Abstract: A neural implant system for communicating neural impulses generated by a brain of a patient having a body includes a neural implant electrode system that is configured to be implanted in a selected site of the patient's brain. A wireless power receiver and communication circuit is in communication with the neural implant electrode and is configured to be disposed within the patient's body at a predetermined location. An external telemetry and power unit is configured to provide power to and to communicate with the wireless power receiver and communication circuit. The wireless power source and transceiver circuit is configured to operate outside of the patient's body.

Abstract: A neurotrophic electrode system includes a non-conductive cone, a multi-channel electrode assembly, a dielectric ribbon and a neurite-attracting substance disposed within the cone. The non-conductive cone consists essentially of a material that is stable in a neural environment and defines a cavity. The cavity opens to a small opening at a first end of the cone and opens to a large opening at a second end of the cone that is opposite the first end. The multi-channel electrode assembly includes at least two recording sites that are disposed within the cavity defined by the cone. Each recording site is coupled to a wire that extends out of the large end of the cone. Each wire ends in a connection pad. The dielectric ribbon encases all of the wires but exposes each recording site and exposes each connection pad.

Abstract: A speech synthesis device detects beta peak firings corresponding to intended vocalizations by a subject having a scalp, a mastoid process and a speech motor cortex. A EEG electrode and a negative electrode are disposed on the scalp of the subject adjacent to the speech motor cortex. A transmitter is electrically coupled to the electrodes, and is configured to transmit wirelessly electronic representations of the neural potentials detected by the electrodes. A remote unit receives the electronic representations of the neural potentials from the transmitter. The remote unit is programmed to: detect beta peaks firings in the neural potentials; correlate the beta peaks firings with beta peaks associated with phonemes, words and phrases; and generate audible representations of the phonemes, words and phrases.

Abstract: A neurotrophic electrode system includes a non-conductive cone, a multi-channel electrode assembly, a dielectric ribbon and a neurite-attracting substance disposed within the cone. The non-conductive cone consists essentially of a material that is stable in a neural environment and defines a cavity. The cavity opens to a small opening at a first end of the cone and opens to a large opening at a second end of the cone that is opposite the first end. The multi-channel electrode assembly includes at least two recording sites that are disposed within the cavity defined by the cone. Each recording site is coupled to a wire that extends out of the large end of the cone. Each wire ends in a connection pad. The dielectric ribbon encases all of the wires but exposes each recording site and exposes each connection pad.

Abstract: A neural sensor includes a substrate defining an array of vias passing therethrough, a plurality of conductive surfaces, a light source, a plurality of groups of quantum dot-based luminescence units and a charge-coupled device (CCD) array. Each via allows a neurite to grow therethrough. Each conductive surface is adjacent to a different via and is electrically coupled thereto. The light source directs light toward the substrate. Each group of quantum dot-based luminescence units extends upwardly from a different one of the conductive surfaces generates light at a different predetermined wavelength when excited with light from the light source. Each luminescence unit changes its luminescence when electrically stimulated by a neural potential generated by a neurite. The CCD detects luminescence from each of the plurality of groups of quantum dot-based luminescence units and generates a signal representative of intensity of each wavelength of light detected.

Abstract: A neural sensor includes a substrate defining an array of vias passing therethrough, a plurality of conductive surfaces, a light source, a plurality of groups of quantum dot-based luminescence units and a charge-coupled device (CCD) array. Each via allows a neurite to grow therethrough. Each conductive surface is adjacent to a different via and is electrically coupled thereto. The light source directs light toward the substrate. Each group of quantum dot-based luminescence units extends upwardly from a different one of the conductive surfaces generates light at a different predetermined wavelength when excited with light from the light source. Each luminescence unit changes its luminescence when electrically stimulated by a neural potential generated by a neurite. The CCD detects luminescence from each of the plurality of groups of quantum dot-based luminescence units and generates a signal representative of intensity of each wavelength of light detected.

Abstract: A sensing apparatus and method allows a patient to control an object by asserting a motor unit action potential. An electromyogram sensor is configured to be placed at a selected location on the patient and to sense a motor unit action potential from the patient. The electromyogram sensor is also configured to generate an EMG signal representative of the motor unit action potential. A personal area network transmitting device that is responsive to the EMG signal is configured to generate a wireless signal that corresponds to the EMG signal. A personal area network receiving device is configured to receive the wireless signal and to convert the wireless signal into an electrical signal. A processor is configured to receive the electrical signal and to generate at least one control signal that has a value corresponding to a state of the electrical signal.

Abstract: A device for interfacing neurons includes a substrate that defines at least one via passing therethrough. The via is configured to allow at least one neurite to grow therethrough. A light generating unit is disposed adjacent to the substrate and is configured to generate light of a predetermined frequency when an action potential from the neurite is sensed. A light sensor that is spaced apart from the substrate is configured to assert a neural signal corresponding to the action potential when the light generating unit generates light of the predetermined frequency.

Abstract: In a method of assisting a subject to generate speech, at least one first neural impulse is sensed from a first preselected location in the subject's brain. A first preselected sound is associated with the first neural impulse. The first preselected sound is generated in an audible format. In an apparatus for assisting the subject to generate speech, at least one sensor senses a neural impulse in the subject's brain and generates a signal representative thereof. An electronic speech generator generates a phoneme in response to the generation of the signal. An audio system generates audible sounds corresponding to the phoneme based upon the signal received from the speech generator.

Abstract: A system and method for capturing a neural signal inside a patient's skull, transmitting it to a remote receiver, and using it to control an application. A plurality of skull screws is inserted on the skull and under the scalp, and the skull screws are connected to a transmitter. The differential potential between two skull screws are detected, amplified, and transmitted to a receiver connected to a computing device. The computing device checks for the signal's voltage level and duration before using it for controlling the application.