Being systematic a $2$-special group is completely by two $\mathbb Z/2$-vector
spaces $U=G/Z(G)$ and $V=Z(G)$ together with the induced square map $\Gamma^2U\to V$
which is non-degenerate in the following sense: We have an injective map $\Lambda^2U\to\Gamma^2U$
mapping $u\land v\mapsto\gamma_1(u)\gamma_1(v)$ so that the composite $\Lambda^2U\to\Gamma^2U\to V$ is non-degenerate.
Every map $\Gamma^2U\to V$ occurs for some central extension of $V$ by $U$ and the
extension gives a $2$-special group precisely when $\Lambda^2U\to\Gamma^2U\to V$ is
non-degenerate.

For $V=(\mathbb Z/2)^2$ a map $\Lambda^2U\to V$ corresponds to a pair of alternating
forms on $U$ and the non-degeneracy says exactly that the radicals of the two
forms intersect in zero. Now, if $V$ is even-dimensional there is a single
non-degenerate alternating form and if $V$ is odd-dimensional, then any
$1$-dimensional subspace is the radical of some alternating form so that if
$\dim V>1$ there are always two forms whose radicals intersect
trivially. Picking such a map $\Lambda^2U\to V$ we simply may take any linear extension
to a map $\Gamma^2U\to V$ to a $2$-special group.