A rebound and balance training device includes a frame, a footboard, and a plurality of resilient spring elements extending between and attached to the frame and the footboard to support the footboard above a supporting surface. A user standing on the footboard manually effects repeated vertical bouncing movement between upper and lower positions. The distance traveled by the footboard, the effort required to effect movement, and the stability thereof may be modified by selectively modifying the number, the length, the position, or the elasticity of the resilient elements. In one embodiment, a pair of footboards is employed to simulate skiing movements.

Systems, devices, and methods including a standing lumbar back distractor. The standing lumbar back distractor includes: a stand; a shaft comprising a lower end connected to the base and an upper end distal from the lower end; an elbow support mechanism connected to the upper end of the shaft; and a pelvic support mechanism disposed between the elbow support mechanism and the stand.

A system for patient rehabilitation is disclosed. The system includes a first movable frame including an articulating bed, wherein the bed is configured to be selectively articulated to an inclined position, a suspension system, wherein the suspension system is disposed within the articulating bed and is selectively adjustable to accommodate varying patient height, a harness, wherein the harness is selectively engageable with the suspension system, wherein the harness is selectively adjustable to accommodate varying patient sizes, a second movable frame including a walker, wherein the walker includes a pair of legs and a motor, wherein approximation of the two movable frames permits the patient to easily utilize the walker from the bed. A method of using the system for patient rehabilitation is also disclosed.

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.

A leg support exoskeleton is strapped on as wearable device to support its user during squatting. The exoskeleton includes a knee joint connected to a first line and a second link, which is configured to allow flexion and extension motion between the first link and the second link. A force generator has a first end that is rotatably connected to the first link. A constraining mechanism is connected to the second link and has at least two operational positions. In a first operational position, the second end of the force generator engages the constraining mechanism, where the first link and the second link flex relative to each other. In a second operational position, the second end of the force generator does not engage the constraining mechanism; the first link and the second link are free to flex and extend relative to each other.

A leg support exoskeleton is strapped on as wearable device to support its user during squatting. The exoskeleton includes a knee joint connected to a first line and a second link, which is configured to allow flexion and extension motion between the first link and the second link. A force generator has a first end that is rotatably connected to the first link. A constraining mechanism is connected to the second link and has at least two operational positions. In a first operational position, the second end of the force generator engages the constraining mechanism, where the first link and the second link flex relative to each other. In a second operational position, the second end of the force generator does not engage the constraining mechanism; the first link and the second link are free to flex and extend relative to each other.

An improved walker has a detachable propulsion unit, which is attached to the walker by a platform member which extends forwardly from the propulsion unit, with an upwardly extending walker structure partially attached to the platform member. The user steps onto the propulsion unit while support on either side by the handles of the walker. The platform member is so attached to the propulsion unit as to allow a left section and a right section of the propulsion unit to be independently movable with respect to one another, thereby allowing operation of the propulsion unit. The propulsion unit may be a hover board or power board.

The invention relates to a device for carrying out vibration exercise by way of a device user, comprising a platform, two handles which are connected directly or indirectly to the platform and make support of the device user by means of his/her hands possible, and an actuator which is set up to set the platform and the handles which are connected to the platform in a vibration movement, it being possible for the spacing between the two handles to be varied.

The present invention relates to a method for training of neuromuscular functions using a gait trainer comprising an electrical motor, a weight sensor and a cable and a gait trainer therefore.

The method may comprise an act of determining a counterbalance weight to be applied to the cable by the electrical motor and an act of measuring with the weight sensor an actual applied weight to the cable by the patient, wherein a drive direction of the electrical motor is determined based on comparing the counterbalance weight with the measuring of the actual applied weight to the cable by the patient.

The gait trainer may comprise a hoist system with a rotatable cable drum and a cable to wind or rewind the cable around a rotatable cable drum in accordance with the drive direction set, based on the compared counterbalance weight with the measuring of the actual applied weight to the cable by the patient.

The gait trainer may further comprise an electrical motor adapted for axial engagement with the rotatable cable drum and adapted to drive the rotatable cable drum in a drive direction. The gait trainer may further comprise a weight sensor, a control unit, a processor and a motor controller.

The hoist system may be freely suspended by the weight sensor.