Abstract: Implantable systems are described that include a stimulation device positionable in vivo and configured to communicatively couple to electrodes configured to stimulate or block body tissue and an auxiliary device positionable in vivo and including one or more coils configured to wirelessly couple, in vivo, to the stimulation device and to wirelessly couple to an ex vivo device. The auxiliary device may include a coil driver and a power source controlled by a processor and memory for storing data instructions for the coil driver and for storing data received from the stimulation device. The auxiliary device may also include a radio transceiver and an antenna. The stimulation device may include a housing, a coil, a power source and an integrated circuit for controlling the electrodes. The stimulation device may be coupled to a cuff via a lead and physically coupled to the auxiliary device.

Abstract: The present invention provides an implantable neuromodulation system for delivering an electrical signal to a nerve to stimulate, inhibit or block conduction of action potentials in the nerve. The system comprises a neural interface device comprising first and second electrodes; a signal generator and a first closed-loop controller configured to generate a control signal based a property of the signal based on a measured voltage across the first and second electrodes, and cause the signal generator to adjust the electrical signal to modify the property of the signal.

Abstract: A nerve interface device including at least one cuff portion having an assembled position in which the cuff portion forms at least part of a passageway for receiving a nerve along a longitudinal axis passing through the passageway; and first and second rings of electrodes mounted on the at least one cuff portion, each ring of electrodes including a plurality of electrodes. Each electrode in the first ring has a corresponding longitudinally-aligned electrode in the second ring so as to form a plurality of pairs of electrodes spaced apart from each other along the longitudinal axis. The plurality of pairs of electrodes includes at least a first pair of electrodes, the first pair of electrodes mounted on the at least one cuff portion. The at least one cuff portion includes an asymmetric configuration about a central axis perpendicular to the longitudinal cuff axis.

Abstract: A stent for intravascular stimulation comprises a scaffold comprising first and second scaffold structures, each scaffold structure comprising at least one substantially annular portion. The stent further comprises one or more anodal electrodes formed from or electrically coupled to at least a substantially annular portion of the first scaffold structure and one or more cathodal electrodes electrically formed from or coupled to at least a substantially annular portion of the second scaffold structure. The stent further comprises an anodal lead electrically coupled to the first scaffold structure to form a conductive path from the one or more anodal electrodes to a generator and a cathodal lead electrically coupled to the second scaffold structure to form a conductive path from the one or more cathodal electrodes to the generator.

Abstract: A neuromodulation device for measuring an evoked response comprising a first electrode; a second electrode, wherein the first and second electrodes are alternately configured as a stimulation electrode; a sensing electrode for sensing an evoked response to a stimulus pulse; and a controller configured to measure an evoked response at the sensing electrode after a stimulus pulse at a first stimulation electrode configuration and after a stimulus pulse at a second alternate stimulation electrode configuration, and to add said pair of measurements.

Abstract: An implantable neurostimulation system comprises at least one neural interface device for stimulating and/or inhibiting neural activity in a nerve such as the cervical vagus nerve. The device comprises first and second electrodes and at least one signal generator configured to generate first and second electrical signals that stimulate and/or inhibit neural activity in the nerve via the first and second electrodes. The first electrical signal is configured to stimulate neural activity in the nerve to cause at least one pre-determined physiological response; and the second electrical signal is configured to inhibit neural activity in the nerve to at least partially suppress the least one pre-determined physiological response.

Abstract: Implantable systems are described that include a stimulation device positionable in vivo and configured to communicatively couple to electrodes configured to stimulate or block body tissue and an auxiliary device positionable in vivo and including one or more coils configured to wirelessly couple, in vivo, to the stimulation device and to wirelessly couple to an ex vivo device. The auxiliary device may include a coil driver and a power source controlled by a processor and memory for storing data instructions for the coil driver and for storing data received from the stimulation device. The auxiliary device may also include a radio transceiver and an antenna. The stimulation device may include a housing, a coil, a power source and an integrated circuit for controlling the electrodes.

