There is provided in accordance with an exemplary embodiment of the invention a method of treating a subject suffering from a nerve related disorder, the method comprising causing a damage region to one or both of a lumen wall or nearby surrounding tissues, the damage region encompassing a volume having dimensions of less than about 6.8 mm in a substantially radial direction, less than about 5.8 mm in a direction substantially tangential to the lumen, less than about 10 mm in a substantially axial direction, the damage region being located no closer than about 0.2 mm from an inner wall of the lumen, the damage region comprises of greater than about 60% of collagen denatured tissue.

A treatment system delivers a breathing gas and frozen ice or other particles (FSP) to a bronchus of a lung of a patient in order to induce hypothermia. The breathing gas and the FSP are usually delivered through separate lumens. Clogging of an FSP lumen can be inhibited by heating and/or cooling of the lumen. The temperature of exhaled gases or a body temperature may be measured, and a controller can adjust the duration or rate at which the ice particles are delivered in order to control the patient's core temperature based on the measured temperature.

The present invention involves the use of a small profile device for preparation and/or delivery of cold slurry into the human body. The cold slurry can be generated within the device itself or within a separate small chamber, both of which produce a cold slurry using a cooling source and an injectable fluid. The delivery device provides continued agitation to the fluid/slurry through rotation and/or vibration of blades within the device. The fluid/cold slurry is cooled/kept cool through the use of an external cooling device, such as a cooling sleeve, that at least partially surrounds the delivery device. The cooling sleeve can cool or maintain the temperature of the cold slurry through a number of mechanisms. The cold slurry can be delivered using a device in accordance with the present invention to any tissue inside the body, including subcutaneous fat, visceral fat, and brown fat.

This application relates to a hand-held cooling device for supplying a cryogen to a target region for cryotherapy. The device can include a cryogen container configured to contain a first cryogen having a first temperature and a nozzle configured to spray a first modified cryogen to the target region, the first modified cryogen having a second temperature higher than the first temperature. The device can also include a cryogen temperature regulator configured to receive the first cryogen and output the first modified cryogen to the nozzle, the cryogen temperature regulator disposed closer to the nozzle than the cryogen container. The cryogen temperature regulator can include a holder tube, a porous structure disposed inside a holder tube and a heater disposed around the holder tube and heating the holder tube so as to increase the first temperature to the second temperature while the first cryogen passes through the porous structure.

A directable, portable appliance in combination with an adjustable set-point digital temperature controller for non-contact remotely monitoring infrared temperatures of a selected area of human skin and activating an electrical fan for directing cooling air over the selected skin areas of individuals experiencing episodes of thermal chaos, i.e., hot flashes.

Devices for therapeutic interaction with an Abreu brain thermal tunnel (ABTT) terminus. Such devices provide heat to or remove heat from the ABTT terminus, and may also provide heat to or remove heat from veins connected to the ABTT. Therapeutic devices for engaging with the ABTT terminus benefit from diagnostics obtained at the ABTT terminus, or from other locations on the body.

A dynamic support apparatus. The dynamic support apparatus includes a cushion, at least one actuator wherein the at least one actuator defines an interior volume and wherein the interior volume may be configured to be at least partially filled with a fluid, and a support disposed in the interior volume wherein the support configured to support an occupant when the interior volume is not filled with the fluid such that the support is sufficient to support the occupant.

The invention relates to devices and methods for affecting an internal body tube, such as the esophagus, particularly to affecting the internal body tube by inserting a device into the internal body tube and more particularly to affecting the internal body tube by at least partially sealing off a section and moving the walls of the internal body tube, and/or applying cooling to the internal body tube. This invention further relates to methods of using such devices to move portions of an internal body tube away from an area undergoing a treatment or therapy, such as to minimize damage to the internal body tube, and/or providing cooling/temperature monitoring.

Exemplary embodiments of the present disclosure provide method and apparatus for effecting (e.g., lightening) an appearance of skin by cooling or freezing small separated surface regions of the skin to produce regions of local hypopigmentation. The width of the regions can be, for example, smaller than about 1 mm or 0.5 mm, and a distance between these frozen regions can be greater than about 3 times the width of the regions. An exemplary apparatus can be provided that includes a plurality of spatially-separated thermally conductive arrangements that can be affixed or otherwise coupled to a base. For example, the conductive arrangements can be regions of conductive material provided in or proximal to a thermal insulator, or thermally conductive protrusions affixed to the base. The conductive arrangements can be cooled and then contacted with the skin surface to produce the small regions of hypopigmentation.

Disclosed herein is a method to enable a user to use a hypothermia system to cool a body part involved in cancer therapy or in brain trauma. The method enables the user to operate the hypothermia system by her- or himself and still be mobile. The hypothermia system comprises a conformal cap system, a thermally conductive liquid located between the body part to be cooled and the cap system, thermal transfer fluids, phase change materials, thermally insulated cooler, physical measuring devices, mechanical and electrical components, a smart user interface device, a battery, and an uninterruptible power controller. The method allows a user to control the rate of and temperature of cooling down the body part, exhibits parameters associated with the process of cooling the body part, provides alerts if necessary, is portable and entirely self-managed. The hypothermia device is in communication with and can be controlled by an application installed on a smart device, such as a phone. The method of using the hypothermia system can help to eliminate hair loss caused by the side effects of certain chemotherapy treatments or to reduce the metabolic rate of ischemic tissue to prevent or minimize the severity of swelling.