Methods and systems for detecting undesirable electrocautery arcing events during an electrocautery surgical procedure may include introducing an electrosurgical treatment instrument to a surgical site to perform an electrocautery surgical procedure. A healthcare provider may view the surgical site with a surgical camera assembly having a surgical field-of-view. The healthcare provider also may view a portion of the electrosurgical treatment instrument with an electrocautery arc detection system including an arc detection camera having an arc detection field-of-view different than the surgical field-of-view obtained by the surgical camera. The electrocautery arc detection system may identify thermal infrared emission or tissue color changes as indicators of undesirable electrocautery arcing. Some implementations alert a healthcare provider of undesirable electrocautery arcing.

The present is directed to improved systems and methods for skin cooling treatments. A skin cooling treatment system can include a mechanical arm that can have a proximal end and an distal end. The system can include a processor that can control the mechanical arm, and a cryospray applicator. The cryospray applicator can be coupled to the distal end of the mechanical arm and can be moveable by the mechanical arm to deliver a spray of cryogen to a portion of an area of skin tissue for treatment. The cryospray applicator can include an array of orifices through which the cryogen can be sprayed.

Catheter systems of the invention are directed to the removal of occlusions, such as thrombi and plaque, within blood vessels. In certain aspects, catheter systems of the invention include an elongate body defining a first lumen and comprising a distal portion, an inner member configured for insertion into the first lumen, the inner member comprising an energy source configured to deliver therapeutic energy to a treatment site; and a dissolution element coupled to the distal portion of the elongate body. The dissolution element may include a heating element, steam, and a balloon.

Methods for treating a patient using time varying magnetic field are described. The treatment methods combine various approaches for aesthetic treatment. The methods are focused on enhancing a visual appearance of the patient.

An antenna system for tissue ablation comprises an energy transmission member, an antenna body coupled to the energy transmission member, a fluid source, and a choke member including a choke body and a choke connector electrically coupling the choke body to the energy transmission member. The choke connector is in direct contact with fluid from the fluid source and forms a delivery path for the fluid between the choke body and the energy transmission member. The choke connector and the choke body are integrally formed of a continuous wire mesh.

The various examples of the present disclosure are directed towards a multi-physics controller that can predict and monitor ablation procedures. In some examples of the present disclosure, fat saturation images can be used to create custom microwave ablation bioelectric/biothermal models. In some examples of the present disclosure, a deformation correction methodology can be used. Thereby, microwave and mechanics computational models can forecast therapeutic delivery intraoperatively while correcting for deformation.

In an embodiment, a method for effecting thermal therapy using an in vivo probe includes positioning the probe in a volume in a patient, identifying an irregularly shaped three-dimensional region of interest and automatically applying thermal therapy to the region using the probe. Applying thermal therapy may include identifying a first emission level at a first rotational angle based in part on a depth of a radial portion of the region in the direction of probe emission, activating emission of the probe, causing rotation of the probe to a next rotational angle, identifying a next emission level at the next rotational angle based in part on a depth of a radial portion of the region in the direction of probe emission, activating emission to deliver therapeutic energy, and repeating rotation and emission until therapeutic energy has been delivered to the volume.

A surgical laser system includes a laser source configured to generate laser energy, a laser fiber optically coupled to the laser source and configured to discharge the laser energy and collect electromagnetic energy feedback from a treatment site a photodetector configured to generate an output signal in response to the electromagnetic energy collected from the treatment site, a display, and a controller configured to produce an image or indication about the temperature at the treatment site on the display based on the output signal.

An irrigated ablation catheter includes a shaft and an electrode assembly affixed to a distal end of the shaft. The distal electrode assembly includes a manifold and an ablation electrode affixed together and extending along a center axis. The electrode has a distal irrigation passageway extending therethrough to an opening at a distal tip of the electrode. The opening of the irrigation passageway is offset in distance from the center axis, and allows a thermal sensor such as a thermocouple to be located in a sensor cavity in the electrode on or near the center axis. One variation involves providing a pair of distal irrigation passageways through the electrode where both of the openings of the passageways are offset from the center axis. The thermal sensor in this variation is located in the sensor cavity substantially on the center axis.

Devices and methods for controlling ablation therapy are provided herein. In one embodiment, an ablation device is provided that includes an elongate body having proximal and distal ends, and an inner lumen extending therethrough. The inner lumen can be configured to receive fluid therein and to deliver fluid to the distal end of the elongate body. The device can also include an ablation element positioned at a distal end of the elongate body that is configured to heat surrounding tissue, and a heater element disposed within the inner lumen adjacent to a distal end of thereof, the heater element being configured to heat fluid flowing through the inner lumen.