An apparatus for microdisruption of cataracts in lens tissue by impulsive heat deposition comprising: a source of pulsed laser radiation, a user input device, a control circuit, and an optical waveguide configured to transmit the pulsed laser radiation. The light intensity which exits the optical waveguide has a wavelength selected to match an absorption peak of at least one component of the lens tissue, a pulse duration time shorter than a time required for thermal diffusion out of the laser irradiation volume and shorter than a time required for a thermally driven expansion of the laser irradiated volume, and a pulse energy resulting in a peak intensity of each laser pulse below a threshold for ionization-driven ablation to occur.

A power supply device for high frequency treatment instrument to treat living tissue includes an output unit to supply high frequency power to the treatment instrument's electrode, a distance information acquisition unit to acquire a distance between the living tissue and the electrode, a determination unit to determine whether the distance satisfies a first condition, and an output control unit to control the output unit so that its output is placed in a controlled state if the distance satisfies the first condition and so that the output is set to a first output level higher than an output level in the controlled state if a second condition is satisfied after the output is placed in the controlled state.

A microwave ablation system incorporates a microwave thermometer that couples to a microwave transmission network connecting a microwave generator to a microwave applicator to measure noise temperature. The noise temperature is processed to separate out components of the noise temperature including the noise temperature of the tissue being treated and the noise temperature of the microwave transmission network. The noise temperature may be measured by a radiometer while the microwave generator is generating the microwave signal or during a period when the microwave signal is turned off. The microwave ablation system may be configured as a modular system having one or more thermometry network modules that are connectable between a microwave applicator and a microwave generator. Alternatively, the modular system includes a microwave generator, a microwave applicator, and a microwave cable that incorporate a microwave thermometry network module.

A system includes signal acquisition circuitry, an oscillator circuit, and a processor. The signal acquisition circuitry is configured to receive from an intra-cardiac probe multiple intra-cardiac signals acquired by multiple electrodes of the probe, and to further receive a common ground signal for the multiple intra-cardiac signals. The signal acquisition circuitry is further configured to digitize the intra-cardiac signals relative to the common ground signal so as to produce multiple digital signals. The oscillator circuit is configured to generate an Alternating Current (AC) signal and to apply the AC signal to the common ground signal provided to the signal acquisition circuitry. The processor is configured to detect the AC signal in the multiple digital signals, and to assess, based on the detected AC signal, respective qualities of physical contact between the electrodes and cardiac tissue.

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.

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 cryoablation temperature control method, system and computer-readable storage medium. The method is used to control a temperature of the interior of a cryoablation balloon and includes: generating, based on an acquired real-time temperature value and a preset target temperature value of the interior of the balloon and/or a real-time gas flow rate value and a target gas flow rate value of a gas recovery passage in a gas outlet channel for the balloon, a first target liquid inlet pressure control signal for controlling a liquid supply flow rate of a high-pressure proportional valve in a liquid supply channel for the balloon; generating, based on an acquired real-time gas pressure value on, and a preset target gas pressure value for, a gas outlet side of the balloon, a first target gas outlet pressure control signal for controlling a gas outlet flow rate of a low-pressure proportional valve in the gas outlet channel for the balloon and for coordinating with the first target liquid inlet pressure control signal to perform control so that a pressure in the interior of the balloon is within a predefined safe pressure threshold value range and the temperature of the interior of the balloon is brought to and/or maintained at the target temperature value. This application allows accurate temperature control within a wide range and a short procedure time.

A surgical device including a surgical generator configured to provide energy for an energy based surgical instrument; a functional device configured to provide a function in its activated state; a switch for activating and deactivating the surgical generator a capacitive sensor including at least one measuring electrode that is arranged at the switch, wherein the capacitive sensor is configured to measure a capacity change or a capacity at the measuring electrode and activate or deactivate the functional device as a function of a measured capacity change or capacity.

Apparatus and methods are described, including a method for use with tissue of a renal nerve (770) passing longitudinally within a wall of a renal artery (8) of a subject. Using one or more stimulating electrodes (850a, 850b) disposed within the renal artery, the tissue is stimulated by passing a stimulating current through the wall of the renal artery. Using a sensor (26), a rate of change of blood pressure of the subject is sensed, following the start of the stimulation of the tissue. In response to the rate of change, it is decided whether to ablate the tissue, and in response to deciding to ablate the tissue, the tissue is ablated. Other applications are also described.

The present invention relates to an RF treatment apparatus controlling the RF energy so that the target tissue is maintained within a range of a treatment temperature if the target tissue is determined to have reached the treatment temperature based on the impedance, a method of controlling the RF treatment apparatus, and a skin treatment method using RF energy. The RF treatment apparatus, the method of controlling the RF treatment apparatus and the skin treatment method using RF energy according to the present invention have an effect in that they can improve the accuracy and efficiency of treatment because whether a target tissue corresponds to a treatment temperature is determined based on impedance of the tissue and the volume of the target tissue corresponding to the treatment temperature can be maximized while maintaining the target tissue to the treatment temperature for a predetermined time.