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Artificial Cells, Nanomedicine, and Biotechnology
An International Journal
Volume 41, 2013 - Issue 6
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Research Article

Nerve communication model by bio-cells and optical dipole coupling effects

Farrah Dilla ZainolInstitute of Advanced Photonics Science, Nanotechnology Research Alliance,Universiti Teknologi Malaysia (UTM), Malaysia
,
Nopparat ThammawongsaHybrid Computing Research Laboratory (HCRL), Faculty of Engineering, King Mongkut's Institute of Technology Ladkrabang (KMITL), Bangkok, Thailand
,
Somsak MitathaHybrid Computing Research Laboratory (HCRL), Faculty of Engineering, King Mongkut's Institute of Technology Ladkrabang (KMITL), Bangkok, Thailand
,
Jalil AliInstitute of Advanced Photonics Science, Nanotechnology Research Alliance,Universiti Teknologi Malaysia (UTM), Malaysia
&
Preecha YupapinNanoscale Science and Engineering Research Alliance (N’SERA), Faculty of Science, King Mongkut's Institute of Technology Ladkrabang (KMITL), Bangkok, ThailandCorrespondence[email protected]
Pages 368-375 | Received 02 Oct 2012, Accepted 15 Nov 2012, Published online: 10 Jan 2013

Figures & data

Figure 1. Nerve cell communication model.

Figure 1. Nerve cell communication model.

Figure 2. The electrical synchronized model by the electrical neurotransmitter.

Figure 2. The electrical synchronized model by the electrical neurotransmitter.

Figure 3. A schematic diagram of a PANDA ring resonator.

Figure 3. A schematic diagram of a PANDA ring resonator.

Figure 4. A schematic of nerve communication system.

Figure 4. A schematic of nerve communication system.

Figure 5. Cell coupling with nano-antenna model.

Figure 5. Cell coupling with nano-antenna model.

Figure 6. Optical spin-up and spin-down states in difference wavelength.

Figure 6. Optical spin-up and spin-down states in difference wavelength.

Figure 7. (a) Spontaneous firing of electrically coupled and (b) Spike transmission through electrical synapses.

Figure 7. (a) Spontaneous firing of electrically coupled and (b) Spike transmission through electrical synapses.

Figure 8. Gap junction of the postsynaptic capacitance behaves as low pass filters.

Figure 8. Gap junction of the postsynaptic capacitance behaves as low pass filters.

Figure 9. The steady-state responsive pattern of excitatory neuron for three different levels of the resting potentials. Red: 0.5; Black: 0.1; blue: 0.05.

Figure 9. The steady-state responsive pattern of excitatory neuron for three different levels of the resting potentials. Red: 0.5; Black: 0.1; blue: 0.05.

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