Exercise apparatuses that may be particularly useful or treating and strengthening connective tissue. For example, apparatuses that may have or be reconfigured to have multiple (e.g., three or more) configurations that are suspended from above by a ceiling or stand. The equipment facilitates the stabilization of the body according to the principle of tensegrity, so that the tension in all movements is omni-directionally coherent, thus creating omni-tensional integrity, which may be helpful in treatment and strengthening of muscular connective tissue (fasciae) in musculoskeletal dynamics, to restore, rebuild, strengthen and regain elasticity within the human fascial network. These apparatuses can support the user at an oblique body angle while the user performs various movements.

In one embodiment, a computer-implemented system includes treatment apparatuses configured to be manipulated by patients while performing an exercise session, patient interfaces associated with the plurality of patients, and a server computing device configured to receive first characteristics pertaining to the patients, and initiate a virtual shared session on the patient interfaces associated with the patients. The virtual shared session includes at least a set of multimedia feeds, and each multimedia feed of the set of multimedia feeds is associated with one or more of the patients. During the virtual shared session, the server computing device may present a first layout including the set of multimedia feeds, the first characteristics, or some combination thereof.

The invention is directed to systems, devices, and methods for measuring force and repetitions during exercise or rehabilitation activities. Devices in accordance with some embodiments may include: a casing; a processor within the casing; a display visibly on the casing; a first attachment portion on one end of the casing; a second attachment portion on an opposite end of the casing; and a force sensor connected to the first and the second attachment portion, the force sensor in communication with the processor. Methods may include: attaching an exercise band to the wireless force measurement device; conducting exercises causing the exercise band to stretch and pull away from the wireless force measurement device; counting, by the device, the number of times the band stretches and pulls away from the device; determining, by the device the amount of force applied through the exercise band during the exercise.

An exercise device for alternating movement of arms and legs by which users perform alternating active exercises and passive exercises repetitively is revealed. The exercise device includes a base, a hand driving member, and a leg driving member. Both the hand and leg driving member are pivotally connected to the base while the leg driving member is arranged under the hand driving member. One end of the hand driving member and one end of the leg driving member are configured to be pivotally rotated on the base. The hand and leg driving members are pivotally connected by a linkage. By the pivotal connections of the above parts, the hand and leg driving members are linked and moved with each other so as to lift up or press down arms and legs for stretching. The stretching of arms and legs also generates pressure on the abdomen of the user to exercise his or her abdomen.

The object of the invention is an apparatus suited for individuals in training dynamic balance and turning manoeuvres while walking, said apparatus allowing said operation while an individual is standing, walking on a flat surface or walking on a treadmill that can rotate around its vertical axis. To serve this purpose, the apparatus of the invention is provided with a base platform (1), in which two universal joints (2, 2) are arranged that are connected with a pelvis element (5) with two vertical rods (3,3′) or vertically adjustable rods (30,30′) via conventional spherical joints (4,4′), and the universal joints (2,2′) have two degrees of freedom that can further be provided by drives (6,7,8).

A walking assist device has a frame, a plurality of wheels, drive units, a battery, and a drive control unit that controls the drive units. The walking assist device also has: a pair of right and left movable handles that are grasped by a user and movable back and forth with respect to the frame in accordance with arm swing performed during walk of the user; handle guide units provided on the frame to guide the movable handles in a movable range that matches the arm swing performed during walk of the user; and a grasp portion state detection unit that detects the state of the movable handles. The drive control unit controls the travel speed of the walking assist device by controlling the drive units on the basis of the state of the movable handles which is detected using the grasp portion state detection unit.

Systems, methods, and computer-readable mediums for operating an electromechanical device are disclosed. The system includes, in one example, the electromechanical device, a patient portal, and a computing device. The computing device is configured to receive user data relating to a user, and receive treatment data relating to treatment plans and outcomes. The computing device is also configured to generate a prehabilitation plan by using a machine learning model to process the user data and the treatment data. The computing device is further configured to select, for the electromechanical device, an electromechanical device configuration that enables exercises of the prehabilitation plan to be performed by the user such that performance improves an area of the user's body. The computing device is also configured to enable the electromechanical device to implement the electromechanical device configuration.

An upper body support assembly for use with an associated railed device having first and second rails is disclosed. The assembly includes first and second upper body supports capable of moving along the first and second rails, respectively. The upper body supports have at least one of: (i) first and second forearm supports, (ii) first and second hand grips, or (iii) a first forearm support and a first hand grip. An interconnecting member extends between and selectively connects both the first and second upper body supports to permit (i) interrelated movement therebetween when connected, and (ii) independent movement therebetween when disconnected. The assembly can achieve two point gait, three point gait, and four point gait movement.

A body weight support system includes a trolley, a powered conductor operatively coupled to a power supply, and a patient attachment mechanism. The trolley can include a drive system, a control system, and a patient support system. The drive system is movably coupled to a support rail. At least a portion of the control system is physically and electrically coupled to the powered conductor. The patient support mechanism is at least temporarily coupled to the patient attachment mechanism. The control system can control at least a portion of the patient support mechanism based at least in part on a force applied to the patient attachment mechanism.

A device for upper-limb rehabilitation, which assists a user in exercising the arm for rehabilitation, has a connector, a placing unit movably connected to the connector, and a driving unit configured to move the connector, wherein when a user places the arm on the placing unit and moves the placing unit, the driving unit is operated to move the connector along the placing unit, so as to enlarge a work space in which the user is capable of moving the arm.