A method having: sending, to a spatially separately arranged server device, a configuration request having an item of identification information of the electrosurgical generator; receiving an item of operating information indicative of an operating mode, wherein the operating mode is capable of partially controlling the energy supply of the electrosurgical instrument by the electrosurgical generator; and storing the operating information in a data memory of the electrosurgical generator. Furthermore, a method for operating a server device, the method having: receiving a configuration request having an item of identification information of an electrosurgical generator; determining, at least partially in dependence on the identification information, an item of operating information indicative of one operating mode of a plurality of predefined operating modes, wherein operating modes are each capable of partially controlling an energy supply of an electrosurgical instrument by the electrosurgical generator; and sending, to the electrosurgical generator, the operating information.

An instrument for coagulation and dissection of biological tissue including a tool with coagulation electrodes and at least one cutting electrode. The electrodes are actuated via an operating circuit including an evaluation circuit, to which an external apparatus delivers an evaluation signal with first and second half-waves having opposite polarities. During at least one first half-wave, the evaluation circuit checks whether a first switch or a second switch are actuated on the instrument. Depending on the evaluation result, a triggering signal is transmitted to a switching unit. Depending on the triggering signal, the switching unit is switched into a first or second switching state. In the second switching state, no voltage suitable for dissection and no current suitable for dissection, respectively, is applied to the cutting electrode. In the first switching state, a voltage suitable for dissection or a current suitable for dissection is applied to the cutting electrode.

A system for tracking a catheter in a patient. The system including a plurality of surface electrodes and a surface patch attached to the patient and a processor coupled to the plurality of surface electrodes and the surface patch. The processor determines a location of at least one of the plurality of surface electrodes, stores locations of the surface patch and the at least one of the plurality of surface electrodes, determines a three-dimensional shell shape that corresponds to a portion of the patient, determines a model of an impedance tracking field in at least a portion of the three-dimensional shell shape, injects current through one or more of the plurality of surface electrodes, fits measured voltages from the catheter to the model of the impedance tracking field to determine locations of the catheter, and provides therapy to the patient based on the locations of the catheter.

A surgical instrument system comprising a handle, a shaft, and a disposable power module is disclosed. The handle comprises a motor, a control switch, and a motor-control processor which is in communication with the control switch. In various instances, the disposable power module comprises a disposable battery and a display unit configured to indicate at least one function of the surgical instrument system.

A treatment instrument includes a grasping piece that is openable and closable to a treatment portion, and includes an electrode member. An electrode inclination surface facing a side on which the treating portion is located is provided on an outer surface of the electrode member of the grasping piece, and the electrode inclination surface extends from an inner side to an outer side in a width direction so as to be inclined in a direction away from the treatment portion.

A method for adjusting the operation of a surgical suturing instrument using machine learning in a surgical suite is disclosed. The method comprises gathering data during surgical procedures, wherein the surgical procedures include the use of a surgical suturing instrument comprising a suturing needle configured to be mechanically advanced through a suturing stroke, analyzing the gathered data to determine an appropriate operational adjustment of the surgical suturing instrument, and adjusting the operation of the surgical suturing instrument to improve the operation of the surgical suturing instrument.

An electrosurgical generator with a high-voltage power supply that supplies a DC output voltage receives the DC output voltage of the high-voltage power supply and generates a high-frequency AC output voltage. When generator is operating, a control unit receives signals from an AC output voltage measuring unit and current measuring unit. The control unit limits an increase of DC output voltage of the high-voltage power supply as soon one predefined maximum value is reached or exceeded. When the generator is operating, the control unit configured to receive signals from a DC output voltage measuring unit that represent a respective current value of the DC output voltage, and to compare a respective current value of DC output voltage with a predefined minimum value for DC output voltage, and to cause the DC output voltage of the high-voltage power supply to increase as soon as it falls below the predefined minimum value.

An electrosurgical generator and associated methods determine a real part of the impedance of treated tissue. The electrosurgical generator includes an output stage, a plurality of sensors, and a controller that controls the output stage. The controller includes a signal processor that determines an RMS voltage, an RMS current, an average power, and a real part of the impedance of the treated tissue based on measured voltage and current by using a plurality of averaging filters. The controller controls the output stage to generate electrosurgical energy based on at least the determined real part of the impedance.

A training data generation method includes: obtaining output information related to an electrical characteristic value in an energy treatment tool when ultrasound energy is being applied from the energy treatment tool to a body tissue; obtaining photography data that contains a photograph taken of a state in which the ultrasound energy is being applied to the body tissue; obtaining a label from the photography data; and adding the label to the output information to generate the training data.

The plasma sensor monitors parameters characterizing the condition of the plasma during the treatment phase and/or the change thereof in order to recognize a prefiguring or already occurred interruption of the plasma in this manner and to avoid this interruption and, in the ideal case, avoid this by already changing the voltage form previously. The mentioned mechanisms can be used by the control device (22) also during a pulse packet. The length of each pulse packet is adapted at each change of the voltage form according to their characteristics in order to guarantee a constant average power.