Integrated expandable interbody spacer (IEIS)

The invention claimed is: 1 . An expandable interbody spacer, comprising: a first endplate including an outwardly facing surface, an inner facing surface and two opposing isosceles-trapezoidal-shaped sidewalls each configured with a central slot; a second endplate including an outwardly facing surface and an inner facing surface and two opposing isosceles-trapezoidal-shaped sidewalls each configured with a central tab extension, wherein the second endplate is positioned directly opposite the first endplate; and a motion assembly located between the opposing sidewalls of the first endplate and the opposing sidewalls of the second endplate, the motion assembly including: a first motion guider having a smooth central cylindrical aperture; a second motion guider having a threaded central cylindrical aperture; and a screw having a screwhead and a partially threaded shank, wherein the partially threaded shank is positioned through the smooth central cylindrical aperture of the first motion guider and into the threaded central cylindrical aperture of the second motion guider, wherein clockwise rotation of the screwhead is configured to increase a height between the first endplate and the second endplate by drawing the first motion guider and the second motion guider together; wherein counterclockwise rotation of the screwhead is configured to decrease a height between the first endplate and the second endplate by moving the first and second motion guiders apart; and wherein the first motion guider further comprises: a rectangular cuboid body having a top face configured to contact the inner facing surface of the first endplate; a bottom face configured to contact the inner facing surface of the second endplate; a first wall which includes the smooth central cylindrical aperture, wherein the first wall faces towards a first wall of the second motion guider; a second wall opposite the first wall; a pair of bullet shaped endcaps attached to the second wall, wherein the pair of bullet shaped endcaps extends outwardly from the motion assembly; a third wall having a rounded profile; a fourth wall having a rounded profile opposite the third wall, wherein the third wall and the fourth wall are located between the top face and the bottom face; and a pair of slanted motion guiding grooves cut into each of the rounded profile of the third wall and the rounded profile of the fourth wall, wherein a first slanted motion guiding groove is configured to slant from a central width axis of the first wall towards the top face near the second wall, and a second motion guiding groove is configured to slant from a central width axis of the first wall towards the bottom face near the second wall, wherein a respective protrusion of a sidewall of the first endplate is configured to slide within the first slanted motion guiding groove and a respective protrusion of a sidewall of the second endplate is configured to slide within the second slanted motion guiding groove of the first motion guider. 2 . The expandable interbody spacer of claim 1 , wherein each central slot located in an opposing isosceles-trapezoidal-shaped sidewall of the first endplate is configured to receive a respective central tab extension of the second endplate. 3 . The expandable interbody spacer of claim 1 , wherein each central slot has a width of about 3 mm, a height of about 7 mm and a depth of about 1 mm. 4 . The expandable interbody spacer of claim 1 , wherein the screw is a locking screw. 5 . The expandable interbody spacer of claim 1 , wherein each of the first endplate, the second endplate and the motion assembly are formed of biocompatible materials. 6 . The expandable interbody spacer of claim 5 , wherein the biocompatible material is titanium. 7 . The expandable interbody spacer of claim 5 , wherein the biocompatible material is polyetheretherketone (PEEK). 8 . The expandable interbody spacer of claim 1 , wherein: the outwardly facing surface of the first endplate has a serrated profile; and the outwardly facing surface of the second endplate has a serrated profile. 9 . The expandable interbody spacer of claim 8 , wherein the serrated profile of each of the first endplate and the second endplate has a pitch of about 1.0 mm, a height of about 0.5 mm and a pitch angle of about 30 degrees. 10 . The expandable interbody spacer of claim 8 , wherein each endplate comprises: the serrated outwardly facing surface; the inner facing surface, wherein the inner facing surface is smooth; a length and a width, wherein the length is greater than the width; a first edge; a second edge opposite to and parallel to the first edge, wherein the first edge and the second edge are located along the length; a third edge; and a fourth edge opposite to and parallel to the third edge, wherein the third edge and the fourth edge are located along the width, wherein each of the isosceles-trapezoidal-shaped sidewalls includes: a first base having a length L 1 , wherein the first base is connected to the inner facing surface of a respective endplate, a second base having a length L 2 , wherein the length L 1 is greater than the length L 2 , a first slanted leg located between a first end of the first edge and a first end of the second edge, a second slanted leg located between a second end of the first edge and a second end of the second edge, and a protrusion extending perpendicularly from each of the first slanted leg and the second slanted leg towards the opposing sidewall. 11 . The expandable interbody spacer of claim 1 , wherein the second motion guider further comprises: a rectangular cuboid body having a top face configured to contact the inner facing surface of the first endplate; a bottom face configured to contact the inner facing surface of the second endplate; a first wall configured to face towards a first wall of the first motion guider; a second wall opposite the first wall, wherein the threaded central cylindrical aperture is located within the rectangular cuboid body between the first wall and the second wall; a rounded endcap attached to either side of the second wall, wherein the rounded endcap extends outwardly from the motion assembly; a third wall having a rounded profile; a fourth wall having a rounded profile opposite the third wall, wherein the third wall and the fourth wall are located between the top face and the bottom face; and a pair of slanted motion guiding grooves cut into each of the rounded profile of the third wall and the rounded profile of the fourth wall, wherein a first slanted motion guiding groove is configured to slant from a central width axis of the first wall towards the top face near the second wall, and a second motion guiding groove is configured to slant from a central width axis of the first wall towards the bottom face near the second wall, wherein a respective protrusion of a sidewall of the first endplate is configured to slide within the first slanted motion guiding groove and a respective protrusion of a sidewall of the second endplate is configured to slide within the second slanted motion guiding groove of the second motion guider. 12 . The expandable interbody spacer of claim 1 , wherein an assembled length has a value in a range of about 15 mm to about 25 mm, an assembled width has a value in a range of about 13 mm to about 15 mm and an assembled height has a value of about 7 mm to about 24 mm. 13 . A method of assembling an expandable interbody spacer for use in lumbar interbody fusion, comprising: installing a motion assembly between opposing isosceles-trapezoidal-shaped sidewalls of a first