A system that can be used to provide highly controlled thermal therapy and compression to both cool and heat a skin surface and a joint and surrounding tissue below the skin surface is provided. The system includes a joint conforming wrap; a power supply module for supply power to the joint conforming wrap and a cable operably coupling the wrap and the power supply module. The joint conforming wrap and power supply module include opposing thermoelectric modules. The joint conforming wrap is designed to provide heat transfer processes to the body of a patient to warm or cool the skin and a joint and surrounding tissue disposed under the skin.

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

A thermal control unit supplies temperature controlled fluid to a patient to control the patient's temperature. The thermal control unit includes a fluid outlet, fluid inlet, heat exchanger, pump, patient temperature probe port, user interface, and controller. The controller receives patient temperature readings from the patient temperature probe port and controls a temperature of the circulating fluid in a first manner when no event data is received regarding treatment of the patient. The controller controls a temperature of the circulating fluid in a second and different manner when event data is received. The event data may relate to medication and/or fluid administered to the patient. The different manners include determining a target fluid temperature in using different inputs and/or alarming in different manners. In some cases, the controller pauses the use of the patient temperature readings while continuing to deliver temperature controlled fluid to the patient.

A pediatric magnetic resonance (MRI) system and sub-system are provided. The pediatric MRI system includes a magnet-gradient assembly, an RF shield-body coil assembly and a pediatric MRI sub-system. The pediatric MRI sub-system includes an infant warmer or isolette having a patient section for accommodating a patient. The infant warmer is positionable relative to the magnet-gradient-body coil assembly of the pediatric MRI system. The pediatric MRI sub-system also includes a warming mattress arranged within the patient section of the infant warmer. The infant warming mattress includes an interior space filled at least partially with a host medium and a conduction heating system at least partially arranged in the interior space to conduct heat to the interior space of the infant warming mattress. The pediatric MRI system also includes at least one local radio frequency (RF) coil that is positionable within the patient section of the infant warmer.

A system and method for providing Thermal contrast therapy are presented. The system may comprise a fluid membrane barrier, a human interface device (HID), fluid tubing, a pump, and a reservoir. The system may be operable to apply any combination of heat, cold, and pressurized compression, light energy, acoustic energy, and vibratory energy to a therapy recipient for treating anal-prostate-perineal and vaginal areas, as well as podological and other extremities. The system may be operable to impart a desired therapy temperature to the human interface device and to expand a membrane containing a therapy fluid. The expanded membrane may conform to the contours of a therapy site. Operation of the human interface device may be controlled using a remote-control device. The therapy recipient may be able to control the temperature of the fluid or gel, as well as reception of light energy, acoustic energy and vibratory pulsing energy to assist in treatment of one or more conditions.

A health care device includes a soft water bag, a control unit disposed on a side of the soft water bag, a temperature control element electrically connected to the control unit and disposed inside the soft water bag. When the control unit controls the temperature control element, the temperature control element disposed inside the soft water bag is energized to heat and control a temperature of liquid in the soft water bag, so as to provide better portability than the conventional products.

A multifunction sleeve for a jointed limb is provided. The sleeve may include multiple sections each with one or more inflatable chambers. One or more temperature sensors, one or more range of motion sensors, one or more thermal elements are provided for application of heat or cold therapy. A control device is provided which is adapted to: receive temperature data from the temperature sensors; receive range of motion data from the range of motion sensors; receive temperature data from the thermal elements; control timing, order and duration of inflation and deflation of the inflatable chambers; and control application, timing, temperature, and duration of the heat or cold therapy. A user device may be adapted to receive, store and analyze the temperature and range of motion data received from the control device and/or the sleeve. Potential adverse events may be predicted based on the data received.

Disclosed are indicators for confirming fluid connections in systems, pads, and methods thereof for targeted temperature management. For example, a pad can include a multilayered pad body, a pad inlet connector, a pad outlet connector, and an indicator for visual indication of charging a conduit layer of the pad body with a supply fluid and confirmation of accurate fluid connections. The conduit layer includes one or more conduits for conveying a temperature-controlled fluid as the supply fluid from a hydraulic system of a control module as well as convey a return fluid back to the hydraulic system. A thermally conductive adhesive layer over the conduit layer is for placement on a portion of a patient's body. The pad inlet connector includes a pad inlet for charging the conduit layer with the supply fluid. The pad outlet connector includes a pad outlet for discharging the return fluid from the conduit layer.

A medical pad for exchanging thermal energy between a targeted temperature management (TTM) fluid and a patient is disclosed. The pad can include a fluid containing layer and a fluid conduit attached therewith via rotatable joint where the joint is configured to facilitate rotation of the fluid conduit with respect to the pad. A method of manufacturing the pad can include coupling a first member of the rotatable joint to a fluid delivery line, coupling the second member to the fluid containing layer, and inserting the first member within an opening of the second member to facilitate a snap-fit retention mechanism between first member and the second member. A method of using the pad can include rotating the fluid delivery line relative to the thermal pad via the rotatable joint when initially applying the pad to the patient or when adjusting an orientation of the pad on the patient.

A targeted temperature management (TTM) system is disclosed that includes a TTM module configured to provide a TTM fluid and a thermal pad configured to facilitate thermal energy transfer between the TTM fluid and a patient. The system further includes a fluid delivery line (FDL) coupled with the TTM module at a proximal end. A hub at the distal end of the FDL includes a delivery hub connector coupled with the delivery conduit connector, a return hub connector couples with the return conduit connector, and a locking mechanism is selectively configurable to alternate between a release configuration and a lock configuration. When the locking mechanism is in the lock configuration, it prevents at least one of separation of the delivery conduit connector from the delivery hub connector or separation of the return conduit connector from the return hub connector.