In one embodiment of the invention, a link of a counter balanced arm is disclosed including, a hollow housing with a cylindrical cavity having an open end and a closed end with a small opening to allow cables to pass through; a first pivotal joint near the closed end of the hollow housing; a second pivotal join near the open end of the hollow housing; a compressible spring assembly received through the open end by the cylindrical cavity of the hollow housing; and a plug coupled to the open end of the cylindrical cavity of the hollow housing.

A device (100) for measuring pose and/or motion of an operator's hand (1) comprising: a first link (10) being adapted to be fixedly held and the distal end (12) being coupled to a second link (20) so as to allow a rotation motion there between about a first axis (15); the second link (20) being coupled to a third link (30) so as to allow a rotation motion there between about a second axis (25), the second axis (25) being substantially perpendicular to the first axis (15); the first edge (41) of the parallelogram linkage (40) being coupled to the third link (30); the second edge (42) of the parallelogram linkage (40) being coupled to a fourth link (50); the fourth link (50) being coupled to a fifth link (60), a distal end (62) thereof being coupled to a sixth link (70); and a grasper (80) being operably coupled to the sixth link (70).

A surgical cutting and fastening instrument comprises an end effector that has a shaft coupled thereto that is coupled to a robotic system. A tool mounting portion includes an electric, DC motor connected to a drive train in the shaft for powering the drive train. A power pack that comprises at least one charge-accumulating device connected to the DC motor for powering the DC motor is provided.

An apparatus and method for medical procedures are provided. The apparatus includes a base, a member having first and second ends, and a curved support configured to support a robotic arm. The method involves adjusting a member to position a curved support configured to support a robotic arm, positioning the robotic arm at a location on the curved support, and adjusting the robotic arm in accordance with a non-surgical adjustment such that the robotic instrument is within range of a target area.

A manipulator with two degrees of freedom and a surgical robot pivot a lower arm support under the driving of a second transmission structure so that a telescopic motion will be achieved with respect to a remote-center-of-motion (RCM); pivot a middle arm support under the driving of a first transmission structure and pivot an instrument assembly in the same way under the action of a first flexible member so that a pivoting motion will be achieved around the RCM. Therefore, the manipulator with two degrees of freedom is achieved.

Systems and methods are provided for autonomous robotic surgery which is preferably integrated with autonomous-assisted intraoperative real-time single modality and/or multi-modality fusion imaging/electrophysiological diagnostics. The robotic surgery systems and methods can be integrated with autonomous-assisted intraoperative body/limb positioning, and integrated with autonomous-assisted land and unmanned aerial vehicular patient transportation.

A medical observation apparatus includes: a camera configured to capture an object image of an observation target; a support configured to support the camera so as to be rotatable about a plurality of mutually-different shafts; a memory configured to store the position of the camera; a brake configured to switch between: a permission state for permitting the camera to rotate about at least one of the plurality of shafts; and a restriction state for restricting the rotation; and a controller configured to perform a reproduction process for switching the brake to the permission state, and thereafter switching the brake from the permission state to the restriction state when the support is operated according to an external force applied to the support by an operator and the camera is located at the position of the camera stored in the memory.

The various inventions relate to robotic surgical devices, consoles for operating such surgical devices, operating theaters in which the various devices can be used, insertion systems for inserting and using the surgical devices, and related methods.

A robotic arm includes a first driving source and a second driving source mounted on a base frame, a first transmission link driven by the first driving source to turn around a first axis, a second transmission link driven by the second driving source to turn around a second axis that is parallel to the first axis, a third transmission link pivoted to the first transmission link, a first driven link pivoted to the second transmission link, a second driven link pivotally coupled between the first driven link and the base frame, a third driven link pivotally connected with the first and second driven link, and a fourth driven link pivotally coupled between the third driven link and the third transmission link. Thus, the robotic arm of the invention has a compact size and can achieve multi-degree of freedom motion.

In one embodiment, a surgical rigid arm (100, 150, 200, 900) includes a first portion (102, 152, 202, 902), a second portion (103, 153, 203, 903) and a central portion (105, 154, 205, 906), where the central portion is extends between the first and second portions. A first end of the first portion and a second end of the second portion are each attached to a peripheral side (14) of a surgical bed (10, 30) such that the first portion and the second portion extend from the surgical bed in a first direction. The central portion extends substantially horizontally and is positioned over the surgical bed, the central portion being connected to the surgical instrument such that a load from the surgical instrument is distributed across the central portion to the first portion and second portion to provide rigid support for the surgical instrument.