An orthotic foot rest is a pedal for a pedaling machine. It includes a platform, an instep-strap and/or a heel strap and a width-adjusting assembly. The platform holds a person's foot that is either bare or in a shoe. When present, the instep-strap forms an arch extending up above the platform such that the person's foot, with or without a shoe, can be slipped under the arch and rest on the platform. When present, the heel strap encircles the person's foot. A width-adjusting assembly adjusts the tension against the side of the foot to secure it in place on the platform. Paired-strap-posts define a u-shaped-slot between them that is wide enough to receive the strap and restrain a cam buckle that is slidably attachable on each of the straps. A release strap enables a person to pull on the release-strap to remove the buckle from the u-shaped-slot.

A micro, compact cycling utility with an adjustable and modifiable structure that can perform as cycling or exercise equipment. The invention encompasses a housing that can be used as a case and/or attachment, crank arms, pedals and a stand. In the exemplary embodiment, the crank arms and pedals and stand are modifiable and adjustable.

In one embodiment, a method is disclosed. The method includes, while the patient uses the treatment apparatus, controlling, based on a treatment plan for a patient, a treatment apparatus. The method includes receiving, by a processing device, data from an electronic device, wherein the data comprises one of a position of a body part of the patient or a force exerted by the body part. The method includes storing, via the processing device, the data for the patient in a computer-readable medium. The method includes causing, via a processing device, presentation of a user interface on a patient interface. The user interface comprises an adjustment confirmation control, and the adjustment confirmation control is configured to solicit a response regarding the patient's comfort level with the one of the position of the body part or the force exerted by the body part.

A training device and a training method for reducing hypertonic are disclosed. The training device includes a base, a driving circuit, two pedals, a control circuit, and a switch circuit. The driving circuit is fixed on the base. Each of the two pedals is coupled to the base. The driving circuit drives each of the two pedals to swing repeatedly between a first position and a second position relative to the base. When the control circuit executes a training program, the control circuit actuates the driving circuit.

A computer-implemented system includes an electromechanical machine and a processing device communicatively coupled to motors. The processing device executes instructions to receive first data comprising information pertaining to motion of one or more pedals of the electromechanical machine, wherein the motion is associated with one or more users performing one or more treatment plans; receive second data comprising information pertaining to one or more characteristics of the one or more users performing the treatment plan, wherein the characteristics comprise performance information, measurement information, personal information, or some combination thereof; identify one or more correlations between at least some of the first data and at least some of the second data; and generate, based on the one or more treatment plans and the one or more correlations, one or more motion profiles for an assembly of the electromechanical machine.

A machine includes a body with an arm having a proximal end and a distal end. The proximal end is pivotally mounted to the body, and the distal end is free to move relative to the body. A carriage is slidably mounted to the arm for movement along a length of the arm. A pedal assembly is rotatably coupled to the carriage for movement with the carriage along the length of the arm. The pedal assembly supports a foot of a user of the machine. Motors are mounted to the body and spaced apart from each other and spaced apart from the distal end of the arm. Cables are coupled to respective ones of the motors and to the carriage. A control system selectively extends and retracts the cables with the motors to cause the pedal assembly to move in prescribed pedaling patterns relative to the body.

An exercise apparatus with oscillating tilt system includes a main frame for supporting all the components of the apparatus, a tiltable upstanding support is tilted oscillating, a mechanism which enabling a user of the apparatus to move hands and feet up and down harmoniously, and another mechanism to change an orientation of the user in relation to the vertical line oscillating during the exercise, and consequently changing the direction of the forces affecting different muscles of the user of the apparatus.

A seated treadmill has a structure with a front portion and a rear portion. A front roller is rotatably mounted on the front portion of the structure, a rear roller is rotatably mounted on the rear portion of the structure, and a belt circumscribes the front and rear rollers. The front and rear rollers are much closer together than prior art treadmills, typically about 10-30 inches. The treadmill may further include a remote control for controlling operation of the treadmill, and a shutoff switch in the event that too much force is placed upon the treadmill, such as, e.g., if the user attempts to stand on the treadmill.

Systems and methods for a muscle signal-driven cycling system for persons with disability for rehabilitation are provided. A system comprises integrating both motor power and muscle power to facilitate rehabilitation cycling-based exercises. By using the intensity of real-time muscle activity signals as inputs, a motor applies either assistive or resistive force to rotate a gear at different speeds to facilitate or impede the cycling motion, and the electrical pulses from an electrical stimulation device can be provided to stimulate target muscles to generate muscle contraction to support the continuous cycling movement.

A computer-implemented system includes an electromechanical machine and a processing device communicatively coupled to motors. The processing device executes instructions to receive data comprising a treatment plan; generate, based on the data, a motion profile for an assembly of the electromechanical machine; determine, based on a prescribed exercise of the one or more prescribed exercises, components to include to enable the user to perform, using the electromechanical machine, the prescribed exercise; validate, based on the components and configuration information pertaining to the electromechanical machine, whether the motion profile associated with the prescribed exercise is achievable with respect to a threshold achievement level; and determining, based on the one or more components and the configuration information, at least one missing component needed to achieve, with respect to the threshold achievement level, the motion profile for the prescribed exercise.