Characterization of Minimal Element

Theorem
Let $C$ be a class.

Let $\prec$ be a relation on $C$.

Let $B$ be a subclass of $C$.

Let $x \in B$.

Let $S_x = \left\{{y \in C \mid y \prec x \text{ and } y \ne x}\right\}$ be the initial segment of $x$ in $C$.

Then $x$ is a minimal element of $B$ iff $B \cap S_x = \varnothing$.

Implication
Suppose $x$ is a minimal element of $B$.

Then for each $z \in B$ such that $z \ne x$, $z \not\prec x$.

Thus $S_x \cap B = \varnothing$.

Reverse implication
Suppose that $x$ is not a minimal element of $B$.

Then for some $z \in B$, $z \prec x$ and $z \ne x$.

Thus $z \in S_x$.

Since $z \in B$, $B \cap S_x \ne \varnothing$.