A device applies therapeutic treatment to a subject. The therapeutic treatment includes any two modalities applied simultaneously, the modalities selected from compression, heat, vibration, and massage. The device includes a main body; hinges coupled to the main body on each side of the main body; and respective plates connected to the hinges, wherein the respective plates contact opposing surfaces of a body.

The present invention generally relates to improved medical devices, systems, and methods, with exemplary embodiments providing improved cooling treatment probes and cooling treatment methods and systems. In some embodiments, freezing of the skin may be desirable to effect the hypopigmentation of the skin of the patient. Generally, embodiments may limit supercooling of the skin of the patient during a cooling treatment. Additionally, embodiments may limit adverse side effects such as hyperpigmentation. It has been found that the freezing behavior (frequency and time to freeze) can be modified by adjusting the thermal parameters of the cooling applicator. Accordingly, in some aspects of the invention, a method of treating the skin may be provided where the thermal parameters of the cooling applicator are adjusted during treatment.

Methods and apparatus for an improved contrast therapy device that delivers alternating heated and chilled temperature fluids to a contrast thermal therapy pad. Mitigation processes maintain water temperature in hot water tanks and cold water tanks in order to keep water temperatures in the respective tanks from drifting beyond a desired setpoint range when the system switches a therapy state from a cooling cycle to a heating cycle or from heating cycle to a cooling cycle. Thermal shock is reduced to the fluid tanks. Mitigation techniques include delaying actuation of a return path flow, such as via a diverting solenoid. Mitigating delay can be a static time delay based upon one or both of: a volume of water in a therapy pad and related volume and rate of flow; and meeting a threshold transition temperature for return fluid temperature.

Systems and methods for manipulating the temperature of a surface are described. Described embodiments include thermal adjustment devices that may include a heatsink and that are operated in two or more modes of operation to apply a desired temperature to a user. In one operating mode the thermal adjustment device may apply a first temperature to an underlying surface while generating heat at a rate faster than the heatsink's heat dissipation rate. The thermal adjustment device may then apply a second temperature to reduce the rate of heat generation to be less than the heatsink's heat dissipation rate. These modes of operation may be applied cyclically to permit continuous operation of the thermal adjustment device. In some embodiments, the temperature profile applied when changing between the modes of operation may be selected such that the user experiences either a reduced, or substantially, neutral thermal sensation.

Provided herein are methods of nerve blockage, for example for treatment of obesity, heart failure, cardiovascular disease, muscle spasms, chronic pain, or urinary retention in a patient. The method comprises first heating a nerve above physiological temperature (e.g., 37° C. in a human), such as from 43° C. to 54° C. for a duration that leads to reversible nerve blockage as opposed to nerve damage. Second, reversible nerve blockage is produced by cooling the nerve below physiological temperature to a temperature in which reversible nerve blockage is achieved, for example from 15° C. to 30° C.

A thermal control unit controls the temperature of a fluid delivered to one or more thermal transfer devices (e.g. thermal pads) in contact with a patient. The thermal control unit generates thermal data while being used to treat the patient and is adapted to receive thermal history data previously generated by a different thermal control unit in the treatment of that patient. Both the current and previous thermal data are displayable on the thermal control unit currently being used, thereby giving the caregiver a complete picture of the thermal history of the patient. The thermal control unit may also be adapted to transmit its thermal data, as well as the thermal history data previously received from the other thermal control unit, to still another thermal control unit. The thermal history data transfer may take place via a cable, wirelessly, by a portable flash drive, or by other means.

The present disclosure includes devices, systems and related methods useable for controlling a patient's body temperature by endovascular heat exchange as well as body surface heat exchange.

In one example, a heating and cooling garment system includes a garment, and a plurality of heating and cooling zones positioned within a portion of the garment. Each heating and cooling zone is configured to independently heat or cool based on heating and/or cooling instructions received from a mobile application executed on a wireless device.

This application relates to a cooling device that sprays a coolant received from a coolant reservoir toward a target region to cool the target region. In one aspect, the cooling device includes a spraying unit from which the coolant is sprayed, a valve configured to regulate a flow of the coolant, and a control unit configured to control opening and closing of the valve, wherein, when cooling starts. The control unit controls a first cooling mode in which a temperature of the target region is decreased and a second cooling mode in which the temperature of the target region is maintained in a predetermined temperature range to be sequentially performed.

A temperature control system comprising a first peripheral fluid circuit for the passage of a first heat exchanger fluid. The first peripheral fluid circuit comprises a first fluid connection for fluidly connecting a first peripheral heat exchanger in series with a first peripheral-evaporator heat exchanger. There is also provided a first peripheral pump for pumping the first heat exchanger fluid around the first peripheral fluid circuit. There is also provided a first evaporator circuit for the passage of an evaporator heat exchanger fluid through the first peripheral-evaporator heat exchanger. The first evaporator circuit comprises a first evaporator pump for pumping the evaporator heat exchanger fluid around the first evaporator circuit. The first evaporator circuit is fluidly isolated from the first peripheral fluid circuit. The first peripheral-evaporator heat exchanger is configured to permit heat exchange between the heat exchanger fluids.