This is maybe more of a math than programming question but I'm thinking the intersection of 2 ellipsoids is a convex shape so maybe you could try another approach than Monte Carlo to deal with such a relatively nicely behaved object.
First you need to (somehow) find a point inside both ellipsoids.
Now create a cube centered at that point, large enough to completely contain both ellipsoids. Subdivide the cube along all 3 axes into 8 equally sized sub-cubes (first step of creating an octree).
After this, apply recursion to the subcubes. If some cube corners are inside both ellipsoids and some are not, subdivide the cube again. Also if some areas of cube faces are inside both ellipsoids and others not, subdivide again.
Repeat to desired recursion depth. You can track the calculation error by summing the volume of cubes that were subdivided.
Now the challenging operation here is resolving "if some areas of a cube face are inside both ellipsoids". An intersection between an ellipsoid and a plane is an ellipse. To inspect each of the 6 cube faces, you need to intersect them with the ellipsoids and then intersect the remaining ellipses with each other if they both overlap the cube face. Luckily for 2D ellipse-ellipse overlap test you can find references more easily...
Monte Carlo will give you n bits of accuracy with O(2^n) effort so for example 24 bits takes 16.7 million samples. If you focus on the shape surface with such a divide and conquer method, you should only need O(2^(n*2/3)) samples which is about 65 thousand for 24 bits.
Also your concern about initial bounding box size becomes irrelevant since excess is quickly removed in initial recursion steps.