Abstract: A surgical instrument includes a body having a firing actuator, a shaft, a motor, an end effector, and a control circuit. The motor is configured to activate in response to a firing actuation of the firing actuator. The end effector is operable to staple and sever tissue and includes a cutting edge configured to selectively translate longitudinally between a proximal position and a distal position in response to an activation of the motor. The control circuit is configured to generate a forward motor control signal to pulsate the cutting edge. The forward motor control signal includes a first time duration including movement of the cutting edge distally from the proximal position to a second longitudinal position, a second time duration including ceased movement of the cutting edge, and a third time duration including movement of the cutting edge distally from the second longitudinal position toward the distal position.

Abstract: An apparatus includes a body, a shaft extending distally from the body, a motor, a stapling assembly disposed at a distal end of the shaft, and a timer circuit operatively coupled to the motor and the firing actuator. The body includes a firing actuator and the motor is configured to activate in response to a firing actuation of the firing actuator. The motor is further configured to deactivate after a first predetermined time period subsequent to the firing actuation. The stapling assembly is configured to selectively move from an open position to a closed position to clamp tissue and is operable to drive a plurality of staples into the clamped tissue in response to activation of the motor. The timer circuit is configured to activate a timer in response to the firing actuation. The timer is configured to run for a second predetermined time period. The timer circuit is configured to ensure deactivation of the motor upon expiration of the second predetermined time period.

Abstract: A surgical instrument includes a body assembly, a shaft assembly extending distally from the body assembly, an anvil, and a stapling head assembly. The stapling head assembly includes at least one annular array of staples, a staple driver, and a trocar. The trocar includes a shaft defining a longitudinal axis, an actuating feature coupled with a motor unit, and at least one coupling feature. The motor unit is configured to actuate the actuating feature to move the at least one coupling feature of the trocar in a transverse direction relative to the longitudinal axis of the shaft between a contracted position and an expanded position. In the contracted position, the shaft of the trocar is configured to move along the longitudinal axis relative to the anvil. In the expanded position, the shaft of the trocar is configured to move together with the anvil along the longitudinal axis.

Abstract: A powered surgical stapler includes a motor unit, a movable member, a controller, a sensor assembly, an anvil, and an opposing deck surface. A method of operating the stapler includes controlling the motor unit to actuate the movable member to move from the open position towards the closed position. The method also includes sensing closure data using the sensor assembly. The closure data includes an initial tissue contact position, a gap formed between the anvil and the opposing deck surface, and an axial force on the anvil. The method also includes communicating the closure data to the controller. The method also includes determining at least one of an adjusted closure rate or an adjusted closure stroke using the closure data. The method also includes controlling the motor unit using at least one of the adjusted closure rate or the adjusted closure stroke.

Abstract: A surgical instrument includes a body assembly, a distally extending shaft assembly, and a distal stapling assembly configured to clamp, staple, and cut tissue. A first user feedback element is configured to visually inform a user of a first condition of the stapling assembly, and a second user feedback element is configured to visually inform the user of a second condition of the stapling assembly. A circuit board assembly includes a circuit board, a first light source configured to illuminate the first user feedback element, a second light source configured to illuminate the second user feedback element, and a light guide feature. The light guide feature is configured to direct light from the second light source toward the second user feedback element and simultaneously inhibit light emitted by the first light source from illuminating the second user feedback element.

Abstract: A method for authenticating the compatibility of a staple cartridge with a surgical instrument is disclosed. The method can comprise inserting a staple cartridge into a surgical instrument, receiving a first signal from a first RFID tag on a first component of the staple cartridge with an RFID reader system, receiving a second signal from a second RFID tag on a second component of the staple cartridge with the RFID reader system, comparing the first signal and the second signal to stored data for a compatible staple cartridge, and locking a staple firing system of the surgical instrument if the first signal and the second signal do not match the stored data for a compatible staple cartridge.

Abstract: A method is provided for operating a powered surgical stapler having a motor unit, a controller. and a stapling assembly having a closure member, a staple driver member, and a knife member. The controller receives a user input that indicates a tissue gap to be defined by the stapling assembly in a closed state. Based on the user input, the controller controls the motor unit to actuate the closure member to transition the stapling assembly to the closed state to define the tissue gap and clamp tissue therein. The controller then controls the motor unit to actuate the staple driver member to drive staples into the clamped tissue. In response to determining that the staple driver member has reached a predetermined longitudinal position, the controller controls the motor unit to initiate actuation of the knife member to cut the clamped tissue.

Abstract: An apparatus includes a body, a motor, a shaft, a stapling assembly, and an electrical potential shifting device. The body includes a firing switch configured to generate a motor drive signal including at least one of a motor activation signal portion or a motor deactivation signal portion. The motor includes a first power terminal and a second power terminal which define an electrical potential energy differential therebetween. The motor is configured to selectively activate and deactivate in response to the electrical potential energy differential. The first power terminal is coupled to a power supply and the second power terminal is coupled to the electrical potential shifting device. The electrical potential shifting device increases the electrical potential energy differential of the motor in response to detecting the motor activation signal portion and decreases the electrical potential energy of the motor in response to detecting the motor deactivation signal portion.

