Abstract: A surgical stapling instrument includes an anvil defining a plurality of staple forming pockets and a stapling head assembly. The stapling head assembly includes a body, a coupling member capable of actuating the anvil relative to the body, a staple deck defining a plurality of staple openings, and a firing assembly capable of driving a plurality of staples against the staple forming pockets of the anvil. The firing assembly includes a proximal driving body and an array of discrete staple driving segments positioned distal to the proximal driving body. The proximal driving body is slidably housed within the body. The staple driving segments each have a free proximal end. The proximal driving body is capable of simultaneously actuating the array of staple driving segments to drive the plurality of staples against the staple forming pockets of the anvil.

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: In general, devices, systems, and methods for control of one visualization with another are provided.

Abstract: In general, devices, systems, and methods for control of one visualization with another are provided.

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

Abstract: A surgical stapling instrument includes an anvil defining a plurality of staple forming pockets, and a stapling head assembly, and a retracting assembly. The stapling head assembly includes a body, a coupling member capable of actuating the anvil, a deck surface, a staple driver assembly, and a knife member. The staple driver assembly actuates through a first firing stroke and a second firing stroke. In the first firing stroke, the staple driver assembly drives a plurality of staples against the staple forming pockets. In the second firing stroke, the staple driver actuates distally past the deck surface. The knife member includes a cutting edge that can sever tissue during the first firing stroke while remaining in a retracted position that is proximal relative to the staple deck surface during the second firing stroke. The retracting assembly can drive the knife member into the retracted position during the first firing stroke.

Abstract: In general, devices, systems, and methods for control of one visualization with another are provided.

Abstract: In general, devices, systems, and methods for multi-source imaging are provided.

Abstract: 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.

Abstract: 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.

Abstract: 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.

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 includes a body, a shaft assembly, an end effector, a stapling assembly, and a drive system. 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 stapling assembly is supported by one of the first jaw or the second jaw of the end effector. The drive system includes a shift mechanism configured to selectively modify a mechanical advantage of a drive input driven by a motor and used to power one or more functions associated with operation of the end effector.

Abstract: An apparatus includes an end effector, a motor, and a processing unit. The processing unit is configured to activate the motor to distally advance a firing member within a body of the end effector. The processing unit is further configured to detect an initiation condition. In response to detecting the initiation condition, the processing unit is configured to activate an algorithmic bumping mode. The bumping mode includes activating the motor to advance the firing member distally with a first plurality starting and stopping motions at a first rate and a first power level. The bumping mode further includes activating the motor to retract the firing member proximally with a second plurality of starting and stopping motions at a second rate and a second power level. The first rate is different than the second rate. The first power level is different than the second power level.

Abstract: A surgical instrument includes a shaft assembly, an end effector, a driving assembly, at least one motor, and a motor controller. The at least one motor is configured to actuate the driving assembly to deploy staples. The motor controller is in communication with the motor. The motor controller is configured to determine whether values of first and second trigger variables exceed predetermined thresholds. The motor controller is configured to modify at least one motor control parameter in response to determining that the values of the first and second trigger variables exceed the predetermined thresholds. The motor control parameters include a motion profile instituted by the motor controller for the motor, a waiting period during which power to the motor is reduced or stopped, or the predetermined threshold relating to current or force for proximal retraction to be different from the predetermined threshold relating to current or force for distal advancement.

Abstract: Examples described herein may include a surgical power device to balance power needs. The surgical power device may determine a first power expectation associated with a first surgical module, a second power expectation associated with a second surgical module, and an available amount of operating room power within an operating room; determine a power budget for the first surgical module and the second surgical module based on the available amount of operating room power, the first power expectation, and the second power expectation; and control the power distribution unit, based on the power budget, to a set a first portion and a second portion of the operating room power supplied to the power distribution unit.

Abstract: Examples described herein may include a surgical computing device that directs data communications to surgical networks. The surgical computing device may include a processor that is configured to determine a present network locus, wherein the present network locus is any of a first surgical network or a second surgical network; identify a data communications session; determine a surgical data type of the data communication session, wherein the surgical data type is any of a first type of surgical data or a second type of surgical data, and direct the data communications session to the first surgical network if the surgical data type is the first type of surgical data or to the second surgical network if the surgical data type is the second type of surgical data.

Abstract: A device may classify data associated with a surgical event of a surgery. The device may generate a third surgical data stream based on a mode of interaction between a first surgical data stream and a second surgical data stream. The device may determine a third classification parameter for the third surgical data stream based on a first classification parameter associated with the first surgical data stream, a second classification parameter associated with the second surgical data stream, and the mode of interaction between the first surgical data stream and the second surgical data stream. The device may determine a data handling scheme for the third surgical data stream based on the third classification parameter in consistency with a healthcare data policy. The device may handle the third surgical data stream according to the data handling scheme.

Abstract: Examples described herein may include a surgical computing device that directs data communications to surgical networks. The surgical computing device may include a processor that is configured to determine a present network locus, wherein the present network locus is any of a first surgical network or a second surgical network; identify a data communications session; determine a surgical data type of the data communication session, wherein the surgical data type is any of a first type of surgical data or a second type of surgical data, and direct the data communications session to the first surgical network if the surgical data type is the first type of surgical data or to the second surgical network if the surgical data type is the second type of surgical data.

Abstract: Systems, methods, and instrumentalities are disclosed for data processing and creating a record of the processing for archival in metadata associated with the results of the processing. The processing may include transformations of the data. Transforming the data may generate transformed data. The processes performed may be archived, for example, in metadata associated with the transformed data. The metadata may be annotated with information associated with previous transforms performed on the transformed data. The metadata may be stored with the transformed data.