Arthroscopic surgical procedures are procedures performed on a joint, such as a knee or shoulder, of a patient. In order to provide space within the joint to perform the procedure, the joint may be distended using a surgical fluid (e.g., saline solution). However, surgical procedures within a joint sometimes result in minor bleeding and create tissue fragments, which can cloud visibility within the joint. To maintain visibility, both inflow and outflow pumps may be employed to provide a continuous fluid flow through the joint. Outflow can occur from multiple sources including various surgical devices; however, depending on the device in use, it may be desired to control the outflow from a particular one of the surgical devices at any given time.
There is provided a pump system including an outflow pump. The pump system includes a stationary housing that defines an internal volume and a front face outside the internal volume extending in a first direction and a second direction transverse to the first direction. The stationary housing includes at least one tube support outside the internal volume extending outwardly from the front face for aligning and supporting a first tube and a second tube. At least one pinch member is movable relative to the at least one tube support. A power actuator is disposed in the internal volume and is operably coupled to the at least one pinch member. The power actuator is configured to have three orientations that define: a first arrangement of the at least one pinch member relative to the at least one tube support configured to pinch closed the first tube, a second arrangement of the at least one pinch member relative to the at least one tube support configured to pinch closed the second tube, and a third arrangement of the at least one pinch member relative to the at least one tube support configured to pinch closed neither the first tube nor the second tube.
In some embodiments, the at least one tube support includes a t-shaped bracket having a central post that extends outwardly from the front face along a longitudinal central axis. The t-shaped bracket also includes a support beam that is attached to and extends across the central post and is spaced from and extends along the front face in the second direction. The t-shaped bracket defines a bracket cavity leading to the internal volume and extending through the central post and into the support beam. The t-shaped bracket defines a first tube notch that is configured to accept the first tube and a second tube notch that is configured to accept the second tube.
In some embodiments, the power actuator includes a sliding shaft that extends along the longitudinal central axis through the front face and out of the internal volume into the bracket cavity. The power actuator also includes a solenoid assembly coupled to the sliding shaft. The sliding shaft is movable by the solenoid assembly along the longitudinal central axis to: a first translational position to move the at least one pinch member to the first arrangement, a second translational position to move the at least one pinch member to the second arrangement, and a third translational position to move the at least one pinch member to the third arrangement.
In some embodiments, the at least one pinch member includes a first pinch bar that extends radially from the longitudinal central axis at a distal end of the sliding shaft in a first lateral direction. The first pinch bar extends along the support beam into the bracket cavity adjacent the first tube notch. The first pinch bar is configured to move toward the front face when the sliding shaft is moved to the first translational position. The first pinch bar is also configured to maintain spacing of a first notch width with the front face when the sliding shaft moves to the third translational position. The at least one pinch member also includes a second pinch bar that extends radially from the longitudinal central axis in a second lateral direction opposite the first lateral direction. The second pinch bar extends into the bracket cavity and is offset from the first pinch bar along the longitudinal central axis by a second notch width. The second pinch bar extends along and is spaced from the support beam. The second pinch bar is configured to move away the front face when the sliding shaft is moved to the second translational position. The second pinch bar is also configured to maintain spacing of the second notch width with the front face when the sliding shaft moves to the third translational position.
In some embodiments, the solenoid assembly includes a first solenoid that has a first coil fixedly attached to the stationary housing. The first solenoid also has a first solenoid core extending and movable along a first core axis in parallel to the longitudinal central axis. The first solenoid is configured to move the first solenoid core in a first core direction along the first core axis from a first core initial position corresponding to the third translational position of the sliding shaft to a first core extended position corresponding to the first translational position of the sliding shaft in response to the first coil being energized. The first solenoid is configured to return the first solenoid core the first core initial position in response to the first coil not being energized. The solenoid assembly also includes a second solenoid that has a second coil fixedly attached to the stationary housing. The second solenoid also has a second solenoid core that extends and is movable along a second core axis in parallel to the longitudinal central axis and spaced from the first core axis. The second solenoid is configured to move the second solenoid core in a second core direction along the second core axis opposite the first core direction from a second core initial position corresponding to the third translational position of the sliding shaft to a second core extended position corresponding to the second translational position of the sliding shaft in response to the second coil being energized. The second solenoid is configured to return the second solenoid core to the second core initial position in response to the second coil not being energized. The solenoid assembly additionally includes a z-shaped bracket that includes a central portion extending rectilinearly in parallel to the longitudinal central axis. The z-shaped bracket includes a first arm that extends orthogonally to the longitudinal central axis and is attached to the first solenoid core and the sliding shaft. The z-shaped bracket also includes a second arm that extends orthogonally to the longitudinal central axis and is attached to the second solenoid core for moving the sliding shaft along the longitudinal central axis.
