The present invention is a bone growth stimulating and promoting cytokine type biological implant preferably comprising PTH coated with a controlled release biodegradable coating that is implanted preferably in the concave side of a scoliotically curved spine in combination with a bone growth inhibiting type biological implant preferably comprising methotrexate or like anti-metabolite coated with a controlled release biodegradable coating that is implanted preferably in the convex side of a scoliotically curved spine. The insertion of the biological implant is highly non-invasion, especially as compared to more conventional spine surgical methods, and the biological implant does not decrease spinal mobility or spinal range of motion.

A back-bracing apparatus and associated methods of use and/or manufacture are provided. The apparatus includes support and belt portions. The support portion includes a plurality of posterior ribs configured to abut and extend along a low back of a user and a bracing web component having a plurality of crossing structures coupling adjacent ribs. At least one rib includes first and second upper slots disposed at opposite sides of an upper portion of the rib and first and second lower slots disposed at opposite sides of a lower portion of the rib. The belt portion includes an inner strap coupled to the support portion and configured to wrap around a torso and a low back of the user, and upper and lower outer straps configured to pass through the first and second upper slots and the first and second lower slots, respectively, and wrap around the inner strap.

A human motion assistance device has upper back straps and is configured to attach to a user. A leg strap arrangement with lower back straps is configured to attach to the user. A differential assembly is connected between the upper back straps and lower back straps to reduce resistance of the upper torso harness and leg strap arrangement during gait. When crouching or lifting, the differential assembly transfers force to stretch and retract the upper torso harness and leg strap arrangement, which provides human motion assistance. The differential assembly can be implements as an x-bar, lever arm, pulley, gears, or tube. The leg strap arrangement has a knee pad adapted to cover a knee of the user. The knee pad opens along a segment. The upper torso harness has a shoulder strap and buckle. The leg strap arrangement is an elastic material.

A back-bracing apparatus and associated methods of use and/or manufacture are provided. The apparatus includes support and belt portions. The support portion includes a plurality of posterior ribs configured to abut and extend along a low back of a user and a bracing web component having a plurality of crossing structures coupling adjacent ribs. At least one rib includes first and second upper slots disposed at opposite sides of an upper portion of the rib and first and second lower slots disposed at opposite sides of a lower portion of the rib. The belt portion includes an inner strap coupled to the support portion and configured to wrap around a torso and a low back of the user, and upper and lower outer straps configured to pass through the first and second upper slots and the first and second lower slots, respectively, and wrap around the inner strap.

Disclosed are systems and methods of correction of spinal deformity that overcome current limitations by utilizing a dynamic, multi-segment torso orthosis that allows motion during wear. The disclosed embodiments utilize a series of elastically coupled segments that conform to the circumference of the torso of a patient. Adjustable elastic coupling mechanisms are utilized to create and alter forces and moments that are applied to the torso through the segments. These elastic coupling mechanisms also allow each circumferential segment to move relative to the other segments giving the brace dynamic capability.

An adjustable back brace configured to aid in the correction of spinal curvature during a treatment period of a patient is provided. In some aspects, the adjustable back brace comprises a rod, an inferior segment, and a superior segment. The inferior segment is configured to stabilize a pelvic region of the patient. The superior segment is configured to apply pressure to one of a first lateral side and a second lateral side of the patient, proximate a thoracic region of the patient to provide a corrective force on the spinal curvature of the patient. The superior segment is also selectively adjustable to be selectively moved and fixedly positioned in a plurality of positions along at least one of the lateral direction or the vertical direction, wherein the plurality of positions are designed for periodic adjustment of the corrective force on the spinal curvature during the treatment period.

The present invention relates to an adjustable scoliosis correction brace that presents a novel structure of scoliosis correction brace with multiple inflatable airbags and are placed at multiple places. These bags can be inflated with air to presses against that curve where the air can be measured with an air gauge attached to the pump which will measure the amount of pressure being applied and trains the spine to return to a straighter portion, reducing the scoliotic curve. Once required to be deflated the air pressure hose can be removed and the brace worn as a normal brace would be worn.

This invention relates to a three-dimensional scoliosis support system capable of providing pain relief and improvement of the spinal balance in scoliosis patients with different curve types. The disclosed bracing system is a tension-based scoliosis orthosis that comprises an rigid back panel. The three de-rotational supports pads of the back panel are connected to each other, providing facilitation or restriction of certain movements of human spine in the three different anatomical planes, i.e., coronal, sagittal and transverse planes. This scoliosis brace includes inelastic straps connected to the de-rotational supports/pads of the back panel, and the bracing system has different sizes and it can be fitted and adjusted accordingly with scoliosis curve type and patient characteristics.

Disclosed herein is a wearable device for body correction, which is capable of adapting a position suitable for pressing a patient's body's curve to be corrected. To this end, the wearable device for body correction includes an outerwear worn on an upper body of a patient, a curve presser disposed on the outerwear and configured to press a curve of the body to be corrected, a strength adjuster disposed on the outerwear, connected to the curve presser by a wire, and configured to adjust a strength of pressure applied by the curve presser by adjusting an amount of winding/unwinding of the wire, and a guide rail disposed on the outerwear and configured to guide vertical sliding of at least one of the curve presser and the strength adjuster.

Devices, systems, and methods for maintain a preselected tension between a first portion and a second portion of an orthotic brace include a controlled tension unit that includes a housing coupled to a first portion of the orthotic brace, the housing having a cavity formed therein, one or more constant-force spring mounted at or near a first end of the cavity, and a connector cable having a first end connected to an end of the one or more constant-force spring and a second end extending out of the housing through a second end of the cavity. The second end of the connector cable is configured to connect with a coupling element coupled to a second portion of the orthotic brace. In this arrangement, the controlled tension unit is configured to maintain a preselected tension between the first portion and the second portion of the orthotic brace.