A surgical stapler for stapling the tissue of a patient is disclosed. The surgical stapler comprises a handle, a shaft extending from the handle, and an end effector extending from the shaft, wherein the end effector comprises a plurality of staples and an anvil configured to deform the staples. The surgical stapler further comprises a firing mechanism configured to deploy the staples, a sensor configured to detect a target, a controller configured to calculate the firing path based on the target, and a motorized drive system configured to move the end effector toward the target along the firing path.

Systems and methods for designing and implementing patient-specific surgical procedures and/or medical devices are disclosed. In some embodiments, a method includes receiving a patient data set of a patient. The patient data set is compared to a plurality of reference patient data sets, wherein each of the plurality of reference patient data sets is associated with a corresponding reference patient. A subset of the plurality of reference patient data sets is selected based, at least partly, on similarity to the patient data set and treatment outcome of the corresponding reference patient. Based on the selected subset, at least one surgical procedure or medical device design for treating the patient is generated.

An apparatus, system and process for guiding a surgeon during a medical procedure to prevent surgical mistakes are described. The system may include a machine learning medical procedure server that generates one or more machine learning medical procedure models using, at least, medical procedure data captured during medical procedures performed at a plurality of different medical procedure systems. The system may also include a medical procedure system communicably coupled with the machine learning medical procedure server that receives a selected machine learning medical procedure model from the machine learning medical procedure server, and utilizes the selected machine learning medical procedure model during a corresponding medical procedure to control one or more operations of the medical procedure system.

A surgical instrument for treating the tissue of a patient is disclosed. The surgical instrument comprises a handle, a shaft extending from the handle, and an end effector. The surgical instrument further comprises a motorized drive system, a first drive system configured to perform a first end effector drive motion, wherein the first drive system is operably coupled to the motorized drive system, and a second drive system configured to perform a second end effector drive motion, wherein the second drive system is operably coupled to the motorized drive system. The surgical instrument further comprises synchronizing means for repetitively sequencing the first end effector drive motion and the second end effector drive motion.

A surgical instrument system is disclosed which comprises a control screen usable to control the surgical instrument system in real time.

A surgical stapler comprising stored or storable staple cartridges is disclosed. The staple cartridges can have different unfired sizes. In at least one instance, a first stored staple cartridge comprises first staples having a first unfired height and a second stored staple cartridge comprises second staples having a second unfired height which is different than the first unfired height.

A surgical instrument comprising a touchscreen display is disclosed.

Various medical devices and related systems, including robotic and/or in vivo medical devices, and various robotic surgical devices for in vivo medical procedures. Included herein, for example, is a robotic surgical system having a support beam positionable through an incision, and a robotic device having a device body, first and second rotating shoulder components coupled to the device body, and first and second robotic arms coupled to the first and second shoulder components, respectively.

The disclosure relates to a method for guiding position and orientation of a robotic device holding a surgical tool configured for working a planned region of an anatomical structure, the robotic device comprising a base and an actuation unit coupled to the base and configured to move the surgical tool relative to the base, the method comprising: providing a user interface displaying a virtual representation (1) of the anatomical structure and a virtual representation (2) of a target region on the anatomical structure; detecting a presence of a distal tip (3) of the tool in the target region; changing a visual aspect of the virtual representation (2) of the target region when the tool tip (3) is detected in said target region; based on the position of the target region, computing a virtual goal (4) defining a spatial range of position and orientation of the robotic device in which the tool is capable of working at least a determined part of the planned region of the anatomical structure; displaying the virtual goal (4) and a virtual representation of an axis of the base on the user interface, and changing position and orientation of said virtual representation of the base axis as a user changes position and orientation of the robotic device while maintaining the tool tip in the target area; changing a visual aspect of the virtual goal (4) when the virtual representation of the base axis is inside the virtual goal.

Simulated are postures each formed by a manipulator arm and a surgical instrument when a tip end portion of the surgical instrument is located at a three-dimensional position of each lattice point in a lattice model set so as to correspond to the manipulator arm, the surgical instrument being held by the manipulator arm. Extracted is such a combination of the lattice points in the lattice models that the postures interfere with each other. Data of the combination which causes the interference is stored in a storage portion. It is determined whether or not an operating command transferred to a control portion corresponds to the combination which causes the interference. When it is determined that the operating command corresponds to the combination which causes the interference, the control portion executes interference preventing processing.