Loch Ness monster and Jacob's Ladder Surfaces are NOT homeomorphic
I will start with some very general remarks about proper homotopy invariants.
Let $X$ be a connected manifold (one needs much less). Consider an exhaustion of $X$ by compact submanifolds with boundary $K_i$: $$ X= \bigcup_i K_i, K_i\subset int(K_{i+1})~~ \forall i. $$ Every such exhaustion defines a direct system of maps of cohomology groups $$ H^*(X, X-K_i) \to H^*(X, X-K_j), i\le j. $$ The direct limit of this system is denoted $H_c^*(X)$, the compactly supported cohomology of $X$; it is independent of the exhaustion. Feeding the relative cohomology groups and their maps as above into long exact sequence of pairs $(X, X-K_i)$ we get a commutative diagram: $$ \begin{array}{ccccccccc} \to& \tilde{H}^{k-1}(X) & \to & \tilde{H}^{k-1}(X - K_i) & \to & H^k(X, X-K_i) & \to & \tilde{H}^{k+1}(X) & \to\\ & \downarrow & & \downarrow & &\downarrow& &\downarrow& \\ \to& \tilde{H}^{k-1}(X) & \to & \tilde{H}^{k-1}(X - K_j) & \to & H^k(X, X-K_j) & \to & \tilde{H}^{k+1}(X) & \to \end{array} $$ Taking the direct limit we obtain a long exact sequence $$ ... \to \tilde{H}^{k-1}(X) \to \tilde{H}^{k-1}_\epsilon(X) \to H_c^k(X) \to \tilde{H}^{k+1}(X) \to ... $$ The groups $\tilde{H}^{*}_\epsilon(X)$ are again independent of the exhaustion, they are direct limits of the systems $$ \tilde{H}^*(X-K_i) \to \tilde{H}^*(X-K_j), i\le j. $$ (You can see that they are independent of the exhaustion either by appealing to the independence of compactly supported cohomology groups or by repeating the same argument you use for $H^*_c$.)
Remark. This is actually quite general: If $(G_i)_{i\in I}$ is a direct system of groups (or, more generally, objects in some category) and $(G_i)_{i\in J}$ is a subsystem given by a cofinal subset $J\subset I$, then we get a natural isomorphism $$ \lim_{i\in J} G_i\cong \lim_{i\in I} G_i. $$ In our setting, $I$ will be the poset of all compact subsets of $X$ and $J\subset I$ will be a subset of $I$ given by a particular exhaustion $(K_i)$. The assumption that $(K_i)$ is an exhaustion implies that $J$ is cofinal in $I$.
Definition. The groups $\tilde{H}^*_\epsilon(X)$ are the reduced end-cohomology groups of $X$.
Remark. In fact, I did not need the compactly supported cohomology groups, I just wanted to relate the end-cohomology to something you already know.
Independence of the exhaustion implies that these groups are topological invariants of $X$; they are also invariants of proper homotopy type of $X$: Each proper homotopy-equivalence $X\to Y$ induces isomorphisms $$ H^*_c(Y)\to H^*_c(X), H^*_\epsilon(Y)\to H^*_\epsilon(X). $$
Now, back to your question. Take your surface $X$ and exhaust it by compact subsurfaces $K_i$ such that $X-K_i$ consists of two unbounded components. For $Y$, exhaust by compact subsurfaces $L_i$ each of which has connected (unbounded) complement. Computing the end-cohomology we get
$$
\tilde{H}^0_\epsilon(X)= {\mathbb Z}, \tilde{H}^0_\epsilon(Y)=0
$$
since for each pair $j\ge i$ we get isomorphisms
$$
{\mathbb Z}=\tilde{H}^0(X-K_i) \to \tilde{H}^0(X-K_j)= {\mathbb Z},
$$
$$
0=\tilde{H}^0(Y-L_i) \to \tilde{H}^0(Y-L_j)= 0.
$$
Hence, $X$ is not homeomorphic to $Y$. The same proof shows that these surfaces are not properly homotopy-equivalent.
Lastly, even though you did not ask about it, using Richards' classification of surfaces one can prove even more:
Theorem. Two surfaces are properly homotopy-equivalent if and only if they are homeomorphic.
Non-Answer: Here is some figures that would be helpful.
- An easy observation but interesting for me: One can find a loop that after removing it the bounded component of both are homeomorphic to torus minus open disk: figures (a) and (d). So removing one loop trick does not work.
- Unfortunately removing 3 loops also does not work. one can do same process (b-c-d) to (d) and construct bounded components like (a).
