Abstract: Disclosed are micro-wire stimulators that magnetically stimulate nearby cells and/or their processes (e.g., nerve fiber, axons, dendrites, etc.). The micro-wire includes one or more bends. The micro-wire stimulator can facilitate the creation of stronger field gradients in one direction with much smaller gradients in orthogonal directions, allowing for selective targeting, or avoiding, of specific cell types within a targeted region. The bent micro-wire stimulator may be implanted into the cortex of the brain to selectively stimulate nearby neural cells having a particular orientation relative to the stimulator. A tip portion of the micro-wire may be rounded, or it may have corners forming other suitable geometric shapes.

Abstract: Disclosed are micro-wire stimulators that magnetically stimulate nearby cells and/or their processes (e.g., nerve fiber, axons, dendrites, etc.). The micro-wire includes one or more bends. The micro-wire stimulator can facilitate the creation of stronger field gradients in one direction with much smaller gradients in orthogonal directions, allowing for selective targeting, or avoiding, of specific cell types within a targeted region. The bent micro-wire stimulator may be implanted into the cortex of the brain to selectively stimulate nearby neural cells having a particular orientation relative to the stimulator. A tip portion of the micro-wire may be rounded, or it may have corners forming other suitable geometric shapes.

Abstract: An electromagnetic neural stimulation device includes a biocompatible shaft and one or more microcoil systems inside the shaft. A microcoil system includes a microcoil (driven externally) that is complemented with a metallic element juxtaposed against the microcoil as a shield to non-uniformly affect spatial distribution of the strength of the magnetic field generated by the microcoil. The microcoil system is oriented at a position inside the shaft that is predetermined to place the microcoil system in the vicinity of target neurons once the shaft is inserted into the biological tissue. The angular orientation of the microcoil system is optionally varied to selectively stimulate different regions of the neural network.

Abstract: A system and method is provided for preferentially stimulating a portion of neural tissue including a first type of neurons and a second type of neurons. The method includes defining a waveform characterizing an electrical stimulus, wherein the waveform includes an amplitude-modulated wave of the electric stimulus. The method also includes applying the electrical stimulus having the defined waveform to a stimulating element located in proximity to the neural tissue to selectively activate the first type of neurons while leaving the second type of neurons one of substantially unaffected and suppressed in response to the electrical stimulus.

Abstract: An electromagnetic neural stimulation device includes a biocompatible shaft and one or more microcoil systems inside the shaft. A microcoil system includes a microcoil (driven externally) that is complemented with a metallic element juxtaposed against the microcoil as a shield to non-uniformly affect spatial distribution of the strength of the magnetic field generated by the microcoil. The microcoil system is oriented at a position inside the shaft that is predetermined to place the microcoil system in the vicinity of target neurons once the shaft is inserted into the biological tissue. The angular orientation of the microcoil system is optionally varied to selectively stimulate different regions of the neural network.

Abstract: A system and method is provided for preferentially stimulating a portion of neural tissue including a first type of neurons and a second type of neurons. The method includes defining a waveform characterizing an electrical stimulus, wherein the waveform includes an amplitude-modulated wave of the electric stimulus. The method also includes applying the electrical stimulus having the defined waveform to a stimulating element located in proximity to the neural tissue to selectively activate the first type of neurons while leaving the second type of neurons one of substantially unaffected and suppressed in response to the electrical stimulus.

Abstract: An implantable neural stimulation device includes a magnetic coil specifically dimensioned to be implantable inside the tissue and structured to generate, in the vicinity of the target tissue adjacent to which such coils is disposed in operation, magnetic field the strength of which is substantially the same as the strength of magnetic field generated in such tissue during the conventional TMS procedure. The modulation of orientation of microcoil modulates the activation of targeted neuronal tissue.

Abstract: A method, device and system for stimulating visual tissue, typically in the retina or visual cortex, to achieve an artificial percept of light or image. The method includes providing stimulating electrodes suitable for placement in proximity to the visual tissue and generating a series of short-duration stimulation signals having a duration of less than about 0.5 milliseconds each. The short-duration stimulation signals are applied through the stimulating electrodes with varying frequencies that are substantially matched to a spiking range of frequencies of at least one ganglion cell for perceiving brightness or image.

Abstract: A method, device and system for stimulating visual tissue, typically in the retina or visual cortex, to achieve an artificial percept of light or image. The method includes providing stimulating electrodes suitable for placement in proximity to the visual tissue and generating a series of short-duration stimulation signals having a duration of less than about 0.5 milliseconds each. The short-duration stimulation signals are applied through the stimulating electrodes with varying frequencies that are substantially matched to a spiking range of frequencies of at least one ganglion cell for perceiving brightness or image.

Abstract: A method, device and system for stimulating visual tissue, typically in the retina or visual cortex, to achieve an artificial percept of light or image. The method includes providing stimulating electrodes suitable for placement in proximity to the visual tissue and generating a series of short-duration stimulation signals having a duration of less than about 0.5 milliseconds each. The short-duration stimulation signals are applied through the stimulating electrodes with varying frequencies that are substantially matched to a spiking range of frequencies of at least one ganglion cell for perceiving brightness or image.

Abstract: A method, device and system for stimulating visual tissue, typically in the retina or visual cortex, to achieve an artificial percept of light or image. The method includes providing stimulating electrodes suitable for placement in proximity to the visual tissue and generating a series of short-duration stimulation signals having a duration of less than about 0.5 milliseconds each. The short-duration stimulation signals are applied through the stimulating electrodes with varying frequencies that are substantially matched to a spiking range of frequencies of at least one ganglion cell for perceiving brightness or image.

Abstract: A method, device and system for stimulating visual tissue, typically in the retina or visual cortex, to achieve an artificial percept of light or image. The method includes providing stimulating electrodes suitable for placement in proximity to the visual tissue and generating a series of short-duration stimulation signals having a duration of less than about 0.5 milliseconds each. The short-duration stimulation signals are applied through the stimulating electrodes with varying frequencies that are substantially matched to a spiking range of frequencies of at least one ganglion cell for perceiving brightness or image.

Abstract: A method, device and system for stimulating visual tissue, typically in the retina or visual cortex, to achieve an artificial percept of light or image. The method includes providing stimulating electrodes suitable for placement in proximity to the visual tissue and generating a series of short-duration stimulation signals having a duration of less than about 0.5 milliseconds each. The short-duration stimulation signals are applied through the stimulating electrodes with varying frequencies that are substantially matched to a spiking range of frequencies of at least one ganglion cell for perceiving brightness or image.