A point slerp is meaningful if you're working with a spherical space (such as a planet's surface or likewise).

Off the top of my head I would take the cross product of your start and end points (as vectors) to get a rotation axis then you can calculate a rotation for the X, Y, and Z (to avoid having to create your own matrix class, as you seem to want to).

http://en.wikipedia.org/wiki/Rotation_matrix#Dimension_three

That link shows a rotation matrix for an axis/angle pair. Just write out the multiplication for each component and simplify to get a matrix-less tranformation.

edit:

Heres a simple decomposed rotation about an axis (x, y, z):

```
X' = (x^2 + (1 - x^2) * cos(theta) + (x * y * (1 - cos(theta)) - x * sin(theta)) + (x * z * (1 - cos(theta)) + y * sin(theta))
Y' = (x * y * (1 - cos(theta)) + z * sin(theta)) + (y^2 + (1 - y^2) * cos(theta)) + (y * z * (1 - cos(theta)) - x * sin(theta))
Z' = (x * z * (1 - cos(theta)) - y * sin(theta)) + (y * z * (1 - cos(theta)) + x * sin(theta)) + (z^2 + (1 - z^2) * cos(theta))
```

Since you want a parameterized rotation as well, make sure you calculate the angle between your vectors (the inverse cosine of the scalar product of the two points) and set your theta as a value between 0 and that angle based on your interpolation parameter.