TY - JOUR
T1 - A model for transcutaneous current stimulation
T2 - Simulations and experiments
AU - Kuhn, Andreas
AU - Keller, Thierry
AU - Lawrence, Marc
AU - Morari, Manfred
PY - 2009
Y1 - 2009
N2 - Complex nerve models have been developed for describing the generation of action potentials in humans. Such nerve models have primarily been used to model implantable electrical stimulation systems, where the stimulation electrodes are close to the nerve (near-field). To address if these nerve models can also be used to model transcutaneous electrical stimulation (TES) (far-field), we have developed a TES model that comprises a volume conductor and different previously published non-linear nerve models. The volume conductor models the resistive and capacitive properties of electrodes, electrode-skin interface, skin, fat, muscle, and bone. The non-linear nerve models were used to conclude from the potential field within the volume conductor on nerve activation. A comparison of simulated and experimentally measured chronaxie values (a measure for the excitability of nerves) and muscle twitch forces on human volunteers allowed us to conclude that some of the published nerve models can be used in TES models. The presented TES model provides a first step to more extensive model implementations for TES in which e.g., multi-array electrode configurations can be tested.
AB - Complex nerve models have been developed for describing the generation of action potentials in humans. Such nerve models have primarily been used to model implantable electrical stimulation systems, where the stimulation electrodes are close to the nerve (near-field). To address if these nerve models can also be used to model transcutaneous electrical stimulation (TES) (far-field), we have developed a TES model that comprises a volume conductor and different previously published non-linear nerve models. The volume conductor models the resistive and capacitive properties of electrodes, electrode-skin interface, skin, fat, muscle, and bone. The non-linear nerve models were used to conclude from the potential field within the volume conductor on nerve activation. A comparison of simulated and experimentally measured chronaxie values (a measure for the excitability of nerves) and muscle twitch forces on human volunteers allowed us to conclude that some of the published nerve models can be used in TES models. The presented TES model provides a first step to more extensive model implementations for TES in which e.g., multi-array electrode configurations can be tested.
KW - Active nerve model
KW - Capacitive effects
KW - Finite element model
KW - Transcutaneous electrical stimulation
UR - http://www.scopus.com/inward/record.url?scp=62149124049&partnerID=8YFLogxK
U2 - 10.1007/s11517-008-0422-z
DO - 10.1007/s11517-008-0422-z
M3 - Article
C2 - 19005714
AN - SCOPUS:62149124049
SN - 0140-0118
VL - 47
SP - 279
EP - 289
JO - Medical and Biological Engineering and Computing
JF - Medical and Biological Engineering and Computing
IS - 3
ER -