Various systems and methods for controlling an ultrasonic surgical instrument according to the location of tissue grasped within an end effector are disclosed. A control circuit can be configured to apply varying power levels, via a generator, to an ultrasonic transducer driving an ultrasonic electromechanical system to oscillate an ultrasonic blade. Further, the control circuit can measure impedances of the ultrasonic transducer corresponding to the varying power levels and determine a location of tissue positioned within the end effector according to a difference between the impedances of the ultrasonic transducer relative to a threshold.

An ultrasonic electromechanical system for an ultrasonic electromechanical system may include an ultrasonic blade, a clamp arm disposed opposite the ultrasonic blade, an ultrasonic transducer acoustically coupled to the ultrasonic blade, in which the ultrasonic transducer is configured to oscillate the ultrasonic blade in response to a drive signal, and a control circuit coupled to the ultrasonic transducer. The control circuit can be configured to determine a position of a tissue clamped between the ultrasonic blade and the clamp arm, and control an amount of power of the drive signal based at least in part on the position of the tissue.

An irreversible electroporation and radio frequency ablation (IRE/RFA) generator incudes an IRE pulse generator, harmonic filtration circuitry, and a waveform interleaver. The IRE pulse generator is configured to generate biphasic IRE pulses. The harmonic filtration circuitry is configured to convert the IRE pulses into an RF signal. The waveform interleaver, which is configured to receive the IRE pulses and the RF signal and generate an IRE/RFA output signal by interleaving in alternation one or more of the IRE pulses with one or more periods of the RF signal.

A method for controlling an output of an energy module of a modular energy system. The energy module can comprise a plurality of amplifiers configured to generate a drive signal at a frequency range and a plurality of ports coupled to the plurality of amplifiers. The method includes determining to which port of the plurality of ports the surgical instrument is connected, selectively coupling an amplifier of the plurality of amplifiers to the port of the plurality of ports to which the surgical instrument is connected, and controlling the amplifier to deliver the drive signal for driving the energy modality to the surgical instrument through the port.

A sine wave generator includes a resonator circuit, a control circuit and a pulse generator. The resonator circuit is configured to receive energy pulses and to generate a resonator sinusoidal signal responsively to the energy pulses. The control circuit is configured to estimate a signal measure of the resonator sinusoidal signal, or of a signal derived from the resonator sinusoidal signal. The pulse generator is configured to generate the energy pulses responsive to the signal measure estimated by the control circuit, and to drive the resonator circuit with the energy pulses.

A surgical system comprising a generator and a surgical instrument configured to receive power from the generator is disclosed. The surgical instrument comprises a housing, a shaft defining a longitudinal axis, an end effector, and an internal charge accumulator. The housing comprises a motor. The end effector is operably responsive to actuations from the electric motor, transitionable between an open and closed configuration, and rotatable about an articulation axis transverse to the longitudinal axis. The generator is incapable of supplying a sufficient power directly to the motor to perform the actuations. The internal charge accumulator is in electric communication with the generator and supplies power to the motor. The internal charge accumulator is chargeable by the generator to a threshold value at a charge rate dependent on a charge level of the internal charge accumulator. The charge rate is independent of a charge expenditure by the surgical instrument.

An electrosurgical instrument comprising a housing, a shaft extending from the housing, an end effector extending from the shaft, an articulation joint rotatably connecting the end effector to the shaft, and a wiring circuit is disclosed. The housing comprises a printed control board. The wiring circuit extends from the printed control board through the shaft and into the end effector. The wiring circuit is configured to monitor a function of the end effector and communicate the monitored function to the printed control board. The wiring circuit comprises a proximal rigid portion fixed to the shaft, a distal rigid portion fixed to the end effector, and an intermediate portion extending from the proximal rigid portion to the distal rigid portion. The intermediate portion comprises a resilient portion and a stretchable portion.

A surgical instrument comprising a motor assembly, a shaft defining a shaft axis, a distal head, a rotary drive member, and a distal head lock member movable between a first position where the distal head is unlocked from the shaft and a second position where the distal head is locked to the shaft is disclosed. The motor assembly comprises a motor and a controller configured to operate the motor in first and second operating modes. The distal head comprises an end effector movable between an open configuration and a closed configuration. The distal head is rotated about the shaft axis when the distal head lock member is in the first position and the rotary drive member is actuated. The end effector is moved from the open configuration toward the closed configuration when the distal head lock member is in the second position and the rotary drive member is actuated.

A surgical instrument comprising an end effector including a proximal end, a distal end, a first jaw, and a second jaw is disclosed. The first jaw comprises a first electrode. The second jaw comprises a second electrode and a monopolar electrode centrally disposed down a length of the end effector. The first electrode and the second electrode cooperate to deliver bipolar energy to the tissue in a bipolar cycle. The monopolar electrode comprises a wedge shape that graduates in width along the length of the end effector. The monopolar electrode is electrically isolated from the first and second electrodes. The monopolar electrode is configured to employ monopolar energy to cut the tissue in a monopolar cycle.

A surgical end effector for use with an electrosurgical instrument is disclosed. The end effector comprises a first jaw including a first electrode and a second jaw including a second electrode. The end effector is transitionable from an open configuration to a closed configuration to grasp tissue. The second electrode is laterally offset from the first electrode. The first electrode and the second electrode are configured to cooperate to deliver a bipolar energy to the tissue. The second jaw further comprises a monopolar electrode configured to deliver a monopolar energy to the tissue and a compliant substrate. The monopolar electrode and the second electrode are fixedly attached onto the compliant substrate in a spaced apart arrangement. The compliant substrate is configured to apply a biasing force to the second electrode and the monopolar electrode toward the first jaw in the closed configuration.