Abstract: In one general aspect, various embodiments of the present invention can include a motorized surgical cutting and fastening instrument having a drive shaft, a motor selectively engageable with the drive shaft, and a manual return mechanism configured to operably disengage the motor from the drive shaft and retract the drive shaft. In at least one embodiment, a surgeon, or other operator of the surgical instrument, can utilize the manual return mechanism to retract the drive shaft after it has been advanced, especially when the motor, or a power source supplying the motor, has failed or is otherwise unable to provide a force sufficient to retract the drive shaft.

Abstract: A surgical system is disclosed comprising a firing member movable from a proximal position toward a distal position during a firing stroke, a motor configured to drive the firing member toward the distal position, and a control system configured to operate in an open-loop configuration and a closed-loop configuration. In the open-loop configuration, the control system is configured to cause the motor to drive the firing member to a predetermined position between the proximal position and the distal position, determine a time required to drive the firing member to the predetermined position, compare the determined time to a predetermined time, and set a motor velocity of the motor based on the comparison. In the closed-loop configuration, the control system is configured to drive the firing member at the set motor velocity.

Abstract: An apparatus includes an external body, a floor attached to the external body, an applicator pad, and a cover. The external body defines an internal cavity and extends between a bottom and top end. The applicator pad extends from the floor into the internal cavity defined by the external body. The applicator pad has an absorbent material that can absorb an electro-lubricant. The applicator pad is dimensioned to be grasped by a pair of jaws of a surgical instrument. The cover is associated with the top end of the external body and partially defines the internal cavity of the external body. The cover allows the pair of jaws to enter the internal cavity via the cover to grasp the applicator pad.

Abstract: In general, systems and methods described herein include active or passive sensing mechanisms, such as sensors, that can monitor at least one exposure condition of an adjunct and any medicant(s) retained therein. In some instances, the active or passive sensing mechanisms can also track the extent of the adjunct's and medicant(s)'s exposure, e.g., frequency, intensity, and/or duration).

Abstract: An apparatus includes an end effector and a drive system. The drive system is configured to drive a jaw closure assembly to provide the end effector in a first closed position. The drive system is further configured to operatively disengage the jaw closure assembly and operatively engage a firing assembly, then distally advance a firing member to actuate the end effector. The drive system is further configured to detect an initiation condition; and in response to detecting the initiation condition, operatively disengage the firing assembly and operatively re-engage the jaw closure assembly. The drive system is further configured to drive the jaw closure assembly to provide the end effector in a second closed position, then operatively disengage the jaw closure assembly and operatively re-engage the firing assembly. The drive system is further configured to distally advance the firing member further within the end effector to further actuate the end effector.

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

Abstract: The present disclosure provides a method for controlling a surgical instrument. The method includes connecting a power assembly to a control circuit, wherein the power assembly is configured to provide a source voltage, energizing, by the power assembly, a voltage boost convertor circuit configured to provide a set voltage greater than the source voltage, and energizing, by the voltage boost convertor, one or more voltage convertors configured to provide one or more operating voltages to one or more circuit components.

Abstract: A surgical instrument includes a body, a shaft, a motor, a firing assembly, an end effector, and a control circuit. The motor is activatable to actuate the firing assembly through a firing stroke to staple and sever tissue with the end effector. The control circuit is configured to monitor one or more use metrics of the surgical instrument. Responsive to at least one of the one or more use metrics exceeding a predetermined threshold, the control circuit is further configured to initiate at least one of providing a notification to a user or disabling the firing assembly.

Abstract: A modular surgical instrument system that comprises modular components and a control circuit electrically couplable to the modular components. The modular components comprise a shaft and a handle assembly. The handle assembly comprises a disposable outer housing. The disposable outer housing is movable between an open configuration and a closed configuration. The handle assembly further comprises a control inner core receivable inside the disposable outer housing in the open configuration. The disposable outer housing is configured to isolate the control inner core in the closed configuration. The modular components further comprise a loading unit releasably couplable to the shaft and a staple cartridge releasably couplable to an end effector. The loading unit comprises the end effector.

