Wearable assistance devices and methods of operating the same are provided. A wearable assistance device includes an upper-body interface with a front side and a rear side and a lower-body interface with a front side and a rear side. The assistance device also includes one or more elastic members, each of the elastic members mechanically coupling the upper-body interface to the lower-body interface and extending from the rear side of the upper-body interface to the rear side of the lower-body interface and along a back of the user so as to provide an assistive force parallel to the back of the user. Further, the assistance device also includes a clutch mechanism associated with each one of the elastic members, the clutch mechanism configured for selectively adjusting the assistive force provided by the one of the elastic members.

Systems and methods for correcting spinal deformity utilize a dynamic, multi-structure torso orthosis that allows motion during wear. The disclosed embodiments utilize a series of elastically coupled ring structures 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 these ring structures. In some instances, the ring structures are formed from individual elements that can be linked to accommodate particular anatomies. In other instances, a superior ring structure can be configured to accommodate the patient's upper torso.

A rear-entry ankle brace includes an elastomeric component defining an inside elbow channel configured to span an ankle joint. A channel opening extends the length of the elastomeric component for direct insertion on top of a leg. One or more leg straps are used to adjustably tension first and second rear edges of the channel opening toward one another and secure the brace to the lower leg. Two foot straps are used to adjustably tension first and second bottom edges of the channel opening toward one another and secure the brace to the mid-foot. The foot straps overlap on the bottom to define a plantar surface of the brace and cross over each other on the topside of the elastomeric component and are secured to a leg strap. A pair of stabilizing stirrups optionally are included on the inside surfaces of the elastomeric component and receive the malleoli.

A brace including (i) two or more supports configured to contact body parts on opposite sides or ends of one or more joints when the brace is in use and (ii) one or more force application mechanisms that apply a controllable force to the supports in opposite directions to alleviate compression in the one or more joints is disclosed. Methods of manufacturing the brace and of alleviating compression in one or more joints using the brace are also disclosed.

The invention relates to a method for controlling an orthopaedic joint device of a lower extremity. The joint device has an upper part (2) and a lower part (3) mounted in a hinged manner on the latter. Arranged between the upper part (2) and the lower part (3) is an energy converter (5) by which, during walking, kinetic energy from the relative movement between the lower part (3) and the upper part (2) is converted or stored and supplied again to the joint in order to support the relative movement, wherein kinetic energy within one movement cycle is converted and/or stored and, within the same movement cycle, is supplied again as kinetic energy to the joint device (1) in a controlled manner and staggered in time.

Systems and methods for correcting spinal deformity utilize a dynamic, multi-structure torso orthosis that allows motion during wear. The disclosed embodiments utilize a series of elastically coupled ring structures 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 these ring structures. In some instances, the ring structures are formed from individual elements that can be linked to accommodate particular anatomies. In other instances, a superior ring structure can be configured to accommodate the patient's upper torso.

A device for treatment of plantar fasciitis is provided. The device includes a foot strap, a thigh strap and a resistance band. The foot strap includes an inner surface and an outer surface. The inner surface of the foot strap is sized to secure around a foot of a user in between the ankle and toes. The thigh strap also includes an inner surface and an outer surface. The inner surface of the thigh strap is sized to secure around a thigh of the user. The resistance band includes a first end attached to the foot strap and a second end attached to the thigh strap. To treat the plantar fascia, the user bends their foot downwards and curls the toes against the resistance of the resistance band.

A cervical collar device for applying a constant upward push force includes a flexible neck brace and a constant upward push force device. The flexible neck brace includes a top and a bottom with a height therebetween, and a first side and a second side with a length therebetween. The height and the length of the flexible neck brace is configured for placement around a neck of a user. The constant upward push force device is positioned inside said flexible neck brace. The constant upward push force is configured to provide a constant upward push force between said top and said bottom of said flexible neck brace.

An active wearable system includes a one or more positioning elements configured as a torso support and/or other wearable item, one or more sensors for sensing motion, posture, or gait of a subject, and at least one of force applying elements for applying force to selected regions of a body of a subject, and feedback device and other actuators, under the control of control circuitry responsive to sensed motion, posture or gait of the subject. In an aspect, force is applied according to spatial or temporal patterns. Related devices and methods are described.

Orthotic and prosthetic devices having integrated features such as cushioning features are described, as well as methods for computer aided designing and making of these devices. The orthotic or prosthetic devices comprise a cushioning layer superimposed onto an orthotic or prosthetic shell, the cushioning layer comprising an array (35) of discrete solid and resilient cushioning elements (31). In one preferred embodiment, said cushioning structure is a beam, defined around a centerline of any arbitrary shape. In another preferred embodiment, said cushioning structure has the shape of a spiral.