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 an end effector and a system configured to feed staples into the end effector is disclosed.

A surgical instrument comprising a touchscreen display is disclosed.

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.

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.

Disclosed herein are various medical devices and related systems, including robotic and/or in vivo medical devices. Also disclosed are 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.

A method for operating a medical-robotic device is provided. The robotic device includes a number of components able to be moved autonomously in an environment of the robotic device. Planning data for an autonomous movement or constraint of at least one subset of the movable components is provided to the robotic device. A movement or constraint of the corresponding movable components to be carried out autonomously by the robotic device is planned based on the planning data provided. The planned movement or constraint is visually presented. A way for an operator to exert influence on the planned movement or constraint is provided, and the movement or constraint is autonomously carried out as a function of the influence exerted.

The embodiments relate to various medical device components, including components that are incorporated into robotic and/or in vivo medical devices. Certain embodiments include various modular medical devices for in vivo medical procedures.

A semi-autonomous robot system (10) that includes scanning and scanned data manipulation that is utilized for controlling remote operation of a robot system within an operating environment.

The invention relates to a robotic system for moving a shapeable instrument like a shapeable catheter within an object like a person. The system (1) comprises a robotic device (2, 3) for modifying the shape of the instrument (2) and moving the instrument within the object (7) and a control unit (4) for controlling the robotic device based on structure information like a roadmap, a target position and shape and an actual position and shape such that the instrument is moved and the shape of the instrument is modified from the actual position and shape to the target position and shape. Since the control unit considers structure information while controlling the robotic device, the navigation of the instrument can be automatically performed under consideration of knowledge about regions within the object, through which the instrument is navigatable. The navigation may therefore be performed without or with few user interactions only.