A device for indirect temperature regulation of the brain of a human via a nasal cavity thereof, the device comprising: a membrane having a membrane surface area, a length, a center point with respect to the length, a width, and a center point with respect to the width, said membrane adapted to be arranged in contact with a surface of the nasal cavity, said membrane defining a closed volume and having the shape of the nasal cavity such that when in use, it expands and conforms to the nasal cavity, a first catheter, a second catheter, and means for circulating said fluid into said volume via said first catheter and out of said volume via said second catheter.

A cryogenic fluid composition may include water (H20), and at least one salt. The ratio of water to the at least one salt is approximately between 1% and 6% salt with the remainder water. A cryogenic fluid production device may include a cylindrical housing, and a heat exchanger disposed within the cylindrical housing. The heat exchanger may include an inlet, a channel, and an outlet. A coolant may be conveyed through the inlet, the channel, and the outlet of the heat exchanger. The cryogenic fluid production device may further include an interior wall, and an auger disposed within the interior wall of the heat exchanger.

A cooling device for removing heat from subcutaneous lipid-rich cells of a subject having skin is provided. The cooling device includes a support having a first portion and a second portion. A first cooling element having a first heat exchanging surface is located at the first portion of the support. A second cooling element having a second heat exchanging surface is located at the second portion of the support. At least one of the first and second cooling elements is movable along the support and is configured to rotate for adjusting an angle between the first and second heat exchanging surfaces.

A multi-layer thermal electronic massage roller with a cylindrical body forming a generally solid body, including an innermost core layer, insulative layer, heating element binder layer, a heating element, a conductive sleeve to pull heat away from the electronic components and direct it to the user, a stiff cylindrical layer, and an outermost fabric layer. The device further includes a battery, a power port and a thermal control module to variably adjust the temperature. A method for configuring the multi-layer thermal electronic massage roller is also provided, including configuration of the elements of the device for optimum performance and disclosure of materials for embodiments of the invention.

A medical cooling device for reducing the body core temperature of a patient and a method for operating the same are provided. The cooling process provided by the medical cooling device is based on the state or degree of shivering of the patient.

A thermostatic massage pad includes: a thermostatic pad, wherein a thermostatic water pipe is arranged inside the thermostatic pad; a cooling pad, wherein a cooling water pipe is arranged inside the cooling pad; a casing, wherein a thermostatic water pump and a cooling water pump are respectively arranged inside the casing, a thermostatic water tank is arranged at a top of the thermostatic water pump, a cooling water tank is arranged at a top of the cooling water pump, a water inlet end of the thermostatic water pump is connected to a water outlet of the thermostatic water tank, and a water inlet end of the cooling water pump is connected to a water outlet of the cooling water tank; a thermoelectric cooler, wherein an end surface of the thermoelectric cooler is fixedly connected to a wall surface of the thermostatic water tank.

Methods for treating Blepharitis, Meibomian Gland Dysfunction and Dry Eye Syndrome include thermal massage, thermal debridement, and thermal expression. Particular embodiments include use of handheld devices that provide the thermal therapy to tissue by contacting a surface heated with thermal energy to a patient's tissue. Thermal energy can be continuously provided during operation. In particular embodiments, a handheld device comprises a base assembly operatively connected to a removeable thermal energy applicator. A wide range of thermal applicators may be connected to the base assembly to provide different treatments, including heat application, debridement, and expression of the treated tissue or gland.

The present invention refers to a device to transfer heat and infrared energy with dynamic temperature control and homogeneous heat distribution that places one or more applicator modules on an affected area, later with a control module you can resort to a predefined therapy according to the affected area and some personal data of the patient, or to a therapy provided by the therapist, or even to set a temperature at which the device will heat up; the invention also refers to the manufacturing process of said device. The user can define the time interval that the therapy will last. Alternatively, the user may use a mobile application to control, monitor and personalize therapies, which he or his therapist may define from the mobile application or from a web application, where said pair of applications will be connected to a web API for data synchronization.

A method and apparatus used to prevent brain death by use of rapid and safe cooling of the brain is disclosed. The cisterna magna is accessed through a patient's neck and cooled artificial cerebrospinal fluid (aCSF) is circulated about spaces within the brain and in a subarachnoid space surrounding the brain by entering the cisterna magna with an entry through the neck of the patient with a specially designed needle/cannula which allows the flow of cooled aCSF about the brain. aCSF exits from an opening in the skull where a temperature/pressure sensor is placed. Data is sent to a computer-controlled motorized system that pumps cooled aCSF to the needle/cannula placed in the cisterna magna. The pumping of aCSF is controlled to maintain a predetermined temperature and/or pressure of the exiting aCSF.

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.