Abstract: A nerve stimulation system is disclosed including a nerve interface device having a cuff that receives a nerve of a user; and first and second rings of electrodes mounted on the cuff, each ring of electrodes including a plurality of electrodes and wherein each electrode in the first ring has a corresponding longitudinally-aligned electrode in the second ring so as to form a plurality of pairs of electrodes spaced apart from each other along the longitudinal axis. The system includes a stimulation device in communication with the pairs of electrodes to generate different electrical signals for the pairs of electrodes, a signal routing module to store signal routing information necessary to cause a physiological response in a user and to cause the signals to be delivered accordingly, and a configuration module for monitoring and updating the signal routing information based on information detected or received by the nerve stimulation system.

Abstract: Implantable systems are described that include a stimulation device positionable in vivo and configured to communicatively couple to electrodes configured to stimulate or block body tissue and an auxiliary device positionable in vivo and including one or more coils configured to wirelessly couple, in vivo, to the stimulation device and to wirelessly couple to an ex vivo device. The auxiliary device may include a coil driver and a power source controlled by a processor and memory for storing data instructions for the coil driver and for storing data received from the stimulation device. The auxiliary device may also include a radio transceiver and an antenna. The stimulation device may include a housing, a coil, a power source and an integrated circuit for controlling the electrodes. The stimulation device may be coupled to a cuff via a lead and physically coupled to the auxiliary device.

Abstract: A nerve interface device including at least one cuff portion having an assembled position in which the cuff portion forms at least part of a passageway for receiving a nerve along a longitudinal axis passing through the passageway; and first and second rings of electrodes mounted on the at least one cuff portion, each ring of electrodes including a plurality of electrodes. Each electrode in the first ring has a corresponding longitudinally-aligned electrode in the second ring so as to form a plurality of pairs of electrodes spaced apart from each other along the longitudinal axis. The plurality of pairs of electrodes includes at least a first pair of electrodes, the first pair of electrodes mounted on the at least one cuff portion. The at least one cuff portion includes an asymmetric configuration about a central axis perpendicular to the longitudinal cuff axis.

Abstract: A system for stimulation of a nerve and measuring impedance. The system includes a neural interface device including a plurality of electrodes; a voltage or current source operatively connected to at least a subset of the electrodes, wherein the voltage or current source is configured to generate an electrical signal to be applied to the electrodes; an impedance measuring module operatively connected to at least a subset of the electrodes, wherein the impedance measurement module is configured to measure the impedance between the electrodes; and a controller arranged to determine an amplitude of an action potential induced in the nerve, via the electrical signal, based on the measured impedance and to adjust the electrical signal in order to induce an action potential having a target amplitude.

Abstract: An implantable system is disclosed that includes an encapsulated housing including a radioactive source. The encapsulated housing is internally coated with a light-generating coating that converts the radioactive energy to light, that is then output in vivo to a photodiode positioned proximate to at least part of the encapsulated housing in vivo. The photodiode is configured to generate electrical current from the light, which electrical current is output to a power conditioning circuit that is configured to use the electrical current as an input electrical current and to output power to a load in vivo. The encapsulated may also be internally coated, at least in part, with a light directing coating that causes light to be directed toward an optical lens that focuses the light on the photodiode. The radioactive source may be a gas having a low half-life and which poses no health risk to a patient if released.

Abstract: Implantable systems are described that include a stimulation device positionable in vivo and configured to communicatively couple to electrodes configured to stimulate or block body tissue and an auxiliary device positionable in vivo and including one or more coils configured to wirelessly couple, in vivo, to the stimulation device and to wirelessly couple to an ex vivo device. The auxiliary device may include a coil driver and a power source controlled by a processor and memory for storing data instructions for the coil driver and for storing data received from the stimulation device. The auxiliary device may also include a radio transceiver and an antenna. The stimulation device may include a housing, a coil, a power source and an integrated circuit for controlling the electrodes. The stimulation device may be coupled to a cuff via a lead and physically coupled to the auxiliary device.

Abstract: An implantable system is disclosed that includes an encapsulated housing including a radioactive source. The encapsulated housing is internally coated with a light-generating coating that converts the radioactive energy to light, that is then output in vivo to a photodiode positioned proximate to at least part of the encapsulated housing in vivo. The photodiode is configured to generate electrical current from the light, which electrical current is output to a power conditioning circuit that is configured to use the electrical current as an input electrical current and to output power to a load in vivo. The encapsulated may also be internally coated, at least in part, with a light directing coating that causes light to be directed toward an optical lens that focuses the light on the photodiode. The radioactive source may be a gas having a low half-life and which poses no health risk to a patient if released.