In some embodiments, the pump system further includes a solenoid controller coupled to the solenoid assembly. The solenoid controller is configured to reduce a voltage supplied to the solenoid assembly from an initial voltage to a predetermined reduced voltage after a predetermined amount of time. The reduction of the voltage supplied to the solenoid assembly from the initial voltage to the predetermined reduced voltage after the predetermined amount of time reduces an amount of power required to maintain a pinch applied by the at least one pinch member in the first translational position of the sliding shaft and by the at least one pinch member in the second translational position of the sliding shaft in the second translational position of the sliding shaft.
In some embodiments, the at least one tube support includes a central barrier extending outwardly from the front face. The central barrier has a first central barrier side that extends along the first direction and a second central barrier side opposite the first central barrier side that extends along the first direction. The at least one pinch member includes a first movable component extending outwardly from the front face and is selectively spaced from the first central barrier side of the central barrier. The first movable component is movable along the second direction toward the first central barrier side of the central barrier. The at least one pinch member also includes a second movable component that extends outwardly from the front face and is selectively spaced from the second central barrier side of the central barrier. The second movable component is movable along the second direction toward the second central barrier side of the central barrier. The power actuator includes at least one motor that is operably coupled to the first movable component and the second movable component. The at least one motor is configured to move the first movable component toward the first central barrier side of the central barrier to pinch the first tube against the first central barrier side of the central barrier in the first arrangement. The at least one motor is also configured to move the first movable component away from the first central barrier side of the central barrier to release the first tube in the third arrangement. In addition, the at least one motor is configured to move the second movable component toward the second central barrier side of the central barrier to pinch the second tube against the second central barrier side of the central barrier in the second arrangement. The at least one motor is also configured to move the second movable component away from the second central barrier side of the central barrier to release the second tube in the third arrangement.
In some embodiments, the first movable component and the second movable component are configured to slide along the second direction and the at least one motor includes a first motor and a second motor.
In some embodiments, the first movable component and the second movable component are oblong and configured to rotate about respective axes extending orthogonally from the front face and spaced from one another.
In some embodiments, the at least one tube support includes a first barrier extending outwardly from the front face and having a first barrier edge extending along the first direction for facing the first tube. The at least one tube support also includes a second barrier extending outwardly from the front face opposite and spaced from the first barrier and having a second barrier edge extending along the first direction for facing the second tube. In addition, the at least one pinch member includes a central movable component that extends outwardly from the front face between the first barrier and the second barrier. The central movable component is selectively spaced from the first barrier and the second barrier and is movable toward one of the first barrier and the second barrier. The power actuator includes at least one motor operably coupled to the central movable component and is configured to move the central movable component toward the first barrier edge of the first barrier to pinch the first tube against the first barrier edge of the first barrier in the first arrangement. The at least one motor is also configured to move the central movable component away from the first barrier edge of the first barrier to release the first tube in the third arrangement. Additionally, the at least one motor is configured to move the central movable component toward the second barrier edge of the second barrier to pinch the second tube against the second barrier edge of the second barrier in the second arrangement. The at least one motor is also configured to move the central movable component away from the second barrier edge of the second barrier to release the second tube in the third arrangement.
In some embodiments, the first barrier edge and the second barrier edge directly face one another and the central movable component extends along the second direction from a first central component end to a second central component end. The at least one motor includes a central component shaft extending through the front face. The central component shaft is rotatable about a first central component end axis disposed at the first central component end. The central component shaft connects to the first central component end. The central component shaft is configured to rotate the central movable component about the first central component end axis to rotate the second central component end of the central movable component toward the first barrier edge of the first barrier to pinch the first tube against the first barrier edge of the first barrier in the first arrangement. The central component shaft is also configured to rotate the central movable component about the first central component end axis to rotate the second central component end of the central movable component away from the first barrier edge of the first barrier to release the first tube in the third arrangement. Additionally, the central component shaft is configured to rotate the second central component end of the central movable component toward the second barrier edge of the second barrier to pinch the second tube against the second barrier edge of the second barrier in the second arrangement. The central component shaft is also configured to rotate the central movable component about the first central component end axis to rotate the second central component end of the central movable component away from the second barrier edge of the second barrier to release the second tube in the third arrangement.
In some embodiments, the first barrier and the second barrier are offset from one another along the first direction and the first barrier edge and the second barrier edge do not directly face one another. The central movable component extends in the second direction from a first central component side to a second central component side opposite the first central component side. The at least one motor is configured to move the central movable component along the second direction to slide the central movable component toward the first barrier to pinch the first tube between the first central component side and the first barrier edge of the first barrier in the first arrangement. The at least one motor is also configured to move the central movable component along the second direction to slide the central movable component away from the first barrier to release the first tube from between the first central component side and the first barrier edge of the first barrier in the third arrangement. In addition, the at least one motor is configured to slide the central movable component toward the second barrier to pinch the second tube between the second central component side and the second barrier edge of the second barrier in the second arrangement. The at least one motor is configured to move the central movable component along the second direction to slide the central movable component away from the second barrier to release the second tube from between the second central component side and the second barrier edge of the second barrier in the third arrangement.
