Disclosed are stationary massage device, system and methods for self-administrated or assisted soft tissue strain release (including trigger point therapy, strain-and-counterstrain therapy and neuromuscular release). The massage device comprises a body, wherein the body may include branches, each having flat surfaces, edges, ridges or corners. The surfaces, edges and ridges may be pushed along the myofilament direction of the soft tissues to produce pressing, rubbing, stretching and pulling actions on the soft tissues as stripping massages. The system can be configured to form different geometric shapes, and made of different materials of different firmness. The system can be further configured to perform unheated, or heated massages; and cooling treatments. In addition to being used alone, the system can be mounted on a piece of wall, a standing frame, furniture or a garment.

This invention is a sleep environment control system which uses wearable technology with physiological sensors to predict when a person will have a hot flash and to proactively provide localized cooling or accelerated airflow for that person for a limited time to alleviate the adverse effects of that hot flash. In an example, a physiological sensor can be a body temperature sensor, skin conductance sensor, or EEG sensor. This system can reduce interruptions of a person's sleep due to hot flashes and improve their quality of life.

An electric blanket including a flexible sheet-like heating element, a shell comprising two flexible sheets covering the heating element, one or more welds coupling the sheet of the shell about the edges to hermetically seal the heating element there between; and a flexible insulating layer extending over the heating element and covered by the shell providing at least one of thermal insulation and electrical insulation, wherein the heating element is held in position between the two sheets of the shell without using connectors that pierce the two sheets.

A thermal therapy device has a fluid manipulating device for thermally manipulating and circulating therapy providing fluid via flexible conduit to a tissue interacting device. The thermal therapy device utilizes a thermoelectric cooling device including a chilled fluid reservoir for extracting heat from the tissue being treated during the cold therapy cycle and utilizes a resistive electric heater for heating the tissue being treated during the hot therapy cycle.

A full body convective blanket has a head portion, a body portion and a foot portion. The head and foot portions each taper in a decreasing manner from a corresponding opposite side of the body portion to the head and foot ends, respectively, so that the blanket has a rectangular shaped body portion and head and foot portions that are shaped in the form of isosceles trapezoids. Two elongate openings are provided longitudinally along the body portion sandwiching a non-inflatable area. An opening is provided at the head portion of the blanket.

Embodiments include a flexible fabric heater. The fabric heater has a conductive base fabric having elastic properties. The base fabric may be coupled to electrical terminals. A elastomeric layer may be applied on the base fabric. The elastomeric layer may have elastic properties and includes a liquid-resistant material. A first thermal layer may be applied proximate edges along the electrical coupling between the fabric heater and the electrical terminals. The first thermal layer can have heat-resistant properties.

At least some aspects of the present disclosure feature a convective system, comprising: an inflatable convective device and a hose configured to connect to the inflatable convective device to an inflation medium source. The convective device has a pneumatic structure and an opening into the pneumatic structure, where at least part of the convective device is air permeable. The hose includes a nozzle configured to insert into the opening and a hindrance device disposed on the nozzle, where the hindrance device is configured to prevent the hose from slipping from the opening.

At least some aspects of the present disclosure feature a hose clamp to be used with a convective device. The hose clamp includes an encircling element having an inner surface and opposing outer surface, and a grabbing component extending from the encircling element, an engaging component disposed on or integrated with the encircling element and comprising a plurality of engaging elements

An inflatable air mattress for preventing snow accumulation is provided. The mattress comprises an inflatable portion comprising a textile material, and an outside air intake. A fan draws outside air into the inflatable portion through the air intake, and circulates the air when inflated. An air divider alternates between an inflating position and a circulating position that determines which air the fan blows. An air heater heats the air that passes through the fan. A controller activates the fan and air heater based on a signal from a snow sensor; controls the divider based on a signal from a pressure sensor; and controls the heater based on a signal from a heat sensor.

A combination patient-transfer and intraoperative heater device has a top and bottom chamber separated by a barrier. The patient rests on the top chamber, which has a plurality of apertures for discharge of temperature-controlled filtered heated or cooled air at a regulated pressure for patient comfort and mitigation of infection. Heated or cooled filtered air is delivered to the area surrounding the patient, maintaining body temperature during anaesthesia. The bottom chamber has a plurality of apertures. When air pressure is low or off, the bottom chamber is flat and un-inflated. When air pressure is increased, air enters the bottom chamber and the apertures emit air, creating an air cushion facilitating lateral movement of the lifter device. The device performs two functions that now require separate devices and air blowers, it saves space and reduces both costs and complexity in the operating room while mitigating risk of infection.