A therapeutic cooling and/or compression system, configured to cool a body portion, comprises a conformal covering for covering the body portion configured to extract heat energy from the body portion, a sensor device within the conformal covering for sensing a parameter of the body portion, an actuator configured for changing an amount of heat energy extracted from the body portion, and a control unit configured for regulating the actuator responsive to control input from the sensor device. The system may be portable, enabling a patient to walk while undergoing treatment.

Devices, systems, and methods herein relate to cooling a head of a patient. These systems and methods may comprise a cooling cap assembly comprising a heat exchanger configured to be wrapped around a head of a patient and a compression assembly releasably coupled to the heat exchanger. The compression assembly may comprise an enclosure and an inflatable member coupled to an internal surface of the enclosure. When coupled, the inflatable member may be positioned between the enclosure and the heat exchanger. The heat exchanger may be separate from and moveable relative to the inflatable member.

A device for cooling the skin tissue of a patient during a procedure using energy includes a mat-like structure, the mat-like structure having a bottom wall, a top wall and upstanding walls connecting the top wall and the bottom wall, the walls defining an enclosed volume; it also includes one or more electrodes positioned to protrude from the bottom wall and extend through the volume for connection to a source of energy; further, the volume defines a space for holding a cooling substance for cooling the one or more electrodes and the skin tissue during an energy-based procedure.

Ectoparasite treatment devices utilizing heated air and related treatment methods. In some embodiments, the device may comprise a heating assembly positioned within a housing that is configured to generate heated air and a blower, such as a fan, for moving the heated air. The device may further comprise an air diffuser configured to receive heated air from the blower and to mix the heated air to increase uniformity of temperature of the heated air. A tip comprising a plurality of tines with ports may be removably coupled with the housing. The tip may be fluidly coupled with the diffuser. A temperature sensor and temperature control electronics may be configured to use temperature data and adjust the heating assembly such that the heated air delivered through the tip is maintained between a minimum temperature of about 54 degrees Celsius and a maximum temperature of about 62 degrees Celsius.

Disclosed is a cooling pack for a head including an outer cover fixed at an inside of the head protector. The outer cover adheres to a top of a human body, a refrigerant is embedded in the outer cover, and a plurality of fixers are coupled to the outer cover. The fixers are attachable to or detachable from the head protector, and the refrigerant is formed of a polyester polymer powder.

Refers to equipment (E), the objective of which is to take extremely cold air to a cap (1) comprised by a cylindrical duct (2), located in the upper part of the cylindrical structure (3) of the cap (1) which is coated by a thermal foam (ESP) and any given material (M), wherein the cylindrical duct (2) overlaps a sprinkler (ASP), which is located in the inner part (I) of the cylindrical structure (3) of the cap (1), further, the cap (1) comprises fins (4) which form an angle of 90° in relation to the inner walls (I) of the cylindrical structure (3) of the cap (1), which finally also has reinforcement ribs (5) and a circular support (6) endowed with a central hollow (7) circular and/or oval coated by a thermal foam (ESP) throughout its perimeter.

A heat exchanger cap, and method of manufacture of a heat exchanger cap configured to conform to a human head the cap comprising a first element for covering one side of the head; a second element for covering the other side of the head; and an intermediate joining element joined to, and which spaces apart, the first element and second element. Each of the elements define a single passageway for the passage of fluid through the cap. Each of the elements are provided with a flow interface in the region where the elements are joined. The flow interface defines an inlet for the passage of fluid into the passageway of one of the elements, and an outlet for the passage of fluid from the passageway out of the same element.

A heat exchanger, and method of manufacture of a heat exchanger configured to be placed into contact with an object to regulate the temperature of the object. The heat exchanger comprises a layer of material defining a passage through which a heat transfer fluid may flow. The material layer has a first side for contact with the object; and a second side which, in use, will face away from the object. The first side has a relatively high coefficient of thermal conduction. The second side has a relatively low coefficient of thermal conduction compared to the first side.

A medical cooling device and a method for operating the same are provided.

This disclosure relates to a brain cooling and spinal cord cooling system, device or mechanism for use in military helmets, and in an adapted format in non-military helmets. The system is comprised of an inflatable pad, or a set of interconnected pads, attached to the interior surface of the helmet, together with a series of valves that allow cooling gases to be delivered from a high pressure canister. The use of different cooling gases permits the achievement and maintenance of cooling of the brain for 24 to 96 hours at a mild (36° C.) or moderate (33° C.-35° C.) brain hypothermia, which is 1.5° C.-4.5° C. below the core temperature.