The invention relates to a relief orthosis comprising a foot part which comprises a sole, a shank part extending away from the foot part in the proximal direction, and at least one fastening element for fastening the orthosis to a user, which fastening element is disposed on the foot part and/or on the shank part, wherein the foot part is embodied with an adaptable length.

A method for manufacturing a custom wearable and/or implantable medical device, such as an orthosis (e.g., an ankle brace, etc.), a prosthesis or the like, includes use of scanning processes. A digital model of a surface may be applied to a digital device model to define a custom digital device model. The digital model and, thus, the custom digital device model may include one or more standard features. The custom digital device model may be used with an automated manufacturing process to make some or all of the custom wearable and/or implantable medical device. In some embodiments, additive manufacturing processes may be used to form a portion or all of the custom wearable and/or implantable medical device.

Disclosed herein are devices, systems and methods for redistributing the normal weight distribution of a user in a standing position. One example is a postural platform for either the left or right foot having a bottom surface defining a reference plane, a top surface configured as a foot contact surface and a perimeter side wall between the bottom and top surfaces. The top surface is rotated about a first rotational axis parallel to the reference plane and rotated about a second rotational axis orthogonal to the reference plane. In another example, a system includes first and second postural platforms that are independent of one another. In other examples, the device is a sandal, shoe, sneaker or any foot covering with a tops surface being at a complex angle to a bottom surface.

Methods and apparatus for human anatomical orthoses. In one embodiment, an orthoses is disclosed that has been integrated into a sock and includes a tensioning element that is configured to keep the top portion of the sock at or above a user's calf muscle, a rotary tensioning mechanism disposed adjacent to the top portion of the sock, a support cable that is weaved within the body of the sock such that the support cable is maintained in close proximity with a user's leg when tension is applied thereto, and a supporting structure that is coupled to the support cable, the supporting structure being disposed adjacent to a user's toes. Methods of manufacturing and using the aforementioned orthoses is also disclosed.

Provided is a medical leg placing device to place a users injured leg, the medical leg placing device comprising: a first placer extending in an oblique direction with respect to the ground to place a calf of the leg; and a second placer coupled to one surface of the first placer and extended to place a foot of the leg.

This invention enables an injured leg to place stably without interruption both in a horizontal direction to the ground by crossing two supports coupled to the other surface of the first placer and in an oblique direction by unfolding a pair of supports.

It can be used comfortably for a patient with an injured leg sitting on a chair by adjusting the heights of the supports of a first placer.

An adjustable toe plate for an adjustable boot brace adapted to aid in stretching and supporting inflamed tissues and/or an inflamed plantar fascia within a person's foot while healing. The adjustable toe plate includes a toe plate adjustment mechanism to adjust the angle of the toe plate with respect to its foot portion, such that a person can adjust the position and angle of their toes during the healing process.

The present invention relates to an apparatus comprising: a seat for a patient; a support platform for the feet of the patient, positioned anteriorly to the seat; an alignment system allowing a patient's leg and its corresponding foot to be aligned in the three space planes in order to determine the tibia correct verticality; a system for properly positioning the foot on the platform including at least turrets able to allow pads to be applied in contact with the talus and/or scaphoid inside the foot and in contact with the calcaneus and/or cuboid outside the foot; a foot measurement system in a neutral position; an automatic real time driving system for properly positioning the leg and foot with numerical indication and direction of the movements to be carried out; a central unit capable for receiving and processing the data detected by the measurement system for footprint digitalization.

A medical apparatus has a base portion shaped and configured to engage a proximal portion of a user's limb, a mobile portion shaped and configured to engage a distal portion of the user's limb, and a motor assembly configured to selectively rotate the mobile portion relative to the base portion. Related methods are disclosed herein.

An external ankle brace for restricting movement of an ankle in a first direction and permitting movement of the ankle in a second direction includes a rigid heel enclosure having a rear portion and a forward portion. A lateral upright extension is perpendicular to the rigid heel enclosure and is attached to the lateral sidewall. A medial upright extension is perpendicular to the rigid heel enclosure and is attached to the medial sidewall. At least a chosen one of the lateral and medial upright extensions is selectively pivotally attached to a corresponding lateral or medial sidewall and includes a pivot prevention feature configured to selectively prevent pivoting of the chosen one of the lateral and medial upright extensions with respect to the corresponding lateral or medial sidewall.

Lower-limb exoskeletons used to improve free-living mobility for individuals with neuromuscular impairment must be controlled to prescribe assistance that adapts to the diverse locomotor conditions encountered during daily life, including walking at different speeds and across varied terrain. This system employs an ankle exoskeleton control strategy that instantly and appropriately adjusts assistance to the changing biomechanical demand during variable walking. Specifically, this system utilizes a proportional joint-moment control strategy that prescribes assistance as a function of the instantaneous estimate of the ankle joint moment.