Fascia activation and training devices having an adjustable length, collapsible, elongate device body having opposing ends to which open ended interchangeable cuffs are removably mounted. The end cuffs of the training devices provide for inward and/or outward compression forces to be applied by a user's body members engaging such end cuffs, thereby enhancing fascial activation and training, and providing users with proprioceptive feedback, making motor learning in biomechanical retraining through fascia remodeling possible. Methods of use of such training devices provide for the use of multiple types of training devices in combination, resulting in the enhanced training of biomechanical chains of muscles.

An exercise apparatus includes flexible elongated members configured for attachment to shoes of a user. Motor assemblies are disposed between the elongated members and the shoes, respectively, and cause the flexible elongated members to oscillate. Rotational drums attached to the flexible elongated members and are configured to rotate the flexible elongated members while the elongated members oscillate.

A portable modular stretching apparatus has a basic structure of a base, central rod, pulley, cable system, and two legs jointed at the central rod and alongside the base. Attachments are then added for customized stretching. Attachments provide for hamstring, hips, quadriceps, knees, gastrocnemius, ankle, and metatarsal stretching, limberness, and extension, and hyperflexion. A person adds and removes the attachments based on the desired stretch routine, controls the tension, and removes the attachments, and folds the apparatus when complete.

Exemplary arrangements provide leg training devices suitable for high intensity training of hip flexors while simultaneously training the extensors of hip and knee joints. The exemplary leg training devices include foot fixings which are permanent vertically movable components of the device, each of which are configured to releasably engage a foot of a user in operative engagement therewith while limiting the movement of the foot relative to the foot fixings. Each of the foot fixings is operatively connected to a suitable mechanism that provides a resistance force to vertical movement of the foot fixing by the user's leg. In exemplary arrangements the resistance force may be selectively variable with regard to the magnitude and/or point of application so as to provide the desired training regimen.

A wearable passive exoskeleton device for sit-to-stand and/or stand-to-sit transfer includes a leg exoskeleton frame configured to be worn at a user's leg and a lever arm rotatably coupled to the leg exoskeleton frame so as to provide a handle for the user to move between a sitting position and a standing position (or between a kneeling position and a standing position). The lever arm is rotatable with respect to the leg exoskeleton frame between a stowed position and a deployed position. The lever arm may be a unidirectional lever arm configured to rotate only in a first rotational direction with respect to the leg exoskeleton frame such that a pushing or pulling force exerted in a second rotational direction transmits an assisting force to the user to assist in a sit-to-stand and/or stand-to-sit movement.

The present invention relates to a method for generating a trajectory of an exoskeleton (1) provided with two legs each having a foot, the method comprising the implementation by data-processing means (11a) of a server (10a), of steps of: (a) obtaining at least one n-tuple of gait parameters defining a given gait of the exoskeleton (1); (b) generating at least one periodic elementary trajectory of the exoskeleton (1) for said n-tuple of gait parameters, such that said periodic elementary trajectory comprises in sequence a first trajectory portion and a second trajectory portion, such that in the first trajectory portion each foot performs a pure rotation, and in the second portion only one foot performs a translation.

There is provided a dynamic and proactive system for supporting sitting while detecting and changing sitting postures of a user and method of operation thereof. The system including a frame, a plurality of supports, each configured to support a different body part, and a plurality of joints each configured to move independently of or together with any other of the joints, each of the supports is connected to the frame via a corresponding joint, at least one of the joints is a two dimensional joint which enables a change in angle between the frame and a corresponding support. Each one of the plurality of supports is configured to move with respect to the frame or to another support, thereby enabling any changes in sitting postures of the user. The system comprises sensors, which based on their readings, the system detects user postures and suggests or creates posture changes.

In one embodiment, the exoskeleton structure is fastened to the body of the user by a brace and at the foot level. The exoskeleton includes at least one set of three joints corresponding to the hip abduction/adduction, the hip flexion/extension and the knee flexion/extension, wherein the architecture of the exoskeleton is compatible with a set of different removable, adaptable and backdrivable actuation units dedicated to each joints and remotely located around the trunk of the user to decrease inertia and mass on the distal segments, wherein each joint can be modularily let free, constrained by a visco-elastic mechanism or actuated by one corresponding actuation unit.

A wearable module, for a wearable device, may include: a cover comprising a cover body and a cover hole penetratingly formed in the cover body; a support part including a support body made from a material that is more flexible than that of the cover, a support head that is connected to the support body and that can be attached/detached to/from the cover body, and an attachment part, which is connected to the support body, is positioned on the opposite side of the support head with respect to the support body, and passes through the cover hole to be attached to the outer surface of the support body; and an elastic layer of which a portion is fixed to the support part and which can move relative to the cover.

A method for controlling an ambulatory exoskeleton (1) linked to a user (100), comprising the following steps: —measuring only the vertical component (Z.sub.Ng, Z.sub.Nd) of the pressure (R.sub.d, R.sub.g) under each foot (123, 133) of the user (1); —controlling actuators (40, 41, 42, 43) such that the vertical component (Z.sub.Ed, Z.sub.Eg) of the resultant of the balancing forces (R.sub.Eg, R.sub.Ed) applied to the exoskeleton (1) and exerted by each foot (23, 33) of the exoskeleton (1) on the ground is a function of the vertical component (Z.sub.Ng, Z.sub.Nd) of the pressure (R.sub.d, R.sub.g) measured under the corresponding foot (123, 133) of the user (100).