A surgical stapling device includes a reload assembly that include at least one locking tab to retain a knife carrier of the reload assembly in a retracted position after the stapling device is fired. The at least one locking tab is disposed on the knife carrier and is configured to engage a stop surface of a staple actuator to prevent readvacement of the knife carrier relative to the staple actuator.

A surgical staple has two movable arms connected by a transverse connection area. Each one of the arms has a pinching area and a fastening end and the transverse connection area is deformable to allow the movable arms to be moved together by bending around the axis of the transverse connection area.

Inserters for dynamic implants include hooks that engage connecting means of the implants and rams that press against bridges of the implants when the inserters are actuated.

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.

A device for connecting body tissues has a head part, which can be pushed into a body opening and has a longitudinal axis, wherein tissue staples are accommodated in the head part in a storage position. The tissue staples have a linear main section and two engagement sections projecting perpendicularly therefrom aligned in a first plane perpendicular to the longitudinal axis. Optimal usability in the human body is achieved by rotor elements, which are pivotable about an axis parallel to the main sections of the tissue staples with each have a bearing surface for an engagement section of a tissue staple to rotate said tissue staple from the storage position into a working position in which the tissue staple is arranged in a further plane oriented perpendicularly to the first plane, and in that a slider is provided to advance the tissue staple and deform it into a clamping position.

A surgical instrument for treating the tissue of a patient is disclosed. The surgical instrument comprises a housing including a handle, a housing frame comprising a housing connector, and a drive system comprising at least one electric motor. The surgical instrument further comprises a shaft assembly releasably assembled to the housing including a shaft frame comprising a proximal connector and a distal connector, wherein the proximal connector is releasably coupled to the housing connector and a shaft drive system comprising at least one rotatable shaft operably coupled to the electric motor. The surgical instrument further comprises an end effector releasably assembled to the shaft assembly including an end effector frame comprising an end effector connector releasably coupled to the distal connector of the shaft assembly, a plurality of staple cartridges removably stored in the end effector, and a plurality of end effector drivers operably coupled to the rotatable shaft.

A staple cartridge is disclosed. The staple cartridge can comprise a cartridge body comprising a deck and a bottom surface opposite the deck. The staple cartridge can comprise a plurality of staple cavities, wherein each staple cavity extends into the cartridge body from the deck to the bottom surface. Additionally, a plurality of wells can be defined into the staple cartridge from the deck to a lowermost surface of the well. A plurality of staples can be removably positioned in the staple cavities. The staple cartridge can comprise a tissue thickness compensator releasably secured to the cartridge body, wherein the tissue thickness compensator comprises a compensator body and a plurality of extensions extending from the compensator body into the wells, wherein at least one extension is compressed within one of the wells. Each well can surround at least one staple cavity and/or can extend between at least two staple cavities.

Systems and methods for stapling tissue during surgery are provided. In one exemplary embodiment, a surgical stapling system is provided that includes a staple shaft assembly having a staple advancing and forming assembly and a shaft with a plurality of staples, a drive system operably coupled to the staple shaft assembly and operably coupled to at least one motor, and a control system. The drive system can have a plurality of stages of operation that drive the staple advancing and forming assembly to form a staple around tissue. The control system can be configured to actuate the at least one motor to drive the drive system and thereby control movement of the staple advancing and forming assembly and to modify a force applied to the drive system by the at least one motor during at least one stage of operation based on at least one predetermined threshold.

A surgical instrument including an end effector that has a selectively reciprocatable implement movably supported therein. The implement is selectively advanceable in a distal direction upon application of a rotary actuation motion thereto and retractable in a proximal direction upon application of a rotary retraction motion thereto. An elongate shaft assembly is coupled to the end effector and is configured to transmit the rotary actuation motion and rotary retraction motion to the reciprocatable implement from a robotic system that is configured to generate the rotary actuation motion and said rotary retraction motion.

Devices and methods for acquiring and fastening tissues folds within an internal organ, such as the stomach, and for applying the methods and devices to producing reductions in organ volume or repair of bariatric procedures, are disclosed. An exemplary method for forming a continuous laterally extending tissue fold involves forming a succession of laterally extending folds having adjacent overlapping fold portions. One exemplary tissue-acquisition device has an open-end roller-and-arm structure that allows individual tissue folds to be formed and fastened, then advanced to an adjacent region within the stomach, for capture of a new fold that will form an extension of the existing fold(s).