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.

Exosuit systems and methods according to various embodiments are described herein. The exosuit system can be a suit that is worn by a wearer on the outside of his or her body. It may be worn under the wearer's normal clothing, over their clothing, between layers of clothing, or may be the wearer's primary clothing itself. The exosuit may be assistive, as it physically assists the wearer in performing particular activities, or can provide other functionality such as communication to the wearer through physical expressions to the body, engagement of the environment, or capturing of information from the wearer.

A motion assistance apparatus includes a force transmitting frame having a sliding space therein, the force transmitting frame configured to support a distal part of a user, a slider configured to slide in the sliding space, and a driving frame connected to the slider and configured to slide with respect to a proximal part of the user.

A system is provided for supporting an arm of a user that includes a harness configured to be worn by the user, and an arm support coupled to the harness and including an arm rest to support an arm of the user. The arm support is configured to accommodate and follow movement of the arm without substantially interfering in such movement. The arm support may at least partially offset a gravitational force acting on the arm as the user moves and the arm support follows the movement of the user's arm. For example, the arm support may transfer at least a portion of the weight of the user's arm to the torso or other region of the user's body and/or may apply an opposing force to at least partially offset the gravitational force acting on the arm.

A respiration-assistance apparatus or method can include or use a lifting element such as to cyclically push, pull, or lift, toward a superior direction of the subject, at least one subject region during an inhalation portion of a respiration cycle of the subject. A cyclical member can couple the lifting element to a fixed reference. Abdominal or ribcage compression can be provided. A multi-action or other cam can be used, such as together with a reciprocating element. Examples can be configured for use with a wheelchair, a bed, a vacuum or suction affixation element, a wearable garment, etc.

A patient support system with chest compression system and harness assembly with sensor system. The harness assembly secures shoulders and hips of the patient on a patient support surface during transport. A chest compression system is integrated into the harness assembly in a manner that provides chest compressions to the patient while the patient is secured on the patient support surface. The tension of the harness assembly is selectively adjusted and/or a fluid bladder may be selectively expanded. A controller is in communication with the chest compression system and controls operation of the chest compression system. The sensor system is integrated into the harness assembly and in communication with the controller. The chest compression system may be removable from the harness assembly via an adapter. The chest compression system may be integrated into the patient support apparatus to secure the patient to the patient support surface while providing chest compressions.

Wearable assistance devices and methods of using the same are disclosed. Embodiments relate to bimodal wearable assistance devices that provide assistance in one mode, and no or reduced assistance in a second mode, for reducing muscle stress, fatigue, injury and/or pain in the lower back or other body segments, and enabling comfortable, free or increased range of motion. Other embodiments relate to interfaces for wearable assistance devices that can loosen/tighten.

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.

In order to avoid chronic damage for people performing physical labor and to support the execution of activities, an exoskeleton is provided as a support device with a device for implementing rotational and translational human movements. The exoskeleton, which is coupled to at least one body part of a person, comprises at least one man-technology interface, a device for implementing rotational and translational human movements, and an actuating unit which, under certain circumstances, is supplemented by a sensor system and a controller.

An inversion table comprises a tabletop that tilts upon a frame from up to a vertical orientation to up to 90° below horizontal. Shoulder supports are oriented and located such that the top of a user's shoulders rest against the shoulder supports and the user's body weight is borne by their shoulders when the tabletop is tilted below horizontal. Ankle supports hold the user on the inversion table as the tabletop tilts.