Disclosed herein is a medical pad for exchanging thermal energy between a targeted temperature management (TTM) fluid and a patient. The pad can include a central pad and a plurality of extension pads coupled with the central pad, where the extension pads extend away from right and left lateral sides of the central pad and where each of the central pad and the plurality of extension pads includes a fluid containing layer configured for circulation of a TTM fluid therein. A method can include removing a portion of the hydrogel liner and placing a remaining portion of the hydrogel liner between the hydrogel layer and the patient. The method can also include rotating and folding one or more of the extension pads to defeat the thermal energy exchange of the rotated and folded extension pads.

The invention includes a forced-air blanket for providing a profusion of air to a patient, comprising a bottom layer with a plurality of openings configured to allow a profusion of air to pass through the bottom layer and an upper layer bonded to the bottom layer around a periphery, wherein the upper layer is also bonded to bottom layer by a plurality of linear seals and a plurality of staked seals. In an embodiment, at least one of more of the linear seals have one end which is joined to a portion of the periphery. In another embodiment, the forced-air blanket may further include at least one elongated seal that is positioned proximate to the inlet. The arrangement of the plurality of staked seals, elongated seals and linear seals assists in providing a blanket that is of a low-profile with even air distribution.

The invention relates to a system for acquiring the vital status of animals, which comprises at least one first device for acquiring vital functions, and at least one signal transmission means, wherein the first device has at least two first and/or second sensors arranged at a distance from each other. The components of the system for acquiring the vital status of animals can be detachably connected with each other by connectors.

The invention further relates to a method for determining the vital status of animals, wherein the vital functions are acquired by a first device with at least two first and/or second sensors arranged at a distance from each other, wherein the acquired data are transmitted by at least one signal transmission means to a data processing device, and there processed and evaluated, and from the data processing device to an external output device, which outputs the vital status of animals.

The invention provides fluid warming apparatus comprising: a fan; a heater, the fan and the heater being configured to generate a heated fluid flow having a principle flow direction and an inhomogeneous temperature distribution in a distribution direction perpendicular to the said principle flow direction; and a plurality of temperature sensors offset from each other in the said distribution direction, wherein at least two of the temperature sensors are configured to measure temperatures of respective portions of the heated fluid flow having different temperatures.

A system and associated methods for round-the-clock monitoring of an animal's health status includes an animal harness that is worn by the animal, and one or both of a mobile device and a remote server. The animal harness includes a plurality of sensors for collecting health measurements of the animal. The animal harness also includes a transceiver that communicates the heath measurements to one or both of the mobile device and the remote server, where a user may view the health measurements. Firmware in the animal harness, an application running in the mobile device, and software in the remote server processes and corrects the health measurements to generate a health status of the animal and notifications are generated when the animal's health is not within a safe range defined by the user.

Non-human animal compression therapy devices and methods. In some embodiments, the compression therapy devices includes one or more sleeves, each of the one or more sleeves being configured to fit a limb of a non-human animal, and each of the one or more sleeves comprising one or more inflatable chambers; and a controllable air source operably connected with the one or more inflatable chambers and configured to controllably inflate and deflate the one or more inflatable chambers. In some embodiments, at least one cycle of inflating and deflating of the one or more chambers starts by inflating the most distal chamber. In some embodiments, the compression therapy is given to eliminate or ease suffering from a disease or disorder or a sporting or work-related injury.

A protective dressing includes an outer dressing and an adhesive layer. The outer dressing includes an opening and a cavity sized to receive a phase-change material (PCM) insert inserted through the opening. The adhesive layer is configured to adhere to a patient's skin surrounding an anatomic site. When adhered to the patient's skin, the PCM insert modifies the patient's skin at the anatomic site. The PCM insert may be removed and replaced with another PCM insert. For example, a warm PCM insert may be replaced with a refrigerated PCM insert. The opening of the outer dressing may be self-sealing. The opening of the outer dressing may be sealed with an upper layer dressing coupled to the PCM cooling insert.

Personal thermal stability control herein provides for personalized temperature regulation dependent upon biometric sensor feedback, sleep stage, and so on, particularly for sleeping users, predicting and preemptively responding to fluctuations indicative of thermal stability, resulting from such things as transitions between sleep stages, hot flashes, night sweats, and general thermal instability. Specifically, in one embodiment, a system herein may comprise: an on-demand cooling system; one or more biometric sensors configured to monitor one or more corresponding indicators of thermal stability of a user; and a controller configured to: a) receive the one or more corresponding indicators of thermal stability of the user; b) predict an onset of a thermal instability of the user based on the one or more corresponding indicators of thermal stability of the user; and c) activate the on-demand cooling system to counteract the predicted onset of a thermal instability of the user.

Various implementations include a Human Thermoregulation Simulator (HTRS) that simulates the natural and primary thermoregulatory functions of a patient that are relevant during therapeutic hypothermia procedures. For example, in various implementations, a HTRS includes a core container configured to be at least partially filled with water, and the core container includes a heat generator configured to heat the water inside the core container. A middle container is disposed concentrically around the core container, and the middle container includes a foam layer configured to be saturated by water. An outer container is disposed concentrically around the middle container, and the outer container includes a network of tubing disposed on at least a portion of an inner surface of the outer container. The HTRS also includes a pump configured to circulate water from the core container through the network of tubing.

A system including tubing and a filter configured to be fluidly coupled to a vacuum source and to a heater/cooler unit by the tubing. The filter includes a filter container having negative air pressure in the filter container provided by the vacuum source to pull aerosol from the heater/cooler unit into the filter container and eliminate and/or reduce the aerosol emitted from the heater/cooler unit.