A somatosensation and proprioceptor stimulation surface configured to stimulate rapid-firing nerves in the receptive field of a user's glabrous skin. The somatorsensation and proprioceptor stimulation surface includes a plurality of protuberances disposed thereupon, each protuberance sized and spaced apart appropriately to impress the receptive field when pressed in contact with the glabrous skin of the user. Each protuberance widens from an apex toward a base whereby increased pressure applied to the surface increases an area of contact and stimulation by applying stimulation over a larger area of skin. The protuberances are spaced apart to maximize stimulation of rapid firing nerves while lessening overstimulation. The somatosensation and proprioceptor stimulation surface is rendered in the form of a mat or floor covering and alternatively as an insole for wear in a user's shoes.

A walking training system and an operation method capable of performing training effectively are provided. A walking training system according to an embodiment includes a harness attached to a trainee's trunk, a first pulling unit configured to apply a pulling force to the harness from a first direction along a horizontal direction, a second pulling unit configured to apply a pulling force to the harness from a second direction along the horizontal direction, and a control unit configured to control the first and second pulling units.

A human interface device is configured to be coupled to a trunk of a person and comprises a frame, a fabric coupled to said frame configurable to be under tensile forces, and a belt configured to be coupled to two side edges of said frame wherein when said belt is worn by said person, an area of said fabric will be pushed against the person’s lower back conforming to the shape of the lower back of said person. In operation when said human interface device is worn by said person, the weight of any load coupled to or supported by said frame will be partially supported by the friction force between the area of said fabric which is pushed against the person’s lower back, and the person’s lower back allowing said person to carry said load.

A rollator is disclosed, including first and second upright members, each including handle portions, wheels, hinges disposed between the wheels and the handle portions, channels disposed along the upright members between the hinges and the wheels, and lateral hinges orthogonal to the hinges. First and second foldable support members having wheels are attached to the hinges. At least one lateral support member is disposed between and attached to the lateral hinges, and includes an intermediate hinge. Brake systems include brake lines communicating between brake controls and brakes. In a reversible storage configuration, the foldable support members are rotated to be at least partially disposed in the channels, and the lateral hinges and intermediate hinge rotate to collapse the lateral support member, bringing the upright members with the folded foldable support members adjacent to one another.

In an embodiment, an exoskeleton that can be applied to a limb of a wearer (P) includes a first member (12) and a second member (14) with an articulation (16) set in between to enable a relative movement of angular orientation of the first member (12) and of the second member (14) over a range of angular orientation. The exoskeleton (10) can likewise present at least one of the following features: —i) the second member (14) includes: —a first structure (14a), which can be oriented at the aforesaid articulation (16) with respect to the first member (12) over the entire said range of angular orientation; and —a second structure (14b), which can be coupled to the limb of the wearer (P) with a latch device (20) for latching the second structure (14b) to the first structure (14a), the latch device (20) being selectively disengageable at a certain angular position of the aforesaid range of angular orientation to render the first structure (14a) orientable with respect to the first member (14) independently of the second structure (14b); and/or —ii) the exoskeleton includes a distal end platform (22) coupled to the exoskeleton via a ball joint (18).

The present disclosure relates to the field of exercising equipment. A device (100, 200, 300, 400, 500, 600) disclosed in the present disclosure increases the reverse blood flow rate, i.e., flow rate of blood from legs towards heart. The device (100, 200 300, 400, 500, 600) includes a pedal (125, 220, 330, 420, 520, 630) configured to support a foot of a leg thereon. The device (100, 200, 300, 400, 500, 600) includes a drive mechanism (140, 250, 350, 530) to oscillate the pedal (125, 220, 330, 420, 520), thereby rocking the foot about the axis of the ankle joint to cause natural movement of the foot as during walking.

A lumbar herniated disc treatment device includes an upright post, a rail vertically mounted on the upright post, a chest fixing device up-and-down, slidably mounted on the rail, a lumbar traction and torsion device up-and-down slidably mounted on the rail and positioned below the chest fixing device, and a waist massage device up-and-down slidably mounted on the rail and positioned between the chest fixing device and the lumbar traction and torsion device.

Provided are an assistance device, an assistance garment, and an assistance method that enable easy replacement of a part of structure, suppression of fatigue of a wearer, and reduction of a load in an action of the wearer, without requiring time and effort for putting on and taking off. An assistance device 1 is art assistance device 1 that is provided on a garment and reduces a load in an action of a wearer 5. The assistance device 1 is provided with an assisting part 10 that is replaceable and applies force for assisting the an action to the body of the wearer 5 by changing flexibility, and an assist-control part 12 that controls the flexibility.

Systems and methods for exerting forces on a body, including a support structure defining a space and a plurality of surface contacting units that are configured to exert force upon the body, such that the weight is distributed away from the primary weight bearing regions to non-weight bearing regions of the body, or vice versa, without exerting significant shear or frictional forces on surfaces of the body. The systems and methods may be used to exert forces to cause fluid shift in different compartments of the body. Applications include treatment of various disease conditions including pressure ulcers, heart failure, high blood pressure, preeclampsia, osteoporosis, injuries of spine and to slow microgravity-induced bone and muscle loss. The systems and methods may be used to simulate gravity, weightlessness or buoyancy, in rehabilitation medicine. The system may include a chair, bed, a wearable suit or an exoskeleton.

Patient therapy and patient condition sensing devices and methods can be operated as a function of estimated internal hydrostatic pressure of a body part, for example at a position where a pressure or compression therapy is applied. Information relating to a patient's position, posture, ambulation and/or a physiological condition such as blood pressure can be used to control pressure or compression therapy.