The P.A.C.K is designed to provide the individual with continuous refreshing air during extreme weather. The P.A.C.K mounts a fan pointed upward towards the users' body. The innovative aspect of the P.A.C.K is that it is a “hands free” portable device that allows the user to be active all the while with both hands available for work unlike the existing devices that requires the use of one hand limiting the activity of the user. This is achieved by attaching the unit to the users' pant belt. The P.A.C.K has an element guard that channels the air towards the body.

A garment structure having an adjustment mechanism for abutting at least one pad unit against a human body includes a garment body, at least one adjustment belt, and at least one pad unit being an electrode pad unit, a heating pad unit, or an electrode pad unit with a heating unit. The adjustment belt has one end connected to the garment body, and another end fixed to an outer surface of the garment body. When the adjustment belt is pulled tight, the garment body is dragged to move toward the skin. The pad unit is disposed on the garment body, and moves, along with a portion of the garment body being dragged, to abut against the skin. A user wearing the garment structure can pull and secure the adjustment belt to enable the pad unit to easily and quickly abut against the skin to proceed with electrotherapy and/or heat therapy.

Approaches for portably and discreetly treating muscle cramping using one or more of a selectively controllable transcutaneous electrical nerve stimulation (TENS) unit and a heating element comprising resistive fabric. Cramping of the muscle may be detected with a surface electromyography (sEMG) unit. Artificial intelligence techniques may be applied using the sEMG signals and/or user input to identify effective treatment settings.

A non-invasive, non-surgical, medication free therapy system for application to a targeted body location is provided. The therapy system includes a pouch having a first side and a second side. The first side is configured for contact with the targeted body location. Each of the first and second sides has an inner surface. The inner surfaces of the first and second sides define an internal cavity. A cold temperature source is contained within the internal cavity and is in direct contact with the inner surfaces of the first and second sides. One or more attachment straps are configured for attachment to the second side of the pouch and further configured to position the therapy system adjacent to the targeted body location. The one or more attachment straps still further configured for repeatable and removable attachment to the pouch.

A heating device includes a heating unit and device electronics. The heating unit is configured to deliver heat to a user's body. The heating unit includes a substrate and a heating element supported by the substrate. The device electronics are coupled to the heating element and are configured to store a first heating profile that includes data indicating how power should be delivered to the heating element over a first period of time. The device electronics are configured to deliver power to the heating element according to the first heating profile. The device electronics are configured to wirelessly receive a second heating profile from an external computing device. The second heating profile includes data indicating how power should be delivered to the heating element over a second period of time. The device electronics are configured to deliver power to the heating element according to the second heating profile.

A system and method for providing Thermal contrast therapy are presented. The system may comprise a fluid membrane barrier, a human interface device (HID), fluid tubing, a pump, and a reservoir. The system may be operable to apply any combination of heat, cold, and pressurized compression, light energy, acoustic energy, and vibratory energy to a therapy recipient for treating anal-prostate-perineal and vaginal areas, as well as podological and other extremities. The system may be operable to impart a desired therapy temperature to the human interface device and to expand a membrane containing a therapy fluid. The expanded membrane may conform to the contours of a therapy site. Operation of the human interface device may be controlled using a remote-control device. The therapy recipient may be able to control the temperature of the fluid or gel, as well as reception of light energy, acoustic energy and vibratory pulsing energy to assist in treatment of one or more conditions.

Devices that are implantable within a patient's body, and more specifically, to implantable joints (e.g. hip joint, knee joint, shoulder joint, etc.) having a heating system. For example, a device implantable within a patient's body may include a first member configured to be coupled to a first bone and a second member configured to be coupled to a second bone, the first and second members being operatively coupled to form a moveable joint. A heating system may be configured to controllably heat at least a portion of the at least one of the first and second members. The heating system may include a controller operable to cause a heating element to apply heat based on one or more external conditions (e.g. temperature, humidity, etc.).

A heating device includes a heating unit and device electronics. The heating unit is configured to deliver heat to a user's body. The heating unit includes a substrate and a heating element supported by the substrate. The device electronics are coupled to the heating element and are configured to store a first heating profile that includes data indicating how power should be delivered to the heating element over a first period of time. The device electronics are configured to deliver power to the heating element according to the first heating profile. The device electronics are configured to wirelessly receive a second heating profile from an external computing device. The second heating profile includes data indicating how power should be delivered to the heating element over a second period of time. The device electronics are configured to deliver power to the heating element according to the second heating profile.

A heating device includes a heating unit and device electronics. The heating unit is configured to deliver heat to a user's body. The heating unit includes a substrate and a heating element supported by the substrate. The device electronics are coupled to the heating element and are configured to store a first heating profile that includes data indicating how power should be delivered to the heating element over a first period of time. The device electronics are configured to deliver power to the heating element according to the first heating profile. The device electronics are configured to wirelessly receive a second heating profile from an external computing device. The second heating profile includes data indicating how power should be delivered to the heating element over a second period of time. The device electronics are configured to deliver power to the heating element according to the second heating profile.

The present disclosure generally relates to a textile (100) and a manufacturing method (200) thereof. The textile (100) comprises: a fabric body (102) formed from one or more types of yarns; a continuous channel (104) formed within the fabric body (102); and an insulated conductive element (106) disposed within the continuous channel (104), wherein the textile (100) is heatable in response to electrical current being conducted through the insulated conductive element (106).