An orthopedic system includes an orthopedic device defining a posterior aspect, an anterior aspect opposite the posterior aspect, and a structure at least in part defining a receiving space arranged to receive an activity tracking device. An activity tracking device is positionable and securable in the receiving space of the orthopedic device. The activity tracking device is arranged to generate information associated with activity level or compliance of a patient wearing the orthopedic device during treatment.

A pneumatic compression assembly that includes a sleeve having an outer layer and an inner layer that defines a sleeve interior configured to receive a body part of a user, and at least a first vibration assembly configured to provide vibration to the body part of the user. A plurality of inflatable compartments are arranged longitudinally along the sleeve between the inner layer and the outer layer. The first vibration assembly includes a plurality of vibration motors positioned between the inner layer and the outer layer of the sleeve.

A garment worn on the upper body is provided with a back support system that can be selectively actuated as needed, and otherwise remains relatively unobtrusive when not actuated. The back support system includes a selectively inflatable and deflatable air bladder positioned at a desired location on a rear part of the garment opposite a portion of the wearer's back that needs support. Preferably, the air bladder is disposed within a pocket or compartment, preferably defined on an interior side of the garment, thereby leaving the exterior of the garment relatively unaltered in a visual sense. In a particular example, the air bladder of the present invention has a physical configuration designed to support specific portions of the spinal column as well as adjoining musculature.

A walking brace is provided. The walking brace includes a U-shaped malleable stay configured to hold a manually-bent shape. The walking brace includes an integral portion. The integral portion includes a footbed, a first upright disposed at a first side of the footbed and a second upright disposed on a second side of the footbed. The integral portion is overmolded onto the U-shaped malleable stay such that the U-shaped malleable stay extends through each of the footbed, the first upright and the second upright. Other walking braces are provided wherein the integral portion includes a pocket configured to receive the U-shaped malleable stay at an underside of the integral portion such that the U-shaped malleable stay extends through each of the footbed, the first upright and the second upright. A method of manufacturing a walking brace is also provided.

A foot and ankle support system using one or more pressure-flexed support bars made of resilient material, each of which can be adjustably positioned and removably attached to selected positions along the medial, lateral, or posterior heel sides of an article of footwear. One end of the support bar is affixed to the base portion of the article of footwear and the other end is affixed to the collar or ankle portion causing the resilient support bar to flex into a bow-like position. Each support bar stores energy and returns resistance when engaged by various directional movements of the foot during walking, running, sports activities or rehabilitation. A plurality of pressure-flexed support bars work in tandem to provide additional support and control of foot inversion and eversion, pronation and supination. An alternative embodiment uses a pressure-flexed bladder type support bar filled with air, gas, liquid gel or other material.

A pneumatic compression assembly that includes a sleeve having an outer layer and an inner layer that defines a sleeve interior configured to receive a body part of a user, and at least a first vibration assembly configured to provide vibration to the body part of the user. A plurality of inflatable compartments are arranged longitudinally along the sleeve between the inner layer and the outer layer. The first vibration assembly includes a plurality of vibration motors positioned between the inner layer and the outer layer of the sleeve.

Systems, methods, and devices are described for providing a brace having an inflation control. The control directs fluid flow from an inflation component to one or more inflatable cells of the brace. The inflatable cells are independently inflated and deflated by the inflation component through the control. The control allows a user to create a fluid path between the inflation component and one of the inflatable cells by positioning the control in an orientation corresponding to the desired inflatable cells. Each inflatable cell is independently inflated and deflated in various orientations of the control.

A buoyancy-based cervical traction system has a floatation and a head rest supported by the flotation system. The head rest is adapted to support a person's head above the neck and apply traction to the neck when the person is in a body of liquid. The system has a position adjustment system adapted to allow selective adjustment of the position at which the person's head rest will be relative to an upper surface of the liquid when the person and the cervical traction system are in the liquid, the person's head is supported by the head rest, and the cervical traction system and person are floating in the liquid at equilibrium.

Apparatus and associated methods relate to a wearable compression therapy system for ambulatory therapy, the system including a wearable garment having one or more inflatable chambers, and a pneumatic engine locally coupled to the garment to provide control and inflation of the one or more inflatable chambers. In an illustrative embodiment, the pneumatic engine may control a pump and one or more valves to inflate the inflatable chambers. The valves and pump may be coordinated according to a pre-programmed profile. In some embodiments, the pneumatic engine may have a wireless interface configured to receive control signals from a remote mobile device untethered from the garment. The pneumatic engine may send to the remote mobile device signals indicative of sensed conditions of the compression therapy system. In some embodiments, the pneumatic engine may include a power source that advantageously permits the user to be untethered from a source of power.

A full body elevator includes an inflatable upper body elevator having a sloped backrest panel and a generally flat, horizontal butt rest panel extending from the backrest panel; and an inflatable lower body elevator having a leg portion with a leg support panel sloping from the butt rest panel and a foot portion with a foot support panel selectively inflatable and extendable with respect to the leg portion.