Variable lordotic interbody spacer

We claim: 1 . An apparatus for enabling a spinal fusion treatment and including a variable lordotic interbody spacer, the apparatus comprising: a face plate having a front surface and a rear surface, the face plate further having at least one actuation channel and at least two stabilizer channels formed through a portion of the face plate; superior and inferior endplates, each of the endplates having first and second endplate arms coupled by an endplate base in a generally U-shaped configuration, each endplate arm coupled to the rear surface of the face plate via a hinge opposite from the base, and each endplate arm having a ramp recess on a top surface and a bottom surface; an actuation frame positioned between the superior endplate and the inferior endplate, the actuation frame having first and second frame arms coupled by a frame base in a generally U-shaped configuration, each frame arm having a stabilizer feature opposite from the frame base and configured to pass through a corresponding stabilizer channel, each frame arm having an actuation ramp pin on a top surface and on a bottom surface fitted to a corresponding ramp recess, the actuation frame further including a receptacle formed at the inside of the frame base between each frame arm; and an actuation screw having a head, body and threaded end, the actuation screw body passing through the actuation channel, the head retained at the front surface and the threaded end threadably coupled to the receptacle of the actuation frame, wherein, when operated, the actuation screw moves the actuation frame between the superior endplate and the inferior endplate to adjust an angle formed there between. 2 . The apparatus of claim 1 , wherein the at least two stabilizer channels are in the form of plus-shaped recesses sized and configured to receive the first and second frame arms, respectively. 3 . The apparatus of claim 1 , wherein, when rotated, the actuation screw moves the actuation frame toward the face plate to adjust the angle formed between the superior and inferior endplates. 4 . The apparatus of claim 1 , further comprising at least one blocking assembly formed on the front surface of the face plate, each blocking assembly comprising a blocking screw and a blocking screw channel, wherein the blocking assembly allows for threaded insertion of the blocking screw into the corresponding blocking screw channel. 5 . The apparatus of claim 4 , wherein one blocking assembly is located adjacent to the head of the actuation screw, wherein, when tightened, the blocking screw of the one blocking assembly prevents the operation of the actuation screw. 6 . The apparatus of claim 4 , further comprising at least one bone screw channel formed through the face plate between the front and rear surfaces, wherein one blocking assembly is located adjacent to a corresponding bone screw channel, and wherein, when tightened, the blocking screw of the one blocking assembly retains a bone screw in the corresponding bone screw channel. 7 . The apparatus of claim 1 , wherein each of the superior endplate and the inferior endplate further includes a center housing formed between and in parallel with each corresponding endplate arm and coupled at one end to the corresponding endplate base, the superior endplate and the inferior endplate center housings forming a receptacle channel in between, wherein the receptacle of the actuation frame is guided by the receptacle channel when the actuation frame moves with respect to the face plate. 8 . The apparatus of claim 1 , further comprising at least one tool keying recess and at least one tapped recess formed on the front surface of the face plate, wherein the at least one tool keying recess and the at least one tapped recess are formed so as to lock the apparatus to a corresponding tool. 9 . The apparatus of claim 1 , wherein the rear surface of the face plate includes a protrusion having the actuation channel passing through and guiding the body of the actuation screw, wherein the protrusion is further coupled to the hinge. 10 . The apparatus of claim 1 , wherein the hinge comprises tabs located on an end of the each endplate arm coupled to the rear surface of the face plate via pins, wherein the tabs are fastened, via the pins, to the rear surface of the face plate at corresponding pin recesses. 11 . The apparatus of claim 1 , wherein the rear surface of the face plate is formed with a tapered wall to provide clearance for the hinge. 12 . The apparatus of claim 1 , wherein each of the superior endplate and the inferior endplate have a recess formed in the endplate base to receive a knob formed on the outer frame base of the actuation frame. 13 . The apparatus of claim 1 , wherein an area inside the generally U-shaped configurations of the superior endplate, the inferior endplate, and the actuation frame form graft window regions, the graft window regions allowing for insertion of graft material within the variable lordotic interbody spacer. 14 . A standalone variable lordotic interbody spacer configured to be implanted between two adjacent vertebrae comprising: a face plate having a front surface and a rear surface, the face plate further having at least one actuation channel and at least one stabilizer channel formed through a portion of the face plate, the at least one stabilizer channel having a plus-shaped recess; superior and inferior endplates, each of the endplates having first and second endplate arms coupled by an endplate base, each endplate arm coupled to the rear surface of the face plate via a hinge opposite from the base, and each endplate arm having a ramp recess on a top surface and a bottom surface; an actuation frame positioned between the superior endplate and the inferior endplate, the actuation frame having first frame arm, a second frame arm, and a center core coupled by a frame base, each frame arm having ramped protrusions extending along a portion of the arms and configured to be received in the plus-shaped recess in the face plate; and an actuation screw having a head, body, and threaded end, the actuation screw body passing through the actuation channel, the head retained in the face plate and the threaded end threadably coupled to the receptacle of the actuation frame, wherein, the spacer has a collapsed position where the superior and inferior endplates are in contact with one another and an expanded position where the superior and inferior endplates are separated a distance from one another. 15 . The spacer of claim 14 , wherein the actuation frame includes actuation ramp pins in the form of discrete vertical protrusions on top and bottom surfaces of the actuation frame. 16 . The spacer of claim 14 , wherein the actuation ramp pins extend perpendicular from the first and second frame arms. 17 . The spacer of claim 14 , wherein, when in the expanded position, a gap is formed between superior endplate and inferior endplate. 18 . The spacer of claim 14 , wherein, when rotated, the actuation screw moves the actuation frame toward the face plate to adjust an angle formed between the superior and inferior endplates. 19 . A method of implanting a variable lordotic interbody spacer in a disc space between two adjacent vertebrae, the method comprising: inserting the spacer in the disc space, the spacer comprising: a face plate having a front surface and a rear surface, the face plate further having at least one actuation channel and at least two stabilizer channels formed through a portion of the face plate; super