Systems configured to acquire temperature signals from an Abreu Brain Thermal Tunnel (ABTT), to analyze the temperatures signals, and to determine a condition of a human body from the analysis, and a method for doing the same, are described. In addition, systems for application of thermal signals to the ABTT for treatment of conditions are described.

Systems configured to acquire temperature signals from an Abreu Brain Thermal Tunnel (ABTT), to analyze the temperatures signals, and to determine a condition of a human body from the analysis, and a method for doing the same, are described. In addition, systems for application of thermal signals to the ABTT for treatment of conditions are described.

A thermal accessory controller comprising an input conduit providing a liquid path for a thermal liquid from the thermal accessory controller to a thermal accessory, an output conduit providing a liquid path for the thermal liquid from the thermal accessory to the thermal accessory controller, a first liquid pump in liquid communication with the input conduit and the output conduit, and a thermal liquid reservoir in liquid communication with the first liquid pump. The thermal accessory controller includes a first liquid block in liquid communication with the first liquid pump, the first liquid block including an internal channel for transferring the thermal liquid, and a second liquid block including an internal channel for transferring a coolant liquid. The thermal accessory controller includes a heating component in liquid communication with the first liquid pump, a cooling component in liquid communication with the second liquid block, and a heat transfer component configured to transfer heat from the first liquid block to the second liquid block.

A thermal accessory controller for controlling the temperature of a thermal accessory. The thermal accessory controller comprises a liquid reservoir for storing a thermal liquid that circulates through the thermal accessory, a temperature control system (TCS) in liquid communication with the liquid reservoir that adjusts the temperature of the thermal liquid according to a TCS target temperature value, and a control unit that controls the temperature control system using the TCS target temperature value. The control unit receives a TCS target temperature, receives a temperature measurement from a temperature sensor, and determines a magnitude of a difference between the TCS target temperature and the temperature measurement. The control unit executes a proportional-integral-differential (PID) algorithm to cause the temperature control system to adjust the temperature of the thermal liquid based on the difference between the TCS target temperature and the temperature measurement.

A rollable apparatus includes a housing being annular in shape, a heating element mounted about the exterior of the housing, a vibration-inducing motor mounted in the interior of the housing and attached thereto, and a set of batteries mounted in the interior of the housing. The set of batteries is provided for powering the heating element to control the temperature of the housing and for powering the vibration motor to induce oscillatory motion in the housing. The apparatus also includes a set of user controls mounted so as to be accessible at the exterior of the housing, a front cover removably mounted so as to form a portion of the exterior of the housing at one end thereof, and a skin of pliable cushioning material covering the housing.

According to some embodiments, a method of treating a skin surface of a subject comprises heating a skin surface, abrading native skin tissue of a subject using a microdermabrasion device, wherein using the microdermabrasion device comprises moving the microdermabrasion device relative to the skin surface while simultaneously delivering at least one treatment fluid to the skin surface being treated and cooling the abraded skin surface.

A temperature-controlled massage node that imparts either or both a heating or cooling effects is provided, which may be attached to a massager to impart a heating or cooling effect on a user with a massage effect, or optionally, without a massage effect. The temperature-controlled massage node may be affixed to the massager or may be removably coupled. The temperature-controlled massage node may be powered by the same power source as the massager or may include an independent power source located, for example, in the massage node. The massage node may be used with a massager that provides percussive massage effects, such as a massage gun, or may be used with a vibrating massager. Optionally, the massage node may include independent power, a controller and a motor to supply both a vibrating massage effect and hot and cold effect, either alone or in combination.

A temperature-controlled massage node that imparts either or both a heating or cooling effects is provided, which may be attached to a massager to impart a heating or cooling effect on a user with a massage effect, or optionally, without a massage effect. The temperature-controlled massage node may be affixed to the massager or may be removably coupled. The temperature-controlled massage node may be powered by the same power source as the massager or may include an independent power source located, for example, in the massage node. The massage node may be used with a massager that provides percussive massage effects, such as a massage gun, or may be used with a vibrating massager. Optionally, the massage node may include independent power, a controller and a motor to supply both a vibrating massage effect and hot and cold effect, either alone or in combination.

A heat exchanger module (HEM) and system uses a flexible substrate with one or more open channels, to which a substrate cover is bonded, thereby forming closed channels in the flexible substrate. Thermoelectric coolers (TECs) are attached to optional thermally diffusing copper squares atop the substrate cover. An interface cover is attached to the TEC tops, with a compliant thermally conductive material opposite the TECs and ultimately in contact with a patient. A liquid is passed through the closed channels, which act as thermal references for the TECs. Current is supplied by a controller to the TECs to induce TEC cooling or heating relative to the liquid. One or more temperature sensors detect the temperature of the interface cover, which are used as inputs to the control of the TEC supply current. The HEM may be used for heating, cooling, or cycling between heating and cooling for various medical uses.

The system includes a pump, a heat exchanger, a bladder, a thermometer, and a controller. The heat exchanger is in fluid communication with the pump. The bladder is configured to be placed over a carotid artery, and is in fluid communication with the heat exchanger. The thermometer is located with respect to the heat exchanger and configured to measure a temperature of fluid downstream from the heat exchanger. The controller is in electrical communication 28 with the thermometer and the heat exchanger. The controller is configured to 20 control power delivered to or flow through the heat exchanger such that the temperature of the fluid downstream from the heat exchanger measured by the thermometer is between 2 degrees C. and 10 degrees C. for between 10 minutes and 50 minutes.