Abstract: A staple cartridge including a cartridge body and a first RFID feature. The cartridge body defines a longitudinal axis extending from a proximal end to a distal end of the cartridge body. The cartridge body is configured to be received within a jaw of a surgical stapler. The cartridge body also defines a plurality of staple apertures that are configured to house staples. The proximal portion of the cartridge body defines a pocket, and the pocket is proximal to a proximal most staple aperture of the plurality of staple apertures. The first RFID feature is fixed within the pocket. The first RFID feature is configured to communicate with a second RFID feature presented by the jaw of the surgical stapler.

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: Disclosed is a surgical instrument, comprising a shaft, an articulation joint extending distally from the shaft, and an end effector extending distally from the articulation joint. The end effector comprises a jaw, and a staple cartridge seatable in the jaw. The staple cartridge comprises a cartridge body, staples removably stored in the cartridge body, and a first antenna. The surgical instrument further comprises a remote power source configured to supply power, a second antenna configured to cooperate with the first antenna when the staple cartridge is seated in the jaw to transmit at least one of the power and a data signal to the staple cartridge, and a tuning electronics package located in a cavity in a proximal portion of the end effector. The tuning electronics package is configured to facilitate a locally tunable wireless transmission of the at least one of the power and the data signal.

Abstract: A surgical instrument comprising a firing drive and a bailout retraction system is disclosed.

Abstract: A surgical end effector includes a cartridge. The cartridge includes first and second sensor arrays disposed in the cartridge. The first sensor array is configured to sense a function of a first component located within the cartridge and the second sensor array is configured to sense a function of a second component located within the cartridge. The first and second sensor arrays are electrically coupled to an electronic circuit. The electronic circuit includes a control circuit configured to receive signal samples from the first sensor array, receive signal samples from the second sensor array, and process the signals samples received from the first and second sensor arrays to determine a status of the cartridge.

Abstract: A surgical stapler. The surgical stapler includes a drive system, an electric motor, a battery and a control system. The electric motor is mechanically coupled to the drive system. The battery is electrically couplable to the electric motor. The control system is electrically connected to the electric motor and includes an H-bridge circuit, an electrically resistive element and an electrically inductive element. The H-bridge circuit includes a high side and a low side. The low side of the H-bridge circuit includes first and second switching devices. The electrically resistive element is electrically connected in series with the first switching device. The electrically inductive element is electrically connected to the electrically resistive element. The control system is configured to control a force applied to the drive system based on a current downstream of the electrically resistive element.

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 surgical end effector includes a cartridge. The cartridge includes first and second sensor arrays disposed in the cartridge. The first sensor array is configured to sense a function of a first component located within the cartridge and the second sensor array is configured to sense a function of a second component located within the cartridge. The first and second sensor arrays are electrically coupled to an electronic circuit. The electronic circuit includes a control circuit configured to receive signal samples from the first sensor array, receive signal samples from the second sensor array, and process the signals samples received from the first and second sensor arrays to determine a status of the cartridge.

Abstract: A method of operating a surgical assembly is disclosed. The method includes receiving a first input from a first RFID scanner indicative of a first information stored in a first RFID chip of a first modular component of the surgical assembly, receiving a second input from a second RFID scanner indicative of a second information stored in a second RFID chip of a second modular component of the surgical assembly, determining an operational parameter of a motor of the surgical assembly based on the first input and the second input, and causing the motor to effect a tissue treatment motion of the first modular component.

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

Abstract: A surgical instrument system that comprises a shaft and a handle assembly releasably couplable to the shaft. The handle assembly comprises a disposable outer housing defining a sterile barrier. The disposable outer housing is movable between an open configuration and a closed configuration. The handle assembly further comprises a control inner core receivable inside the disposable outer housing in the open configuration. The disposable outer housing is configured to isolate the control inner core within the sterile barrier in the closed configuration. The surgical instrument system further comprises an end effector releasably couplable to the shaft and an electrical interface assembly configured to transmit data and power between the control inner core and the end effector. The electrical interface assembly comprises a first interface portion on a first side of the sterile barrier, and a second interface portion on a second side of the sterile barrier opposite the first side.