Maximal Left and Right Ideal iff Quotient Ring is Division Ring/Quotient Ring is Division Ring implies Maximal Left Ideal

Theorem
Let $R$ be a ring with unity.

Let $J$ be an ideal of $R$.

If the quotient ring $R / J$ is a division ring then $J$ is a maximal left ideal.

Proof
Let $K$ be a left ideal of $R$ such that $J \subsetneq K \subset R$.

Let $x \in K \setminus J$. Since $x \notin J$ then $x + J \ne J$, the zero in $R / J$.

Since $R / J$ is a division ring then $x + J \in R / J$ has an inverse, say $s + J$.

That is:
 * $1_R + J = \paren {s + J} \circ \paren {x + J} = \paren {s \circ x } + J$

By Left Cosets are Equal iff Product with Inverse in Subgroup then:
 * $1_R - s \circ x \in J \subsetneq K$

By the definition of a left ideal then:
 * $x \in K$ and $s \in R \implies s \circ x \in K$
 * $1_R - s \circ x \in K$ and $s \circ x \in K \implies \paren {1_R - s \circ x } + \paren {s \circ x } = 1_R \in K$
 * $1_R \in K \implies \forall y \in R, y \circ 1_R = y \in K$

Hence $K = R$

The result follows.