What is the Cellular Potts Model?

Julien

\Delta U_P = \lambda_P \left( P - P_0 \right)^2

\Delta U_P = \lambda_P \left( P - P_0 \right)^2

\frac{d\vec{p}}{dt} = r \left[ -\vec{p} + \epsilon \frac{R}{\sigma_R} \vec{q} \right]

\frac{d\vec{p}}{dt} = r \left[ -\vec{p} + \epsilon \frac{R}{\sigma_R} \vec{q} \right]

\vec{p}

\vec{p}

\vec{q}

\vec{q}

A \approx 315 \ \ \ \ r \approx 10

A \approx 315 \ \ \ \ r \approx 10

\frac{100 \ \text{ng Dextran}}{10 \ \text{mm}\cdot\text{mL}} = 0.25 \frac{\text{nM}}{\text{mm}}

\frac{100 \ \text{ng Dextran}}{10 \ \text{mm}\cdot\text{mL}} = 0.25 \frac{\text{nM}}{\text{mm}}

By Julien Varennes

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