Systems, methods and computer-accessible mediums can be provided that can establish particular parameters for electric pulses based on a characteristic(s) of the tissue(s), and control an application of the electric pulses to tissue(s) for a plurality of automatically controlled and separated time periods to ablate the tissue(s) through mediation of membrane potential and through inducing the cells through a plurality of charge-discharge cycles such that an electroporation of a majority of the tissue(s) is prevented or reduced.

A system is provided to detect a breach of an insulative sheath in a bipolar electrosurgical instrument the system including: a first pulse detection circuit to detect a first high frequency (HF) signal component of a HF signal conducted on a lead of the bipolar instrument; a second pulse detection circuit to detect a second HF signal component of the HF signal conducted on a conductive shield surrounding the lead; magnitude difference sampling logic to produce sample values indicative of magnitude difference between the first HF signal component and the second HF signal component; and current detection logic to detect current flow between the shield and anatomical tissue based upon the sample values.

Apparatus and associated methods relate to controlling electrical power of an electrotherapeutic signal that is provided to a biological tissue engaged by an electrosurgical instrument during a medical procedure. Electrical power—a product of a voltage difference across and an electrical current conducted by the engaged biological tissue—is controlled according to a therapeutic schedule. The electrotherapeutic schedule can be reduced or terminated in response to a termination criterion being met. In some examples, the termination criterion is a current characteristic, such as, for example, a decrease in current conducted by the engaged biological tissue. In some examples, the termination criterion is a biological tissue resistance characteristic, such as, for example, an increase in the biological tissue resistance that exceeds a predetermined delta resistance value.

An electrosurgical generator includes a power supply unit which, when operating, supplies a direct voltage circuit, and a high-voltage inverter supplied from it that generates a high-frequency alternating voltage that is applied to outputs for connection of the electrosurgical instrument. The inverter includes a clock-driven power switch and a zero-crossing detector that recognizes zero crossings of the oscillation generated by the inverter. A signal for the generated alternating voltage is applied to the zero-crossing detector via a voltage divider which is a capacitive voltage divider with at least one capacitor that is resistant to high voltage. Undesirable direct voltage components at the center tap in the presence of changes to the supply voltage can be avoided thereby, since charge reversals as a result of changes to the supply voltage occur on both sides, and their effects thus cancel out.

The present invention is directed to a method of ablation. The method includes the steps of inserting a probe having an ablation electrode into a body of a living subject and urging the ablation electrode into a contacting relationship with a target tissue. A measurement of at least one electroanatomic parameter is made between the ablation electrode and the target tissue, and the measurement is haptically communicated to an operator. Responsively to the communicated measurement, ablating the target tissue using the ablation electrode.

Systems and methods for facilitating assessment and convenient display of graphical output indicative of lesion formation and outputting data indicative of lesion formation to a 3D mapping system to display on a 3D model are disclosed herein.

An irreversible electroporation and radio frequency ablation (IRE/RFA) generator includes 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 output signal having a composition of the adapted IRE pulses having a final shape and repetition rate, the converted RF sinusoidal signal, or a combined IRE/RFA output signal, by switching between the received IRE square pulses and the received converted RF sinusoidal signal.

Various systems and methods for determining the state of an end effector of an ultrasonic surgical instrument are disclosed. A control circuit can be configured to measure a complex impedance of an ultrasonic electromechanical system including an ultrasonic blade and compare the measured complex impedance to reference complex impedance patterns that each correspond to a state of the end effector. Accordingly, the control circuit can further be configured to determine the state of the end effector according to which of the plurality of reference complex impedance patterns the measured complex impedance corresponds.

Disclosed are systems, apparatus, and methods for performing robotic surgery, including a surgical robot having a plurality of robotic arms, an image capture device operably coupled to a first one of the plurality of robotic arms and a light source, a surgical tool operably coupled to a second one of the plurality of robotic arms and a light sensor, and a computing device including a processor and a memory storing instructions which, when executed by the processor, cause the computing device to determine whether the light sensor coupled to the surgical tool is detecting at least a predetermined amount of light emitted by the light source coupled to the image capture device, and provide a notification when it is determined that the light sensor coupled to the surgical tool is not detecting at least the predetermined amount of light emitted by the light source coupled to the image capture device.

Systems and methods for estimating tissue parameters, including mass of tissue to be treated and a thermal resistance scale factor between the tissue and an electrode of an energy delivery device, are disclosed. The method includes sensing tissue temperatures, estimating a mass of the tissue and a thermal resistance scale factor between the tissue and an electrode, and controlling an electrosurgical generator based on the estimated mass and the estimated thermal resistance scale factor. The method may be performed iteratively and non-iteratively. The iterative method may employ a gradient descent algorithm that iteratively adds a derivative step to the estimates of the mass and thermal resistance scale factor until a condition is met. The non-iterative method includes selecting maximum and minimum temperature differences and estimating the mass and the thermal resistance scale factor based on a predetermined reduction point from the maximum temperature difference to the minimum temperature difference.