According to the cobordism hypothesis, if $\mathcal{C}$ is a symmetric monoidal $(\infty,n)$-categories with duals, then framed fully extended TQFTs with target $\mathcal{C}$ are an $\infty$-groupoid, and so a homotopy type. More precisely, by the cobordism hypothesis this groupoid is equivalent to the core $\mathcal{C}^\sim$ of $\mathcal{C}$: the $\infty$-groupoid obtained from $\mathcal{C}$ by discarting all the noninvertible $k$-morphisms in $\mathcal{C}$ for $k\geq 1$. More generally, for $G$-cobordism one gets the $\infty$-groupoid $(\mathcal{C}^\sim)^{hG}$ of $G$-homotopy invariants in $\mathcal{C}^\sim$.
My question is: what are the shapes, i.e., the homotopy types arising this way? In other words, given a (nice) topological space $A$, a nonnegative integer $n$ and a group $G$ over the infinite orthogonal group $O$ (i.e., a sequence of compatible group homomorphisms $G(k)\to O(k)$), are there conditions on $A$, $n$ and $G$ ensuring there exists symmetric monoidal $(\infty,n)$-categories with duals $\mathcal{C}$ such that $(\mathcal{C}^\sim)^{hG}\simeq A$?
The reason behind the question is that for such a triple one could interpret the set $[X,A]$ of homotopy classes of maps from a (nice) topological space $X$ to $A$ as the set of isomorphism classes of $\infty$-functors $\Pi X \to (\mathcal{C}^\sim)^{hG}$ and so (again by the cobordism hypothesis) as isomorphism classes of $G$-TQFTs over $X$ with target $\mathcal{C}$.
