A device and a method for coagulation and/or dissection of biological tissue is disclosed. The device comprises an apparatus and an instrument electrically connected thereto. The instrument includes an operation circuit with a manually operated switch. An evaluation circuit of the apparatus provides an evaluation signal for the instrument. The apparatus can create a supply voltage or a supply current for the instrument. In the initial condition the evaluation signal comprises only one polarity. The evaluation signal is provided to a control circuit of the instrument in which a characteristic of the evaluation signal is adjusted depending on the operating condition of the switch. The evaluation circuit detects this characteristic and initiates the output of the supply voltage and changes the polarity of the evaluation signal according to the requested cutting mode. In the cutting mode the evaluation signal comprises at least temporarily also a second polarity.

An electrosurgical system is disclosed, including an electrosurgical generator and an electrosurgical instrument which is or can be connected to the electrosurgical generator, wherein the electrosurgical instrument comprises at least a first activation element and a second activation element and the electrosurgical generator is configured to, on actuation of the first activation element, deliver an electrosurgical therapy signal having a first signal shape to the electrosurgical instrument, and, on actuation of the second activation element, deliver an electrosurgical therapy signal having a second signal shape. The system is characterized in that the first signal shape and the second signal shape are identical, and in that the electrosurgical generator is further configured to only perform success monitoring of a tissue effect achieved by the electrosurgical therapy signal on actuation of the first activation element.

A surgical cautery device includes a voltage generator, a controller, forceps, an actuator, and a receiver. The voltage generator is configured to be electrically connected to a power source. The forceps are electrically coupled to the voltage generator and configured to cauterize tissue. The actuator is configured to generate and wirelessly transmit an on/off signal. The receiver is operable to wirelessly receive the on/off signal. The controller controls power to the voltage generator from the power source in response to the on/off signal.

A surgical instrument includes a body, an ultrasonic blade, a clamp arm, and a resilient member. The body includes an electrical conductor and defines a longitudinal axis. The clamp arm is pivotably coupled with the body at a pivot assembly. The clamp arm is operable to compress tissue against the ultrasonic blade. The clamp arm includes an electrode operable to apply RF energy to tissue, wherein the clamp arm is configured to be loaded onto and removed from the body at the pivot assembly along a path that is transverse to the longitudinal axis defined by the body. The resilient member is located within the pivot assembly. The resilient member is configured to provide electrical continuity between the electrode of the clamp arm and the electrical conductor of the body.

In accordance with aspects of the present disclosure, an adaptor assembly includes a plug, a selector assembly, and a connector. The plug is coupled to an electrosurgical generator and is configured to receive electrosurgical energy from the electrosurgical generator. The selector assembly includes a first position and a second position. The first position is configured to indicate a first setting of the electrosurgical generator. The second position is configured to indicate a second setting of the electrosurgical generator. The selector assembly, when actuated, indicates the selected position to the electrosurgical generator to initiate the corresponding setting. The connector is configured to couple to a surgical instrument and convey the electrosurgical energy to the surgical instrument. The electrosurgical energy, when based on the first setting, is different from the electrosurgical energy, when based on the second setting.

A surgical system comprising a surgical hub, a surgical instrument, a generator configured to energize an end effector; and a smoke evacuation system configured to remove smoke from a surgical site is disclosed. The surgical instrument comprises the end effector. A control command is passed directly from the surgical hub to the surgical instrument. The surgical instrument is configured to pass the control command received from the surgical hub to the generator and the smoke evacuation system in a daisy-chain manner.

A surgical system comprising a surgical instrument, a generator configured to supply power to an end effector, and a processor configured to run a control program to operate the surgical system is disclosed. The surgical instrument comprises the end effector which includes a first jaw and a second jaw. At least one of the first jaw and the second jaw is moved with respect to one another between an open position and a closed position. Tissue is configured to be positioned between the first jaw and the second jaw. The processor is configured to detect a first parameter of the surgical system, detect at least one user input, and modify the control program in response to the detected first parameter and the at least one user input.

A surgical instrument comprising a housing, a shaft assembly, a processor, and a memory is disclosed. The shaft assembly is replaceably connected to the housing. The shaft assembly comprises an end effector. The memory is configured to store program instructions which, when executed from the memory cause the processor to send an electrical interrogation signal to the attached shaft assembly, receive a response signal from the attached shaft assembly, cause a default function to be performed when a response signal is not received by the attached shaft assembly, determine an identifying characteristic of the attached shaft assembly as a result of the performance of the default function, and modify a control program based on the identifying characteristic of the attached shaft assembly.

A surgical instrument includes an end effector and a housing mechanically coupled to the end effector. The end effector includes a first actuating device configured to perform a first surgical procedure and a second actuating device integrally associated with the first actuating device and configured to perform a second surgical procedure, the second surgical procedure being independently operable and different than the first surgical procedure. An outer portion of the first actuating device and an outer portion of the second actuating device form a portion of an outer housing of the end effector. The housing includes a first actuator, mechanically coupled to the first actuating device and configured to impart movement to the first actuating device and a second actuator, mechanically coupled to the second actuating device and configured to impart movement to the second actuating device.

An electrosurgical pencil for use in performing surgery on a surgical site includes a main body forming a handle grippable by user and having open front and rear ends. The pencil has a vent tube open at its forward end, and slidably mounted in the body. The tube is adjustable independently from a retracted position to various extended positions. An elongate electrode is mounted in the tube and independently slidable therein. The electrode is adjustable manually in its longitudinal direction from a retracted position to extended positions. A first conducting strip can be mounted in the vent rube in contact with the electrode. A second conducting strip can be mounted in the main body and is in sliding contact with the first strip in order to provide power to the electrode.