Medical devices and related methods, and, more specifically, cryogenic surgical systems and related methods are disclosed. Some example cryogenic surgical systems may include a cryosurgical control unit configured to cool a cryosurgical probe to a temperature colder than a temperature at which flow of cryogenic fluid to the probe is stopped. Some example tank level indicating systems may utilize the pressure of the fluid in the tank and a temperature of the exterior wall of the tank to indicate liquid level.

The invention relates to an end piece intended for equipping a device for cosmetic treatment of keratin materials with an electric current, the end piece comprising an application member (6) comprising an electrode (1) and a counter electrode (2), said electrode (1) and counter electrode (2) being separated from one another by an electrically insulating zone (3).

An energy output section outputs first electric energy so that a high-frequency current flows between electrodes through a treated target, and outputs second electric energy so that heat occurs in an end effector. A controller outputs the first electric energy at the same time as the second electric energy in at least a part of a period during which the heat is continuously denaturing the treated target from an output start of the second electric energy. The controller makes, based on judging that the treated target entered a predetermined state, an electric power of the first electric energy increased.

In an example, a method for delivering an anesthetic agent to a target tissue in a nasal cavity of a patient includes inserting a cryotherapy device into the nasal cavity of the patient. The cryotherapy device includes a cryotherapy delivery feature and one or more protrusions. The method also includes positioning the cryotherapy delivery feature in contact with the target tissue, and delivering, using the cryotherapy delivery feature, a cryotherapy treatment to the target tissue. After inserting the cryotherapy device into the nasal cavity, the method includes actuating the one or more protrusions from a retracted state to an extended state. After actuating the one or more protrusions to the extended state, the method includes penetrating the target tissue with the one or more protrusions. After penetrating the target tissue, the method includes delivering, via the one or more protrusions, an anesthetic agent into the target tissue.

A system and method for performing a radiofrequency (RF) ablation procedure with a cooled RF probe includes measuring one or more local perfusion characteristics at an ablation site within a patient. The method also includes determining a heat transfer due to local perfusion at the ablation site based on the one or more local perfusion characteristics. Further, the method includes determining an operating threshold for the cooled RF probe based, at least in part, on the heat transfer. Moreover, the method includes controlling the cooled RF probe based on the operating threshold to create a lesion at the ablation site within the patient.

A dermal conditioning device is for creating at least one pressure point on at least an external surface of an eyelid. The device includes at least one skin tissue lesion generator, at least one controller, a power supply and a housing, the controller coupled to the skin tissue lesion generator. A power supply couples to the skin tissue lesion generator and the controller and the housing encasing the skin tissue lesion generator and the controller. The controller controls the skin tissue lesion generator to generate at least one signal and to apply the signal to stress the external surface of an outer layer of the eyelid, the stress causing a formation of the pressure point on the eyelid without tissue coagulation, thereby activating at least one of a corneal reflex, a menace reflex, and a lacrimation reflex of the eyelid by activating at least one nociceptor on the eyelid.

A medical apparatus includes a probe, which includes an insertion tube configured for insertion into a body cavity of a patient, a distal structure connected distally to the insertion tube and including a plurality of electrodes, which are configured to contact tissue within the body, and temperature sensors fixed to the distal structure and configured to output signals indicative of a temperature of the tissue contacted by the electrodes. The apparatus further includes an electrical signal generator configured to apply between one or more pairs of the electrodes bipolar pulses having an amplitude sufficient to cause irreversible electroporation (IRE) in the tissue contacted by the spines, and a controller configured to control a timing of the bipolar pulses applied by the electrical signal generator responsively to the signals output by the temperature sensors.

A method for treating a skin lesion can include lowering a temperature of a treatment site to a temperature range sufficient to induce vasoconstriction in a dermis of the treatment site and administering a laser light through a medium to the skin lesion while maintaining the temperature of the treatment site within the temperature range. The medium can include a first portion and a second portion, where the laser light is transmitted through the first portion and the second portion sequentially, the second portion includes a contact surface for contacting the treatment site, and the second portion has a higher thermal conductivity than the first portion. The method can further include identifying the skin lesion and analyzing one or more characteristics of the skin lesion.

Time-of flight camera system and methods for automated dermatological cryospray treatments are disclosed herein. A method of controlling a skin cooling treatment system including a mechanical arm with a cryospray applicator coupled to a distal end of the mechanical arm, can include receiving a point cloud generated from a portion of skin of a patient for receiving a skin cooling treatment and generating a polygon mesh surface representative of the portion of skin of the patient from the point cloud. The polygon mesh surface can include a plurality of linked vertices. The method can include generating waypoints and delivery vectors based on the polygon mesh surface, linking the waypoints to form a treatment path, and delivering a skin treatment to the portion of skin according to the treatment path.

Methods and system for atrial fibrillation mapping utilizing cardiac mapping based on medical image(s). The methods and system also adapted for any balloon based catheters including cryoballoon catheter, laser balloon catheter, or “hot balloon” catheter, as well as circular catheters. The methods and system includes overlaying of two or more images on top of each other (where the images are of various types or modalities) and aligning the images, where the transparency between the images can be adjusted for navigating and optimal placement of the balloon based catheters or circular catheters. The cardiac system also adopted for guiding optimal placement of the left ventricular (LV) lead placement for cardiac re-synchronization (CRT) therapy, and for mapping and displaying activation times from various branches of the coronary sinus for optimizing CRT therapy.