A nerve conduction model is constructed by using some liquid-membrane cells that mimic the function of the K and Na channels. By imitating two types of Na channels (ligand-gated Na channels and voltage-gated Na channels), a new mechanism for the directional propagation of the action potential along the axon toward the axon terminal is proposed. When the nerve cell is excited by an external (outer) stimulus, it can be presumed that the ligand-gated channels work as power sources at the synapse to propagate the change in the membrane potential, and then the voltage-gated channels locally assist the propagation at each site of the axon (nodes of Ranvier).
A new model system of nerve conduction, which has two sites (the potential-sending and the potential-receiving sites) was constructed by the use of some liquid-membrane cells which mimic the function of the K(+) and Na(+) channels. The model system setup was such that the membrane potential of the K(+)-channel cell (resting potential) was different from that of the Na(+)-channel cell (action potential). Initially, the K(+)-channel cell at the potential-sending site was connected to that at the potential-receiving site. After switching from the K(+)-channel cell to the Na(+)-channel cell at the potential-sending site, the membrane potential of the K(+)-channel cell at the potential-receiving site began to vary with the generation of the circulating current. By placing several K(+)-channel cells in parallel at the potential-receiving site, the propagation mechanism of the action potential was interpreted and the influence of the resistor and the capacitor on the propagation was evaluated.
The TFPB -salts of bis(triphenylphosphoranylidene)ammonium (BTPPATFPB) and tetraethylammonium (TEATFPB) were obtained by mixing a methanol solution of NaTFPB with a methanol solution of BTPPACl (Sigma-Aldrich Co.) and TEACl The propagation of the change in potential differences across liquid membranes from the potential-sending cell to the potential-receiving cell was investigated by use of a system combined with three liquid membrane cells, which were composed of two aqueous phases and a 1,2-dichloroethane solution phase. The ionic composition of one potential-sending cell (S) was identical to that of the receiving cell (Rec), and that of another potential-sending cell (Ap) was different from that of the Rec. When the connection of cell Rec was switched from cell S to cell Ap, the change in the membrane potential was caused by the circulating current. The greater the ratio of the interfacial area of the membrane of cell Ap to that of cell Rec, the faster the change in the membrane potential propagated from cell Ap to cell Rec.
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