Disk brake piston

The invention claimed is: 1. A disk brake piston comprising: a spindle nut; and a load bearing column within a piston body, the load bearing column comprising: a footing configured to push against a brake pad; and a core extending from the metal footing and slidably located within the piston body; wherein the spindle nut is configured to contact and push the metal core which pushes the metal footing which pushes on the brake pad. 2. The disk brake piston of claim 1 , wherein the piston body is of a different material from the load bearing column and the spindle nut. 3. The disk brake piston of claim 2 , wherein the piston body material is a phenolic polymer. 4. The disk brake piston of claim 2 wherein the load bearing column material and the spindle nut material are metals. 5. The disk brake piston of claim 4 , wherein the load bearing column and the spindle nut are steels. 6. The disk brake piston of claim 1 , wherein the spindle nut comprises an outer perimeter surface having a first shape and the piston body comprises an inner surface that contacts the outer perimeter surface of the spindle nut and the inner surface has a second shape that is complementary to the first shape and, prevents relative rotation of the spindle nut to the piston body. 7. The disk brake piston of claim 1 , further comprising a spindle, the spindle comprising an elongate structure having external threads, wherein the external threads threadably engage an opening in the spindle nut, and upon rotation of the spindle, the spindle nut moves laterally to push on an end of the core. 8. The disk brake piston of claim 1 , wherein the piston body comprises: a first zone and a second zone, the first zone being proximate the footing and the second zone being distal the footing, wherein, the first zone comprises: a central bore including an o-ring groove, wherein an o-ring is present in the o-ring groove and sealingly contacts the core and the piston body, and the second zone comprises a second central bore, the second central bore having a larger diameter than the central bore, and the second central bore having an internal surface with a first shape, the spindle nut having an outer surface complementary to the first shape so as to prevent relative rotation of the spindle to the piston body. 9. The disk brake piston of claim 8 , further comprising a retainer, the retainer being attached to a portion of the core extending into the second zone. 10. The disk brake piston of claim 1 , wherein when the spindle nut pushes on the metal core, a first lateral force is applied to the metal core and is greater than a lateral force applied to the piston body by the spindle nut in the direction of the first lateral force. 11. The disk brake piston of claim 1 , wherein the footing pushes on the brake pad through an intervening material. 12. The disk brake piston of claim 6 , wherein the first shape is circular with two opposed flat portions and the second shape is a shape with flat portions that correspond to the flat portions of the first shape. 13. The disk brake piston of claim 1 , wherein the spindle nut comprises a hollow in an end which contacts the core such that the hollow aligns the core and the nut. 14. The disk brake piston of claim 13 , wherein the hollow is conically shaped. 15. The disk brake piston of claim 14 , wherein the core contacts the hollow at a location between a peak of the conical shape and a base of the conical shape. 16. The disk brake piston of claim 14 , wherein the core is connected to the spindle nut through a sliding non-rotating joint. 17. A method of using the brake piston of claim 1 comprising: rotating a spindle threadably engaging the spindle nut, whereupon the spindle nut pushes on the load bearing column and the load bearing column pushes on a brake pad. 18. The method of claim 17 , wherein the spindle nut pushes on the load bearing column with a first lateral force that is greater than a lateral force applied to the piston body by the spindle nut in the direction of the first lateral force.