In an example, an electrosurgical generator includes a power converter configured to convert a supply power received from a power source to an output power. The output power is suitable for delivering electrosurgical energy. The electrosurgical generator also includes a current sensor configured to sense a current of the output power and generate a logarithmic and analog representation of the current, and a voltage sensor configured to sense a voltage of the output power and generate a logarithmic and analog representation of the voltage. The electrosurgical generator further includes a controller configured to: (i) receive the logarithmic and analog representation of the current sensed by the current sensor, (ii) receive the logarithmic and analog representation of the voltage sensed by the voltage sensor, and (iii) adjust, based on the logarithmic and analog representation of the current and the voltage, a voltage

A system for monitoring tissue lesion development during a medical ablation process applied to a patient, the system comprising a catheter ablation device having at least one catheter electrode, the device connectable via an electrical feedline to a source of electrical energy and configured to apply ablation energy to ablate tissue in a target region, a plurality of external electrodes for application to the body of the patient, measurement circuitry for determining an electrical characteristic of a current path between the at least one catheter electrode and the external electrodes in the absence of said application of ablation energy, and an electrical controller. The system can be used for monitoring the size of a lesion during a catheter ablation process applied to the tissue of a subject, comprising alternating between an ablation phase involving delivery of ablation energy to a catheter electrode and a measure phase involving measuring an electrical characteristic of a current path passing through a lesion area formed by the ablation, in which the two phases are sequentially repeated until analysis of the measurement results indicate attainment of a desired lesion size.

An example RF ablation system including a transseptal needle having an ablation electrode thereon can be used to perform a transseptal perforation using RF energy. Ablation energy can be applied and/or terminated based on a change in impedance at the ablation electrode when the electrode come into or out of contact with tissue. The transseptal needle can further include magnetic field sensors and one or more electrodes. The magnetic field sensors can be positioned approximate a distal end of the transseptal needle and can be configured to provide location information of the distal end.

A flexible catheter has an ablation electrode disposed in its distal segment. The ablation electrode a cavity formed in its external surface, a microelectrode configured to fit into the cavity, a conductive wire lead connecting the microelectrode to receiving circuitry, and an electrical shield surrounding the wire lead. A power generator is connected to the ablation electrode and the electrical shield in a generator circuit. A back patch electrode adapted to contact with the subject is connected in the generator circuit. The microelectrodes can be active while energizing the ablation electrode.

A method for determining motional branch current in an ultrasonic transducer of an ultrasonic surgical device over multiple frequencies of a transducer drive signal. The method may comprise, at each of a plurality of frequencies of the transducer drive signal, oversampling a current and voltage of the transducer drive signal, receiving, by a processor, the current and voltage samples, and determining, by the processor, the motional branch current based on the current and voltage samples, a static capacitance of the ultrasonic transducer and the frequency of the transducer drive signal.

Devices, systems and methods are provided for treating conditions of the heart, particularly the occurrence of arrhythmias. The devices, systems and methods deliver therapeutic energy to portions the heart to provide tissue modification, such as to the entrances to the pulmonary veins in the treatment of atrial fibrillation. Generally, the tissue modification systems include a specialized catheter, a high voltage waveform generator and at least one distinct energy delivery algorithm. Other embodiments include conventional ablation catheters and system components to enable use with a high voltage waveform generator. Example catheter designs include a variety of delivery types including focal delivery, “one-shot” delivery and various possible combinations. In some embodiments, energy is delivered in a monopolar fashion. However, it may be appreciated that a variety of other embodiments are also provided.

The disclosure provides a method of manufacturing a flexible circuit electrode assembly and an apparatus manufactured by said method. According to the method, an electrically conductive sheet is laminated to an electrically insulative sheet. An electrode is formed on the electrically conductive sheet. An electrically insulative layer is formed on a tissue contacting surface of the electrode. The individual electrodes are separated from the laminated electrically insulative sheet and the electrically conductive sheet. In another method, a flexible circuit is vacuum formed to create a desired profile. The vacuum formed flexible circuit is trimmed. The trimmed vacuum formed flexible circuit is attached to a jaw member of a clamp jaw assembly.

Embodiments described herein provide various examples of mitigating electrical burn risks when using a monopolar electrosurgery tool on a patient in an electrosurgery procedure. In one aspect, a process receives an electrode configuration of the monopolar electrosurgery tool which includes a location of an active electrode of the monopolar electrosurgery tool at a surgical site on the patient's body and a location of a return electrode of the monopolar electrosurgery tool elsewhere on the patient's body. The process further obtains information of a metal implant inside the patient's body. Next, the process computes a plurality of potential current paths between the locations of the active electrode and the return electrode. The process then determines if one or more current paths in the plurality of computed potential current paths flow through the metal implant. If so, the process informs a surgical staff of potential electrical burn injuries associated with the electrode configuration.

An auxiliary return system for use with a bipolar electrosurgical device includes a tissue guard defining open proximal and distal ends and a body extending therebetween. The body includes outer and inner peripheral surfaces, the inner peripheral surface defining a lumen extending between the open proximal and distal ends, the outer peripheral surface including an elongated channel defined therein configured to receive a ground wire, a distal end of the elongated channel includes a pocket defined between the inner and outer peripheral surfaces of the body. An electrically conductive rivet includes a proximal end configured to engage the inner peripheral surface of the body and a distal end configured to engage the outer peripheral surface of the body to secure the rivet within the pocket. The distal end including a connector configured to engage the ground wire to provide electrical continuity between the ground wire and the rivet.

An electrosurgical apparatus performs a cut or incision on epithelial tissue of the body of a human or animal patient. The apparatus includes a generator system configured to generate a radio-frequency electric signal, and a hand piece held by an operator and having an end provided with a single active electrode electrically connected to the generator system. The electric signal generates a cut or an incision when the active electrode comes into contact with epithelial tissue of the body. The electric signal has a power ranging from 0.5 W-20 W and a frequency ranging from 40 kHz-90 kHz. The energy emitted by the signal is transferred from the active electrode to the tissue of the body through capacitive coupling. The tissue is cut at a peripheral temperature ranging from 45° C.-60° C. The electric circuit is closed to ground through a capacitive effect, as the apparatus does not use a return plate.