Let $X,Y \subset \mathbb{R}^n$ be open subsets. Denote by $C^\infty(X)$ the smooth functions on $X$, let $\mathcal{E}'(Y)$ be its dual space considered as a space of distributions. Let $L(C^\infty(X), \mathcal{E}'(Y))$ be the continuous linear operators. This space itself is equipped with the topology of bounded convergence (see for example Operator topology).
An instance of the Schwartz kernel theorem states that
$L(C^\infty(X), \mathcal{E}'(Y)) \simeq \mathcal{E}'(X \times Y)$,
which morally says that I can write every continuous linear operator $T \colon C^\infty(X) \to \mathcal{E}'(Y)$ as an integral operator with a distributional kernel $k(y,x) \in \mathcal{E}'(X \times Y)$ as
$ (Tu)(y) = \int k(y,x)u(x) dx $
(where the integral denotes the pairing of functions with distributions).
Now let $E$ and $F$ be Hilbert $A$-modules for a $C^*$-algebra $A$. I can still consider smooth functions with values in the Banach space $E$. Also $F$-valued distributions still make sense. They can be defined by
$\mathcal{E'}(Y,F) = L(Y,F) = \mathcal{E}'(Y) \hat{\otimes} F$,
where the tensor product is the completion of the projective tensor product (well, since $\mathcal{E}'(Y)$ is nuclear this doesn't really matter).
I was wondering if in this case there is an analogue of the Schwartz kernel theorem with $A$-linearity and adjointability build into it, thus stating something like
$L_A^*(C^\infty(X,E), > \mathcal{E}'(Y,F)) \simeq > \mathcal{E}'(X \times Y, > \text{Hom}_A^*(E,F))$
Here the left hand side should denote adjointable continuous $A$-linear operators (part of the question is to find the right notion of adjointability, $A$-linearity should be clear) and $\text{Hom}_A^*(E,F)$ are the adjointable $A$-linear operators from $E$ to $F$.
I know that there exists a Schwartz kernel theorem for vector-valued distributions (see e.g. theorem 1.8.9 in http://user.math.uzh.ch/amann/files/distributions.pdf). This looks like
$\mathcal{E}'(X \times Y,Z') \simeq L(C^\infty(X), \mathcal{E}'(Y,Z'))$
for a Banach space $Z$ and I heard that Schwartz has proven similar theorems in much greater generality, but without considering Hilbert modules of course. The above theorem is close to what I want, if $\text{Hom}_A^*(E,F)$ has a predual, then it implies
$\mathcal{E}'(X \times Y,\text{Hom}_A^*(E,F)) \simeq L(C^\infty(X), \mathcal{E}'(Y,\text{Hom}_A^*(E,F)))$.