A patient temperature control system for automated temperature control according to a programmed protocol. In one aspect, at least one programmed protocol may be established for each of a plurality of patient thermal therapy phases. In turn, the temperature of a thermal exchange medium may be controlled upon the programmed protocol during each of the phases. A plurality of programmed protocols may be established, wherein a selected protocol may be utilized for automated temperature control during patient thermal therapy. The protocol may include a target patient temperature and/or a set duration for one or more of the phase of thermal therapy. The protocol may be user-definable and modifiable during therapy. In a multiphase configuration, automatic termination and initiation of successive phases may be selectively established by a user, based on target patient temperature data and/or set duration data on a phase-specific basis.

Systems and methods include a heat transfer body with opposing major surfaces formed from a thermally conductive substrate in intimate thermal interaction with an alumina exterior surface that extends across the major surfaces of the body. In an illustrative example, the heat source may be a substantially planar, silicone-based heater source (P-SBHS). The heat transfer body may be configured to thermally interact, for example, heat from a heat source proximate a first of the major surfaces to a second of the major surfaces. A temperature sensor module may be located, for example, proximate to the first major surface such that a temperature sensor thermally interacts with the first major surface. The temperature sensor module may, for example, insulate the temperature sensor from the P-SBHS.

A pressure injuries therapeutic support surface is illustrated. The surface comprises an integrated system designed for a concurrent physical and psychoneuroimmunological approach over a user, wherein the system comprises one or a plurality of independent fluid-filled main chambers, made of waterproof, flexible, extendable, and elastic material and at least two accessory chambers connected to each main chamber with at least with two free-flow conduits. The system is managed through a powered mechatronic array with its own hardware and software based on microcontrollers for the simultaneous operation of specific multidisciplinary devices.

A method and system in accordance with a particular embodiments of the technology includes applying a substance onto skin of a human subject. The applied substance can include a freezing point depressant and a liposome, an oil-in-water emulsion, a water-in-oil emulsion, or an oil-in-oil emulsion and can be configured to protect or target tissue. The substance and a surface of the skin can be cooled using the applicator to treat acne and other skin conditions.

Embodiments of the present disclosure may include an apparel device, including an apparel body including an outer layer and an inner layer, and an interior configured to receive a body part of a user. Embodiments may also include a heat transfer panel disposed between the outer layer and the inner layer. In some embodiments, the heat transfer panel includes a first side and a second side, the first side disposed adjacent the interior of the apparel body. Embodiments may also include a compressed fluid source in fluid communication with the second side of the heat transfer panel. In some embodiments, the compressed fluid source may be configured to selectively deliver compressed fluid to the heat transfer panel. In some embodiments, the heat transfer panel may be configured to cool the interior of the apparel body upon delivery of the compressed fluid to the heat transfer panel.

An eye compress assembly includes two thermally adjustable heating and cooling device and a bridge connecting the two devices is provided. The thermally adjustable device is configured to apply thermal treatment against the eye region. Within the thermally adjustable heating and cooling device the thermoelectric element is powered by a battery. A power input port is provided in the bridge to connect into a power supply in order to recharge the battery.

The present invention provides a device for rejuvenating a region of skin or mucosal tissue, comprising: a pulsed electromagnetic frequency generator; a plurality of electrodes in communication with the pulsed electromagnetic frequency generator and an RF tissue diathermy device. The electrodes apply the pulsed electromagnetic power and the RF tissue diathermy to the tissue, heating it such that one portion of the region of mucosal tissue is maintained at a predetermined temperature range T.sub.1 while another portion of the region of mucosal tissue is at least temporarily maintained at predetermined temperature range T.sub.2.

A hot air producing system produces and stores hot air, and applies the stored hot air to a human body. The system includes a heating apparatus to heat the air, a temperature setting gauge to allow a user to set a desired temperature, a pressure gauge to measure a pressure of the air in the container, a pump to pump the hot air, a fill connection, an expandable container for receiving and storing the hot air, with a valve to connect to the fill connection such that the expandable container can receive the hot air, an adjustable flow release mechanism to allow a user to adjust an amount of flow of hot air out of the expandable container, and a flexible hose connected to the adjustable flow release mechanism, with a nozzle to direct the hot air to a portion of the human body.

A flexible catheter is inserted into the esophagus to cool or warm the esophagus, particularly during certain procedures which can tend to change the temperature in the area of the esophagus. The catheter is inserted through the mouth and throat to a position, for example, proximate the heart, but within the esophagus. One or more balloons are inflated to block areas of the esophagus, while a gel is injected into the esophagus where it is immobilized by the one or more balloons. A coolant is pumped through a coolant tube affixed to the catheter, where it exchanges heat with the conductive gel.

An electric heating pad for warming a patient includes a heated underbody support or heated mattress. The heated underbody support or mattress includes a heater assembly having a flexible sheet-like heating element, conductive bus bars attached at or near side edges of the heating element, and fabric side edge extensions attached to heating element side edges. The heated underbody support or mattress also includes a layer of polymeric foam positioned under the heater assembly and a shell, including at least two sheets of flexible material, covering at least a portion of the heater assembly and the layer of polymeric foam. When the heater assembly is wrapped around the top surface of the layer of polymeric foam, side edges of the heating element extend partially down the two side walls of the layer of polymeric foam and the conductive bus bars lie adjacent those two side walls.