 for selective engagement with the flange 148 according to the position of the lever arm 142. As the lever arm 142 traverses its arced path by rotation of the disk 132, the lever arm 142 drives the collar 150 to slide along the shaft 30 for selective engagement with the flange 148. As shown in
Referring to
Referring to
Referring now to
Turning to
As shown in
In the illustrative embodiment, the flange 148 can selectively engage with the collar 150 in four angular positions to fix the rotational position of the shaft 30 about the axis 15. As mentioned above, the position of the shaft 30 (and thus the flange 148) under free rotation is illustratively directed by the position of any attached patient support tops 14, 20 according to the desired position of the patient's body. The flange 148 illustratively includes four holes 151 arranged corresponding to the positions the holes 151 of the plate 149 (and thus the pins 154) such that coincident positioning of any hole 151 of the flange 148 with any hole 151 of the plate 149 provides coincident positions of the remaining holes 151 of the flange 148 and plate 149 to receive the pins 154. The four angular positions of the flange 148 are defined by the coincident positioning of one hole 151 of the flange 148 with each hole 151 of the plate 149 to receive a corresponding pin 154 through the plate 149 to block relative rotation between the flange 148 and plate 149 in any of four locked angular arrangements.
In the illustrative embodiment, the four locked angular arrangements of the patient support tops 14, 20 about the axis 15, are defined at 90 degree intervals including those arrangements shown in
As indicated in
In the illustrative embodiment as shown in
The controlled rotation provided by the rotation control assembly provides fine rotation control for positioning the patient support tops and the patient's body. In the illustrative embodiment, the controlled rotation of the shaft 30 provided by the actuator 160 can be selected by the user within a range of about −30 degrees to about +30 degrees, but in some embodiments, may include a range of about −180 degrees to about +180 degrees.
As shown in the illustrative embodiment of
As shown in
In the illustrative embodiment, the indicator 168 is a magnet and the sensor 170 is a reed switch in communication with an actuator 172 for selectively blocking rotation of the disk 132. In some embodiments, the indicator 168 and sensor 170 may be any suitable combination of communicating features having any suitable arrangement to indicate the position of the trigger 140. As shown in
As shown in
In the illustrative embodiment as shown in
As shown in
Returning to
With reference to
The traction assembly 188 illustratively includes a traction arm 196 that extends laterally from the tower base 12 (radially relative to axis 15 and illustratively parallel to axis 135). In the illustrative embodiment, the traction arm 196 extends from the tower base 12 on an opposite side from the grip 136. The traction arm 196 is illustratively connected with the tower base 12 by a hinged connection 198 allowing a user to collapse the traction arm 196 by folding the traction arm up for storage. The tension line 190 extends from the pulley 192 along the traction arm 196 to the pulley 194 to turn from the lateral direction towards the floor.
In the illustrative embodiment as shown in
Referring now to
As suggested in
As shown in
Referring briefly to
In the illustrative embodiment, only one of the tower bases 12, 1012 includes the rotation lockout assembly 22, 122, but in some embodiments, the other tower base 12, 1012 may include another rotation lockout assembly and/or a rotation lockout assembly in communication with the rotation lockout assembly 22, 122 for operation.
Current operating room tables, for example, the Allen Advance Table (AAT) available from Allen Medical Systems, Inc. of Batesville, Indiana—and many other 2-column operating room tables indicated for complex spinal procedures—can allow the user to perform a 180 degree flip of the patient for procedures that require anterior and posterior incisions. The present disclosure includes devices, systems, and methods for performing a flip of a patient's body, including with the patient supported by a supine top (with the patient in the supine position) a secondary prone top is positioned above the patient, this prone top is then attached to the table and subsequently adjusted to secure or sandwich the patient in preparation for a flip; a member of the clinical staff can release a Flip Rotation Axis (FRA) of the table by activing a lever. Activating the lever can be achieved by a two-step process including depressing a safety button and pulling a trigger. In some embodiments, the safety button must first be depressed before pulling the trigger. Upon release of the FRA, the clinical staff can manually rolls the sandwiched patient 180 degrees, thereby flipping the patient. A member of the clinical staff can locks the FRA by re-engaging the lever. With the patient fully supported by the prone top, the supine top can be detached from the table.
As described above, releasing the FRA is necessary in order to flip the patient. Unintentional or unknowing release the FRA, the patient could be subjected to a hazardous situation, potentially resulting in patient harm. For example, if a patient is on the table and supported only by a single top (i.e. they are not sandwiched between two tops) and the FRA is released, the patient could be dropped. Additionally, if the patient is transferred from a gurney or stretcher to the table and the FRA is released, the patient could also be dropped. Although certain risks can be reduced by providing notification to the user that the FRA is released, without active lockout of the FRA from being released absent confirmation criteria, fall risks persist. Affirmative safety lockout can avoid releasing the FRA when there is only one top secure with the table.
The present disclosure can include a functional behavior of the table. If a user attempts to activate the lever to release the FRA without confirming the desire for release by at least one of additional input and confirmation signal, the FRA will not be permitted to release. For example, in some embodiments, release of the FRA requires depressing a safety trigger together with manual rotation of the rotation disk. In some embodiments, when a presence sensing system determines that there is only one patient support top connected with the connection bar of the table, the table will prevent the FRA from being released. The user will be notified that this release action is not allowed upon pressing the safety button (the first step in the process of activating the lever).
The present disclosure includes devices, systems, and methods for top presence sensing wherein the table can include one or more sensors to detect the number of support tops attached with the connection bars, for example, whether one or two tops are attached to the table. The present disclosure includes devices, systems, and methods for Flip Rotation Axis (FRA) lockout wherein the table can include an actuator and lockout assembly that can selectively allow or prevent the activation of the lever that releases the FRA. The present disclosure includes devices, systems, and methods for Graphical User Interface (GUI) wherein the table can include display means for displaying an indication that the FRA cannot be released in the event that there is one top on the table and the user presses the safety button (the first step in activating the lever). The present disclosure includes devices, systems, and methods for system on a module (SoM) and device communication to control and direct the system behavior.
Although certain illustrative embodiments have been described in detail above, variations and modifications exist within the scope and spirit of this disclosure as described and as defined in the following claims.
The present application is a continuation of U.S. application Ser. No. 16/038,519, filed Jul. 18, 2018, now U.S. Pat. No. 11,213,448, which claims the benefit, under 35 U.S.C. § 119(e), of U.S. Provisional Application No. 62/539,484, filed Jul. 31, 2017, and each of which is hereby incorporated by reference herein.
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20220079826 A1 | Mar 2022 | US |
Number | Date | Country | |
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62539484 | Jul 2017 | US |
Number | Date | Country | |
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Parent | 16038519 | Jul 2018 | US |
Child | 17537703 | US |