Hille equation

The Hille equation relates the maximum ionic conductance of an ion channel to its length and radius (or diameter), with the commonly used version implicitly takes into account a hemispherical cap.^[1] As it is ultimately based on a macroscopic continuum model, it does not take into account molecular interactions, and real conductances are often several times less than the predicted maximal flux.

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The Hille equation predicts the following maximum conductance ${\displaystyle g}$ for a pore with length ${\displaystyle l}$, radius ${\displaystyle a}$, in a solvent with resistivity ${\displaystyle \rho }$:

${\displaystyle \frac{1}{g}=(l+\pi \frac{a}{2})\times \frac{\rho }{\pi a^2}}$

Rearranging the terms, the maximal flux based on length ${\displaystyle l}$ and diameter ${\displaystyle d}$ can be shown to be:

${\displaystyle \frac{1}{g}=\frac{l\rho }{(\pi (\frac{d}{2}{)}^2)}+\frac{\rho }{d}}$

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