A user attachment for an apparatus for gait rehabilitation providing a possibility for a user to receive support during walking in a walking direction. A harness is attached to the body of the user and can be connected to a weight supporting device. This connection is a driven attachment arm attached at the weight supporting device which can be detachably connected with the harness. The driven attachment arm is connected via a double parallelogram unit with the harness attachment element. A guiding attachment arm can be connected with the weight supporting device and can be detachably connected with the harness attachment element for a rotative connection of the driven attachment arm with the guiding attachment arm.

Two vertical front posts and two vertical rear posts are mounted on a flat platform of the automated device. The front posts mounted in the horizontal guide are symmetrically moved by the spacing adjustment mechanism within the range between the position of the joined front posts to a dimension between their inner surfaces equal to the width of the wheelchair, and the moved apart position to a dimension where the width dimension of the wheelchair is located between the mechanical legs suspended on the front posts. On the inner surfaces of the front posts, there are vertical guides with a screw drive mechanism for pelvic height adjustment. The mechanical legs girdle the patient's lower limbs from the outside by pelvic control units that induce a symmetrically alternating movement of the hip joint hinges in both mechanical legs with ellipsoid trajectories, and by adjustable thigh and shin connectors and foot connectors.

An overhead support system includes a plurality of posts; a plurality of beams configured to connect to and span between the posts; a counterbalance system configured to be attached to the plurality of posts; a harness configured to be worn by and support a patient; a plurality of pulleys configured to be disposed on the plurality of posts; a plurality of cables, each cable including a first end configured to be operatively connected to the harness and a second end configured to be operatively connected to a counterbalance system, each cable passing over one of the pulleys; and a mechanism configured to selectively adjust a tension in at least one of the plurality of cables to support some or all of the weight of the patient. The counterbalance system compensates to maintain support while the patient is located between the posts and the harness is lower than the pulleys.

An apparatus is disclosed comprising an upper frame and a lower frame together connected by at least one lifting means, wherein the lower frame comprises two sidebars connected at opposite ends of a lower crossbar to form a “U” shape, wherein the upper frame comprises two handrails, each having a free end and an attachment end, wherein the attachment end of each handrail is rotatably connected to an upper crossbar, and the lifting means are disposed between the lower crossbar and upper crossbar such that the upper frame experiences a force exerted by the lifting means when the handrails parallel to a plane formed by the lower frame. In another embodiment, the apparatus is a walker having a harness in removable communication with the handrails.

An apparatus includes a drive mechanism, a patient support mechanism, and an electronic system. The drive mechanism is included in a trolley and is configured to suspend the trolley from a support track. The drive mechanism includes a first sensor configured to sense an operating condition of the drive mechanism. The patient support mechanism couples to the trolley and includes a tether and a second sensor. The tether can be operatively coupled to a patient such that the patient support mechanism supports the patient. The second sensor is configured to sense an operating condition of the patient support mechanism. The electronic system is included in the trolley and has at least a processor and a memory. The processor is configured to define a gait characteristic of the patient based at least in part on a signal received from the first sensor and a signal received from the second sensor.

A walking training system includes a treadmill configured to prompt a trainee to walk, a display device installed such that the trainee views the display device while walking on the treadmill, a camera configured to image the trainee at an angle of view at which a gait of the trainee is recognizable, a calculation unit configured to calculate a tilt of a body core of the walking trainee based on an image captured by the camera, and a display control unit configured to control the display device to display a body core line associated with the tilt, and an index indicating at least an end of a permissible range of a deflection of the body core line.

Provided is a walking assistance method and apparatus for providing an assistance torque to an ankle of a user. To provide an assistance torque to an ankle of a user, a first pressure value and a second pressure value are received from a first pressure sensor and a second pressure sensor, a ratio between the first pressure value and the second pressure value is calculated, a gain value is determined based on the ratio, an assistance torque value is calculated based on the ratio and the gain value, and a driver is controlled to output the assistance torque value.

A balance assist and fall prevention assembly for preventing falls and providing balance assistance includes a plurality of rails and a harness. The rails are mountable to a ceiling of a structure and are selectively interconnectable so that respective rails are extend along an associated route in the structure that is routinely traversed by a user. A trolley is rollably engaged to the plurality of rails. The harness can be selectively donned by the user so that the harness is removably engaged to the user. A tether is engaged to and extends between the harness and the trolley. The tether is selectively length adjustable so as to extend substantially linearly between the harness and the trolley with the user standing substantially upright and beneath the trolley. The tether thus improves balance of the user and to prevents falling of the user.

A mobility assistance apparatus includes first and second frames positioned on left and right sides of a user; a hinge arm mechanism coupled to the first and second frames; and a pivotable securing unit or a walking seat coupled to the frames to transfer at least a portion of the user's body weight from the legs and to transfer weight through the user's hip or pelvis to the first and second frame enabling the user to stand or work for an extended period without requiring the user's arms to hold the frame; a wheel coupled to the first and second frames; a brake coupled to the wheel to provide friction to the wheel when actuated; and a tensioner coupled to the brake to adjust cable tension during wheel braking.

A walking training system according to this embodiment includes a harness, at least three pulling units, and a control unit configured to control the at least three pulling units in such a way that a position of the harness in a horizontal plane becomes a target position. One of the at least three pulling units is a first pulling unit configured to apply a pulling force to the harness from front of the trainee, another one of the at least three pulling units is a second pulling unit configured to apply a pulling force to the harness from rear of the trainee, and another one of the at least three pulling units is a third pulling unit configured to apply a pulling force to the harness from a direction different from the first and second pulling units.