In some embodiments, the first tube and the second tube both attach to a connector and combine into an outflow tube exiting the connector. The at least one pinch member includes a movable portion of the connector configured to move relative to the front face. The power actuator includes a motor operably coupled to the movable portion of the connector. The motor is configured to move the movable portion of the connector to pinch closed the first tube in the first arrangement. The motor is also configured to move the movable portion of the connector to pinch closed the second tube in the second arrangement. Additionally, the motor is configured to move the movable portion of the connector to pinch closed neither the first tube nor the second tube in the third arrangement.
In some embodiments, the power actuator includes a solenoid assembly including a first solenoid having a first coil fixedly attached to the stationary housing and having a first solenoid core extending and movable along a first core axis in parallel to a longitudinal central axis. The first solenoid is configured to move the first solenoid core in a first core direction along the first core axis. The first solenoid core is movable from a first core initial position corresponding to the third arrangement of the at least one pinch member to a first core extended position corresponding to the first arrangement of the at least one pinch member in response to the first coil being energized. The first solenoid core is also configured to return to the first core initial position in response to the first coil not being energized. The solenoid assembly also includes a second solenoid having a second coil fixedly attached to the stationary housing and having a second solenoid core extending and movable along a second core axis in parallel to the longitudinal central axis and spaced from the first core axis. The second solenoid is configured to move the second solenoid core in a second core direction along the second core axis being in the same direction as the first core direction. The second solenoid is movable from a second core initial position corresponding to the third arrangement of the at least one pinch member to a second core extended position corresponding to the second arrangement of the at least one pinch member in response to the second coil being energized. The second solenoid is also configured to return to the second core initial position in response to the second coil not being energized. The solenoid assembly also includes a first shaft half coupled to the first solenoid core by a first bracket half extending transverse to the first core axis from the first solenoid core toward the longitudinal central axis. In addition the solenoid assembly includes a second shaft half coupled to the second solenoid core by a second bracket half extending transverse to the second core axis from the second solenoid core toward the longitudinal central axis. The at least one pinch member includes a first half pinch bar extending radially from the longitudinal central axis in a first lateral direction. The first half pinch bar is configured to move away the front face when the first shaft half is in a primary first shaft half position corresponding to the first arrangement of the at least one pinch member while maintaining spacing with the front face when the first shaft half is in a tertiary first shaft half position corresponding to the third arrangement of the at least one pinch member. The at least one pinch member also includes a second half pinch bar extending radially from the longitudinal central axis in a second lateral direction opposite the first lateral direction. The second half pinch bar is configured to move away the front face when the second shaft half is in a primary second shaft half position corresponding to the second arrangement of the at least one pinch member while maintaining spacing with the front face when the second shaft half is in a tertiary second shaft half position corresponding to the third arrangement of the at least one pinch member.
There is also provided a method of operating a pump system including an outflow pump. The method including the step of providing a stationary housing defining an internal volume and a front face outside the internal volume extending in a first direction and a second direction transverse to the first direction and including at least one tube support outside the internal volume extending outwardly from the front face for aligning and supporting a first tube and a second tube. The method continues with the step of moving at least one pinch member relative to the at least one tube support using a power actuator operably coupled thereto amongst three orientations. The three orientations include: a first arrangement of the at least one pinch member relative to the at least one tube support configured to pinch closed the first tube; a second arrangement of the at least one pinch member relative to the at least one tube support configured to pinch closed the second tube; and a third arrangement of the at least one pinch member relative to the at least one tube support configured to pinch closed neither the first tube nor the second tube.
In some embodiments, the at least one tube support includes a t-shaped bracket extending outwardly from the front face and the power actuator includes a solenoid assembly coupled to a sliding shaft. Thus, the method further includes the step of providing a first tube notch defined by the t-shaped bracket and a second tube notch defined by the t-shaped bracket. The method also includes the step of moving the sliding shaft extending along a longitudinal central axis through the front face and out of the internal volume of the stationary housing and into a bracket cavity defined by the t-shaped bracket using the solenoid assembly between one of: a first translational position to move the at least one pinch member to the first arrangement, a second translational position to move the at least one pinch member to the second arrangement, and a third translational position to move the at least one pinch member to the third arrangement.
In some embodiments, the at least one pinch member includes a first pinch bar adjacent the first tube notch and a second pinch bar adjacent the second tube notch each extending radially from the longitudinal central axis and offset from one another along the longitudinal central axis. So, the method further includes the step of moving the first pinch bar toward the front face in response to the sliding shaft moving to the first translational position. The method also includes the step of moving the second pinch bar away from the front face toward a support beam of the t-shaped bracket spaced from the front face and extending along the second direction in response to the sliding shaft moving to the second translational position. In addition, the method includes the step of maintaining spacing of the first pinch bar from the front face of a first notch width and of the second pinch bar from the front face of a second notch width when the sliding shaft is in the third translational position.
