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Capacitance and Myelination vs. Conduction Velocity Mengqi Xing, Basheer Subei, Rafael Romero.

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Presentation on theme: "Capacitance and Myelination vs. Conduction Velocity Mengqi Xing, Basheer Subei, Rafael Romero."— Presentation transcript:

1 Capacitance and Myelination vs. Conduction Velocity Mengqi Xing, Basheer Subei, Rafael Romero

2 Membrane Thickness Soliton Model of Action Potentials – Soliton (mechanical wave) propagates along membrane that causes AP – Thermodynamically sound – Δ in membrane thickness = Δ in Capacitance Piezoelectricity

3 Myelin Distribution Myelin sheaths – Δ membrane thickness Δ membrane capacitance – Speed up AP propagation Distribution of Myelin – Nodes of Ranvier Hodgkin-Huxley Model – Myelination Passive Cable Model

4 Methods Testing Spatial Distribution of Myelin: – 6 Different Distributions – Control, Full, Short, Long, Mid Gap, Multiple Gap – Scaled up axon dimensions Studying: – Effect of Membrane Thickness/Distribution – Significance of Nodes of Ranvier – Conductance velocity

5 Different Distributions Control Short Myelin Full Long Myelin Mid GapMultiple Gap

6 Control

7 Full Myelin

8 Short Myelin

9 Long Myelin

10 Mid Gap Myelin

11 Multiple Gap

12 Average Conduction Velocity ControlMultiple GapMid GapFull Velocity (m/s)191.36438.55620.46049

13 Discussion Main Points: – Myelination Fast conduction BUT AP decays No gates ∴ no current to recharge AP – No myelination Signal Slow Gates throughout axon allow propagation Nodes of Ranvier – Recharge AP & prevent signal decay

14 Thanks!

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