A sequential compression and temperature therapy blanket with a plurality of air chambers is disclosed. The air chambers are filled and released by a valve assembly that may be separate from or integrated within the blanket. The temperature therapy blanket includes a fluid bladder for delivering hot and/or cold therapy to a patient. The temperature therapy blanket may also include an air bladder for providing compression.

An in-ear stimulation device for administering caloric stimulation to the ear canal of a subject includes (a) first and second earpieces configured to be insertable into the ear canals of the subject; (b) at least first and second thermoelectric devices thermally coupled to respective ones of the first and second earpieces; (c) a first heat sink thermally coupled to the first thermoelectric device opposite the first earpiece and a second heat sink thermally coupled to the second thermoelectric device opposite the second earpiece; and (d) a controller comprising a waveform generator in communication with the first and second thermoelectric devices, the waveform generator configured to generate a first control signal to control a first caloric output to the first thermoelectric device and a second control signal to control a second caloric output to the second caloric device.

A device for delivering caloric vestibular stimulation to an individual, includes: (a) an earpiece configured to be at least partially insertable into the ear canal of the individual for delivering a first thermal stimulus; (b) an input unit for receiving a user input indicating efficacy of said first thermal stimulus, and (c) a controller operatively associated with said earpiece and said input unit for: (i) controlling said earpiece to provide said first thermal stimulus, and (ii) receiving a signal corresponding to the user input and generating a control signal to control the earpiece and delivering a subsequent thermal stimulus different from said first thermal stimulus. In some embodiments, each thermal stimulus is an actively controlled time varying waveform stimulus.

A nerve tissue stimulator configured for contacting to or insertion in the body of a subject to stimulate a tissue therein, said probe comprising: (a) a support configured for contacting to or positioning adjacent a tissue of said subject; (b) at least one thermoelectric device (TED) on said support and positioned for thermally stimulating said nerve tissue.

A rapid contrast therapy system can provide cold, heat/hot/warm (hereafter referred to as hot), and/or rapid contrast therapy, which involves rapidly alternating between cold therapy and hot therapy. The system can circulate cold or hot fluid, such as water, through a hose, into a therapy wrap, and then back to the fluid reservoirs of the system. The system can utilize a vapor compression system or other chiller technology to cool the cold water reservoir, and immersion heaters can be used to heat the hot water reservoir.

A device for delivering caloric vestibular stimulation to an individual, includes: (a) an earpiece configured to be at least partially insertable into the ear canal of the individual for delivering said caloric vestibular stimulation; (b) a power supply operatively associated with said earpiece; and (c) a controller operatively associated with said power supply and said earpiece for configuring said caloric vestibular stimulation as at least a first and second time-varying waveform. Preferably, the waveforms are actively controlled waveforms.

A combination therapy pad that includes a first layer and a second layer operatively coupled to the first layer. A fiber-optic array is disposed between the first layer and the second layer. A third layer is operatively coupled to the first layer. The third layer includes a vacuum tube in fluid communication with a vacuum source and a therapeutic fluid tube in fluid communication with a therapeutic fluid source. The third layer provides at least one of vacuum therapy and therapeutic fluid treatment to a wound area.

One aspect of the invention provides a cooling device including a cooling unit and a control unit. The control unit is programmed to control operation of the cooling unit in order to cool one or more sebaceous glands within a local region for a period of time and to a temperature sufficient to disrupt function of the one or more sebaceous glands without permanently injuring epidermal tissue or cooling subcutaneous adipose tissue to 25 C. or below 25 C.

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.

A temperature management system is configured to control a temperature of a patient's body using a heat exchange device. The temperature management system is configured to deliver temperature management treatment or therapy to a patient. A user interface of the system is configured to display operational data and patient data on the user interface in a configuration that allows a user to determine or review one or more periods of the performed temperature management treatment.