A multicarrier ablation system comprising: an antenna for application to biological tissue; a multi-carrier signal generator configured to provide a forward radio frequency (RF) signal to the antenna, the forward RF signal comprising multiple subcarriers that occupy respective frequencies within a bandwidth of the RF signal; and a monitoring circuit configured to receive a reflected RF signal from the antenna and control the multi-carrier signal generator to adjust one or more parameters of the forward RF signal during an ablation procedure based on the reflected RF signal.

A portable hair removal device (10), comprising a head portion (30), and a housing (20) connected to one end of the head portion (30). An emitter capable of emitting light is provided in the housing (20), and the light emitted by the emitter passes through the head portion (30) and then acts on the skin for hair removal. The head portion (30) is provided with at least a phototherapy lamp (32), and light emitted by the phototherapy lamp (32) acts on the skin through the head (30) and takes care of the skin. The portable hair removal device (10) has rich functions and a good skin care effect.

The present invention relates to a pathology treatment apparatus comprising: an ultrasound generator device (1), a remote control unit (2) for delivering electricity to the device (1) during at least an activation cycle and determining and controlling the operating parameters thereof, each activation cycle (50) being preceded by a standby cycle, means (31, 32) of electrical connection between the device (1) and the control unit (2), notable in that the control unit (2) is programmed to detect a fault with the electrical connection between the device (1) and the said control unit (2) during at least a standby cycle.

A method and system of adaptive cold atmospheric based treatment for diseased tissues, such as an area with cancerous cells, is disclosed. A plasma device generates a cold atmospheric plasma jet directed at the area having cancerous cells. A sensor is operable to sense the viability of the cancerous cells in the area. A controller is coupled to the plasma device and sensor. The controller is operative to control an initial plasma jet generated by the plasma device. The controller receives a sensor signal from the sensor to determine cell viability of the selected cells from the initial plasma jet. The controller adjusts the plasma jet based on the viability of the cancerous cells.

The present disclosure includes catheter systems and methods for treatment of occlusions, including coronary artery chronic total occlusions. The catheter system comprises a catheter coupled to a control system with a distal end inserted into a patient and proximal to a location within a blood vessel with an occlusion. The catheter comprises a flexible outer sheath surrounding a housing with a plurality of lumens to perform various functions to penetrate occlusions.

An in vivo temperature control system has a monitor for the internal temperature of a biological organ such as the esophagus, and for directly controls the temperature in the organ side depending on the monitoring. The in vivo temperature control system includes: a catheter insertable into a living body; a temperature probe containing a temperature sensor, the probe being insertable into the catheter; a liquid storage section for storing a temperature-controlled liquid; a pump for supplying the liquid from the liquid storage section to the catheter; and a control section for controlling driving of the pump based on a signal detected from the temperature probe; wherein the control section controls the pump when the signal has reached a preset threshold, and the pump is driven such that the liquid in the liquid storage section is released to the outside through the catheter.

In certain examples, aspects are directed to an ablation tool or other procedure-specific tool to treat or assess biological tissue (e.g., ablate cardiac tissue) having a first tissue side and a second, opposite tissue side at which a magnetic-draw element is to be located. In a specific example, a first magnetic element is associated with or coupled to a catheter tool having an expandable portion to transition from a first state towards a second state for providing an expanded girth, so that the expandable portion surrounds the first magnetic element and moves the procedure-specific tool, in part by the first magnetic element moving via magnetic attraction. While the first magnetic element and the magnetic-draw element align on either side of the biological tissue, the procedure-specific tool may be used for the procedure.

An electrosurgical device includes jaw members, a thermal cutting element coupled to one of the jaw members. When the jaw members are in an approximated position, power is delivered to the thermal cutting element to maintain the temperature of the thermal cutting element at an operating temperature for cutting sealed tissue grasped between the jaw members. When the jaw members are in the spaced apart position, power is delivered to the thermal cutting element to maintain the temperature of the thermal cutting element at a standby setpoint temperature. In response to a determination of contact between tissue and the thermal cutting element when the jaw members are in the spaced apart position, power is delivered to the thermal cutting element to increase the temperature of the thermal cutting element from the standby setpoint temperature to a cutting setpoint temperature for dissecting tissue.

A medical laser system for outputting laser pulses includes at least one laser cavity configured to generate at least one laser pulse, a rotating mirror configured to receive and reflect the at least one laser pulse, a beam splitter configured to receive and reflect a portion of the at least one laser pulse received from the rotating mirror, an energy-sensing device configured to detect the portion of the at least one laser pulse, an energy measurement assembly configured to generate a feedback signal based on the portion of the at least one laser pulse detected by the energy-sensing device, and a controller configured to generate an electronic control pulse based on the feedback signal received from the energy measurement assembly to generate at least one adjusted laser pulse.

A surgical instrument includes a housing having an elongated shaft extending distally therefrom and configured to support an end effector assembly at a distal end thereof. The end effector assembly includes first and second jaw members each having a tissue sealing plate disposed thereon and adapted to connect to an electrosurgical energy source for delivery thereto upon activation thereof. A sensor is disposed on one (or both) of the tissue sealing plates and is configured to communicate data relating to tissue disposed between the first and second jaw members to the electrosurgical energy source for correlation to a resonance frequency of the tissue. The resonance frequency of the tissue, in turn, is used to adjust one or more parameters associated with the delivery of electrosurgical energy to the tissue upon activation thereof.