Abstract: Methods of operating a surgical instrument are disclosed herein.

Abstract: A surgical instrument comprising a sensing circuit and a control system which is responsive to data from the sensing circuit.

Abstract: A surgical instrument comprising a sensing system is disclosed.

Abstract: A surgical instrument including a flex circuit comprising a sensor system.

Abstract: A surgical instrument includes a body assembly, a shaft assembly extending distally from the body assembly, an anvil, and a stapling head assembly. The stapling head assembly includes at least one annular array of staples, a staple driver, and a trocar. The trocar includes a shaft defining a longitudinal axis, an actuating feature coupled with a motor unit, and at least one coupling feature. The motor unit is configured to actuate the actuating feature to move the at least one coupling feature of the trocar in a transverse direction relative to the longitudinal axis of the shaft between a contracted position and an expanded position. In the contracted position, the shaft of the trocar is configured to move along the longitudinal axis relative to the anvil. In the expanded position, the shaft of the trocar is configured to move together with the anvil along the longitudinal axis.

Abstract: A method is provided for operating a powered surgical stapler having a motor unit, a controller, and a stapling assembly having a plurality of movable members that are actuatable longitudinally by the motor unit to clamp, staple, and cut tissue. The controller determines that a movable member of the stapling assembly is in a first predetermined position, and then executes an actuation algorithm to activate the motor unit to actuate the movable member longitudinally from the first predetermined position toward a second predetermined position. The controller observes an actual longitudinal displacement of the movable member between the first and second predetermined positions. The controller compares the actual longitudinal displacement to an expected longitudinal displacement and determines that the actual longitudinal displacement differs from the expected longitudinal displacement by a difference value. The controller then adjusts the actuation algorithm based on the difference value.

Abstract: A method is provided for operating a powered surgical stapler having a motor unit, a controller. and a stapling assembly having a closure member, a staple driver member, and a knife member. The controller receives a user input that indicates a tissue gap to be defined by the stapling assembly in a closed state. Based on the user input, the controller controls the motor unit to actuate the closure member to transition the stapling assembly to the closed state to define the tissue gap and clamp tissue therein. The controller then controls the motor unit to actuate the staple driver member to drive staples into the clamped tissue. In response to determining that the staple driver member has reached a predetermined longitudinal position, the controller controls the motor unit to initiate actuation of the knife member to cut the clamped tissue.

Abstract: A powered surgical stapler includes a motor unit, a movable member, a controller, a sensor assembly, an anvil, and an opposing deck surface. A method of operating the stapler includes controlling the motor unit to actuate the movable member to move from the open position towards the closed position. The method also includes sensing closure data using the sensor assembly. The closure data includes an initial tissue contact position, a gap formed between the anvil and the opposing deck surface, and an axial force on the anvil. The method also includes communicating the closure data to the controller. The method also includes determining at least one of an adjusted closure rate or an adjusted closure stroke using the closure data. The method also includes controlling the motor unit using at least one of the adjusted closure rate or the adjusted closure stroke.

Abstract: A surgical instrument comprising a staple cartridge assembly is disclosed. The staple cartridge comprises a cartridge body defining a longitudinal axis, staples removably stored in the staple cavities, a cover releasably attached to the cartridge body, and a sled movable from a proximal unfired position to a distal fired position during a firing motion. The staple cartridge further comprises a first RFID tag affixed to the cartridge body at a first longitudinal position, a second RFID tag affixed to the sled, wherein the proximal unfired position of the sled is at a second longitudinal position which is not at the first longitudinal position, and a third RFID tag affixed to the cover at a third longitudinal position which is not at the first longitudinal position and the second longitudinal position.

Abstract: A surgical instrument comprising an RFID system is disclosed. A staple cartridge of the surgical instrument comprises one or more RFID tags which are detectable by one or more RFID readers in the surgical instrument.

Abstract: A method for authenticating the compatibility of a staple cartridge with a surgical instrument is disclosed. The method can comprise inserting a staple cartridge into a surgical instrument, receiving a first signal from a first RFID tag on a first component of the staple cartridge with an RFID reader system, receiving a second signal from a second RFID tag on a second component of the staple cartridge with the RFID reader system, comparing the first signal and the second signal to stored data for a compatible staple cartridge, and locking a staple firing system of the surgical instrument if the first signal and the second signal do not match the stored data for a compatible staple cartridge.

Abstract: A surgical instrument comprising a controller, a staple firing system, and an RFID system is disclosed. The controller is in communication with a first RFID reader and a second RFID reader of the RFID system and the staple firing system. In various embodiments, the controller verifies the presence of the staple cartridge in the surgical instrument upon receiving the first signal from the first RFID tag. Also, in various embodiments, the controller verifies that the staple cartridge is an unfired staple cartridge upon receiving the second signal from the second RFID tag. The controller can also be configured to track the progress of the staple firing stroke through the RFID system.