Abstract: Electrodes for use in neural stimulation applications, shaped to have fractal or pseudo-fractal geometries, with a generally planar core portion of the electrode using a base fractal geometry. A series of successively smaller holes is provided in the core portion, where each hole in the generally planar core portion can have a perimeter shape that is self-similar to a perimeter shape of the generally planar core portion. The selected electrode geometry affects the spatial distribution of the electric field in neuron-bearing tissue. This spatial distribution is related to the irregularity—or non-uniformity—of current density on the electrode surface. Optimized electrode geometries increase the efficiency of neural stimulation by maximizing the spatial variation of current density on the electrode surface.

Abstract: Electrodes for use in neural stimulation applications, shaped to have fractal or pseudo-fractal geometries, with a generally planar core portion of the electrode using a base fractal geometry. A series of successively smaller holes is provided in the core portion, where each hole in the generally planar core portion can have a perimeter shape that is self-similar to a perimeter shape of the generally planar core portion. The selected electrode geometry affects the spatial distribution of the electric field in neuron-bearing tissue. This spatial distribution is related to the irregularity—or non-uniformity—of current density on the electrode surface. Optimized electrode geometries increase the efficiency of neural stimulation by maximizing the spatial variation of current density on the electrode surface.

Abstract: A functional magnetic resonance imaging (fMRI) compatible magnetomechanical vibrotactile device (MVD) uses wire coils having small oscillatory currents to interact with the large static magnetic field inherent to MRI scanners. The resulting Lorentz forces which are exerted on the MVD can be oriented to generate large vibrations that may be easily converted to translational motions as large as several centimetres. Representative data demonstrate the flexibility of MVDs to generate different well-controlled vibratory and tactile stimuli to activate special proprioceptive and cutaneous somatosensory afferent pathways.

Abstract: A functional magnetic resonance imaging (fMRI) compatible magnetomechanical vibrotactile device (MVD) uses wire coils having small oscillatory currents to interact with the large static magnetic field inherent to MRI scanners. The resulting Lorentz forces which are exerted on the MVD can be oriented to generate large vibrations that may be easily converted to translational motions as large as several centimeters. Representative data demonstrate the flexibility of MVDs to generate different well-controlled vibratory and tactile stimuli to activate special proprioceptive and cutaneous somatosensory afferent pathways.