In some embodiments, an insertion device for a single port robotic surgery apparatus includes a plurality of instrument channels positioned in an interior of a housing and extending along substantially an entire length of the housing, the plurality of instrument channels configured to removably house a plurality of surgical instruments, a plurality of openings in a rear exterior surface of the housing, the plurality of openings providing access to the plurality of instrument channels and configured to facilitate insertion of the plurality of surgical instruments into the plurality of instrument channels, and an illumination device supported at least partially at the rear exterior surface of the housing and positioned proximal to the plurality of openings, the illumination device configured to illuminate the openings to facilitate insertion of the plurality of instruments through the plurality of openings.

Graphical user guidance for a robotic surgical system is provided. In one embodiment, a graphical user interface for a robotic surgical system comprises a first region and a second region. The first region is used to display an endoscopic view of a surgical site inside a patient taken by an endoscopic camera of the robotic surgical system, and the second region is used to display user feedback information. The graphical user interface overlays a guidance message on top of the endoscopic view of the surgical site in the first region to provide user instructions for interacting with a user input device to engage a robotic arm of the robotic surgical system. Other embodiments are provided.

An automatic control method of a mechanical arm and an automatic control system are provided. The automatic control method includes the following steps: obtaining a color image and depth information corresponding to the color image through a depth camera; performing image space cutting processing and image rotation processing according to the color image and the depth information to generate a plurality of depth images; inputting the depth images into an environmental image recognition module such that the environmental image recognition module outputs a displacement coordinate parameter; and outputting the displacement coordinate parameter to a mechanical arm control module such that the mechanical arm control module controls the mechanical arm to move according to the displacement coordinate parameter.

A surgical instrument may comprise an elongated shaft extending between a proximal end and a distal end and defining a longitudinal axis. The surgical instrument may also comprise a plurality of cables extending along the longitudinal axis and a first bending section positioned between the proximal end and the distal end of the elongated shaft. The first bending section may comprise links having pairs of articulation holes extending longitudinally through the links to permit the plurality of pull wires to pass therethrough. Each pair of articulation holes may comprise first and second articulation holes that are spaced apart from the longitudinal axis (i) at different radii and (ii) at a same rotation angle.

Certain aspects relate to systems and techniques for surgical robotic arm setup. In one aspect, there is provided a system including a first robotic arm configured to manipulate a medical instrument, a processor, and a memory. The processor may be configured to: determine a minimum stroke length of the first robotic arm that allows advancing of the medical instrument by the first robotic arm to reach a target region from an access point via a path, determine a boundary for an initial pose of the first robotic arm based on the minimum stroke length and a mapping stored in the memory, and during an arm setup phase prior to performing a procedure, provide an indication of the boundary during movement of the first robotic arm.

A medical device having a force transmission mechanism that includes a chassis having a pivotal support that defines a first axis. An axle is supported by the pivotal support and is free to rotate around the first axis of rotation. The axle defines a second axis of rotation perpendicular to the first axis of rotation. A first control arm is coupled to a first end of the axle and is free to rotate around the second axis of rotation. A second control arm is coupled to an opposite second end of the axle and is free to rotate around the second axis of rotation independently of the first control arm. A distal component is coupled to an elongate tube that is coupled to the chassis. Four drive elements coupled to the control arms control motion of the distal component. In one implementation, the medical device is a teleoperated surgical instrument.

The invention relates to a support arm articulation device (50) for movably holding a medical device, comprising a first and a second fastening element (52, 54), which are connected to each other in a pivotable way by means of a spring arm (56), wherein the spring arm (56) comprises a supporting arm (58) and a lever arm (60), which are mounted in a pivotable way on the first fastening element (52) with an associated supporting arm pivot axis (64) and lever arm pivot axis (66), wherein the two pivot axes (64, 66) are spaced apart from one another, wherein the supporting arm (58) is mounted on the second fastening element (44) in a pivotable way, and the lever arm (60) is mounted on the supporting arm (58) by means of a spring device (78) such that a weight of the held medical device is supported in different pivot positions, wherein the spring device (78) comprises an adjustment device, by means of which a position of the mounting (68, 70) of the lever arm (60) on the supporting arm (58) is adjustable along a longitudinal extension of the supporting arm (58). Further, the invention relates to a support arm system and a method for operating a support arm articulation device.

A user interface for a surgical robotic system includes a plurality of handles, each removably attachable to a user interface assembly by a quick release connector. The selection of handles can include handles of varying size, degree of complexity, handles adapted for laparoscopic motion, handles adapted for true cartesian motion or handles customized to surgeon anthropometric data, etc.

Surgical kit inspection systems and methods are provided for inspecting surgical kits having parts of different types. The surgical kit inspection system comprises a vision unit including a first camera unit and a second camera unit to capture images of parts of a first type and a second type in each kit and to capture images of loose parts from each kit that are placed on a light surface. A robot supports the vision unit to move the first and second camera units relative to the parts in each surgical kit. One or more controllers obtain unique inspection instructions for each of the surgical kits to control inspection of each of the surgical kits and control movement of the robot and the vision unit accordingly to provide output indicating inspection results for each of the surgical kits.

A surgical end effector assembly is disclosed. The surgical end effector assembly comprises a shaft, an end effector comprising a first jaw and a second jaw movable relative to the first jaw, and an articulation joint attaching the end effector to the shaft, wherein the articulation joint defines an articulation axis about which said end effector is articulatable relative to the shaft. The articulation joint comprises a first rotary drive member rotatable about the articulation axis and a second rotary drive member rotatable about the articulation axis, wherein the first rotary drive member and the second rotary drive member are rotatable in the same direction to articulate the end effector about the articulation axis. The surgical end effector assembly further comprises a jaw drive output cooperatively driven by the first rotary drive member and the second rotary drive member configured to clamp and unclamp tissue with the second jaw.