A method for manufacturing a belt, which molds a heating member 13 by 20 to 98 parts by weight selecting at least one of nonferrous metals constituted by tourmaline, bentonite, pozzolan, mica, red clay, zeolite, magnesium oxide, white clay, calcium, and silica, 0.1 to 30 parts by weight selecting at least one of A type Tio sol, Ag sol, and Zno having a particle size of 5 to 20 nm, graphene 01 to 10 parts by weight having a particle size of 0.20 to 2.25 nm, and functional metal colloidal 0.05 to 8 parts by weight having a size of 1 to 10 nm by selecting at least one of Ag, Au, Zn Pt, and Y, 20 to 98 parts by weight are combined by selecting at least one of the nonferrous metals and thereafter, ground into particle sizes of 500 to 1500 meshes.

A wearable device may include a first side, a second side, at least one electrode, and at least one thermocouple. The first side may be the side in contact with a subject, and the at least one electrode and the at least one thermocouple may be arranged on the first side.

A unique and innovative vest provides vibrating and heating massage. A controller is used to control vibrating modules and heating elements positioned on the vest. Through a vibration button and a heat button, the controller allows a user to selectively control vibrating and vibrating/heating massages. Using increase/decrease intensity buttons the vest facilitates optimal massage effects per the user's desire. The vibrating modules is configured to vibrate and/or oscillate in various controlled directional and rotational movements, providing a therapeutic massage. Multiple body zone switches corresponding to various massage zones of the user's body offer the user efficient control of any specific local area for achieving effective massage, thus substantially facilitating the recovery of muscles/tissues injury, alleviation of body pain, stress relief of neck, back, shoulders, etc. Further, the massage vest includes a design that promotes good posture while the user is seated.

Aspects of the present disclosure relate to a warming system including a warming device. The warming device includes a clinical garment comprising a body portion adapted to cover a portion of a patient, an inner surface for facing the patient, and an outer surface for facing away from the patient. The body portion includes sleeves sized and positioned for receiving the patient's arms and a torso portion adapted to cover an anterior torso of a patient. A first pneumatic convective device can be disposed adjacent to the inner surface of the clinical garment. The pneumatic convective device can include an opening formed in the clinical garment for admitting a stream of pressurized, warmed air into the first pneumatic convective device. The warming system can also have a second pneumatic convective device in a fully-folded configuration or partially-folded configuration and disposed on a portion of the clinical garment.

A method and an article of manufacture are disclosed for exchanging heat with a human body part to reduce fever, reduce localized swelling, warm up feet, cool down the body, increase body core temperature, and the like. A double walled water-tight article of clothing, such as a boot or a glove, may include a fluid inlet and outlet. A single walled but water-tight article of clothing may be used around a body part and allow the water to contact the skin inside the article of clothing for more rapid and direct heat exchange. Pumps, heating or cooling elements, thermometers or other devices may be included with the article of clothing. The article of clothing may be compartmentalized to concentrate the fluid around a particular body part. The fluid may continuously enter through an inlet and exit from an outlet in the article of clothing, or be a fixed amount.

Medical devices for inducing hypothermia are disclosed. Induced hypothermia is a treatment used to reduce secondary complications caused by reduced oxygen and blood flow during traumatic injuries and surgeries. However, induced hypothermia also has negative side effects such as shivering and lowered immune system. These devices incorporate Highly-Oriented Pyrolytic Graphite (HOPG) for solid conduction to lower the temperature at targeted locations on and inside the body. The benefits of incorporating HOPG include: highly efficient heat conduction, flexibility in design and manufacture, reduction of dependence on inefficient and unstable fluid-filled implants and catheters, and anti-thrombotic effects.

The present invention relates to a smart textile capable of providing acupuncture therapy to the wearer through strategically positioned electrodes throughout the textile, connected via silver coated fabric. Through the instant invention, heat therapy can be applied to specific points on the body, while being safe due to the absence of wires.

A textile product comprising a non-conductive section comprising a network of non-conductive fibres and an electric pathway comprising a network of conductive fibres, the electric pathway for conducting or transmitting an electrical signal when connected to a power source, is provided herein. The electric pathway and the non-conductive section are integrated into a common layer of the textile.

A temperature regulation system for regulating the temperature of a portion of a body, in particular of a user's body. The system comprises one humidity sensor for measuring humidity in the vicinity of the portion of a body, one temperature adjustment element for providing heat to a portion of the body, a memory unit for storing one threshold humidity related value (H.sub.thresh) and one reference user information related values (t.sub.ref, .sub.ref), a controlling unit in communication with the humidity sensor, with the memory unit and with the temperature adjustment element, and configured to determine one instant user information related value (t.sub.inst, .sub.inst), perform a comparison between one instant user information related value (t.sub.inst, .sub.inst) and one triggering user information related value (t.sub.trig, .sub.trig) based on said reference user information related value (t.sub.ref, .sub.ref), activate the temperature adjustment element to provide heat to a portion of the body depending on the result of said comparison. The controlling unit is further configured to receive one instant humidity (H.sub.inst) measured in the vicinity of the portion of the body from the humidity sensor, perform a comparison between said instant humidity related value (H.sub.inst) and one triggering humidity related value (H.sub.trig) based on said threshold humidity related value (H.sub.thresh), and to set the one triggering user information related value (t.sub.trig, .sub.trig) to a value lower than said reference user information related value (t.sub.ref, .sub.ref) when the instant humidity related value (H.sub.inst) is greater or equal to said threshold humidity related value (H.sub.thresh).

A heater system includes a bag forming a cavity, a fluid bladder carried within the cavity and forming a fluidly sealed chamber. The fluid bladder being configured to store electrorheological fluid within a fluidly sealed chamber. The heater system further including an electrical wire in fluid communication with the electrorheological fluid and a heater blanket carried within the cavity. The method includes altering the electrorheological fluid with a current and providing heat with a heater blanket.