A cryosurgery system, comprising two or more cryoprobes is provided. Each cryoprobe includes a probe shaft having a distal section insertable in a patient and a proximal coupler. A connector interface with connection ports permits connections to a corresponding cryoprobe. Each connection port can have an isolating sleeve between the proximal coupler and the connection port when the proximal coupler of the respective cryoprobe is inserted in the connection port. The isolating sleeve can include an electrically insulating material so as to electrically isolate each cryoprobe connected to its corresponding connection port from other cryoprobes connected to their corresponding connection ports. An electrical measurement system can be connected to each connection port to detect electrical signals associated with the probe shaft. A control system can detect, based on the electrical signals detected by the electrical measurement system whether the probe shaft is electrically connected to the electrical heater.

A surgical system and a computing device for a surgical system that is configured to calculate actual operating parameters of an electrosurgical instrument, including an actual angle between the jaw members of the electrosurgical instrument, and to display a user interface. The user interface includes an ideal angle range between the jaw members and the actual angle between the jaw members of the electrosurgical instrument relative to the ideal angle range. The computing device is further configured to determine if the actual angle between the jaw members of the electrosurgical instrument is outside the ideal angle range.

A fractional handpiece and systems thereof for skin treatment include a passively Q-switched laser assembly operatively connected to a pump laser source to receive a pump laser beam having a first wavelength and a beam splitting assembly operable to split a solid beam emitted by the passively Q-switched laser assembly and form an array of micro-beams across a segment of skin. The passively Q-switched laser assembly generates a high power sub-nanosecond pulsed laser beam having a second wavelength.

A method of performing an electrosurgical procedure includes activating an electrode of a surgical instrument by applying an output power signal with a first energy output profile from a generator to the electrode. An induced electrical parameter of a conductive component is monitored via one or more sensors, the induced electrical parameter being associated with a predetermined electrical parameter threshold. The induced electrical parameter includes a parasitic energy loss. When the induced electrical parameter measured from a conductive component of the surgical instrument meets or exceeds the predetermined electrical parameter threshold during the operation, the output power signal of the generator is adjusted from a first energy output profile to a second energy output profile. The adjustment is operable to reduce the induced electrical parameter measured from the conductive component of the surgical instrument; and to reduce the parasitic energy loss without ceasing delivery of energy to the electrode.

An electrosurgical system includes an instrument, an RF energy generator, and two ground pads. The instrument includes an electrode and a conductive shield that is configured to collect a capacitive coupling current that is induced by the application of RF energy to tissue by the electrode. A first electrical lead couples the first ground pad with the ground return of the conductive shield and the generator. The ground return is configured to divert a first portion of the capacitive coupling current to the generator via the first electrical lead. A second electrical lead couples the second ground pad with the ground return of the conductive shield and the generator. The ground return is configured to divert a second portion of the capacitive coupling current to the generator via the second electrical lead. The first and second portions of the capacitive coupling current are substantially equal.

Apparatus, including an enclosure having a base and a cover with respective conductive layers. The conductive layers connect to form a shield attenuating electromagnetic radiation originating outside the enclosure in a range of 10 kHz-100 kHz by at least 20 dB within the enclosure. An adapter circuit within the enclosure processes electrophysiological signals to generate an output signal. A first connector passing through the enclosure connects to a probe to receive the electrophysiological signals and convey them to the adapter circuit. A second connector passing through the enclosure receives the output signal from the adapter circuit and conveys it to a console. A control input receives a control signal indicative of a frequency within the range, and a sensing circuit senses a magnetic field within the enclosure and outputs a warning signal when the magnetic field at the frequency indicated by the control signal exceeds a preset threshold.

A method of determining the status of a fluid cooled microwave ablation system is provided including providing an electrical current to a pump to pump fluid through an ablation system along a fluid path to cool the ablation system, measuring an electrical current drawn by the pump, and determining a status of the ablation system based on the measured electrical current. In another aspect of the disclosure, an ablation system is provided including an ablation probe defining a fluid path for circulation of fluid therethrough, a generator configured to supply energy to the ablation probe for treating tissue, a pump configured to pump fluid through the fluid path of the ablation probe to cool the ablation probe, a sensor configured to measure an electrical current drawn by the pump, and a computing device configured to determine a status of the ablation system based on the measured electrical current.

A computing device for generating and using a graphical user interface (GUI) is disclosed. The computing device includes one or more controllers configured to generate a graphical representation of a plurality of electrodes of an ablation catheter for displaying via the GUI; designate, via the GUI, at least some of the plurality of electrodes to be active electrodes; automatically designate the active electrodes as a source electrode or a sink electrode; assign an amount of energy to each of the designated source electrodes; and estimate an amount of energy associated with each of the designated sink electrodes based at least in part on the assigned energy of the designated source electrodes.

A system includes a catheter, a pulse generator and a controller. The catheter is configured for insertion into a body of a patient, and includes at least a first electrode, a second electrode and a third electrode, which are disposed at a distal end of the catheter and are configured to contact tissue within the body. The pulse generator is configured to apply one or more bipolar ablation pulses between the first and second electrodes, for ablating the tissue in contact with the first and second electrodes. The controller is configured to: (i) control the pulse generator to apply the one or more bipolar ablation pulses between the first and second electrodes, (ii) receive a signal indicative of a voltage, measured between the third electrode and a reference during application of the ablation pulses, and (iii) issue a notification in response to detecting that the voltage violates a predefined criterion.

An energy module is disclosed. The energy module includes a control circuit and a two wire interface coupled to the control circuit. The two wire interface is configured as a power source and as a communication interface between the energy module and a neutral electrode.