An orthopaedic device with a shell mechanism which can be brought into a closed position in which it engages at least partially around a body part arranged in the shell mechanism, and into an open position, in which the body part can be brought into the shell mechanism, wherein the shell mechanism can be brought from the open position to the closed position by means of the body part being introduced into the shell mechanism. The device has at least one actuation element which is arranged and designed in such a way that it is actuated when the body part is introduced into the shell mechanism, and it brings the shell mechanism from the open position to the closed position, wherein the actuation element has a tensile force transmission element, in particular a band or a cloth.

An anatomical brace for dynamically stabilizing the elbow during elbow articulation, the anatomical brace comprising: a brace body comprising a distal portion for fitting over the forearm of a user and a proximal portion for fitting over the upper arm of a user; a hinge mechanism comprising a distal segment, a proximal segment and a pivot for pivotally connecting the distal segment and the proximal segment, the distal segment of the hinge mechanism being mounted to the distal portion of the brace body and the proximal segment of the hinge mechanism being mounted to the proximal portion of the brace body; a pivot cable guide mounted to the anterior portion of the pivot; an upper arm cable guide mounted to at least one of the proximal segment of the hinge mechanism and the proximal portion of the brace body, the upper arm cable guide being configured to change the direction of a cable extending through the upper arm cable guide; an ulnar collateral ligament (UCL) cable guide mounted to the brace body and configured to direct a cable extending through the ulnar collateral ligament (UCL) cable guide over the ulnar collateral ligament (UCL) and toward the distal portion of the brace body; and a cable having a first end and a second end; the first end of the cable being mounted to the distal segment of the hinge mechanism, the second end of the cable being mounted to the distal portion of the brace body, and the cable being routed proximally along the distal segment of the hinge mechanism, through the pivot cable guide, proximally along the proximal segment of the hinge mechanism, through the upper arm cable guide, and through the ulnar collateral ligament (UCL) cable guide; wherein, when the anatomical brace is mounted to the arm of a user so that the distal portion of the brace body is secured to the forearm of the user, and the proximal portion of the brace body is secured to the upper arm of the user, and when the elbow thereafter moves to full extension, the cable is tensioned, whereby to apply a force to the ulnar collateral ligament (UCL) of the user, and when the elbow thereafter moves to full flexion, the cable is relaxed, so that the force applied to the ulnar collateral ligament (UCL) is released.

Provided is a shoulder brace having a forearm part, an upper-arm part, a torso part, an elbow-joint part, and a shoulder-joint part. The upper-arm part includes a rotary annulus to be coupled to an outside of the shoulder-joint part, the rotary annulus having line-shaped protrusions and grooves that are alternately formed along an inner circumference thereof. The shoulder-joint part includes a joint shaft, a push button provided on a first end thereof and coupled with the joint shaft, a locking ring coupled to a middle portion of the joint shaft and having line-shaped protrusions and grooves that are alternately formed along an outer circumference thereof, and a stopper formed on a second end thereof and providing space to allow the joint shaft to be movable when the push button is pushed, thus allowing a lock state to be released.

A motion assistance apparatus including a proximal frame configured to support a proximal part of a user, a distal frame configured to support a distal part of the user, and a force transmitting member slidably connected to the proximal frame, and rotatably connected to the distal frame is provided.

A global osteoarthritis knee brace or orthopedic support includes a flexible, elastic sleeve having a tubular shape with a patella opening at an anterior surface with slits on either side of the opening. The brace includes a first pair of rigid longitudinal stiffeners pivoted therebetween at a hinge that is disposed at the lateral side of the sleeve and likewise at the medial side of the sleeve. The brace further includes an adjustable, flexible patella support having elongated strips at the ends thereof, wherein the patella support is positioned in the interior of the sleeve proximate with the patella opening, where the elongated strips pass from the interior of the sleeve through the slits to the exterior of the sleeve, and extend upward to be adjustably anchored to the sleeve. The wearer pulling on the elongated strips adjusts the patella support.

