An apparatus and method for medical procedures are provided. The apparatus includes a base, a member having first and second ends, and a support configured to support a plurality of robotic arms. Each robotic arm configured to support and position a robotic instrument according to multiple surgical degrees of freedom.

A device for assisting surgery includes means for offsetting a rotation of a first type and a second type, a mechanism for transmitting a rotation of a third type, and a mechanism for transforming the rotation of a third type into a translation. An elastic element is connected at one end to the mechanism for transmitting the rotation of a third type. The mechanism for transmitting the rotation of a third type is connected to a rotary motor, the rotation of the motor in a first direction causing the lowering of a tool and an elongation of the elastic element, the rotation of the motor in a second direction causing the raising of the tool and a contraction of the elastic element, and, when the tool is lowered and the rotary motor is not exerting any torque, the elastic element returns to an initial shape causing the raising of the tool.

A tool holder for use as a surgical assistant, the tool holder including: first and second beam members; a frame; at least one linkage member coupled to the frame and the first and second beam members; a mounting configuration to hold a tool, the mounting configuration being coupled to the first and second beam members; and a drive mechanism mounted with respect to the frame, wherein the at least one linkage member and the mounting configuration are coupled to the first and second beam members in a parallelogram configuration, the drive mechanism is configured to drive a tilt movement of the mounting configuration with respect to the frame by movement of the first beam member with respect to the second beam member to orient the mounting configuration to a tilt angle, and the drive mechanism is configured to drive a pan movement of the tool about a pan axis, the drive mechanism being further configured to orient the pan axis with respect to the frame dependent on the tilt angle.

A surgical instrument holding device includes first and second parallel links, a wiring member and a connector. The first parallel link has two first link portions arranged in parallel with each other, each having one end in an axial direction as a first end portion. The second parallel link has two second link portions arranged in parallel with each other, each having one end in an axial direction as a second end portion. The wiring member is disposed along the parallel links. The connector has two first link supporters by which the respective first end portions are rotatably supported, two second link supporters by which the respective second end portions are rotatably supported, a first wiring supporter that supports the wiring member on a part between the two first link supporters, and a second wiring supporter that supports the wiring member on a part between the two second link supporters.

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.

A driving device includes a corrector, an actuator, and a position sensor. The actuator includes a nut connected to a movable part, a ball screw shaft onto which the nut is screwed, and a pulse motor that drives to rotate the ball screw shaft. The corrector includes a correction amount map in which a position correction amount for calibrating a predictable error is mapped for each position of the movable part. The corrector estimates an ideal movement position to which the movable part moves based on a command signal and refers to the correction amount map to calculate the position correction amount corresponding to a present position detected by the position sensor. The corrector generates a correction signal by correcting the command signal so as to reduce the difference between a corrected present position obtained by correcting the present position by the position correction amount and the ideal movement position.

A medical device is provided. The medical device includes a parallel manipulator. The parallel manipulator has an end platform coupled to a surgical tool and a base platform coupled to a machine module. The machine module is coupled to the surgical tool through a transmission shaft disposed between the end platform and the base platform. The transmission shaft has a transmission yoke, a runner, a first rod coupled to the transmission yoke, a second rod coupled to the runner, and a universal joint coupled between the first rod and the second rod.

Apparatus and methods are described including a robotic system configured for performing intraocular surgery. During a training stage, a computer processor receives programming instructions for performing one or more steps of cataract surgery in an automated manner, based upon standard ranges of dimensions of respective portions of a human eye. During a subsequent stage, the computer processor drives the robotic system to perform the one or more steps of cataract surgery on an eye of a given patient, by receiving at least one image of the eye, determining one or more dimensions of the eye from the at least one image, and performing the one or more steps of cataract surgery based upon the programming instructions and the determined dimensions of the eye. Other applications are also described.

A surgical stapling system for treating tissue of a patient is disclosed. The surgical stapling system comprises an end effector, a firing member, a motor, a RF transceiver configured to transmit RF signals, and a sensing array. The end effector comprises an elongate channel, an anvil rotatable relative to the elongate channel from an open position toward a closed position, and a staple cartridge removably positioned in the elongate channel. The staple cartridge comprises a plurality of staples removably stored therein. The firing member is movable between an unfired position and a fired position. The staples are deployed from the staple cartridge based on the firing member being moved toward the fired position. The motor is configured to drive the firing member toward the fired position. The sensing array is configured to sense compression of the tissue, properties of the tissue, and a presence of metallic elements within the tissue.

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.