To provide a holder which is for a heating and cooling tool and which fits on the upper arm and can provide a stable heating or cooling effect to skin. This holder for a heating and cooling tool is mounted on the upper arm, and comprises: a holding part having a pocket in which a heater or cooler is accommodated; and a belt joined to the holding part so that an insertion space into which the upper arm is inserted is formed between the holding part and the belt, wherein the holding part is made of a material that does not substantially expand or contract, and the belt is made of an elastic material to allow the belt to conform to changes in the thickness of the upper arm accompanying bending and straightening of the elbow.

A vertical motion adjuster for a thermotherapy device includes a conveyance unit provided with a movable member configured to move along a mat, a support unit having a first side and a second side, the first side rotatably coupled to one side of the conveyance unit, and an elevation unit installed between the conveyance unit and the support unit and configured to adjust an angle of inclination of the support unit by raising or lowering the second side of the support unit such that the second side of the support unit is moved in the shape of an arc.

Disclosed are methods, devices, and systems for treatment of an abnormal wound healing response. The methods, devices, and systems can be used to treat solid ulcerated tissue, such as diabetic foot ulcers (DFUs), arthritic tissue, muscle soreness, joint pain, varicose veins, obesity, and peripheral artery disease. Additionally, the methods, devices, and systems can promote the healing of xenograft, allograft, autograft, or engineered tissue following reconstruction surgery. The methods, devices, and systems include the ability to determine an optimal set of pulse parameters that are specific to wound healing. In embodiments, the methods, devices, and systems include components for guiding the user on electrode placement based on anatomical or electrical measurements, delivering a custom series of electric pulses, applying heat, and using feedback from physiologic measurements to control the device.

Disclosed are methods, devices, and systems for treatment of an abnormal wound healing response. The methods, devices, and systems can be used to treat solid ulcerated tissue, such as diabetic foot ulcers (DFUs), arthritic tissue, muscle soreness, joint pain, varicose veins, obesity, and peripheral artery disease. Additionally, the methods, devices, and systems can promote the healing of xenograft, allograft, autograft, or engineered tissue following reconstruction surgery. The methods, devices, and systems include the ability to determine an optimal set of pulse parameters that are specific to wound healing. In embodiments, the methods, devices, and systems include components for guiding the user on electrode placement based on anatomical or electrical measurements, delivering a custom series of electric pulses, applying heat, and using feedback from physiologic measurements to control the device.

A means can be used instead of or with conventional temperature control to achieve warming device temperature control at a lower cost, prevent or reduce deterioration of a warming device over time, and lower generated heat temperature due to storage at high temperatures. The warming device can be used for the same. A higher level temperature control means can be used for warming devices for medical applications. An improved warming device can be used for medical applications with a high level of safety and efficacy. A temperature control agent controls a maximum temperature of a warming device with a heat generating composition that generates heat by reaction with oxygen. Said agent includes an aliphatic compound that has a particle form that will not pass through a standard sieve with a #60 mesh, a melting point of 35-65? C., and an aqueous solubility (g/100 mL) at 20? C. of ?5.

A warming device containing a topsheet to be located close to a skin of a user, a backsheet to be located far from the skin of the user, and a heat generating element interposed between the topsheet and the backsheet. The heat generating element contains an oxidizable metal, a carbon material, an electrolyte, and water, the heat generating element is configured to generate vapor from the heat generating element itself as heat is generated, the topsheet includes a breathable fiber sheet including fibers containing at least a polyethylene terephthalate resin, and the topsheet contains first fibers having a fiber diameter of more than 15 ?m in plan view as measured by observation under a scanning electron microscope.

A device comprising a casing; at least one vibratory source; at least one power source; at least one switch to actuate the vibratory source; electrical communication between the vibratory source, the power source, and the switch; and an optional thermal element for modulating the temperature of a contacted area of a surface. Also disclosed herein are methods for using the disclosed device.

A device that is used to reduce the pain of a needle stick to a person, the device having a casing containing a vibratory device and a temperature reducing device, and a method for using the device to reduce the pain of a needle stick by applying both thermal and vibration analgesia to a subject during a needle stick.

A heating body, in which a heat-generating composition that generates heat in the presence of air, is accommodated in a bag body formed by heat sealing a one-surface side laminated base material including a first base material and a second base material, and a covering material, at a peripheral edge portion thereof. The first base material has a nonwoven fabric layer and a heat sealable resin layer; and the second base material is a sheet in which an olefin-based nonwoven fabric layer and a resin film are laminated using an olefin-based resin. The first base material and the second base material are capable of forming a space into which a body part can be inserted or held. The heat sealable resin layer and the nonwoven fabric layer are bonded together, and the resin film of the second base material and the covering material are bonded together.

A device comprising a casing; at least one vibratory source; at least one power source; at least one switch to actuate the vibratory source; electrical communication between the vibratory source, the power source, and the switch; and an optional thermal element for modulating the temperature of a contacted area of a surface. Also disclosed herein are methods for using the device.