An apparatus includes a shaft assembly, an end effector, and a drive member visualization assembly. The end effector includes a first jaw, a second jaw, a staple cartridge, and a drive member capable of actuating along a firing stroke to fire a plurality of staples out of the staple cartridge or to sever tissue. The drive member visualization assembly provides an electronic indication linked to a physical location of the drive member within the upper jaw and the lower jaw during the firing stroke.

A surgical instrument includes a body, a shaft assembly, an end effector, a stapling assembly, and a restriction feature. The shaft assembly extends distally from the body. The end effector being on a distal end of the shaft assembly and incudes a first second jaw. The stapling assembly is supported by one of the first jaw or the second jaw. The stapling assembly includes a wedge sled. The wedge sled is configured to move relative to the one of the first jaw or the second jaw to drive movement of one or more staples. The restriction feature is configured to releasably hold the wedge sled in a predetermined position within the stapling assembly while the stapling assembly is in a pre-fired configuration. At least a portion of the restriction feature is configured to respond to movement of the edge sled to release the restriction feature from the wedge sled.

A surgical stapling instrument includes a shaft assembly, an end effector at a distal end of the shaft assembly and having a first jaw with an anvil and a second jaw operable to cooperate with the first jaw to clamp tissue, and a cartridge inserted into the second jaw. The cartridge includes staples, a movable member translatable distally during a firing stroke to discharge the staples into tissue, a first sensor assembly configured to monitor a first condition of the cartridge, and a second sensor assembly configured to monitor a second condition of the cartridge. A first processor is coupled with the first and second sensor assemblies and is configured to receive first and second signals from the sensor assemblies, respectively, where each signal is indicative of the respective condition of the cartridge. The first processor is configured to selectively permit or restrict the firing stroke based upon the signals.

A surgical stapling instrument includes a shaft assembly and an end effector. The end effector includes a first jaw having an anvil, and a second jaw. The instrument also includes a stapling assembly supported by the second jaw and including a plurality of staples, a staple actuator, and a driver assembly. The driver assembly includes a laterally-opposed pair of distal drivers that receive respective staples, a proximal driver that receives a respective staple, and a cam surface. The staple actuator is configured to engage the cam surface during distal translation of the staple actuator to drive the respective staples into contact with the anvil. The staple actuator and the cam surface are configured such that, when the respective staples contact the anvil, the engagement between the staple actuator and the cam surface is centered at a location along the cam surface distal of a centroid of the first driver assembly.

A surgical instrument includes a body, a shaft assembly, an end effector, an actuation assembly, and a bailout mechanism. The shaft assembly extends distally from the body. The end effector is disposed on a distal end of the shaft assembly and includes a first jaw and a second jaw. The actuation assembly includes a pusher member configured to move relative to the end effector to drive movement of the first jaw, the second jaw, or both the first jaw and the second jaw. The bailout mechanism includes a first elongate actuation element and a second elongate actuation element. A portion of the bailout mechanism is configured to selectively apply tension to the first elongate actuation element and the second elongate actuation element to move the pusher member. The first elongate actuation element is stronger in tension than the second elongate actuation element cable.

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.

A surgical stapling instrument includes a shaft assembly and an end effector. The end effector includes a first jaw having an anvil, a second jaw configured to removably receive a staple cartridge, and a driving assembly translatable distally through the second jaw for pivoting the second jaw toward the first jaw to clamp tissue between the first jaw and the second jaw. The instrument also includes a lockout mechanism configured to transition between a first state in which the lockout mechanism prevents distal translation of the driving assembly through the second jaw, and a second state in which the lockout mechanism permits distal translation of the driving assembly through the second jaw. The lockout mechanism is configured to transition from the first state to the second state when the staple cartridge is removably received by the second jaw.

A surgical instrument includes a shaft assembly, an end effector, a firing system, and a firing lockout assembly. The end effector is operatively coupled with the shaft assembly. The end effector includes first and second jaws. The first jaw includes an anvil. The second jaw is configured to removably receive an unspent staple cartridge. The firing system extends through at least a portion of the shaft assembly and the end effector. The firing lockout assembly is selectively coupled with the firing system. The firing lockout assembly is disposed proximal to the end effector. The firing lockout assembly is configured to allow actuation of the firing system in an unlocked configuration in response to the unspent staple cartridge being coupled with the second jaw; and inhibit actuation of the firing system in a locked configuration in response to the unspent staple cartridge being absent from the second jaw.

A method of operating a robotically controlled surgical instrument that includes an end effector, a driving assembly, and a lockout, the method includes inhibiting actuation of the driving assembly when the lockout is in a locked configuration in response to an unspent staple cartridge being absent from a first jaw of the end effector. The method also includes inserting the unspent staple cartridge into the first jaw of the end effector to switch the lockout to an unlocked configuration. The method also includes actuating the driving assembly to pivot the first jaw, which includes the staple cartridge, toward a second jaw of the end effector to at least one of staple or cut tissue with the end effector when the lockout is in the unlocked configuration.

A surgical stapling apparatus includes a housing assembly and an adapter assembly. The adapter assembly defines a longitudinal axis and is selectively attachable to the housing assembly. The adapter assembly includes an end effector and an articulation assembly. The articulation assembly includes an articulation drive screw, an articulation nut threadedly mounted to the articulation drive screw, an articulation yolk coupled to the articulation nut, and an articulation tube that is positioned to move in response to movement of the articulation nut. Movement of the articulation tube causes the end effector to articulate relative to the longitudinal axis.