An energy module connectable to a surgical instrument is disclosed. The energy module can include a circuit, which can include a first amplifier and a second amplifier coupled to a port of the energy module to which a surgical instrument is connectable. The first amplifier can be configured to generate a first drive signal at a first frequency range and the second amplifier can be configured to generate a second drive signal at a second frequency range. The circuit can be configured to control the amplifiers to deliver the first drive signal, the second drive signal, and/or a combination of the first and second drive signals to a surgical instrument connected to the port.

A modular surgical system is disclosed. The modular surgical system comprises a header module, a first surgical module, a second surgical module, and a module identification circuit. The second surgical module is arrangeable in a stack configuration with the header module and the first surgical module. The module identification circuit is configured to cause a pre-determined current to be transmitted to the first surgical module through the second surgical module in the stack configuration, detect a first voltage indicative of a first position of the first surgical module in the stack configuration, and detect a second voltage indicative of a second position of the second surgical module in the stack configuration. The second voltage is different than the first voltage.

A modular energy system including a header module and a module. The header module includes a display screen for displaying a user interface. The header module is configured to receive data, including safety critical data, from the module, control the display screen to cause the UI to display UI content based on the received data, the UI content including safety critical UI content based on the safety critical data, and transmit the displayed safety critical UI content to the module for verification thereby. The module is configured to confirm whether the transmitted safety critical data coincides with the displayed safety critical UI content. In the event that it is determined that they do not coincide, the header module and/or the module can be configured to stop the function(s) of the module, display an alert on the display screen, and take various other actions.

A dual-output generator is configured to output two or more waveforms at different frequencies. In particular, the dual-output generator is configured to provide low-frequency output, which may be suitable for ultrasonic surgical instruments, and a high-frequency output, which may be suitable for electrosurgical instruments, while reducing the amplitude of all remaining frequencies other than the two selected low and high frequencies to about zero.

Apparatus and methods for delivering electromagnetic energy to a patient's tissue and reducing pain experienced by the patient during treatment of the patient's tissue with the delivered electromagnetic energy. The tissue treatment apparatus includes a delivery device configured to transfer the electromagnetic energy through the skin surface to a region of tissue, and also includes a vibration device that is mechanically coupled with the delivery device. The vibration device is configured to transfer mechanical vibrations along an axis substantially normal to the skin surface to the region of tissue being treated.

Systems and methods for performing a self-verification system test upon activation of an electrosurgical generator are described. The systems and methods allow for enhancing surgical outcomes by providing generators having accurate RF energy generation, measurement, calibration and self-testing system. This is achieved through implementation of an automated self-verification process at a power start-up of the generator, which allows for rapidly identifying a potential generator issue prior to any use of a connected electrosurgical instrument or supply of any RF energy to the tissue or vessel through the electrosurgical instrument. Additionally, one or more internal impedance loads are integrated within the electrosurgical generator. The internal impedance loads with multiple configurations are utilized to verify the voltage, current, power, and/or phase measurements of the generator. By incorporating or integrating the self-verification process and its related hardware resources within the electrosurgical generator, many improvements in outcome of pre-surgical procedures may be achieved.

Apparatus and methods for delivering coolant to an energy delivery device used to treat tissue with electromagnetic energy. A cooling system includes a pump that is configured to pump a coolant to the energy delivery device.

Various forms are directed to systems and methods apparatus for operating a surgical instrument that includes an adapter configured to couple to a generator. The generator configured to provide an energy signal for treating tissue The adapter includes at least one input port configured to receive the energy signal from the generator, where the energy signal includes an energy component comprising one or more energy modalities. An energy storage circuit is configured to charge and store energy from the generator as a DC output. The adapter also includes at least one output port configured to couple to one or more surgical instruments for treating tissue. The one or more energy modalities comprises any one of an ultrasonic, a bipolar radio frequency (RF), a monopolar RF, a reversible electroporation, an irreversible electroporation, or a microwave component, or any combination thereof.

Systems, devices, and methods for electroporation ablation therapy are disclosed, with the system including a pulse waveform signal generator for medical ablation therapy, and an endocardial ablation device includes at least one electrode for ablation pulse delivery to tissue. The signal generator may deliver voltage pulses to the ablation device in the form of a pulse waveform. The system may include a cardiac stimulator for generation of pacing signals and for sequenced delivery of pulse waveforms in synchrony with the pacing signal.

An electrosurgical generator for supplying electrosurgical energy to tissue includes sensor circuitry configured to measure at least one tissue or energy parameter and a controller configured to generate a plot of the at least one tissue or energy parameter including a plurality of tissue parameter values, wherein the controller is further configured to normalize the plot of the at least one tissue or energy parameter with respect to treatment volume.