TY - JOUR
T1 - Computer simulation of voltage sensitive calcium ion channels in a dendritic spine
AU - Lee, Pilhwa
AU - Sobie, Eric A.
AU - Peskin, Charles S.
N1 - Funding Information:
E.A.S. and C.S.P. were supported in part by the Systems Biology Center New York (NIH Grant P50GM071558 ).
PY - 2013/12/7
Y1 - 2013/12/7
N2 - Membrane current through voltage-sensitive calcium ion channels at the postsynaptic density of a dendritic spine is investigated. To simulate the ion channels that carry such current and the resulting temporal and spatial distribution of concentration, current, and voltage within the dendritic spine, the immersed boundary method with electrodiffusion is applied. In this simulation method a spatially continuous chemical potential barrier is used to simulate the influence of the membrane on each species of ion. The amplitudes of these barriers can be regulated to simulate channel gating. Here we introduce this methodology in a one-dimensional setting. First, we study the current-voltage relationship obtained with fixed chemical potential barriers. Next, we simulate stochastic ion-channel gating in a calcium channel with multiple subunits, and observe the diffusive wave of calcium entry within the dendritic spine that follows channel opening. This work lays the foundation for future three-dimensional studies of electrodiffusion and advection electrodiffusion in dendritic spines.
AB - Membrane current through voltage-sensitive calcium ion channels at the postsynaptic density of a dendritic spine is investigated. To simulate the ion channels that carry such current and the resulting temporal and spatial distribution of concentration, current, and voltage within the dendritic spine, the immersed boundary method with electrodiffusion is applied. In this simulation method a spatially continuous chemical potential barrier is used to simulate the influence of the membrane on each species of ion. The amplitudes of these barriers can be regulated to simulate channel gating. Here we introduce this methodology in a one-dimensional setting. First, we study the current-voltage relationship obtained with fixed chemical potential barriers. Next, we simulate stochastic ion-channel gating in a calcium channel with multiple subunits, and observe the diffusive wave of calcium entry within the dendritic spine that follows channel opening. This work lays the foundation for future three-dimensional studies of electrodiffusion and advection electrodiffusion in dendritic spines.
KW - Continuous-time Markov process
KW - Current-voltage relationship
KW - Electrodiffusion
KW - The immersed boundary method
UR - http://www.scopus.com/inward/record.url?scp=84884938146&partnerID=8YFLogxK
U2 - 10.1016/j.jtbi.2013.08.019
DO - 10.1016/j.jtbi.2013.08.019
M3 - Article
C2 - 23999286
AN - SCOPUS:84884938146
SN - 0022-5193
VL - 338
SP - 87
EP - 93
JO - Journal of Theoretical Biology
JF - Journal of Theoretical Biology
ER -