In some embodiments, the solenoid assembly includes a first solenoid and a second solenoid. Consequently, the method further including the step of energizing a first coil of the first solenoid. Additionally, the method includes the step of moving a first solenoid core of the first solenoid in a first core direction along a first core axis in parallel to the longitudinal central axis from a first core initial position corresponding to the third translational position of the sliding shaft to a first core extended position corresponding to the first translational position of the sliding shaft in response to the first coil being energized. The method also includes the step of returning the first solenoid core to the first core initial position in response to the first coil not being energized. The next step of the method is energizing a second coil of the second solenoid. Next, moving a second solenoid core of the second solenoid in a second core direction along a second core axis in parallel to the longitudinal central axis opposite the first core direction from a second core initial position corresponding to the third translational position of the sliding shaft to a second core extended position corresponding to the second translational position of the sliding shaft in response to the second coil being energized. The method additionally includes the step of returning the second solenoid core to the second core initial position in response to the second coil not being energized.
In some embodiments, the method further includes the step of reducing a voltage supplied to the solenoid assembly from an initial voltage to a predetermined reduced voltage after a predetermined amount of time using a solenoid controller coupled to the solenoid assembly. Next, reducing an amount of power required to maintain a pinch applied by the at least one pinch member in the first translational position of the sliding shaft and by the at least one pinch member in the second translational position of the sliding shaft in the second translational position of the sliding shaft.
In some embodiments, the at least one tube support includes a central barrier extending outwardly from the front face. The at least one pinch member includes a first movable component and a second movable component each extending outwardly from the front face and selectively spaced from the central barrier. The power actuator includes at least one motor operably coupled to the first movable component and the second movable component. So, the method further includes the step of moving the first movable component toward a first central barrier side of the central barrier in the first arrangement. Also, the method includes the step of moving the first movable component away from the first central barrier side of the central barrier in the third arrangement. The method also includes the step of moving the second movable component toward a second central barrier side of the central barrier opposite the first central barrier side in the second arrangement. Additionally, the method includes the step of moving the second movable component away from the second central barrier side of the central barrier in the third arrangement.
In some embodiments, the at least one tube support includes a first barrier extending outwardly from the front face and a second barrier extending outwardly from the front face and spaced from the first barrier. The at least one pinch member includes a central movable component extending outwardly from the front face and disposed between the first barrier and the second barrier. The power actuator includes at least one motor operably coupled to the central movable component. Thus, the method further includes the step of moving the central movable component toward a first barrier edge of the first barrier extending along the first direction in the first arrangement. Also, the method includes the step of moving the central movable component away from the first barrier edge of the first barrier in the third arrangement. The method also includes the step of moving the central movable component toward a second barrier edge of the second barrier extending along the first direction in the second arrangement. In addition, the method includes the step of moving the central movable component away from the second barrier edge of the second barrier in the third arrangement.
In some embodiments, the first barrier edge and second barrier edge directly face one another and the central movable component extends along the second direction from a first central component end to a second central component end. Consequently, the method further includes the step of rotating the second central component end of the central movable component toward the first barrier edge of the first barrier in the first arrangement using a central component shaft of the at least one motor extending through the front face and rotatable about a first central component end axis disposed at the first central component end. The method continues with the step of rotating the second central component end of the central movable component away from the first barrier edge of the first barrier in the third arrangement using the central component shaft of the at least one motor. The method also includes the step of rotating the second central component end of the central movable component toward the second barrier edge of the second barrier in the second arrangement using the central component shaft of the at least one motor. The method proceeds by rotating the second central component end of the central movable component away from the second barrier edge of the second barrier in the third arrangement using the central component shaft of the at least one motor.
In some embodiments, the first barrier and the second barrier are offset from one another along the first direction and the first barrier edge and the second barrier edge do not directly face one another. The central movable component extends along the second direction from a first central component side to a second central component side. So, the method further includes the step of sliding the central movable component along the first direction toward the first barrier in the first arrangement using the at least one motor. Also, the method includes the step of sliding the central movable component along the first direction away from the first barrier in the third arrangement using the at least one motor. The method also includes the step of sliding the central movable component along the first direction toward the second barrier in the second arrangement using the at least one motor. Additionally, the method includes the step of sliding the central movable component along the first direction away from the second barrier in the third arrangement using the at least one motor.
In some embodiments, the first tube and the second tube both attach to a connector and combine into an outflow tube exiting the connector. The at least one pinch member includes a movable portion of the connector that is movable relative to the front face. The power actuator includes a motor operably coupled to the movable portion of the connector. Therefore, the method further includes the step of moving the movable portion of the connector to pinch closed the first tube in the first arrangement. The method also includes the step of moving the movable portion of the connector to pinch closed the second tube in the second arrangement. Additionally, the method includes the step of moving the movable portion of the connector to pinch closed neither the first tube nor the second tube in the third arrangement.
