The hard part for the case at hand is the rule for `d`

. Perhaps, there are simpler ways to do it, but one way is to expand the powers to products, to make it work. Let's say this is your expression:

```
expr = (a^2 (alpha + beta)^2)/(b^2 + c^2) + (a (alpha + beta))/(b^2 + c^2) + 1
```

and these are the rules one would naively write:

```
rules = {a/(b^2 + c^2) -> d, alpha + beta -> gamma}
```

What we would like to do now is to expand powers to products, in both `expr`

and `rules`

. The problem is that even if we do, they will auto-evaluate back to powers. To prevent that, we'll need to wrap them into, for example, `Hold`

. Here is a function which will help us:

```
Clear[withExpandedPowers];
withExpandedPowers[expr_, f_: Hold] :=
Module[{times},
Apply[f,
Hold[expr] /. x_^(n_Integer?Positive) :>
With[{eval = times @@ Table[x, {n}]}, eval /; True] /.
times -> Times //.
HoldPattern[Times[left___, Times[middle__], right___]] :>
Times[left, middle, right]]];
```

For example:

```
In[39]:= withExpandedPowers[expr]
Out[39]= Hold[1+(a (alpha+beta))/(b b+c c)+((alpha+beta) (alpha+beta) a a)/(b b+c c)]
```

The following will then do the job:

```
In[40]:=
ReleaseHold[
withExpandedPowers[expr] //.
withExpandedPowers[Map[MapAt[HoldPattern, #, 1] &, rules], Identity]]
Out[40]= 1 + d gamma + a d gamma^2
```

We had to additionally wrap the l.h.s. of rules in `HoldPattern`

, to prevent products from collapsing back to powers there.

This is just one case where we had to fight the auto-simplification mechanism of Mathematica, but for this sort of problems this will be the main obstacle. I can't assess how robust this will be for larger and more complex expressions.

gamma + ad*gamma^2 (I cut and pasted that from my notebook result).