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.

The lumbar therapy belt is a therapeutic device. The lumbar therapy belt is configured for use with a patient. The patient is further defined with a torso, a spine, a pelvis, an abdomen, and a lumbar region. The lumbar therapy belt includes a belt, a fastener, and a plurality of pads. The fastener and the plurality of pads attach to the belt. The belt is a strap. The fastener attaches the belt to the patient such that the plurality of pads are positioned over the lumbar region. The plurality of pads press against the lumbar region such that the normal movement of the patient causes the plurality of pads to stretch the muscles of the lumbar region, including spinal muscles, laterally so as to relieve downward pressure on the spinal discs and nerves.

Disclosed is a lumbar support belt including: a support belt body intended to surround at least one part of a user's torso; at least a first sensor capable of measuring the pressure exerted by the support belt on a user or the elongation of the support belt body; and a module including at least a second sensor capable of measuring at least one parameter relating to the actimetry of the user. The module is removably attached to a second location of the support belt body.

A welded orthopedic back brace is disclosed. In an embodiment, at least one belt member is coupled to a spinal support element. The materials of the belt member are thermally fused to form a unitary segment. In another embodiment, an anterior portion of a posterior pad of the spinal support element includes thermally fused materials to provide a user with an added degree of comfort.

An orthopedic brace features a belt brace and an adjustable spinal support extension. The belt brace includes a structural member. The adjustable spinal support extension is configured for insertion into the structural member. The adjustable spinal support extension includes a sleeve, a first strut member, and a second strut member adjustably coupled to the first strut member to alter a length of the spinal support extension. The first strut member and the second strut member are partially enclosed within the sleeve and a fastener of the structural member is attachable to a fastener on the sleeve when the adjustable spinal support extension is placed within the sleeve.

A back support device for supporting a lower back of a user may include an elastic strap, a first clasping element attached to a first end of the elastic strap, a second clasping element slidably disposed over the elastic strap and configured to releasably engage the first clasping element to form a continuous loop, and a buckle element secured to a second end of the elastic strap. The buckle element is slidably disposed on a medial portion of the elastic strap for adjusting a perimeter length of the continuous loop. The continuous loop is movable between a first position in which the continuous loop has a first perimeter length and a second position in which the continuous loop has a second perimeter length via elastic elongation. The first perimeter length is less than the second perimeter length.

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.

An orthopedic sacroiliac brace is provided. The brace includes a belt portion including a first posterior sacral panel coupled to the belt portion and configured to be disposed directly posterior of a first posterior side of an ilium of a user, and a second posterior sacral panel coupled to the belt portion and configured to be disposed directly posterior of a second posterior side of the ilium. Adjustably tightening the belt portion around the user causes the first and second posterior sacral panels to apply respective anterior forces to the first and second posterior sides of the ilium, thereby providing adjustable stabilizing support, compression and/or alignment to a sacroiliac joint of the user. Brace can also include an anterior abdominal panel configured to be disposed against an anterior portion of an abdomen of the user and coupled to the belt portion. Related methods of use and manufacture are also provided.

A thoracic lumbar sacral orthosis attachment for configuring an orthopedic device as a thoracic lumbar sacral orthosis by connecting the attachment to the orthopedic device. The attachment has an anterior aspect including an anterior panel arranged to connect to an orthopedic device. An anterior thoracic extension (ATE) is securable to the anterior panel, and a support bar extends from the ATE. A strap system includes an axillary strap system and/or a shoulder strap system removably securing onto a surface of the orthopedic device, and/or the ATE.

An article of footwear includes a motorized tensioning system, sensors, and a gesture control system. Based on information received from one or more sensors the gesture control system may detect a prompting gesture and enters an armed mode for receiving further instructions. In the armed mode the system may detect a variety of different control gestures that correspond to different tensioning commands.