For a detailed description of example embodiments, reference will now be made to the accompanying drawings in which:
Various terms are used to refer to particular system components. Different companies may refer to a component by different names—this document does not intend to distinguish between components that differ in name but not function. In the following discussion and in the claims, the terms “including” and “comprising” are used in an open-ended fashion, and thus should be interpreted to mean “including, but not limited to . . . .” Also, the term “couple” or “couples” is intended to mean either an indirect or direct connection. Thus, if a first device couples to a second device, that connection may be through a direct connection or through an indirect connection via other devices and connections.
“Control system” shall comprise, singly or in combination, a field programmable gate array (FPGA), application specific integrated circuit (ASIC), programmable logic device (PLD), programmable logic controller (PLC), microcontroller, specifically implemented processor-based system, configured to read electrical signals and take control actions responsive to such signals.
The following discussion is directed to various embodiments of the invention. Although one or more of these embodiments may be preferred, the embodiments disclosed should not be interpreted, or otherwise used, as limiting the scope of the disclosure, including the claims. In addition, one skilled in the art will understand that the following description has broad application, and the discussion of any embodiment is meant only to be exemplary of that embodiment, and not intended to intimate that the scope of the disclosure, including the claims, is limited to that embodiment.
Various embodiments are directed to fluid management during surgical procedures, such as arthroscopic procedures. More particularly, example embodiments are directed to pump systems or fluid controllers including an outflow pump. The outflow pump couples to a surgical site by way of tubes which are also connected to a cannula or other surgical devices to provide an outflow of surgical fluid from a surgical site. The fluid controller can also include an inflow pump utilized along with the outflow pump to provide a continuous fluid flow through the surgical site. Outflow from the surgical site can occur from multiple sources (e.g., the cannula or other surgical devices). The tubes utilized for outflow can include a first tube and a second tube. Depending on the device in use, the pump system can control the outflow from a particular one of the surgical devices at any given time by closing one of the first and second tubes and opening the other of the of the first and second tubes. Thus, the pump system can include a pinch valve movable between multiple positions or orientations to pinch closed the first and second tubes. The specification first turns to a brief description of why having a pump system with a pinch valve having three distinct positions or orientations may provide a competitive advantage in the marketplace.
Related-art pump systems are available from a variety of manufacturers. In most cases, the related-art pump systems employ pinch valves with only two positions or orientations that are either pinching closed the first tube or the second tube at any given time (i.e., a two-position pinch valve). However, such two-position pinch valves present challenges when the first and second tubes are loaded onto the outflow pump during an initial setup of the pump system for a surgical procedure. If, for example, the two-position pinch valve is in a first position for pinching closed the first tube, the second tube may be loaded during the initial setup. Next, the two-position pinch valve must be commanded to toggle (e.g., using a button, lever) to the second position for pinching closed the second tube while the first tube is loaded to complete the initial setup. Similarly, after the surgical procedure is completed, the two-position pinch valve must be commanded to toggle between the first and second positions in order to remove the first and second tube from the pump system.
Embodiments of pump systems utilizing a pinch valve mechanism having three distinct positions or orientations are discussed herein. Specifically, the pinch valve mechanisms described include at least one tube support that aligns and supports the first and second tubes and at least one pinch member that may be moved relative to the at least one tube support using a power actuator operably coupled to the at least one pinch member. In more detail, the power actuator is configured to have three orientations that define: a first arrangement of the at least one pinch member relative to the at least one tube support configured to pinch closed the first tube, a second arrangement of the at least one pinch member relative to the at least one tube support configured to pinch closed the second tube, and a third arrangement of the at least one pinch member relative to the at least one tube support configured to pinch closed neither the first tube nor the second tube. The specification now turns to an example system.
The example surgical system 100 further comprises a plurality of instruments associated with the surgical site 112 out which fluid may flow; however, various embodiments are applicable to any situation in which surgical fluid flows from the surgical site 112, including surgical fluid flowing directly out an incision through the skin of the patient. The example surgical system 100 comprises a first instrument in the form of a mechanical resection device 120, such as a blade, burr device, or “shaver.” So as not to unduly complicate the disclosure, the mechanical resection device 120 will be referred to as shaver 120 with the understanding that any mechanical resection device may be used. The shaver 120 may comprise a tubular member that defines an internal channel in communication with a distal opening, and a mechanical blade in operational relationship to the distal opening. The mechanical blade may be turned or oscillated by a motor (e.g., a motor within handle 122). The shaver 120 may be fluidly coupled to a source of suction (e.g., wall suction in a surgical room, a peristaltic pump, or other vacuum pump) by way of tube 126, and may be electrically coupled to a shaver control system 128 by way of an electrical connection 130 (electrical connection shown in dashed lines in
Another example instrument that may be used is an ablation device. In particular, the example surgical system 100 further comprises an ablation device 132. The ablation device 132 may comprise a tubular member that defines an internal channel in communication with a distal opening, and a metallic electrode in operational relationship to the distal opening and disposed within the surgical site 112. The ablation device 132 may be fluidly coupled to a source of suction (e.g., wall suction in a surgical room, or a peristaltic pump) by way of tube 136, and may be electrically coupled to an ablation control system 138 by way of an electrical connection 140 (shown with a dashed line). In operation, the ablation control system 138 provides electrical energy to the metallic electrode, which creates plasma near the metallic electrode. The metallic electrode and distal opening may be placed proximate to tissue to be removed or resected, and the plasma may volumetrically reduce and/or disassociate the tissue, creating tissue fragments and ablation by-products. Moreover, the tissue fragments, ablation by-products, and surgical fluid within the surgical site may be drawn through the channel inside the ablation device 132 by way of tubing 136. In some example systems, the ablation control system 138 may be electrically coupled (shown by bubble “B”) to the fluid controller 108 such that the fluid controller 108 can proactively respond to activation of the ablation device 132 (discussed more below).
