Systems and methods described herein include a pressure delivery component that has a pressure applicator configured to selectively apply therapeutic pressure to a treatment portion of a user body, and also includes a thermal delivery component that has a thermal applicator that is a configured to apply thermal treatment to the treatment portion. The thermal applicator may be removably disposable in operative relationship with the pressure delivery component in a use configuration of the treatment delivery component such that the thermal applicator is disposable between the treatment portion and the pressure applicator when the treatment delivery component is disposed on the treatment portion in the use configuration. Moreover, the pressure applicator is operable to apply pressure to the thermal applicator to enhance apposition of the thermal applicator to the treatment portion.

A targeted temperature management (TTM) system is disclosed that includes a TTM module to provide a TTM fluid, a fluid delivery line (FDL) including a FDL hub, a fluid delivery lumen and a fluid return lumen, and a pad to facilitate thermal energy transfer between the TTM fluid and a patient, the pad including a fluid delivery conduit extending away from the pad portion and including a first leak prevention valve configured to enable the TTM fluid to flow in a distal direction while preventing flow in a proximal direction, and a fluid return conduit extending away from the pad portion, the fluid return conduit including (i) a return conduit connector at a proximal end thereof, and (ii) a second leak prevention valve configured to enable the TTM fluid to flow in the proximal direction while preventing flow in the distal direction.

Thermal management devices and associated systems and methods are disclosed herein. In some embodiments, a representative device can comprise (i) thermoelectric components (TECs) each including a first side configured to be operated at a desired temperature and a second side opposite the first side, and (ii) a heat transfer system including an array of fluid distribution networks, an inlet passage coupled to the fluid distribution networks, and an outlet passage coupled to the fluid distribution networks. In operation, a working fluid flows through the fluid distribution networks from the inlet passage to the outlet passage, and absorbs heat from the fluid distribution networks. The inlet and outlet passages can be fluidically coupled to individual fluid distribution networks such that pressure drop and/or temperature drop of the working fluid across the individual fluid distribution networks is about the same as one another.

A smart thermal patch for adaptive thermotherapy is provided. In an embodiment, the patch can be a stretchable, non-polymeric, conductive thin film flexible and non-invasive body integrated mobile thermal heater with wireless control capabilities that can be used to provide adaptive thermotherapy. The patch can be geometrically and spatially tunable on various pain locations. Adaptability allows the amount of heating to be tuned based on the temperature of the treated portion.

An electric heating pad for warming a patient. The electric heating pad may be a heated underbody support, heated mattress or heated mattress overlay. An embodiment of the heating pad includes a flexible sheet-like heating element including an upper edge, a lower edge, and at least two side edges. The heating pad may also include a shell covering the heating element and comprising at least two sheets of flexible material (e.g., two sheets may be one sheet folded over to form at least two sheets). The two sheets of flexible material may be coupled together about the edges of the heating element by a weld. The material of the two sheets may include urethane. In some embodiments, a catalyst to accelerate hydrogen peroxide decomposition is coated on or impregnated into an element within the shell, or on the interior surface of the shell.

A heating pad assembly includes a flexible heating pad having a flexible substrate forming a plurality of deflectable tabs and one or more electrically conductive heating traces routed through the plurality of deflectable tabs and configured to radiate heat therefrom in response to electrical current flowing through the one or more heating traces.

A targeted temperature management (TTM) system includes a TTM module configured to provide a TTM fluid and a pad configured to facilitate thermal energy transfer between the TTM fluid and a patient. The system includes a fluid delivery line (FDL) with a hub at the distal end of the FDL. The pad includes a connector including a flapper valve configured to alternate between open and closed positions based on whether the connector is coupled with the FDL hub. The flapper valve in the closed position covers openings of each of the fluid delivery conduit and fluid return conduit when the connector is uncoupled from the FDL hub. The flapper valve is configured to deform into the open position upon coupling of the connector and the FDL hub thereby establishing fluid communication therebetween.

Provided are systems and methods for reducing pain during an injection or an insertion of an object into the skin of a subject.

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 device for providing vestibular and somatosensory stimulation through bone conduction of sound waves to skeletal bones is provided in the form of a pad that is applied to or wrapped around the individual in treatment, which is comfortable in use and may contain particulate filler material capable of providing bone conduction stimulation adjacent to the location of a bone conduction transducer and expand the sound conduction site over a larger area. The device may be located beneath a pillow or mattress.