An additive manufactured orthopedic and prosthetic device having a frame with an outer surface and an inner surface. The device includes a channel for a strap member positioned between the outer surface and the inner surface, wherein a bespoke device can be manufactured from 3D printing for supporting an anatomical region of a wearer.

A method, system, apparatus, and/or device for supporting a plantar flexion ridge. The method, system, apparatus, and/or device may include a leg calf shell further with a leg calf shell plantar flexion ridge at a lowermost point. The method, system, apparatus, and/or device may include a boot shell connected to a bottom portion of the leg calf shell. The boot shell may include a boot shell plantar flexion ridge at an uppermost point or the boot shell. The boot shell plantar flexion ridge may contact the leg calf shell plantar flexion ridge at a plantar flexion ridges region. The method, system, apparatus, and/or device may include a posterior stretch cord assembly. The first end of the posterior stretch cord assembly may attach to a back of the leg calf shell and the second end of the posterior stretch cord assembly may be attached to a back of the boot shell.

A lower extremity orthosis includes a foot engagement portion and an elongated positioning member. The foot engagement portion is configured to engage a patient's foot and includes opposing sidewalls extending from a sole-supporting surface configured to engage with a sole of the patient's foot. The elongated positioning member includes a foot-underlying portion and a lower leg-underlying portion, with the foot-underlying portion of the elongated positioning member serving to couple the elongated positioning member to the foot engagement portion. The lower extremity orthosis may be selectively and removably engaged with a heel offloading device via the lower leg-underlying portion of the elongated positioning member, such that the lower extremity orthosis is configured to prevent or reduce plantar flexion when the heel offloading device is used and the lower extremity orthosis is applied to the patient's foot.

A mobility enhancement device has an elongate strap of flexible material and a slide member having an inner face secured to a first surface of the strap and an outer smooth surface configured for sliding engagement with a floor surface. The strap is secured in a loop about a user's foot or footwear with releasable fastener devices associated with opposite end portions of the strap secured together and the slide member positioned to face downward from a ventral region of the sole of the foot or footwear so that the outer smooth surface is positioned for sliding engagement with a floor surface during ambulation or transfer.

A system and method are provided herein for modeling of force vectors for serial casts to correct orthopedic deformities includes a camera configured to capture a three-dimensional image of the deformity, a computing device programmed to generate a three-dimensional model of the deformity based on the image of the deformity, determine the boundary conditions for the deformity based on the three-dimensional image of the deformity, and generate force vectors for a series of casts to correct the deformity. In exemplary embodiments, the system can print a series of casts to correct the deformity.

A hinged ankle brace including a foot bed member and an ankle cuff which are hinged together by flexible joint members. The flexible joint members yieldably resist hinged movement between the foot bed member and the ankle cuff in a plantarflexion and dorsiflexion direction. Disc-shaped spacer-washers are positioned at the inner sides of the flexible joint members. The design of the upper ends of the medial and lateral wings of the foot bed member and the ankle cuff permits a limited amount of inversion and eversion movement between the foot bed member and the ankle cuff. The flexible joint members and the spacer-washers also permit a limited amount of inversion and eversion between the foot bed member and the ankle cuff.

The present disclosure provides a joint protection device, comprising a joint protection body that matches a shape of a joint. The joint protection body is a hollow housing having an opened bottom and comprises a front supporting portion and side supporting portions providing supports for the joint. A notch is provided in a portion of the joint protection body, which is close to a joint movement area. The notch divides the joint protection body into a plurality of joint pieces, adjacent joint pieces are connected by two local junctions respectively provided at appropriate positions on two sides of the joint protection body and can rotate with the local junctions as rotation fulcrums. Meanwhile, the present disclosure further provides other joint protection devices similar to the above, where an upper end of a joint protection body is provided with a clearance structure to ensure forward and backward movement of the joint.

An orthopedic device for the orthotic or prosthetic provision of a patient is provided. The orthopedic device includes a knee joint, which has a proximal upper part and a distal lower part arranged pivotably thereon, an ankle joint, a pivoted foot part which can be fastened distally to the ankle joint, and a shin part arranged between the ankle joint and the knee joint. The upper part of the knee joint or a thigh part fastened thereto that can be attached to the patient's body and is coupled with the foot part by means of a force transfer device, which causes a plantar flexion of the foot part when a knee is flexed.

A flat foot orthosis has two bodies and a pelvis portion. Each one of the two bodies has a wearing space, a foot portion, an ankle portion, a shank portion, a knee portion, a thigh portion, a toe portion, a hallux valgus region, a substrate, a first elastomer, and a second elastomer. The substrate and the first elastomer are disposed adjacent to each other, and surround the wearing space. The substrate extends from the toe portion to the thigh portion. The first elastomer spirally extends from an instep of the foot portion to the thigh portion through the rest. The two first elastomers surround and fetter where the wearer's pelvis and the wearer's waist meet. The second elastomer extends from the hallux sheath, is connected to the first elastomer, and wraps over the hallux valgus region.

The present invention discloses an exoskeleton which comprises a force balance back-carrying unit composed of a back-carrying assisting unit and a front-carrying assisting unit, a hip unit and a lower limb supporting unit, wherein the force balance back-carrying unit transfer the weight of a back-carrying load and/or a front-carrying load to the lower limb supporting unit through the hip unit to achieve the effort of assisting for the back-carrying load and/or the front-carrying load, wherein the length of the hip unit can be adjusted on the left-right plane and the upper-lower plane to adapt to wearers with different body types. On the other hand, the exoskeleton of the present invention is also provided with a buffer device to reduce the impact of the loads on the exoskeleton. The exoskeleton of the present invention also adopts quick-release joints, so as to modularize each part and standardize a docking interface of each module. The present invention can adapt to wearers with different hip shapes, and can transfer the weight of the back-carrying load and the front-carrying load to the lower limb supporting unit separately and simultaneously, so as to increase the weight-bearing efficiency and reduce the injuries to the back, the hands and the ankle joint.