Provided is a temperature-controllable cryoablation system, comprising a catheter, a fluid-conveying unit and a control unit, wherein the catheter comprises a central cavity and a balloon located at the distal end of the catheter, and an input channel allowing a freezing fluid to be input into the balloon and an outflow channel allowing the freezing fluid to flow out of the balloon are provided in the central cavity; the fluid-conveying unit supplies the freezing fluid and discharges the freezing fluid; and the control unit controls the fluid-conveying unit so as to control, according to a target temperature value, the temperature of the balloon to be close to the target temperature value. When the cryoablation system works stably, the temperature of the balloon at the distal end of the catheter can be close to the target temperature value by controlling an input pressure of the freezing fluid, such that the operative risk is small, and a safer and more stable ablation mode is achieved when the same ablation depth is reached.

Aspects of the present disclosure are directed to an electronic switchbox for automatically switching between receive and transmit functionalities. In one embodiment, an electronic switchbox automatically switches between receiving electrocardiograph signals and transmitting cardioversion impulses.

A system for monitoring temperature when carrying out laser light-based lithotripsy in which includes an endoscopic assembly comprising a working channel for a fiber optic cable which is optically coupled to a laser on a proximal side and include a light exit aperture on a distal side, and an irrigation fluid channel opening into a region of the light exit aperture on the distal side which is in fluid communication with an irrigation fluid reservoir on the proximal side. The system includes a modular unit including a flow sensor, which determines the irrigation flow rate without coming into contact with the irrigation fluid; input, via which operating parameters of the laser can be determined, can be transmitted to a processor connected to the input; a temperature sensor which determines the temperature of the irrigation fluid without coming into contact with the irrigation fluid; an analyzer, which numerically determines the temperature of the irrigation fluid and the determined applied laser power, and the temperature generated intracorporeally during the laser lithotripsy at the location of the light exit aperture, and a comparator, which produces a signal in the event that a threshold value is exceeded.

A surgical instrument end effector assembly includes a first jaw member and a second jaw member. The second jaw member includes an ultrasonic blade body and first and second electrodes disposed on either side of the ultrasonic blade body and extending longitudinally along a majority of a length of the ultrasonic blade body. The ultrasonic blade body is adapted to receive ultrasonic energy from an ultrasonic waveguide. The first and second electrodes taper in width proximally to distally and are adapted to connect to a source of electrosurgical energy. The first jaw member is movable relative to the second jaw member between a spaced-apart position and an approximated position for grasping tissue therebetween.

An improved electrosurgical instrument, specifically a scissor style vessel sealer, comprising two overmoulded jaws formed from a structural polymer held in place by a pivot pin. The moulded structural polymer replaces many metal components which would otherwise be required for such an assembly. Not only does the use of the moulded structural polymer simplify the assembly of the instrument, it also enables the following additional functionality: moulded pivot holes, flanges providing lateral support, and a flexible lever arm which is designed to provide the force needed to clamp and seal vessels.

A surgical instrument is disclosed comprising an actuator and circuitry mounted on and/or embedded in the actuator.

An electrosurgical forceps includes a pair of first and second shaft members pivotably coupled to one another, an end effector assembly coupled to the pair of first and second shaft members, and a resilient, compressible pivot assembly pivotably coupling the first and second shaft members to one another.

A surgical device may include a housing configured for handling by a user and comprising a plurality of operator interfacing features. The device may also include a patient interfacing tip arranged at, or spaced apart from, a distal end of the housing and controllable by the operator interfacing features. The patient interfacing tip may include a pair of jaws configured to grasp tissue, an electrode on each jaw configured to seal tissue, and an articulating blade configured to cut tissue in a grasp of the pair of jaws. The device may also include an optical element extending from the housing to the patient interfacing tip and configured to emit laser energy to cut tissue, wherein the pair of jaws, electrode, and articulating blade are adapted for coarse cutting of tissue and the optical element is configured for precise cutting of tissue.

A surgical instrument includes a housing, energizable member, first activation switch, cable assembly, and second activation switch. The housing is operatively associated with the energizable member. The first activation switch is coupled to the energizable member and is selectively transitionable from an open condition to a closed condition. The cable assembly is coupled to the housing at a first end and includes a plug at a second, opposite end, the plug housing a second activation switch selectively transitionable from an open condition to a closed condition. The plug is adapted to connect to the source of electrosurgical energy, wherein transitioning of the first activation switch from the open condition to the closed condition transitions the second activation switch from the open condition to the closed condition such that the second activation switch communicates with the source of electrosurgical energy to initiate the supply of energy to the energizable member.

A treatment device for treatment of overactive bladder conditions operates to suction to grasp and conform a mucosal tissue of the bladder wall to a portion of the tissue treatment device, and deliver energy to non-superficial target tissue at a substantially uniform depth from the mucosal tissue. The tissue treatment device incorporates multiple instruments for different functions needed to treat overactive bladder conditions. The tissue treatment device provides simplified interfaces and mechanisms for operating each of the multiple instruments in a controlled manner. Further, the tissue treatment device is configured to have a low and smooth profile that permits the tissue treatment device to be used without a tubular sheath.