Dual-shaft implant expansion driver with reversible driver key mechanism and expandable intervertebral implant system

What is claimed is: 1. A surgical driver apparatus to manipulate an expandable intervertebral implant, comprising: a housing; an inner driver shaft configured to rotate with respect to the housing; an outer driver shaft positioned coaxial with the inner driver shaft and configured to rotate independently from the inner driver shaft; an idler driver shaft mechanically connected to the outer driver shaft, wherein rotation of the idler driver moves the outer driver shaft; and a driver key comprising a driving feature and a counter-driving feature, wherein the driver key is configured to engage the housing to rotate at least one of the inner driver shaft and the outer driver shaft, wherein the driver key is configured to engage the housing in: a first orientation to expand the implant toward a parallel expansion configuration; a second orientation to expand the implant toward an anterior expansion configuration; and a third orientation to expand the implant toward a posterior expansion configuration. 2. The surgical driver apparatus of claim 1 , wherein in the first orientation the driving feature engages with the inner driver shaft to rotate the inner driver shaft via rotation of the driving feature and engages the counter-driving feature with the idler driver shaft to restrain rotation of the outer driver shaft, wherein in the second orientation the driving feature engages with the idler driver shaft to rotate the outer driver shaft via rotation of the idler driver shaft resulting from rotation of the driving feature and engages the counter-driving feature with the inner driver shaft to restrain rotation of the inner driver shaft, and wherein in the third orientation the driving feature engages with the inner driver shaft and the idler driver shaft to rotate the inner driver shaft and the outer driver shaft via rotation of the driving feature. 3. The surgical driver apparatus of claim 2 , wherein the counter-driving feature is disposed outside of the housing in the third orientation. 4. The surgical driver apparatus of claim 2 , wherein the inner driver shaft comprises an inner socket feature and the idler driver shaft comprises an idler gear feature radially aligned with the inner socket feature. 5. The surgical driver apparatus of claim 4 , wherein the driving feature comprises an internal socket and an external gear feature at a mating end of the driving feature. 6. The surgical driver apparatus of claim 5 , wherein the internal socket of the driving feature is configured to engage the inner socket feature of the inner driver shaft in the third orientation, and wherein the external gear feature of the driving feature is configured to mesh with the idler gear feature of the idler driver shaft in the third orientation. 7. The surgical driver apparatus of claim 5 , wherein the idler driver shaft comprises an idler socket feature extending axially from the idler gear feature in a direction opposite a first side of the housing. 8. The surgical driver apparatus of claim 7 , wherein the internal socket of the driving feature engages the inner socket feature of the inner driver shaft in the first orientation, and wherein the counter-driving feature engages the idler socket feature in the first orientation. 9. The surgical driver apparatus of claim 7 , wherein the internal socket feature of the driving feature engages the idler socket feature of the idler driver shaft in the second orientation, and wherein the counter-driving feature engages the socket feature of the inner driver shaft in the second orientation. 10. The surgical driver apparatus of claim 1 , wherein the idler driver shaft is positioned parallel to the inner driver shaft. 11. The surgical driver apparatus of claim 1 , wherein a second side of the housing is disposed opposite a first side of the housing. 12. A surgical implant system, comprising: an intervertebral implant, wherein the implant comprises: an upper endplate; a lower endplate; a frame; a plurality of moveable actuators received in the frame and positioned between the upper endplate and the lower endplate; and an actuator screw that extends through the plurality of moveable actuators from an anterior end of the implant, wherein rotation of the plurality of moveable actuators with respect to the actuator screw causes at least one of the plurality of moveable actuators to move with respect to the actuator screw, thereby causing the implant to expand to a parallel expansion configuration, an anterior expansion configuration, or a posterior expansion configuration; and a surgical driver, wherein the surgical driver comprises: a housing; an inner driver shaft configured to rotate with respect to the housing; an outer driver shaft positioned coaxial with the inner driver shaft and configured to rotate independently from the inner driver shaft; an idler driver shaft mechanically connected to the outer driver shaft, wherein rotation of the idler driver moves the outer driver shaft; and a driver key comprising a driving feature and a counter-driving feature, wherein the driver key is configured to engage the housing to rotate at least one of the inner driver shaft and the outer driver shaft, wherein the driver key is configured to engage the housing in: a first orientation to expand the implant toward the parallel expansion configuration; a second orientation to expand the implant toward the anterior expansion configuration; and a third orientation to expand the implant toward the posterior expansion configuration. 13. The surgical implant system of claim 12 , wherein the inner driver shaft is configured to engage the actuator screw, and wherein the outer driver shaft is configured to engage an anterior actuator of the plurality of moveable actuators, the anterior actuator disposed proximate an anterior end of the implant. 14. The surgical implant system of claim 12 , wherein the surgical driver comprises a spring configured to bias the outer driver shaft in a direction toward the anterior actuator. 15. The surgical implant system of claim 12 , further comprising a measurement device comprising an inner shaft thread follower configured to measure a posterior expansion height for a posterior portion of the implant, the inner shaft thread follower having a threaded carriage and a button dial, the threaded carriage having internal threads configured to mesh with a threaded portion of the inner driver shaft and the button dial disposed at least partially within a slot in the housing and configured to move along a first slot in response to movement of the inner driver shaft with respect to the housing to indicate the posterior expansion height on a scale disposed on the housing. 16. The surgical implant system of claim 12 , further comprising a measurement device comprising an idler shaft thread follower configured to measure a lordosis angle of the implant, the idler shaft thread follower having a threaded carriage and a button dial, the threaded carriage having internal threads configured to mesh with a threaded portion of the idler driver shaft and the button dial disposed at least partially within a slot in the housing to indicate the lordosis angle of the implant on a scale disposed on the housing. 17. The surgical implant system of claim 12 , wherein the housing further comprises a scale configured to indicate an anterior height of an anterior portion of the implant based at least in part on axial movement of the inner driver shaft and the outer driver shaft with respect to the housing. 18. The surgical implant system