Phantom Model of Transcutaneous Electrical Stimulation with Kilohertz Signals

Medina, Leonel E.; Grill, Warren M.; IEEE

Abstract

Transcutaneous electrical stimulation (TES) of nerve fibers may be optimized by overcoming the impedance of the skin using high-frequency (HF) stimulation signals. The excitation properties of nerve fibers depend on the spatiotemporal distribution of the extracellular field, and therefore quantifying the potentials during HF-TES is warranted. We present a physical phantom of TES that includes elements representing the skin and underlying tissue, and incorporates dispersion of the electrical conductivity as required during HF stimulation. We used both agar-based gels and biological materials, and doped the gels with graphite to add dispersion. We measured the dielectric properties of the materials, which we modified by adjusting the concentration of sodium chloride and graphite. We assembled up to three layers of material, and quantified the impedance as a function of frequency and depth. The impedance at any depth decayed with frequency, which suggests that HF signal may reach deeper structures in TES.

Más información

Título según WOS: ID WOS:000377414600107 Not found in local WOS DB
Título de la Revista: 2019 9TH INTERNATIONAL IEEE/EMBS CONFERENCE ON NEURAL ENGINEERING (NER)
Editorial: IEEE
Fecha de publicación: 2015
Página de inicio: 430
Página final: 433
Notas: ISI