Continuing to refer to
Still referring to
The fluid controller 108 additionally includes a second positive displacement pump 164 or outflow pump configured to provide suction or aspiration to the surgical site 112. Thus, the fluid controller 108 may be known as a dual flow pump system 108 or simply pump system 108. The second positive displacement pump 164 is illustratively shown as a peristaltic pump (and hereafter just second peristaltic pump 164). The suction inlet of the second peristaltic pump 164 is coupled to the shaver 120, ablation device 132, and/or outflow cannula 142 and its discharge is fluidly coupled to a waste receptacle 166. Accordingly, the pump system 108 is designed to use two tube sets 168, 170 during operation, an inflow tube set 168 including the tube 162 and an outflow tube set 170 for connection to the shaver 120, ablation device 132, and/or outflow cannula 142. In more detail, the outflow tube set 170 splits into two lumens or channels (i.e., a first tube 172 and a second tube 174) such that two surgical instruments (e.g., the shaver 120, ablation device 132, and/or outflow cannula 142) may be used, one at a time, within the surgical site 112 using the second peristaltic pump 164.
Before proceeding, it is noted that while it is theoretically possible to have both a shaver 120 and ablation device 132 inserted into the surgical site 112 at the same time, in many cases only one such instrument will be used, or will be used at any given time, and thus it is possible that a single entry point through the patient's skin into the surgical site 112 may be created and used for both the example classes of instruments. The instrument the surgeon chooses to use may be inserted into the entry point, used within the surgical site 112, and then withdrawn such that the second instrument can be inserted and used. Furthermore, while tube 136 and tube 126 are both shown connected together, it should be understood that in cases where both shaver 120 and ablation device 132 are used at the same time, only one would likely be connected to the second tube 174 at a time and either the shaver 120 or ablation device 132 would likely be connected to a separate source of suction (e.g., wall suction in a surgical room) other than the second peristaltic pump 164. Alternatively, the outflow tube set 170 may include more than two tubes 172, 174 (e.g., an nth tube for use with whichever of the shaver 120 or ablation device 132 that is not connected to the second tube 174).
The pump system 108 further includes the pinch valve mechanism 176 and will be electronically informed regarding which instrument 120, 132 is in use (e.g., via analog signals indicative of activation of the surgical instruments 120, 132 from the shaver control system 128 or the ablation control system 138 and/or based on a pressure of surgical fluid measured at the outlet of the second peristaltic pump 164 as measured by a pressure sensor 177), and will actuate the pinch valve mechanism 176 to close off or pinch the tubing of the surgical instrument 120, 132 not in use and only enable outflow through the outflow cannula. For example, when the shaver 120 or ablation device 132 is in use, the first tube 172 for the outflow cannula 142 may be pinched closed, and when use of the shaver 120 or ablation device 132 is discontinued, the second tube 174 for the shaver 120 or ablation device 132 may be pinched closed while the first tube 168 for the outflow cannula 142 is opened to flow. As will be discussed in more detail below, the pinch valve mechanism 176 includes at least one tube support 178, at least one pinch member 180 movable relative to the at least one tube support 178, and a power actuator 182 operably coupled to the at least one pinch member 180 and configured to move the at least one pinch member 180 relative to the at least one tube support 178 to selectively pinch either the first tube 172 or the second tube 174.
Referring simultaneously to
In more detail, the solenoid assembly 500 includes a first solenoid 502 having a first coil 504 fixedly attached to the stationary housing 200 and a first solenoid core 506 extending and movable along a first core axis C1 in parallel to the longitudinal central axis C. The first solenoid 502 is configured to move the first solenoid core 506 in a first core direction 508 along the first core axis C1. Specifically, the first solenoid core 506 moves from a first core initial position corresponding to the third translational position of the sliding shaft 400 to a first core extended position corresponding to the first translational position of the sliding shaft 400 in response to the first coil 504 being energized. The first solenoid core 506 returns to the first core initial position in response to the first coil 504 not being energized (e.g., using a spring of the first solenoid 502).
