A core muscle exercising and resistance training device includes a weighted bar having opposed bar ends adapted to removably mount at least one weight or other force generating element. A pad element is removably and frictionally mounted on the bar, the pad element being constructed from a lightweight foam material having a density within a specific range. The pad has an outer surface with a radius of curvature substantially the same as a normal cervical curvature. In use, the outer pad surface is placed adjacent a user's cervical curve and the weighted bar, the additional isometric resistance generating elements and the pad element act in combination to apply a force upon the user's core cervical curve muscles for improving the user's cervical curve posture by gradually modifying the cervical curvature to conform with clinically desirable curvature.

A cervical traction device is provided. A frame presents an anterior support under the maxilla of a user, while a posterior support is applied to the lower portion of the occiput of the user. Thus, pressure is avoided on the potentially unstable mandible, and the lower and upper teeth are not compressed against one another. A series of suspension points on the frame allows the angle at which traction may be applied to the cervical vertebrae to be varied.

A three-dimensional spine correction robot includes: a pillar, a seat, human body fixing belts, a head fixing apparatus, a bracket, pillar casing pipes, a spine lateral push-and-pull apparatus and a seat locking mechanism. The head fixing apparatus is fixed on the top of the bracket. The pillar casing pipes are movably sleeved over the pillar, and each pillar casing pipe is connected to a human body fixing belt. The lower end of the pillar casing pipe is connected to the seat, and the upper end is connected to the pillar. A first elastic connection object is connected between the pillar casing pipes. The spine lateral push-and-pull apparatus may move up and down along the pillar and swing. The seat is connected to the pillar through a bearing, and may move up and down along the pillar. The seat locking mechanism is fixed between the bracket and the seat.

Exoskeleton technology is described herein. Such technology includes but is not limited to exoskeletons, exoskeleton controllers, methods for controlling an exoskeleton, and combinations thereof. The exoskeleton technology may facilitate, enhance, and/or supplant the natural mobility of a user via a combination of sensor elements, processing/control elements, and actuating elements. User movement may be elicited by electrical stimulation of the user's muscles, actuation of one or more mechanical components, or a combination thereof. In some embodiments, the exoskeleton technology may adjust in response to measured inputs, such as motions or electrical signals produced by a user. In this way, the exoskeleton technology may interpret known inputs and learn new inputs, which may lead to a more seamless user experience.

The present invention is generally directed to corrective spinal traction systems and methods. It is further directed to use of such spinal traction systems to treat various medical problems associated with abnormal spinal curvature. In one aspect, the present invention is directed to a spine corrective traction system. The system comprises an overhead system allowing a patient's spine to be pulled in every and any vector the human spine moves in three dimensional space, and in two to three planes simultaneously. It further includes a seat assembly that allows for a patient to be seated upright, supine and every angle and vector between 90 degrees upright and 0 degrees horizontal.

Disclosed is a backbone retraction apparatus which includes a support member supporting a hip of a user, a center member coupled to the support member by a hinge structure, a backrest member inserted into the center member, a neck support member inserted into the backrest member, moving means comprising a wire having a first side fixed to the center member and a second side fixed to the neck support member and a first latching protrusion protruded from the backrest member and adapted to have the wire hung on the first latching protrusion, the second side of the wire being fixed under the first latching protrusion, and length adjustment means adapted to be connected to the support member and the backrest member.

A Yoga block designed to promote cervical lordosis by contouring the block to allowing room for the shoulders and a cut out for the spinous processes at the top of the block.

A spine regularity rotation motion device includes a T-shaped hanger, a neck traction belt, an n-shaped base, and a horizontal rotary drive platform, wherein the T-shaped hanger is connected to the neck traction belt via a pulling belt at one end, and is connected to the n-shaped base through a main elevating post at another end. A user can rest his face on the neck traction belt, which is gently pulled upwards to increase the space between the cervical joints and align the spine to the center. The horizontal rotary drive platform is provided inside the n-shaped base with a correction seat on the top for the user to sit on. The seat allows the hip of the user to move in a regularity rotation manner that is opposite to the directions of the twisted and/or bent lumbar spine or skewed pelvis. An underarm support is also provided to raise the spine and reduce stacking to facilitate the rehabilitation process.

An exercise apparatus may include a first horizontal bar, a second horizontal bar, a titled body supporting unit, a supporting assembly and an adjusting unit. In one embodiment, both the first horizontal bar and second horizontal bar are located at a rear portion of the exercise equipment, so the user can fully extend his arms and stretch the back muscle and cervical spine when grasping the horizontal bar. The adjusting unit is used to adjust the titled angle of the titled body supporting unit. The user can hold either the first or second horizontal bar and lay the body on top of the titled body supporting unit, such that the titled body supporting unit can sustain a substantial portion of the user's weight to enable the user to lift the body with the arms holding on the horizontal bar, even though the user is elder or overweight.

The multi-use stretching and exercising device is comprised of a non-elastic strap, with removable comfort support pad and two affixed hand finger grip mounts. The strap having a left end and right end is affixed at the left end by a hand finger grip mount and at the right end by another hand finger grip mount. The device is capable of being set in motion in response to a force acting upon both opposing hand finger grip mounts while the strap with removable comfort support is in contact with the head, leg, arm or overhead structure.