An exoskeleton for supporting an arm of a user includes a torso attachment device for releasably connecting the exoskeleton to a torso of the user, a bracket which is connectable to the torso attachment device, a lifting rod which is connectable to the torso attachment device via the bracket and which is reversibly movable in a first direction and a second direction relative to the bracket, a cantilever for supporting the arm of the user which is releasably connectable to the arm of the user, and a ratchet mechanism. The ratchet mechanism connects a first end of the lifting rod to a first end of the cantilever where the ratchet mechanism allows rotation of the cantilever in a first direction of rotation and blocks rotation of the cantilever in a second direction of rotation.

A system having an arrangement for supporting an arm of a user is disclosed. The arrangement has an actuator, which is connected to a shoulder element by a joint chain. The joint chain is designed to extend along the shoulder blade of a shoulder of the user and to introduce vertically acting forces into the shoulder element. Moreover, the joint chain is guided by a flexible structure that extends over the shoulder of the user. By virtue of the deformability of the flexible structure, it is possible to ensure that a lifting of the shoulder, resulting from a lifting of a hand of the user, is not impeded.

A traction apparatus develops a pull force through some or all the compressed joints of the ankles, the knees, the hips and the vertebrae of an individual, after the individual attaches to the ankles, or the waist, or the shoulders, a harness connected to suspended weights, and then positions self to rest supine over an inclinable, full length frictionless surface of full-width idler rollers, and inserts self's head's occipital portion into a crescent shaped hollow head restrainer which arrests the body's pull by the weights.

An example of an automated external defibrillator (AED) includes a housing including a lid, printed graphical instructions indicating sequential steps for treatment of a patient with the AED, a speaker configured to provide audible messages associated at least in part with the printed graphical instructions, and defibrillation electrodes stored under the lid and configured for application during the treatment of the patient according to steps including a step of peeling a left electrode pad from a liner of the left electrode pad, a step of applying the left electrode pad to the patient, a step of peeling a right electrode pad from a liner of the right electrode pad, and a step of applying the right electrode pad to the patient.

A robotic exoskeleton comprising a back portion providing at least two degrees of freedom, two shoulder portions, each shoulder portion providing at least five degrees of freedom, two elbow portions, each elbow portion providing at least one degree of freedom, and two forearm portions, each forearm portion providing at least one degree of freedom. Associated robotic forearm joints and robotic shoulder joints are also addressed.

A pendular joint decompression device including a table configured to support a person lying on his or her back, and a traction system including cabling, a leg-receiving unit secured to the cabling and configured to link this cabling to the person's legs, a traction unit configured to act on the cabling, an oscillator configured to act on the cabling, and a control unit capable of controlling the traction unit and the oscillator in order to combine lateral oscillation movements and traction movements on the person's raised legs, characterized by the fact that the leg-receiving unit is configured to apply, for each of the person's legs, a force on the rear of the calf and a force on the front of the ankle, simultaneously, when the traction unit acts on the cabling.

A system and method by which movements desired by a user of a lower extremity orthotic is determined and a control system automatically regulates the sequential operation of powered lower extremity orthotic components to enable the user, having mobility disorders, to walk, as well as perform other common mobility tasks which involve leg movements, perhaps with the use of a gait aid.

A system for interfacing with an operator's body for distributing forces to the operator's body received by the system from a function unit. The system includes a frame and a plurality of contact units connected to the frame which are positioned and communicate with the operator's torso to distribute the received forces. The plurality of contact units each include a first and second support having an elastic body positioned therebetween which allows relative movement between the first and second supports.

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 lumbar traction arrangement, comprising movement means arranged to receive a sitting person and arranged to allow movement of the person, and traction means operatively coupled to the movement means causing variable vertical traction to the person's lumbar during movement provided by the movement means.