A massaging garment assembly includes a body suit that is wearable on a user's body to cover areas of the user's body generally associated with massage therapy. A plurality of first massage balls is each of movably embedded into the body suit to massage the user's body at common massage point. A plurality of sets of second massage balls is each movably embedded into the body suit to massage the user's body at the common massage points. A plurality of first massage rollers is each of the first massage rollers is movably embedded into the body suit to massage the user's body at the common massage points. A plurality of sets of second massage rollers is each movably embedded into the body suit to massage the user's body at the common massage points.

A vibrating glove comprises an elastic material based glove comprising a textured surface on the palm region and a plurality of finger portions having rugged surfaces, a plurality of vibration motors; a rechargeable port connected to a rechargeable battery; the plurality of vibration motors, the rechargeable battery connected to the rechargeable port, being positioned within the elastic glove under the outer cover, the rechargeable port connected to the recharagble battery is positioned near the wrist portion, a plurality of modes for vibration, an illuminating means, a vibration and illumination mode depending upon the mood of the user, to enjoy the simulation of the body part.

A garment assembly includes a sleeve member having outer and inner surfaces, a first vibration assembly associated with the sleeve member, and a control module associated with the sleeve member. The first vibration assembly includes a plurality of vibration motors that are arranged in a circle about a center point. An angular distance between each vibration motor of the plurality of vibration motors is approximately the same. The control module includes a battery, and the first vibration assembly is in electrical communication with the control module.

A garment assembly that includes a garment member with an inner surface and an outer surface, a power source, and at least a first linear motor positioned adjacent the inner surface of the garment member. The first linear motor is electrically coupled to the power source and includes a shaft member that includes a magnet. A distal end of the shaft member is configured to reciprocate against the inner surface of the garment member.

A garment provides therapeutic pressure to the body of a wearer in response to a two-factor authentication system. The garment includes reversibly inflatable chambers configured to press against the body of a wearer. The garment includes a pump fluidly connected to the chambers and a controller. The controller sends an inflation signal to the pump to inflate the chambers and a deflation signal to the pump to deflate the chambers. The garment includes touch-sensitive fabric. In some implementations, the controller sends the inflation signal to the pump in response to one or more touches to the touch responsive fabric. In some implementations, the controller sends the inflation signal to the pump in response to biometric data.

The back massaging device is intended to provide users with a vest that includes massaging units inbuilt within the vest. More specifically, it is an aim of the device to provide an inbuilt massaging unit with massaging arms that can travel from the shoulders to the lower back of the user. To accomplish this, the device includes two massaging units that can traverse J-shaped tracks inbuilt within the vest. In other words, the back massaging vest allows for a portable massaging device for users on the go or want to do other activities while having the comfort of a massage. The massaging arms in particular traverse a track that allow full coverage of the user's back. Further, the massaging device may be wirelessly controlled with a remote control or a wireless communication device.

A chest compression assist glove is disclosed herein. The chest compression assist glove solves numerous problems in the performance of CPR by a human and is intended to provide mechanical advantage for a single rescuer performing chest compressions. The chest compression assist glove disclosed herein mitigates the fatigue and degradation of performance experienced by the rescuer due to the high energy demands of performing an intrinsically mechanically disadvantaged action over a sustained period.

A therapeutic apparel article is configured with a supple wearable fabric article that can be configured over limb or nub of an amputated limb. The therapeutic apparel article is configured with a plurality of nodes for detachably attaching vibrating devices thereto. In addition, a control unit having a power source may be detachably attached to the wearable fabric article. A conductive network may extend from the control unit and/or the power source to provide electrical power to the nodes and the vibrating devices attached. A user may attach vibrating devices to various nodes of the wearable fabric article as desired. In addition, the vibrating devices and the control unit can be detached from the wearable fabric article to enable the wearable fabric article to be washed.

A leg massaging trouser assembly treats leg pain while driving. The leg massaging trouser assembly includes trousers having a pair of leg portions. Each leg portion includes a pocket mounted to an inside leg surface and having an open end. Each leg defines a slit opening in communication with an interior of the pocket, each pocket configured to receive a therapeutic device operable to massage a driver's legs. Each leg includes an adjustment area having a plurality of fasteners adjacent each slit. An upper fastener, such as a flap, is coupled to the leg therapeutic device and is pivotally movable between an open configuration that allows insertion or removal of the leg therapeutic device from a pocket and a closed configuration attached along the adjustment area, which secures the leg therapeutic device and enables each leg to be cinched tightly or relaxed.

A neuromuscular enhancement system comprising engineered textile structures is worn by a user to increase strength, preserve energy, and increase motion accuracy. The system can be used in surgery and interface with operating room technology, together providing the surgeon with the ability to perform surgery for longer hours and with increased accuracy. The enhancement system is a flexible structure, worn over the user's body, comprising engineered textile materials that apply forces to different areas of the user's body. The engineered materials can be activated in order to apply a force to a particular region of the body to assist in a desired user output. The engineered materials can be embedded with sensors to detect and monitor motion and other physical properties. The engineered materials can also be embedded with a communication system that conveys information between a computer system and the neuromuscular enhancement system and its various sensors and components. The enhancement system here can be configured for use in applications other than surgery.