An intelligent compression device for controllable compression. The compression device includes a compressible body and a microprocessor. The compressible body encircles a limb of a user and includes an elastomer layer and an activation layer. The elastomer layer includes voxelated liquid crystal elastomers that contract in response to a stimulus. The activation element, which is positioned proximate to the elastomer layer, supplies the stimulus. The microprocessor actuates at least a portion of the activation element layer.

A multi-function exercise treadmill includes a tread belt driven by an electric motor; an underlying frame including two front uprights, an intermediate upright with the electric motor secured thereto, two side rails with the tread belt rotatably disposed therebetween, two cross rails each interconnecting the front uprights and secured to the intermediate upright, a rack disposed on the intermediate upright and including a plurality of cavities configured to place a plurality of dumbbells therein, and a plurality of pairs of bars disposed on the intermediate upright; a massaging strap driven by the electric motor; and a plurality of rally ropes each having one end secured to the cross rail.

A wearable pain management apparatus includes a drum shaped oscillatory motion driver mounted with electromagnetic coils attached to a non-stretching belt tightly strapped around a user's waist. The driver's top surface is pressed against the back of the user's waist. A belt has a ratchet buckle and a group of elongated tracks. A holster with a battery pack is securely clipped onto the belt. A center mounted motor drives a set of torque conversion planetary gears. An off center mounted mass rotates and causes unbalance and an oscillatory motion. A power cable laminated between two surfaces of the belt body terminates on a switch. The user holds a deep breath while pulling hard on the belt end causing the ratchet buckle to lock on the tracks. This action effectively places hand pressure on the apparatus rubbing on their back via the Oscillatory Pulsed Electromagnetic Field to speedily alleviate pain.

An intelligent compression device for controllable compression. The compression device includes a compressible body and a microprocessor. The compressible body encircles a limb of a user and includes an elastomer layer and an activation layer. The elastomer layer includes voxelated liquid crystal elastomers that contract in response to a stimulus. The activation element, which is positioned proximate to the elastomer layer, supplies the stimulus. The microprocessor actuates at least a portion of the activation element layer.

An intelligent compression device for controllable compression. The compression device includes a compressible body and a microprocessor. The compressible body encircles a limb of a user and includes an elastomer layer and an activation layer. The elastomer layer includes voxelated liquid crystal elastomers that contract in response to a stimulus. The activation element, which is positioned proximate to the elastomer layer, supplies the stimulus. The microprocessor actuates at least a portion of the activation element layer.

The invention relates to a locomotion aid (1) for people with limited mobility, comprising at least one frame (1), frame legs (2) which are connected to the frame (V) at a first end (2) and the second ends (2) of which are equipped with casters (3), a hip lock or a lumbar lock (8) which is connected to the frame (1) via a return mechanism (7) and via a mounting (6), and a seat (9) with an integrated brake triggering mechanism, wherein the seat (9) interacts with the hip lock (8), the return mechanism (7), which is in the form of a spring for example, and the mounting (6) when the seat is actuated by the person such that the brake triggering mechanism (5) can be triggered.

In some embodiments, a system may include a first wearable harness worn, during use, on a torso of a subject. The system may include a second wearable harness worn, during use, on a torso of a subject on an outer surface of the first wearable harness. The system may include a plurality of engines which when activated apply an oscillation force to at least one treatment area. At least one of the plurality of engines may be releasably couplable to the first wearable harness using a positioning system such that the oscillation force is applied to the treatment areas. The oscillation force may mobilize, during use, at least some secretions in an airway within the subject at least adjacent the treatment area. The second wearable harness, when activated, may provide a compressive force to at least some of the activated plurality of engines positioned above the treatment area.

In some embodiments, a method may include clearing a biological airway. The method may include positioning an inner wearable harness on a torso of a subject. The method may include selectively positioning at least some of a plurality of engines on and/or adjacent at least one treatment area. At least one of the plurality of engines may be releasably couplable to the inner wearable harness. The method may include positioning an outer wearable harness on a torso of a subject. The method may include applying an oscillation force to at least one of the treatment areas using at least some of the plurality of engines. The method may include adjusting the applied oscillation force to the treatment area by activating the outer wearable harness. The method may include mobilizing at least some secretions in an airway within the subject substantially adjacent the at least one treatment area.

In some embodiments, a method may include monitoring use of a medical device. The method may include positioning a wearable harness of a medical device on a subject. The method may include selectively positioning at least some of a plurality of engines on and/or adjacent to at least one treatment area. The method may include applying an oscillation force to at least one of the treatment areas using at least some of the engines. The method may include mobilizing at least some secretions in an airway within the subject substantially adjacent to the treatment areas. The method may include monitoring use of the medical device by the subject using a controller associated with the medical device to determine if the medical device has been used effectively as prescribed.

In some embodiments, a method may include clearing a biological airway. The method may include positioning an inner wearable harness on a torso of a subject. The method may include selectively positioning at least some of a plurality of engines on and/or adjacent at least one treatment area. At least one of the plurality of engines may be releasably couplable to the inner wearable harness. The method may include positioning an outer wearable harness on a torso of a subject. The method may include applying an oscillation force to at least one of the treatment areas using at least some of the plurality of engines. The method may include adjusting the applied oscillation force to the treatment area by activating the outer wearable harness. The method may include mobilizing at least some secretions in an airway within the subject substantially adjacent the at least one treatment area.