proof of Cayley-Hamilton theorem in a commutative ring

Let $R$ be a commutative ring with identity and let $A$ be an order $n$ matrix with elements from $R[x]$. For example, if $A$ is

then we can also associate with $A$ the following polynomial having matrix coefficents:

$$A^{\sigma }=[\genfrac{}{}{0pt}{}{0}{1}\mathit{\hspace{1em}}\genfrac{}{}{0pt}{}{0}{5}]+[\genfrac{}{}{0pt}{}{2}{1}\mathit{\hspace{1em}}\genfrac{}{}{0pt}{}{0}{0}]x+[\genfrac{}{}{0pt}{}{1}{0}\mathit{\hspace{1em}}\genfrac{}{}{0pt}{}{7}{0}]x^2.$$

In this way we have a mapping $A⟶A^{\sigma }$ which is an isomorphism of the rings $M_n(R[x])$ and $M_n(R)[x]$.

Now let $A\in M_n(R)$ and consider the characteristic polynomial of $A$: $p_A(x)=det(xI-A)$, which is a monic polynomial of degree $n$ with coefficients in $R$. Using a property of the adjugate matrix we have

$$(xI-A)\mathrm{adj}(xI-A)=p_A(x)I.$$

Now view this as an equation in $M_n(R)[x]$. It says that $xI-A$ is a left factor of $p_A(x)$. So by the factor theorem, the left hand value of $p_A(x)$ at $x=A$ is 0. The coefficients of $p_A(x)$ have the form $cI$, for $c\in R$, so they commute with $A$. Therefore right and left hand values are the same.