An orthotic device (10) that may be particularly effective in the treatment of scoliosis comprises a torso section (20) and a resilient reinforcement (40) attached to the torso section. The reinforcement extends diagonally across a front and/or a rear portion of the torso section between a first attachment point (51) at a first side of the torso section and a second attachment point (52) at a second side of the torso section. At least one of the first attachment point and the second attachment point is locally indented into the torso section such that the reinforcement is stretched when device is donned a patient, thereby applying a force to the patient's torso.

A height adjustable orthosis is described. The orthosis features a belt and a posterior frame. Coupled to the belt, the posterior frame includes a first panel including at least a first fastener and a second rear panel including at least a first lock member and a second locking member. The first panel and the second panel are configured to move vertically relative to each other to position the first fastener to engage at least (1) the first locking member at a first height or (2) the second locking member as a second height.

A back brace includes: a back plate; left and right cord plates each slidably mounted to left and right sides of the back plate, respectively, and to which first and second flexible belt members are respectively secured; and a cord guide arrangement for each plate to particularly direct first and second cords. Each of the left and right cord plates include a pair of concentric cord guides, each of which are formed of a circular segment that is 180 degrees or less. The first cord is selectively wound around the pair of concentric cord guides on the upper portions of the left and right cord plates, while the second cord is selectively wound around the pair of concentric cord guides on the lower portion of the cord plates, so pulling on the cords provides a mechanical advantage to buckle the plate to exert a compressive force on the patient's torso.

A core muscle strengthening suit for scoliosis is described. The suit uses pieces of material constructed and assembled to transfer force generated by the wearer while walking to rotate the wearer's trunk in the direction of an existing axial twist to exercise and strengthen countervailing muscles in an attempt to maintain a normal gait. The resulting stronger rotational muscles persist in pulling the wearer's spine into alignment when the suit is removed.

A posture control system includes a brace to which an inflatable bladder is removably coupled. The bladder, when inflated, causes pressure to be applied to a wearer if the wearer does not have proper posture. The pressure irritates the wearer into improving their posture. The brace includes strap systems that are adjustable for size and fit. In embodiments, the strap systems include an upper strap portion that includes an elastic component that also assists the user in improving their posture.

A frame includes a front segment extending across an anterior side of a human and a back segment extending across a posterior side of the human in a fixed spatial relationship. A clamp bar extends between the front segment and the back segment to interface with a first lateral side of the human at a location between an ilium bone structure and a thoracic cage of the human. A lateral restraint is positioned between the front segment and the back segment and is configured to interface with a second lateral side of the human over an engagement area corresponding to a portion of the thoracic cage of the human. A downward treatment force is applied to the frame at a location opposite the clamp bar from the lateral restraint. The human works to laterally translate their spinal column toward the lateral restraint to maintain the frame in a near-level orientation.

An orthopedic device for supporting a lower back of a user includes a mechanical energy store, a pelvic element, an upper body element with a first force transmission element and an upper leg element with a second force transmission element The upper leg element is arranged on the pelvic element such that it can be swivelled about a first swivel axis, the upper body element is movably arranged relative to the pelvic ele-ment, the first force transmission element can be engaged and disengaged with the second force transmission element by moving the upper body element relative to the pelvic element, and the mechanical energy store can be charged and discharged by swiv-elling the upper leg element relative to the upper body element when the first force transmission element is engaged with the second force transmission element.

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.

A wearable orthotic appliance to which at least one corrective element for correcting neuromuscular imbalances may be removably attached is made of fabric assembly held in compressive tension when worn by a user, the fabric assembly including a cavity or chamber into which the corrective element may be placed and secured at any of a plurality of continuously-adjustable positions. Maintenance of the corrective element position during use of the appliance may be assisted by establishing a compression gradient over selected areas of the appliance during assembly. The wearable orthotic appliance may be a shirt, vest, body suit, or other garment or article of clothing, and the corrective elements may be weights, electrodes, or other discrete elements whose therapeutic effect depends on proper positioning relative to the wearer's torso or other body parts.

A cervicothoracic spine restorator is disclosed. In the cervicothoracic spine restorator, a fixing structure is further included, such that relaxation of muscles such as pectoralis major muscle, pectoralis minor muscle, rectus abdominis muscle, and trapezius muscle or latissimus dorsi muscle can be easily performed. Further, the blood vessel may be expanded and the blood may be supplied smoothly to the head. This may help recovery and correction during a short correction period. There is an advantage that a separate correction mechanism, which is used for spine correction such as a abdomen band, is unnecessary.