Abstract: In one embodiment, a neural interface system includes an implantable neural probe having a flexible substrate, electrodes that extend from the substrate that are adapted to contact neural tissue of the brain, a signal processing circuit configured to process neural signals collected with the electrodes, and a wireless transmission circuit configured to wirelessly transmit the processed neural signals, and a backend computing device configured to wirelessly receive the processed neural signals, to process the received signals to reconstruct the collected neural signals, and to analyze the collected neural signals.

Abstract: Calibration of an analog-to-digital converter (ADC) is accomplished via a reference comparator, a first and second multiplexer (MUX), and a finite state machine (FSM). By sampling an analog input with the reference comparator and comparing the results with those of the ADC using the FSM, all the comparators in the ADC can be calibrated without interrupting the ADC's normal operation. The first MUX provides a same reference voltage to the reference comparator as a comparator selected for the calibration, and the second MUX provides the FSM with the output of the selected comparator. The FSM then performs a comparison of the reference comparator and the selected comparator, extracts the polarity of the mismatch, and updates the contents of a memory with the extracted polarity. An offset control in the selected comparator receives a signal corresponding to the extracted polarity stored in the memory and injects offset current into the comparator.

Abstract: Calibration of an analog-to-digital converter (ADC) is accomplished via a reference comparator, a first and second multiplexer (MUX), and a finite state machine (FSM). By sampling an analog input with the reference comparator and comparing the results with those of the ADC using the FSM, all the comparators in the ADC can be calibrated without interrupting the ADC's normal operation. The first MUX provides a same reference voltage to the reference comparator as a comparator selected for the calibration, and the second MUX provides the FSM with the output of the selected comparator. The FSM then performs a comparison of the reference comparator and the selected comparator, extracts the polarity of the mismatch, and updates the contents of a memory with the extracted polarity. An offset control in the selected comparator receives a signal corresponding to the extracted polarity stored in the memory and injects offset current into the comparator.

Abstract: Embodiments of the invention pertain to a method and apparatus for magnetic resonance imaging and spectroscopy (MRI/S). In a specific embodiment, the method and apparatus for MRI/S can be applied at two or more resonant frequencies utilizing a wireless RF receiving coil. In an embodiment, the wireless coil, which can be referred to as the implant coil, can be incorporated into an implantable structure. The implantable structure can then be implanted in a living body. The wireless RF receiving coil can be inductively coupled to another RF coil, which can be referred to as an external coil, for receiving the signal from the wireless implant RF coil. In an embodiment, the implantable structure can be a capsule compatible with implantation in a living body. The implantable structure can incorporate a mechanism for adjusting the impedance of the implant coil so as to alter the resonance frequency of the implant coil.

Abstract: An integrated hybrid microfluidic-IC platform for single cell manipulation and microscopy and method for making the platform. In particular, the integrated platform can incorporate a planar microcoil embedded in a silicon substrate that is subsequently used to fabricate a CMOS IC for the platform. The CMOS IC circuitry provides a two dimensional array of microsites that can incorporate an electrode (microelectrode), sensors, and control logic. A direct conversion receiver (DCR) can also be embedded within the CMOS circuitry to create an integrated IC platform. A microfluidic chamber can be formed on the integrated IC platform. The integrated hybrid platform can provide an increased sensitivity for mass limited samples and high resolution manipulation of biological cells. In addition, individual cell manipulation can be performed via dielectrophoresis (DEP).

Abstract: In one embodiment, a neural interface system includes an implantable neural probe having a flexible substrate, electrodes that extend from the substrate that are adapted to contact neural tissue of the brain, a signal processing circuit configured to process neural signals collected with the electrodes, and a wireless transmission circuit configured to wirelessly transmit the processed neural signals, and a backend computing device configured to wirelessly receive the processed neural signals, to process the received signals to reconstruct the collected neural signals, and to analyze the collected neural signals.