In various embodiments, non-invasive methods to induce motor control in a mammal subject to spinal cord or other neurological injuries are provided. In some embodiments the methods involve administering transcutaneous electrical spinal cord stimulation (tSCS) to the mammal at a frequency and intensity that induces locomotor activity.

An electrical stimulation indoor bike includes a stationary bicycle; an electrical stimulation unit connected to the stationary bicycle either with wire or without wire, and including an electrode pad for applying electrical stimulation to a user's body; and a control unit to control electrical stimulation of the electrical stimulation unit in accordance with an exercise mode of the stationary bicycle. By the electrical stimulation indoor bike, a variety of electrical stimulation according to pedal movement is applied to a body through an indoor bike connected with a low-frequency stimulator, thereby maximizing exercise effect.

In various embodiments, non-invasive methods to induce motor control in a mammal subject to spinal cord or other neurological injuries are provided. In some embodiments the methods involve administering transcutaneous electrical spinal cord stimulation (tSCS) to the mammal at a frequency and intensity that induces locomotor activity.

The present invention relates to a rehabilitation system for rehabilitating a person with a neurological condition, such as a spinal cord injury (SCI). The system includes exercise equipment for enabling the person to exercise. One or more sensors are provided for sensing information from the person during exercise. The system also includes a model of the exercising person configured to receive the sensed information from the sensors and generate electrical stimulation for the person. Advantageously, the personalized computer model may be used to generate suitable electrical stimulation for the person, and avoid excessive stresses on the person which can lead to the fracturing of bones.

A measurement system includes a motion capture system comprising at least one motion capture device configured to detect the motion of one or more body portions of a system user and generate output data; a sensory output device, the sensory output device configured to generate sensory feedback for delivery to the system user; and at least one data processing device operatively coupled to the motion capture system and the sensory output device, the at least one data processing device further configured to determine, by utilizing a trained neural network, one or more poses and/or movements of the one or more body portions of the system user from the motion capture output data, and to provide sensory feedback to the system user, by means of the sensory output device, as to conformity of the one or more poses and/or movements to one or more reference poses and/or movements.

Methods comprising applying electrical stimulation to patients in conjunction with physical training are described.

The present application relates to devices and systems for rehabilitation of the locomotor system, for example limbs. In particular, the present application discloses an apparatus, more in particular a robotic platform capable of optimizing gravity-dependent trunk movements, enabling overground locomotion in non-ambulatory individuals with spinal cord injury and stroke, while promoting durable motor improvement when delivered during gait rehabilitation facilitated by electrical spinal cord stimulation.

Attachments for isokinetic dynamometers and methods of use thereof are provided for use with subjects having limb impairments. An example dynamometer attachment for use with a subject having an impaired limb includes a frame that has fixed thereto a padded limb support, where the padded limb support is configured to secure an impaired limb of the subject. The padded limb support includes a securing mechanism for securing the impaired limb relative to the frame, and the frame is connected to the dynamometer lever arm via an intermediate connector assembly. The connector assembly permits translation of the padded limb support in at least two dimensions relative to the lever arm prior to securing the frame fixedly in place. The translation adjustability of the attachment facilitates the alignment of the dynamometer attachment to the limb or partial limb of the subject without requiring movement of the subject.

A wearer is able to exercise the posterior (flex) muscles of the hand. Elastic bands attached to the glove cause the fingers to contract toward the palm and provide resistance when the fingers are straightened. The elastic bands are secured by bandlettes attached to the fingers and thumb of the glove. Palmlettes are attached at the base of the palm to keep the bands clear of the palm while wearing, so that ordinary tasks can be performed while wearing the glove.

A human body enhanced training system including a smart garment, a control module, a plurality of electrodes and at least one sensor. The smart garment is suitable for being worn by a person. When the smart garment is worn by the person, the smart garment covers at least a portion of the person's body. The control module is mounted with respect to the smart garment. The plurality of electrodes is operably connected to the control module. The plurality of electrodes is capable of stimulating the person's muscles. The at least one sensor is operably connected to the control module. The at least one sensor is capable of collecting physiological data.