The solenoid assembly 500 also includes a second solenoid 510 having a second coil 512 fixedly attached to the stationary housing 200 and a second solenoid core 514 extending and movable along a second core axis C2 in parallel to the longitudinal central axis C and spaced from the first core axis C1. The second solenoid 510 is configured to move the second solenoid core 514 in a second core direction 516 along the second core axis C2 opposite the first core direction 508. More specifically, the second solenoid core 514 moves from a second core initial position corresponding to the third translational position of the sliding shaft 400 to a second core extended position corresponding to the second translational position of the sliding shaft 400 in response to the second coil 512 being energized. The second solenoid core 514 returns to the second core initial position in response to the second coil 512 not being energized (e.g., using a spring of the second solenoid 510).
In addition, the solenoid assembly 500 includes a z-shaped bracket 518 for moving the sliding shaft 400 along the longitudinal central axis C. The z-shaped bracket 518 includes a central portion 520 extending rectilinearly in parallel to the longitudinal central axis C. The z-shaped bracket 518 includes a first arm 522 extending orthogonally to the longitudinal central axis C that attaches to the first solenoid core 506 and the sliding shaft 400. The z-shaped bracket 518 additionally includes a second arm 524 extending orthogonally to the longitudinal central axis C that attaches to the second solenoid core 514.
Instead of the z-shaped bracket 518 shown in
While up until this point, the power actuator 182 (
Regardless of the mechanism by which the fluid controller 108 receives various pieces of information, the control system 900 may implement various modes of operation related to pumping surgical fluid to the surgical site 112 by commanding first peristaltic pump 110 to operate, removing surgical fluid from the surgical site 112 by commanding second peristaltic pump 164 using the motor speed controller 916, and/or commanding the movement of the at least one pinch member 180 (e.g., the first and second pinch bars 402, 406 or first half pinch bar 722 and second half pinch bar 724) by the power actuator 182 (e.g., the solenoid assembly 500, 800 and sliding shaft 400 or solenoid assembly 700 and first shaft half 716 and second shaft half 720) using the solenoid controller 917.
As shown, the first peristaltic pump 110 is turned by motor 918 and the second peristaltic pump 164 is turned by motor 919. The motors 918, 919 may take any suitable form. For example, the motors 918, 919 may be direct current (DC) electric motor, and thus the motor speed controllers 915, 916 provides a DC voltage to the electric motors 918, 919 which controls the speed of the output shafts. In other cases, the motors 918, 919 may be alternating current (AC) electric motors, and thus the motor speed controllers 915, 916 provide an AC voltage at varying voltage and frequency which controls the speed of the output shafts. In yet still other cases, the motors 918, 919 may be a pneumatic motor, and thus the motor speed controllers 915, 916 provide air at varying pressures, where the pressure controls the speed of the output shafts. Thus, regardless of the type of motors 918, 919 implemented, the motor speed controllers 915, 916 control the speed of the motors 918, 919 responsive to commands provided from the control system 900. While in the example system, the command to the motor speed controllers 915, 916 can be an analog signal, in other cases the motor speed controllers 915, 916 may receive commands in packet-based messages (e.g., through the communication logic 914). Finally, while the motors 918, 919 are respectively shown to directly couple to the first peristaltic pump 110 and second peristaltic pump 164, in other cases various gears and/or belts may be used to transfer the rotational motion of the shaft of motors 918, 919 to first peristaltic pump 110 and second peristaltic pump 164, respectively. While
The solenoid controller 917 additionally controls the movement of the solenoid assembly 500, 700, 800 responsive to commands provided from the control system 900. Though in the example system the command to the solenoid controller 917 can be an analog signal, in other cases the solenoid controller 917 may receive commands in packet-based messages (e.g., through the communication logic 914).
In typical surgical procedures, for example, it is common that outflow cannula 142 is used for a comparatively longer period of time (e.g., used for 95% of an overall time of the surgical procedure) as compared to the shaver 120 or ablation device 132 (e.g., used for 5% of the overall time of the surgical procedure). Accordingly, the second tube 174 may be pinched closed longer than the first tube 172. In addition, the tubes 172, 174 take a natural set after a period of time after they are initially pinched (e.g., approximately 5 seconds). Thus, the tubes 172, 174 do not require the same pinch force to be sustained after this period of time in order to maintain the tubes 172, 174 being pinched or closed off. Specifically, it has been observed that the pinch force required to fully pinch the first tube 172 or second tube 174 is relatively higher initially. Once the occlusion of the tube 172, 174 is established, this pinch force may be reduced while still maintaining the occlusion of the tube 172, 174. Consequently, the solenoid controller 917 coupled to the solenoid assembly 500, 700, 800 is configured to reduce a voltage supplied to the solenoid assembly 500, 700, 800 from an initial voltage (e.g., 24 volts) to a predetermined reduced voltage (e.g., 11 volts) after a predetermined amount of time (e.g., approximately 15-20 seconds). So, an amount of power required to maintain a pinch applied by the at least one pinch member 180 (e.g., pinch force of 20 pounds to the first tube 172) in the first translational position of the sliding shaft 400 (or the first shaft half 716 being in the primary first shaft half position) is reduced. Likewise, an amount of power required to maintain a pinch applied by the at least one pinch member 180 (e.g., pinch force of 20 pounds to the second tube 174) in the second translational position of the sliding shaft 400 (or the second shaft half 720 being in the primary second shaft half position) is reduced due to the reduction of the voltage supplied to the solenoid assembly 500, 700, 800 after the predetermined amount of time. Because the outflow cannula 142 may be used for a comparatively longer period of time as compared to the shaver 120 or ablation device 132, power consumed by the solenoid assembly 500, 700, 800 can be advantageously be reduced by the solenoid controller 917 being configured in this way. It should be understood that such a reduction in the voltage supplied to the solenoid assembly 500, 700, 800 could be carried out in many different ways, such as, but not limited to adjusting a duty cycle of a pulse width modulated voltage provided to the solenoid assembly 500, 700, 800.
