Parameters Page
From NeuroWiki
The membrane capacitance, intracellular resistance, and membrane resistance of the axon or dendrite of a neuron can be expressed in more than one way using different units. What follows is a guide for working with these quantities.
Contents
Membrane capacitance
- Membrane capacitance per unit length, $c_m$
- Units: $\mu\text{F}/\text{cm}$
- Depends on axon/dendrite diameter
- Membrane capacitance per unit area, $C_m$
- Units: $\mu\text{F}/\text{cm}^2$
- Independent of axon/dendrite diameter
- This quantity is given directly in the cable simulations.
- The quantities $c_m$ and $C_m$ are related through the circumference of the axon/dendrite: $c_m = C_m \pi d$
Intracellular resistance
- Intracellular resistance per unit length, $r_i$
- Units: $\text{k}\Omega/\text{cm}$
- Depends on axon/dendrite diameter
- Intracellular resistivity, $R_i$
- Units: $\text{k}\Omega\cdot\text{cm}$ (Note that in the simulation, the units given are: $\Omega\cdot\text{cm}$; you will need to keep this in mind during your calculations.)
- Since the total intracellular resistance of a segment of an axon/dendrite decreases with diameter and increases with length, this quantity can be divided by cross-sectional area and multiplied by length to get the total intracelluar resistance between two points on an axon/dendrite. This means the quantity must have units $\text{k}\Omega\cdot\text{cm}$.
- Independent of axon/dendrite diameter
- This quantity is given directly in the cable simulations.
- Units: $\text{k}\Omega\cdot\text{cm}$ (Note that in the simulation, the units given are: $\Omega\cdot\text{cm}$; you will need to keep this in mind during your calculations.)
- The quantities $r_i$ and $R_i$ are related through the cross-sectional area of the axon/dendrite: $r_i = \frac{R_i}{\pi d^2 / 4}$
Membrane resistance
- Membrane resistance of a unit length, $r_m$
- Units: $\text{k}\Omega\cdot\text{cm}$
- The membrane resistance of a unit length of the axon/dendrite is defined as the reciprocal of the membrane conductance per unit length, giving it units $1/(\text{mS}/\text{cm}) = \text{cm}/\text{mS} = \text{k}\Omega\cdot\text{cm}$.
- Depends on axon/dendrite diameter
- Units: $\text{k}\Omega\cdot\text{cm}$
- Membrane resistance of a unit area, $R_m$
- Units: $\text{k}\Omega\cdot\text{cm}^2$
- The membrane resistance of a unit area of the membrane is defined as the reciprocal of the membrane conductance per unit area, $g_m$, giving it units $1/(\text{mS}/\text{cm}^2) = \text{cm}^2/\text{mS} = \text{k}\Omega\cdot\text{cm}^2$.
- Independent of axon/dendrite diameter
- This quantity is given indirectly in the cable simulations by the membrane conductances.
- Units: $\text{k}\Omega\cdot\text{cm}^2$
- The quantities $r_m$ and $R_m$ are related through the circumference of the axon/dendrite: $r_m = \frac{R_m}{\pi d}$
Input resistance
- Input resistance, $r_\text{input}$
- Units: $\text{k}\Omega$
- Depends on axon/dendrite diameter
- This quantity is related to both the membrane resistance and the internal resistance: $r_\text{input} = \sqrt{\frac{r_m r_i}{4}} = \sqrt{\frac{(R_m / \pi d) (R_i / (\pi d^2 / 4))}{4}} = \frac{1}{\pi} \sqrt{\frac{R_m R_i}{d^3}} = \frac{1}{\pi} \sqrt{\frac{R_i}{g_m d^3}}$
Time and length constants
- Time constant, $\tau$
- Units: $\text{ms}$
- Independent of axon/dendrite diameter
- This quantity is related to both the membrane resistance and capacitance: $\tau = r_m c_m = (R_m / \pi d) (C_m \pi d) = R_m C_m$
- Length constant, $\lambda$
- Units: $\text{cm}$
- Depends on axon/dendrite diameter
- This quantity is related to both the membrane resistance and the internal resistance: $\lambda = \sqrt{\frac{r_m}{r_i}} = \sqrt{\frac{R_m / \pi d}{R_i / (\pi d^2 / 4)}} = \sqrt{\frac{d R_m}{4 R_i}} = \sqrt{\frac{d}{4 g_m R_i}}$
