Abstract: A system and method that facilitates stimulating neural pathways, e.g., muscles and/or associated nerves, of a patient's body for the purpose of therapeutic medical treatment by rehabilitating weakened muscles and using neuroplasticity to retrain sequential muscle movements and/or to provide the ability to directly deliver functional motor movements. Use of the present invention is of particular value for treating a patient following a stroke. More particularly, such systems are characterized by a plurality of discrete devices, preferably battery powered but may alternatively include RF-powered devices as well or in combination, configured for implanting within a patient's body via injection, each device being configured to affect a parameter, e.g., via nerve and/or muscle stimulation and/or to sense a body parameter, e.g., temperature, O2 content, physical position, electrical potential, etc.

Abstract: An exercising system and method for the treatment and rehabilitation of the paralyzed muscles of the legs. Stimulators and sensors are implanted in several of the main muscle groups of the legs. A computerized controller uses wireless signals for communications with the implanted stimulators and sensors. The person receiving the treatment sits on an exercise machine such as a stationery bicycle, a leg press, a rowing machine or other leg exercising machine. The controller determines the position of the legs and transmits a series of commands to the stimulators to provide functional electrical stimulation (FES) to the muscles of the legs, which move the legs in a cyclical or reciprocating manner, such as that needed to pedal a bicycle. Using data provided by the implanted sensors, the controller is able to adjust the stimulation commands sent to the muscles of the legs to control the amount of force exerted by the foot, to limit user fatigue and to keep the foot in a neutral position on the pedal or footrest.

Abstract: A system and method that facilitates stimulating neural pathways, e.g., muscles and/or associated nerves, of a patient's body for the purpose of therapeutic medical treatment by rehabilitating weakened muscles and using neuroplasticity to retrain sequential muscle movements and/or to provide the ability to directly deliver functional motor movements. Use of the present invention is of particular value for treating a patient following a stroke. More particularly, such systems are characterized by a plurality of discrete devices, preferably battery powered but may alternatively include RF-powered devices as well or in combination, configured for implanting within a patient's body via injection, each device being configured to affect a parameter, e.g., via nerve and/or muscle stimulation and/or to sense a body parameter, e.g., temperature, O2 content, physical position, electrical potential, etc.