The setting is on evolving hypersurfaces. So for each time $t$, $\Gamma(t)$ is a hypersurface given by the zero level set of the function $\phi(x,t)$. Consider a ball, then the hypersurface has $\phi(x,t) = x_1^2 + ... + x_n^2 - R(t)^2$ as the level set. So for each time $t, \Gamma(t)$ is a ball of radius $R(t)$.
Associated with each surface $\Gamma(t)$ is a normal velocity $V(x,t)$ and a mean curvature $H(x,t)$. Suppose the surface evolves by the rule V = -H. After some calculations, let's say that $V = \dot{R}$ and $H = -\sqrt{x_1^2 + ... + x_n^2}$.
One can then solve this ODE $V=-H$ to get R(t).
But because the mean curvature $H$ is defined only on points on the surface, can't we rewrite $H = -\sqrt{x_1^2 + ... + x_n^2}$ to be $H = -R$? Because if $x_1^2 + ... + x_n^2 - R^2(t) \neq 0$, then then $H(x,t)$ is meaningless.
But if I make this substituion and then solve the ODE, i get a different answer obviously. What's the right thing to do?