An anatomical brace for dynamically stabilizing the elbow during elbow articulation, the anatomical brace comprising: a brace body comprising a distal portion for fitting over the forearm of a user and a proximal portion for fitting over the upper arm of a user; a hinge mechanism comprising a distal segment, a proximal segment and a pivot for pivotally connecting the distal segment and the proximal segment, the distal segment of the hinge mechanism being mounted to the distal portion of the brace body and the proximal segment of the hinge mechanism being mounted to the proximal portion of the brace body; a pivot cable guide mounted to the anterior portion of the pivot; an upper arm cable guide mounted to at least one of the proximal segment of the hinge mechanism and the proximal portion of the brace body, the upper arm cable guide being configured to change the direction of a cable extending through the upper arm cable guide; an ulnar collateral ligament (UCL) cable guide mounted to the brace body and configured to direct a cable extending through the ulnar collateral ligament (UCL) cable guide over the ulnar collateral ligament (UCL) and toward the distal portion of the brace body; and a cable having a first end and a second end; the first end of the cable being mounted to the distal segment of the hinge mechanism, the second end of the cable being mounted to the distal portion of the brace body, and the cable being routed proximally along the distal segment of the hinge mechanism, through the pivot cable guide, proximally along the proximal segment of the hinge mechanism, through the upper arm cable guide, and through the ulnar collateral ligament (UCL) cable guide; wherein, when the anatomical brace is mounted to the arm of a user so that the distal portion of the brace body is secured to the forearm of the user, and the proximal portion of the brace body is secured to the upper arm of the user, and when the elbow thereafter moves to full extension, the cable is tensioned, whereby to apply a force to the ulnar collateral ligament (UCL) of the user, and when the elbow thereafter moves to full flexion, the cable is relaxed, so that the force applied to the ulnar collateral ligament (UCL) is released.

A fabric-based soft actuator includes a first fabric layer, a second (material) layer, a bladder, and a fluid pump. The first fabric layer has anisotropic or isotropic stretch properties. The second layer is a fabric layer with anisotropic or isotropic stretch properties and/or a strain-limiting layer. The bladder is disposed between or integrated with the first fabric layer and the second layer, while the fluid pump is in fluid communication with and configured to inflate the bladder.

In one embodiment, the orthotic device can include a powered hand portion, a switching element, and a controller. The wearer can interact with the switching element to generate input signals for adjusting an operation of the powered hand portion. The controller can receive the input signals and generate control signals to accordingly adjust the operation of the powered hand portion. In some embodiments, a powered hand portion can be comprised of a plurality of linkages and at least one powered actuator to assist with an opening and closing of the hand portion. The plurality of linkages can be operated by at least one electric motor with quick-connect elements to link onto fingers of a user. In some embodiments, an electrically-actuated clutch mechanism can be affixed to an upper arm section and a lower arm section of an orthotic device. The clutch mechanism can be configured into different positions.

Provided are a connecting module and a motion assistance apparatus including the same, the connecting module including a case provided to incline downward from a space recessed between a waist and a hip of a user to a hip joint of the user, a power transmitting assembly disposed in an internal portion of the case, and a supporting module connecting portion disposed at an output terminal of the power transmitting assembly and to be fastened with a supporting module that supports a leg of the user.

Configurable orthoses having a high degree of independent adjustability of various parameters are provided. In the example of a rehabilitation-evaluation ankle-foot orthosis (REAFO), these parameters may include calf band anteroposterior, height, width, sagittal tilt, coronal tilt, and mediolateral displacement adjustments; mediolateral displacement adjustments of a supramalleolar support; heel width/stirrup separation adjustment; and sagittal active joint resistance and neutral angle adjustments. Calf band mediolateral displacement adjustment may be provided by a lockable four-bar pivoting frame linkage of the REAFO. In one aspect, the configurable orthosis is used in conjunction with a plastically deformable precursor member to facilitate the design and manufacture of a definitive orthosis customized for a particular patient. In another aspect, the orthosis communicatively transmits limb shape data to either a positive shape receiver apparatus or a CAD/CAM apparatus, to facilitate design and manufacture of a definitive orthosis.