A medical cooling device and a method for operating the same are provided.

A thermal control unit supplies temperature controlled fluid to a patient to control the patients temperature. The thermal control unit includes a fluid outlet, fluid inlet, heat exchanger, pump, patient core temperature probe port, auxiliary sensor port, and controller. The controller receives patient core temperature readings from the patient temperature probe port and auxiliary sensor readings from the auxiliary sensor port. The controller may control a temperature of the circulating fluid in both a feedback manner using patient core temperature readings and a feedforward manner using readings from the auxiliary sensor. The auxiliary sensor may measure a characteristic of the patients tissue indicative of thermal resistance, and/or the auxiliary sensor may measure a temperature of the patients tissue at an intermediate depth. The controller may use the intermediate temperature to predict arrival at a target patient temperature. The auxiliary sensor may be an ultrasonic sensor, infrared sensor, or the like.

The air flow system includes a hose member having an exterior flow channel and an interior flow channel, a distal connector, a proximal connector, and a flow chamber. The air flow in the interior flow channel is separate from the exterior flow channel. Air flows from the exterior flow channel, through a flow chamber, around a treatment site of inflammation and back to the interior flow channel. The system for air circulation therapy also includes a connector to the hose member, an air pump supply in an inner chamber, and an air recovery unit in an outer chamber. The proximal connector includes a nozzle head, a tubular sleeve, a first set of slot openings, a second set of slot openings, a cover sleeve, and a locking ring. The system includes the flow chamber of a flexible polymeric material.

A cryotherapy apparatus including a heat exchanger, a cryotherapy chamber, cryogenic nitrogen supply and exhaust conduits to and from the heat exchanger, an air return conduit to flow warmed air from the cryotherapy chamber to the heat exchanger, an air supply conduit to flow chilled air from the heat exchanger to the cryotherapy chamber, a variable speed fan to cause flow of air through a loop including the air supply and return conduits, the heat exchanger, and the cryotherapy chamber, and a controller programmed to control the flow rate of air by regulating the speed of the variable speed fan according to a treatment protocol; and a method of delivering cryotherapy according to a customized treatment protocol taking into account one or more of: a patient's treatment goals, a customization factor, a personalization factor, and an adaptation factor.

A thermal control unit for delivering temperature-controlled fluid to one or more patient pads that are in contact with a patient is disclosed. The thermal control unit includes a fluid circuit with an inlet and outlet, a heat exchanger, a pump, and a controller. A fluid quality monitor is included in some embodiments to monitor a cleanliness of the circulating fluid and issue an alert if the cleanliness falls below a threshold. A valve may be included that is controlled by the controller based upon a measurement of the cleanliness of the circulating fluid and/or the passage of a predetermined amount of time. A second valve may also be included in some embodiments that selectively diverts fluid to an additional filter. The additional filter is used to determine if a cleaning action taken with respect to the circulating fluid was effective or not.

A system and method for hyperthermic ablation of cancerous tissue of a human patient is disclosed. A system and method include a vessel that is sized and adapted for receiving the human patient, and a circulation device outside of the vessel for circulating a thermally conductive liquid to and from the vessel, such that the portion of the human patient enclosed in the containment suit is at least partially submerged in the thermally conductive liquid when the human patient is in the vessel. The system and method further include a set of electromagnetic transmission coils at least partially around the vessel for inducing an alternating electromagnetic field around the human patient, the alternating electromagnetic field being directed, via the thermally conductive liquid, to the cancerous tissue that has been provided a conductive nanoparticle, to provide hyperthermic ablation of the cancerous tissue.

A method of controlling an infant care device includes identifying, via a location tracking system, a device location of the infant care device within a care facility by locating a device location tag on the infant care device, and also identifying any local clinician tags worn by a clinician within a predetermined area around the device location. The local clinician tags are compared to a list of authorized clinician tags to identify whether at least one local authorized clinician tag is within the predetermined area around the infant care device. User input is received at a user interface associated with the infant care device to modify operation of the infant care device. Operation of the infant care device is modified based on the user input only if at least one local authorized clinician tag is within the predetermined area around the infant care device at the time of receiving the user input.

A system and method for automatically producing and monitoring a cryotherapy session within a chamber includes a plumbing system coupled to the chamber for cooling the chamber. A central controller may be coupled to the plumbing system. The central controller may be operable for: initiating the cryotherapy session within the chamber with a cryogenic gas flowing through the plumbing system for cooling the chamber to a first temperature; determining if the first temperature has been reached within the chamber; determining if a check-in command has been received for the cryotherapy session; and stopping the cryotherapy session after a predetermined period of time. The central controller may initiate a pre-cooling session for cooling the chamber to a second temperature which is different than the first temperature; and determine if the second temperature has been reached in the chamber. The pre-cooling session generally occurs prior to the cryotherapy session for removing ambient heat.

A hand therapy kit includes hand therapy modules and a housing having defined receptacles in which the hand therapy modules are removably disposed. A module presence sensor is disposed in each receptacle to detect the presence or absence of the corresponding hand therapy module. A microprocessor disposed in the hand therapy kit sends the module presence sensor data to a remote computer that analyzes the module presence sensor data to determine whether the patient is complying with a prescribed treatment regimen. The remote computer can generate warnings, alerts, and/or notifications when noncompliance is detected.

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.