Spine stabilization system

We claim: 1. A spinal stabilization system comprising: an occipital plate having a central portion and at least two extension portions extending from the central portion; at least two rod receivers positioned on each one of the at least two extension portions, the at least two rod receivers configured to receive at least two elongated rods; and at least two locking assemblies configured to retain the at least two elongated rods within the at least two rod receivers, wherein the occipital plate further comprises a plurality of holes for receiving bone fasteners, wherein each one of the extension portions comprises a slot for receiving each one of the at least two rod receivers, and the rod receivers being capable of translating and rotating within a mating track configured within each of the slots, wherein a tapered protrusion borders a circumference of a top surface of at least one of the slots and is configured to be permanently deformed and create a trough when one of the rods directly contacts the tapered protrusion and is locked into the rod receiver, wherein the tapered protrusion is raised above the at least one slot, wherein the at least two locking assemblies comprise a locking cap and a locking set screw received within the locking cap that forces the rod down deforming the protrusion, and wherein the rod rests in a trough formed by the deformed protrusion. 2. The spinal stabilization system according to claim 1 , wherein the occipital plate is configured with a compound curvature having two different radii in an axial and sagittal planes. 3. The spinal stabilization system according to claim 1 , wherein the occipital plate is configured with at least two grooves separating the central portion from the at least two extension portions. 4. The spinal stabilization system according to claim 1 , wherein the occipital plate further comprises a slot positioned adjacent to one of the plurality of screw holes for receiving a cable. 5. The spinal stabilization system according to claim 1 , wherein the occipital plate further comprises a central groove on a bottom portion of the occipital plate. 6. The spinal stabilization system according to claim 1 , wherein the slots of the occipital plate are configured with a mating track that allows for free rotation and translation of the rod receivers. 7. The spinal stabilization system according to claim 1 , wherein the occipital plate further comprises a tapered protrusion that borders a flat portion of each one of the slots. 8. A method for stabilizing the spine comprising the steps of: positioning an occipital plate on a portion of a cranium; securing the occipital plate with bone fasteners to the cranium; positioning at least two elongated rods to the occipital plate; and securing the at least two elongated rods to the occipital plate; wherein the occipital plate comprises a central portion and at least two extension portions extending from the central portion, and at least two rod receivers positioned on each one of the at least two extension portions, the at least two rod receivers configured to receive the at least two elongated rods; and at least two locking assemblies configured to secure the at least two elongated rods within the at least two rod receivers, the at least two locking assemblies comprise a locking cap and a locking set screw received within the locking cap, wherein the occipital plate further comprises a plurality of holes for receiving bone fasteners, wherein each one of the extension portions comprises a slot for receiving each one of the at least two rod receivers, and the rod receivers being capable of translating and rotating within the slots, wherein the method further comprises the step of permanently deforming a protrusion and creating a trough for receiving a rod, wherein the rod is in direct contact with the protrusion to create the trough and the protrusion borders a circumference of a top surface of at least one of the slots, wherein the protrusion is raised above the at least one slot, wherein the method further comprises the step of deforming the protrusion by forcing the locking set screws down on each one of the elongated rods. 9. The method of claim 8 , further comprising the step of aligning a central groove on a bottom portion of the occipital plate with the occiput of the cranium. 10. The method of claim 8 , further comprising the step of rotating and/or translating the rod receivers within the slot of the occipital plate. 11. The method of claim 8 , wherein, when actuating each respective set screw inside the locking cap, the set screw applies a downward force on the rod and an upward force on the locking cap.