A hand-held, non-penetrating, non-phallic shaped apparatus for clitoral massage and stimulation comprising a massager housing having a generally prolate spheroid shape sized to fit entirely within a user's palm leaving a user's fingers free, generally convex top and bottom, first and second convex ends, a power source; a vibrating source contained within the massager housing providing at least one level of vibration; at least one switch for activating said vibration; a generally elliptical three-dimensional concave depression on a surface of the convex top of one of said convex ends of sufficient length, width, and depth for enveloping and facilitating the stimulation of a woman's clitoris and labia; wherein when in use the apparatus is held by the bottom.

A compression device has improved cooling capability. The device includes a wicking layer adapted to move moisture. A portion of the wicking layer is exposed from under bladder material defining a bladder. In use, the wicking layer wicks moisture from the patient's limb and the wicked moisture is able to evaporate through the device at the portion of the wicking layer that is exposed.

A therapeutic device is placed over the breast and improves the quality of breastfeeding experience, aiming to heal and treat specific ailments nursing mothers encounter. The breast care device allows the user to maintain treatment while allowing for mobility during therapy. One aspect of the breast care device is made to contain and distribute therapeutic fluids, which are known to soothe breast pain, nipple cracks, anatomical variations, thrush, bites, milk blister, and other ailments. Another aspect of the breast care device contains an array of light elements for the purpose of light therapy, aiming to soothe the same ailments. The final aspect of the breast care device can contain a variety of electrical components, such as rollers for massage, vibration mechanisms for therapy, or ultrasound for imaging or therapy.

A human interface device is configured to be coupled to a trunk of a person and comprises a frame, a fabric coupled to said frame configurable to be under tensile forces, and a belt configured to be coupled to two side edges of said frame wherein when said belt is worn by said person, an area of said fabric will be pushed against the person's lower back conforming to the shape of the lower back of said person. In operation when said human interface device is worn by said person, the weight of any load coupled to or supported by said frame will be partially supported by the friction force between the area of said fabric which is pushed against the person's lower back, and the person's lower back allowing said person to carry said load.

A garment for providing circulatory-related disorder therapy includes a skin contacting layer, a backing layer, and a coupling. The backing layer is coupled to the skin contacting layer such that the skin contacting layer and the backing layer form a plurality of macro-chambers. A first one of the plurality of macro-chambers is partitioned into a plurality of micro-chambers. Each of the plurality of micro-chambers is in direct fluid communication with at least one other of the plurality of micro-chambers. The coupling is coupled to the backing layer and is configured to supply pressurized air directly into the first macro-chamber such that the pressurized air is delivered to a first one of the plurality of micro-chambers of the first macro-chamber.

Systems and methods for exerting forces on a body, including a support structure defining a space and a plurality of surface contacting units that are configured to exert force upon the body, such that the weight is distributed away from the primary weight bearing regions to non-weight bearing regions of the body, or vice versa, without exerting significant shear or frictional forces on surfaces of the body. The systems and methods may be used to exert forces to cause fluid shift in different compartments of the body. Applications include treatment of various disease conditions including pressure ulcers, heart failure, high blood pressure, preeclampsia, osteoporosis, injuries of spine and to slow microgravity-induced bone and muscle loss. The systems and methods may be used to simulate gravity, weightlessness or buoyancy, in rehabilitation medicine. The system may include a chair, bed, a wearable suit or an exoskeleton.

A system and apparatus for promoting perfusion at a tissue site containing a sprain by applying a vacuum to intact skin extending over or surrounding the tissue site. The system and apparatus comprise a manifold formed from a porous material and configured to be disposed proximate the intact skin for distributing vacuum to the intact skin, and a sleeve adapted to cover the manifold and form a chamber containing the manifold to seal the manifold within the chamber between the sleeve and the intact skin. The system and apparatus further comprise a fluid coupling member adapted to deliver vacuum to the manifold for distribution to the intact skin. A method for applying vacuum to the intact skin of a tissue site is also disclosed and described herein.

An absorbent structure, including a sensor system, can sense and measure the level of wetness contained within the absorbent structure as well as sense and measure environmental conditions. The sensor system may include passive RFID sensors or tags, RFID readers, antenna, a tuning module, a processing module, a memory module and a wireless communication module. The absorbent structure may further include two or more sensors, with a first sensor placed in a first area most likely to first be exposed to liquid and a second sensor spaced apart from the first sensor in an area likely to be exposed to liquid only after the absorbent structure has become more saturated.

A lubrication device and method of use including a housing having an elongated, hollow tube or orifice configured for receiving a soft, porous material, the soft, porous material further including a central opening. The lubrication device further includes a removable end cap accommodating access to the housing inner orifice and porous material. In an exemplary embodiment, the end cap includes an access lid and an access lid opening. The soft, porous material of the present invention is configured for receiving and absorbing a lubricant, and the porous material central opening is configured for receiving a male penis, alternative human appendage, or a simulated male penis or human appendage for transfer of lubricant from the porous material onto the inserted actual or simulated body part. In an exemplary embodiment, the housing of the lubrication device has an outward appearance of an inconspicuous household item.

An absorbent structure, including a sensor system, can sense and measure the level of wetness contained within the absorbent structure as well as sense and measure environmental conditions. The sensor system may include passive RFID sensors or tags, RFID readers, antenna, a tuning module, a processing module, a memory module and a wireless communication module. The absorbent structure may further include two or more sensors, with a first sensor placed in a first area most likely to first be exposed to liquid and a second sensor spaced apart from the first sensor in an area likely to be exposed to liquid only after the absorbent structure has become more saturated.