A surgical staple cartridge assembly that comprises an anvil, a staple cartridge jaw, a longitudinal knife channel, a first longitudinal row of staple pockets comprising a first distal end staple pocket, a second longitudinal row of staple pockets comprising a second distal end staple pocket, a third longitudinal row of staple pockets, staples removably positioned within the staple pockets, a staple driver, and a firing member is disclosed. The staple driver is configured to drive a first distal staple out of the first distal end staple pocket and a second distal staple out of the second distal end staple pocket and, in cooperation with the anvil, deform the first distal staple to a first fired height and the second distal staple to a second fired height. The firing member comprising a first portion configured to engage the anvil and a second portion configured to engage the staple cartridge jaw.

A replaceable staple cartridge comprising a cartridge body, staples, and a staple cartridge tray secured to the staple cartridge body is disclosed. The cartridge body comprises a first longitudinal slot, a deck, and first sides extending downwardly from the deck, wherein an edge is defined between each first side and the deck. The cartridge body further comprises staple cavities defined in said deck and recesses defined in the deck proximal to the staple cavities. The staple cartridge tray comprises a bottom comprising a second longitudinal slot defined therein and second sides extending upwardly from the bottom, wherein each second side comprises a proximal end including a projection, wherein each second side is adjacent to a first side, and wherein each projection wraps around an edge and extends downwardly into a recess defined in the deck.

A motor-driven surgical cutting and fastening instrument that comprises an end effector, an electric motor, and a motor control circuit. The motor control circuit is for monitoring a parameter of the electric motor that is indicative of movement of a moveable member of the end effector, and for adjustably controlling the electric motor based on the monitored parameter to thereby adjustably control movement of the moveable member of the end effector during forward rotation of the electric motor.

A tool assembly for leak resistant dissection of tissue includes an anvil and a cartridge housing a plurality of staples. The anvil and cartridge have a linear longitudinal portion and a transverse portion positioned distally of the longitudinal portion. The linear longitudinal portion of the cartridge and anvil assemblies is substantially longer than the curved distal portion. In use, when a surgical procedure is performed that requires a plurality of cutting operations, e.g., a gastrectomy procedure, the first cutting operation is performed to form a substantially linear cut line having a curved distal portion that curves towards a specimen side of the organ, e.g., the stomach. In each subsequent cutting operation, the proximal portion of the tool assembly is positioned with the existing cut line such that a termination point of the existing cut line is positioned on the specimen side of the tissue or organ being partially removed.

A fastener cartridge can comprise a support portion, a tissue thickness compensator positioned relative to the support portion, and a plurality of fasteners positioned within the support portion and/or the tissue thickness compensator which can be utilized to fasten tissue. In use, the fastener cartridge can be positioned in a first jaw of a surgical fastening device, wherein a second jaw, or anvil, can be positioned opposite the first jaw. To deploy the fasteners, a staple-deploying member is advanced through the fastener cartridge to move the fasteners toward the anvil. As the fasteners are deployed, the fasteners can capture at least a portion of the tissue thickness compensator therein along with at least a portion of the tissue being fastened.

A surgical instrument is disclosed. The surgical instrument can include a first jaw, a second jaw, and a jaw closure lockout system. The first jaw can comprise a pivot pin slot and a slide pin slot. The second jaw can comprise an anvil and, in addition, a mounting portion comprising a pivot pin, which can be movably positioned in the pivot pin slot. A shiftable guide can be movably positioned in the first jaw and can comprise a body and a barrier wall. The body can comprise a slide pin movably positioned in the slide pin slot. The barrier wall can be aligned with a portion of the pivot pin slot when the slide pin is positioned within a range of positions in the slide pin slot, and the barrier wall can be offset from the pivot pin slot when the slide pin is positioned outside the range of positions.

The present disclosure relates to surgical fastener applying apparatus and the application of variable compression to tissue. More specifically, the presently disclosed surgical fastener applying apparatus act to limit the flow of blood through tissue immediately adjacent a cut-line formed therein to effectuate hemostasis, while maximizing the flow of blood through tissue more removed from the cut-line to limit unnecessary necrosis. In one embodiment, a surgical fastener applying apparatus is disclosed having a tool assembly coupled to a distal end thereof with first and second jaws respectively including an anvil and a surgical fastener cartridge. The surgical fastener cartridge includes, among other things, angled pushers that engage surgical fasteners of varying lengths.

A surgical stapling apparatus includes a tool assembly, at least one surgical buttress, and a resilient, porous material. The tool assembly includes a cartridge assembly and an anvil assembly pivotably coupled to the cartridge assembly. The cartridge assembly includes a first tissue facing surface defining staple retaining slots. The anvil assembly includes a second tissue facing surface defining staple pockets for forming staples expelled from the staple retaining slots of the cartridge assembly. The at least one surgical buttress is releasably disposed on at least one of the first and second tissue facing surfaces. The resilient, porous material is releasably disposable between the first and second tissue facing surfaces and in contact with the at least one surgical buttress. The resilient, porous material is configured to expel a liquid therefrom upon compression thereof by an approximation of the cartridge assembly and the anvil assembly.

A surgical stapling apparatus is disclosed which comprises cartridge body and a layer. The layer is implantable against tissue by staples deployed from the cartridge body and deformed by an anvil. The cartridge and the layer comprise co-operating features which reduce relative movement between the cartridge and the layer. Such co-operating features can also releasably retain the layer to the cartridge body. In addition to or in lieu of the above, the anvil and the layer comprise co-operating features which reduce relative movement between the anvil and the layer. Such co-operating features can also releasably retain the layer to the anvil. In certain instances, the layer can be positioned against the anvil, but releasably attached to the cartridge. The layer can comprise buttress material and/or a tissue thickness compensator, for example.

An end effector for a surgical fastening device is provided. The end effector includes a body defining a longitudinal axis, one or more fasteners, an anvil, and a pusher. Each fastener has an unformed configuration and a formed configuration. Each fastener includes first and second arms that extend in opposite directions. The first arm has first and second elbow segments. The first elbow segment is configured to bend as the fastener is formed. The second elbow segment is configured to remain unbent as the fastener is formed. The pusher is configured to advance the fastener distally through the body and into engagement with the anvil to form the fastener against the anvil.