An intra vascular temperature management catheter incudes a shaft through which working fluid can circulate to and from a proximal location on the shaft. The catheter extends from a connector hub. At least one heat exchange member is supported by a distal part of the shaft or other part of the catheter to receive circulating working fluid from the proximal location. A temperature sensor is supported on the catheter for generating a temperature signal representative of blood temperature to a control system. The temperature sensor includes first and second conductive leads having respective first and second distal segments on or in the catheter shaft. The first and second distal segments are arranged to be in thermal contact with blood flowing past the catheter when the catheter is disposed in a blood vessel of a patient. Also, the temperature sensor includes a joining body connected to proximal segments of the first and second leads. The joining body may be supported in the hub or in another location proximal to the first and second conductive leads.

A medical treatment device smart controller that includes a physical electrical connector for connecting to a medical treatment device with a treatment modality that can be changed when a signal is provided to the physical electrical connector. The medical treatment device smart controller also includes a processor coupled to a wireless communication channel and the physical electrical connector and configured to process the change input and send the signal on the physical electrical connection to change the treatment modality of the medical treatment device. The controller also includes memory coupled to the processor, where the processor is configured to write recovery data into the memory, and the recovery data includes the change to the treatment modality of the medical treatment device. The processor is further configured to periodically send the recovery data over the communication channel.

Controllers for dry eye treatment apparatus and methods are described herein which generally comprise a patch or strip affixed to the skin of the upper and/or lower eyelids to deliver heat to the one or more meibomian glands contained within the underlying skin. The treatment strip or strips include one or more strips configured to adhere to an underlying region of skin in proximity to one or both eyes of a subject such that the one or more strips allow for the subject to blink naturally without restriction from the one or more patches. A controller is in communication with the one or more strips and is programmable to monitor a temperature of the one or more strips to provide a treatment therapy above a threshold temperature. Additionally forceps for mechanically expressing the Meibomian glands may be included with the strips and/or controller.

A multi-function heated garment capable of performing multidirectional physical therapy includes a garment body, a hood, a heating control device, a quick charge source, and a heating load. The heating load includes at least one first carbon fiber heating sheet and a second carbon fiber heating sheet arranged inside the garment body and the hood, respectively. Second electrically conductive buttons provided on the garment body are buckled and electrically connected to first electrically conductive buttons provided on the hood. The hood can be connected or disconnected as required. The carbon fiber heating sheets share the quick charge source and the heating control device. It is safe and convenient to use. It can perform multi-directional heating and infrared physical therapy on various parts of the human body.

A device comprising a housing having a handle end and a treatment end. The treatment end is configured to provide an antimicrobial treatment and a heat treatment. The treatment end comprises an applicator having an applicator surface for providing at least the heat treatment. The device includes a heat generation unit configured to heat the applicator surface in use, a source of antimicrobial agent, and a control unit operatively connected to at least the heat generation unit for controlling the heat generation unit. The device can be a hand-held device and used to apply topical treatment to a treatment area of a subject.

A thermal control unit for controlling a patient's temperature includes a fluid outlet for delivering temperature-controlled fluid to a patient, a pump, a heat exchanger, and a controller that automatically implements a step change in the temperature of the fluid delivered to the patient. The step change is implemented prior to the patient reaching a target patient temperature. In the moments after (and in some cases the moments before) the step change, the controller monitors the rate of change of patient's temperature to evaluate whether the patient will reach the target patient temperature without reversing the step change, and/or how long it will likely take for the patient to reach the target patient temperature without reversing the step change. The controller then determines whether to reverse the step change or to switch to another algorithm for controlling the fluid temperature.

A distributed-weight heating pad includes a weighted layer in between two covers that provides additional pressure on a user. The weighted layer has a plurality of pockets with weighted elements therein and formed with channels between pockets that allow or enhance articulation of the distributed-weight heating pad. A heating element layer is also disposed between the covers along with a controller and battery that cause the heating element layer to provide both conductive heating and radiation heating. Moreover, the controller may cause the heat from the heating element layer to have a ramping segment to quickly apply heat until a desired temperature is reached. Other devices and methods are presented.

Devices, systems and methods for controlling a patient's body temperature by endovascular heat exchange and/or surface heat exchange.

In one example embodiment, a system for stimulating tissue with the application of temperature-regulated fluid and negative pressure comprises a negative-pressure source adapted to provide negative pressure to a dressing. The system may further comprise a thermoelectric module thermally coupled to a first heat exchange chamber and a second heat exchange chamber and adapted to transfer heat between said heat exchange chambers. The thermoelectric module can be further adapted to maintain a temperature-regulated fluid fluidly coupled to the first heat exchange chamber and the dressing within a predetermined temperature range by adding heat to and extracting heat from the temperature-regulated fluid as it passes through the first heat exchange chamber.

The disclosure describes a cryogenic device with a display device for displaying one of a plurality of user-interfaces associated with a plurality of cryogenic device states. The cryogenic device is configured to: generate an initial user-interface for display on the display device; determine that the cryogenic device is in a first state; generate, in response to determining that the cryogenic device is in the first state, instructions for rendering a first user-interface, wherein the first user-interface is associated with the first state; and cause the display device to display the first user-interface. In this way, the cryogenic device may have a dynamic user interface that is configured to response to states of the cryogenic device.