Abstract
This work proposes and computationally investigate the use of magnetic neural stimulation as an alternative to electrical stimulation to achieve selective activation of rat sciatic nerve. In particular, they assess the effectiveness of an array of small coils to obtain selective neural stimulation, as compared to a single coil. Specifically, an array of four mm-sized coils is used to stimulate rat sciatic nerve, targeting the regions of fascicles that are associated with different muscles of the leg. To evaluate the selectivity of activation, a three-dimensional heterogeneous multi-resolution nerve model is implemented using the impedance method for the computation of the magnetic and electric fields in the nerve. The performance metric ‘selectivity index’ is defined that measures the recruitment of the targeted region compared to other non-targeted regions of the nerve. The selectivity index takes values between −1 (least selective) and 1 (most selective). For each targeted region, a selectivity index of 0.75 or better is predicted for the proposed array configuration. The results suggest that an array of coils can provide superior spatial control of the electric field induced in the neural tissue compared to traditional extraneural electrode arrays, thus opening the possibility to applications where selective neurostimulation is of interest.
Highlights
Magnetic neural stimulation has received considerable interest as an alternative to electrical neurostimulation for both central nervous system and peripheral nervous system (PNS) neurostimulation applications [1,2,3,4]
Electrical neural stimulation has drawbacks compared to magnetic stimulation, including the need for direct contact between tissue and electrodes and limited control of patterns of fields induced in the neural tissue
Since biological tissue has uniform relative magnetic permeability, the electric field induced in the tissue can be controlled at the targeted site by steering the magnetic field generated by each coil, under the assumption that the coils can be driven using independent circuits. Taking advantage of this feature of magnetic stimulation, we demonstrate in this Letter that the proposed stimulation array can achieve a higher degree of selectivity compared to traditional neurostimulators by using a mm-resolution, heterogeneous, computational model of the rat sciatic nerve based on histological data of the nerve presented in [14]
Summary
Magnetic neural stimulation has received considerable interest as an alternative to electrical neurostimulation for both central nervous system and peripheral nervous system (PNS) neurostimulation applications [1,2,3,4]. Electrical neural stimulation has drawbacks compared to magnetic stimulation, including the need for direct contact between tissue and electrodes and limited control of patterns of fields induced in the neural tissue. Magnetic stimulation can elicit neural activity at the proximal tissue without direct contact between coils and neural tissue. Field patterns can be controlled because the tissue has uniform relative magnetic permeability. The energy requirement can be significantly higher compared to electrical stimulation [3,4,5]
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