Before proceeding, it is noted that the embodiment of
Thus, in example embodiments where the control system 900 is a processor 902, RAM 904, etc., as shown, the ROM 906 and RAM 904 (and possibly other non-transitory storage mediums) store instructions that implement the control of the first and second peristaltic pumps 110, 164 as well as the pinch valve mechanism 176 (
Another example of the pinch valve mechanism in accordance with at least some embodiments is shown in
Referring now to
Specifically, referring to
Referring to
Referring next to
More specifically, as best shown in
As best shown in
Referring next to
Again, the control system 900 may implement various modes of operation related to pumping surgical fluid to the surgical site 112 (
So, as in
When the at least one tube support 178 (
As discussed above with reference to
Also, the solenoid assembly 500 can include a first solenoid 502 and a second solenoid 510, so the method further includes the step of energizing a first coil 504 of the first solenoid 502. Next, moving a first solenoid core 506 of the first solenoid 502 in a first core direction 508 along a first core axis C1 in parallel to the longitudinal central axis C from a first core initial position corresponding to the third translational position of the sliding shaft 400 to a first core extended position corresponding to the first translational position of the sliding shaft 400 in response to the first coil 504 being energized. The method continues by returning the first solenoid core 506 to the first core initial position in response to the first coil 504 not being energized. The method continues with the step of energizing a second coil 512 of the second solenoid 510. Next, moving a second solenoid core 514 of the second solenoid 510 in a second core direction 516 along a second core axis C2 in parallel to the longitudinal central axis C opposite the first core direction 508 from a second core initial position corresponding to the third translational position of the sliding shaft 400 to a second core extended position corresponding to the second translational position of the sliding shaft 400 in response to the second coil 512 being energized. The method also includes the step of returning the second solenoid core 514 to the second core initial position in response to the second coil 512 not being energized.
The method can further include the step of reducing a voltage supplied to the solenoid assembly 500, 700, 800 from an initial voltage to a predetermined reduced voltage after a predetermined amount of time using a solenoid controller coupled to the solenoid assembly 500, 700, 800. The next step of the method is reducing an amount of power required to maintain a pinch applied by the at least one pinch member 180 (e.g., to the first tube 172) in the first translational position of the sliding shaft 400 and by the at least one pinch member 180 (e.g., to the second tube 174) in the second translational position of the sliding shaft 400 in the second translational position of the sliding shaft 400.
Also as discussed above with reference to
As discussed above with reference to
More specifically, the first barrier edge 1102 and second barrier edge 1106 can directly face one another (see e.g.,
Alternatively if the first barrier 1200 and the second barrier 1204 are offset from one another along the first direction Y and the first barrier edge 1202 and the second barrier edge 1206 do not directly face one another and the central movable component 1108 extends along the second direction X from a first central component side 1214 to a second central component side 1216 (see e.g.,
As previously discussed with reference to
The above discussion is meant to be illustrative of the principles and various embodiments of the present invention. Numerous variations and modifications will become apparent to those skilled in the art once the above disclosure is fully appreciated. For example, other pinch valve mechanisms that move normal to the front face of the stationary housing may be used. It is intended that the following claims be interpreted to embrace all such variations and modifications.
This application is a divisional of U.S. application Ser. No. 17/109,525 filed Dec. 2, 2020 titled “Pump System With Pinch Valve For Fluid Management In Surgical Procedures And Method Of Operation Thereof,” which claims the benefit of U.S. Provisional Application Ser. No. 63/073,575 filed Sep. 2, 2020 titled “Pump System with Pinch Valve for Fluid Management in Surgical Procedures and Method of Operation Thereof” Both of the noted applications are incorporated by reference herein as if reproduced in full below.
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Number | Date | Country | |
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20220349397 A1 | Nov 2022 | US |
Number | Date | Country | |
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63073575 | Sep 2020 | US |
Number | Date | Country | |
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Parent | 17109525 | Dec 2020 | US |
Child | 17867089 | US |