A surgical instrument with improved end-effector gripping force. The instrument comprises a shaft, which may be inserted into a body of a patient. The articulated end-effector is mounted on the distal extremity of the instrument shaft and comprises a plurality of links interconnected by a plurality of joints, whose movements are remotely actuated by the surgeon's hands. This remote actuation is accomplished through mechanical transmission, mainly along flexible elements, which are able to deliver motion from a set of actuation elements, placed at a proximal extremity of the shaft, to the instrument's articulated end-effector. The articulated end-effector further comprises one or more cam-and-follower mechanisms that are able to amplify the force transmitted by the flexible elements so that the actuation force at the instrument jaws is maximized and the tension on the transmission elements minimized, thus increasing the fatigue resistance and life of the instrument.

A stiffening device is disclosed that is adapted to cooperate with a flexible kidney stone extractor. The stiffening device includes a tube having a lumen sized to receive a part of flexible kidney stone extractor; a diversion member having a channel that is configured to receive a part of the flexible kidney stone extractor; and a connector coupled between the tube and the diversion member. The connector allows the channel of the diversion member to communicate with the lumen of the tube. A proximal portion of the connector is connected to the diversion member and a distal portion of the connector is connected to the tube.

A medical device includes a handle with a proximal arm and a distal arm. The proximal arm and the distal arm are pivotable via a joint. The medical device also includes a tube coupled to the distal arm and a drive wire. A distal portion of the drive wire includes an expandable end effector. A portion of the drive wire is positioned within the tube, and a different portion of the drive wire extends proximally of the distal arm and is coupled to the proximal arm.

A medical device includes a handle with a proximal arm and a distal arm. The proximal arm and the distal arm are pivotable via a joint. The medical device also includes a tube coupled to the distal arm and a drive wire. A distal portion of the drive wire includes an expandable end effector. A portion of the drive wire is positioned within the tube, and a different portion of the drive wire extends proximally of the distal arm and is coupled to the proximal arm.

An actuator handle for a hand-held surgical tool, the actuator handle comprising: a body part adapted to be gripped by a user's hand, the body part having an end effector mounted or mountable thereon; an actuating member alongside the body part and arranged to be operably moveable by a single finger of the said hand, in a substantially linear manner between first and second positions relative to the body part, for actuating the end effector in use; and one or more coupling components coupled to the actuating member, for mechanically transmitting motive force from the actuating member to the end effector upon movement of the actuating member between the first and second positions by the user in use. A surgical clip, for example for use in aneurysm clipping, is also provided, the clip comprising: first and second clipping arms that are mutually openable and closable; biasing means arranged to resiliently bias the first and second clipping arms into a closed configuration; and first and second engagement fixtures respectively coupled to the first and second clipping arms and arranged such that first and second gripping arms of a complementary surgical clip deployment tool can grip the clip and open the clipping arms by applying a lateral force to the first and second engagement fixtures; wherein each of the first and second engagement fixtures comprises at least part of a ball or at least part of a loop or cup, with which each of the arms of said surgical clip deployment tool can engage in a substantially ball-and-socket manner.

Particular embodiments disclosed herein provide a surgical instrument comprising a device having a proximal end and a functional end configured to be inserted into a body part, an assembly having a proximal end and a distal end, a shaft coupled to the proximal end of the assembly, the shaft having a shaft housing, a bearing positioned around the assembly, wherein the bearing is configured to slide over the assembly, a hub having a sleeve tube. The basket comprises a plurality of grooved levers, each grooved lever having a proximal end received by the shaft housing and a distal end coupled to a tip of the basket, wherein compressing one or more of the plurality of grooved levers moves the bearing and the hub relative to the shaft and toward the functional end of the device, causing the sleeve tube to transition the device from the deactivated state to an activated state.

An ultrasonic instrument includes a body, an actuation assembly, a shaft assembly, and an ultrasonic blade. The body defines a longitudinal axis and is configured to receive an ultrasonic transducer. The actuation assembly includes at least one annular activation member and at least one circuit. The at least one annular activation member extends angularly about the body along a 360 degree angular range. The at least one annular activation member is configured to move laterally relative to the longitudinal axis of the body. The at least one circuit corresponds to the at least one annular activation member. The shaft assembly includes an acoustic waveguide. The ultrasonic blade is in acoustic communication with the acoustic waveguide. The at least one activation circuit is configured to activate the ultrasonic blade in response to lateral movement of the activation member relative to the longitudinal axis of the body.

A surgical instrument with improved end-effector gripping force. The instrument comprises a shaft, which may be inserted into a body of a patient. The articulated end-effector is mounted on the distal extremity of the instrument shaft and comprises a plurality of links interconnected by a plurality of joints, whose movements are remotely actuated by the surgeon's hands. This remote actuation is accomplished through mechanical transmission, mainly along flexible elements, which are able to deliver motion from a set of actuation elements, placed at a proximal extremity of the shaft, to the instrument's articulated end-effector. The articulated end-effector further comprises one or more cam-and-follower mechanisms that are able to amplify the force transmitted by the flexible elements so that the actuation force at the instrument jaws is maximized and the tension on the transmission elements minimized, thus increasing the fatigue resistance and life of the instrument.

Surgical devices and methods are described herein that provide improved motor control and feedback, thereby combining advantages of manually-operated and powered surgical devices. In one embodiment, a surgical device includes a proximal handle portion that includes a motor, a distal end effector coupled to the handle portion, and a cutting element configured to cut tissue engaged by the end effector, wherein the motor is configured to supply power that moves the cutting element. The device also includes a motor control mechanism configured to cause the amount of the power to dynamically change in response to a manual user input when the cutting element is moving.

Particular embodiments disclosed herein provide a surgical instrument comprising a device having a functional end configured to be inserted into a body part, a shaft coupled to a proximal end of the device, and a shaft housing configured to receive a distal end of the shaft and operable to move along a central axis of the shaft. The surgical instrument further comprises a tube coupled to the distal end of the shaft housing and configured to partially house the device such that the functional end of the device at least partially extends beyond the distal end of the tube. The surgical instrument further comprises a plurality of arcuate levers such that pressing one or more of the plurality of arcuate levers moves the shaft housing and the tube toward the functional end of the device, causing the tube to transition the device from a deactivated state to an activated state.