Proposed is an oral cooling device using a cooling balloon, including: a cooling water supply portion provided with a cooler that cools cooling water and a pump that supplies and recovers the cooling water; a cooling water hose portion connected to the cooling water supply portion to transfer the supplied cooling water and recover the recovered cooling water to the cooling water supply portion; and a cooling balloon portion which is connected to an end portion of the cooling water hose portion, expands by the supplied cooling water to cool an inside of an oral cavity of a patient after being inserted into a mouth of the patient, and contracts in a case where the cooling water is recovered to the cooling water supply portion.

A thermal therapy headgear for a patient includes a plurality of thermal reaction compartments, a liquid chamber, a gas chamber, and a gas container. The thermal reaction compartments contain a first of at least two thermal reaction components, and the liquid chamber contains the second thermal reaction component. The gas container has therein a pressurized gas and a gas valve for selectively releasing the pressurized gas into the gas chamber. The gas in the gas chamber will apply pressure to the liquid chamber and force the second thermal reaction component through the valve and into the thermal reaction compartments to react and transfer heat with the patient, and the presence of the gas within the gas chamber will cushion the patient. A method for conducting hypothermic therapy is also disclosed.

Systems and methods are disclosed that relate to a stabilization and cooling apparatus having a stabilizing structure with at least one inflatable chamber, the stabilizing structure configured to become semi-rigid upon inflation of the at least one inflatable chamber. A cooling structure is integrated with the stabilizing structure and includes a single-use cooling element and a thermally conductive material in thermal communication with the single-use cooling element. The apparatus also has an actuator configured to cause inflation of at least one inflatable chamber.

A catheter is provided comprising a flexible heat transfer element provided on an outer surface of the catheter, a conduit arranged to supply an inflation fluid for inflating the flexible heat transfer element so as to form an inflated balloon, a guide wire lumen for receiving a guide wire, and an elongate cooling element arranged to cool said inflation fluid for inflating the balloon. Said cooling element and said guide wire lumen are arranged inside the flexible heat transfer element such that, when inflated the cooling element is substantially central within the balloon and said guide wire lumen is parallel to and radially offset from the cooling element.

A system including apparatus and methods for sanitizing or otherwise reducing biologics present on thermal therapeutic treatment wraps used for treating athletes after workouts or games, physical therapy patients after injury, and hospital patients after surgery is disclosed. The system includes a storage cabinet with an internal conveyor system that exposes each wrap to periodic sanitization or other biologic reduction means, such as ultraviolet light. This prevents growth of bacteria and mold. In some embodiments, warm air is blown into the storage cabinet to assist with drying the wraps.

There is provided a device for insertion into a body cavity, the device includes an insertion member configured to be inserted into the body cavity, an expandable member coupled to the insertion member, the expandable member capable of being expanded to apply pressure onto tissue within the body cavity, a first member configured for storing a first endothermic reactant therein, and a second member configured for storing a second endothermic reactant therein. In particular, the first and second members are configured to, in a state of the device (e.g., compressed state), allow the first and second endothermic reactants to cooperate to effect an endothermic reaction to generate an endothermic product. Furthermore, the expandable member is configured to receive at least one of the first or second endothermic reactant and the endothermic product through a channel within the insertion member. There is also provided a method of fabricating a device for inserting into a body cavity.

A catheter is provided comprising a flexible heat transfer element provided on an outer surface of the catheter, a conduit arranged to supply an inflation fluid for inflating the flexible heat transfer element so as to form an inflated balloon, a guide wire lumen for receiving a guide wire, and an elongate cooling element arranged to cool said inflation fluid for inflating the balloon. Said cooling element and said guide wire lumen are arranged inside the flexible heat transfer element such that, when inflated the cooling element is substantially central within the balloon and said guide wire lumen is parallel to and radially offset from the cooling element.

A thermal therapy headgear for a patient includes a plurality of thermal reaction compartments, a liquid chamber, a gas chamber, and a gas container. The thermal reaction compartments contain a first of at least two thermal reaction components, and the liquid chamber contains the second thermal reaction component. The gas container has therein a pressurized gas and a gas valve for selectively releasing the pressurized gas into the gas chamber. The gas in the gas chamber will apply pressure to the liquid chamber and force the second thermal reaction component through the valve and into the thermal reaction compartments to react and transfer heat with the patient, and the presence of the gas within the gas chamber will cushion the patient. A method for conducting hypothermic therapy is also disclosed.

A process for a therapeutic bladder pressure estimator is operative with a pump connected, in sequence, to a first hose, a supply pressure sensor, a second hose, a bladder having an inlet coupled to the second hose, a bladder outlet coupled to a third hose of substantially equal length to the second hose, a return pressure sensor, and a fourth hose coupled to the return pressure sensor and returning fluid from the pump to the reservoir. The process forms an error signal from the difference between a setpoint and the average of the supply and return pressures. A head pressure measurement may be done by turning the pump off after a steady state reading is made.

A bladder pressure estimator has in sequence a pump, a first hose, a supply pressure sensor, a second hose, a bladder having an inlet coupled to the second hose, a bladder outlet coupled to a third hose of substantially equal length to the second hose, a return pressure sensor, and a fourth hose coupled to the return pressure sensor and returning fluid from the pump to the reservoir. A pressure estimate is formed by establishing the second hose length and inner diameter as the same as the third hose length and inner diameter, and forming the pressure estimate by averaging the supply pressure and return pressure. In an alternative embodiment, a control regulator forms an error signal from the difference between a setpoint and the average of the supply and return pressures. A head pressure measurement may be done by turning the pump off after a steady state reading is made.