阅读说明：本技术 可膨胀椎间植入物和相关方法 (Expandable intervertebral implant and related methods ) 是由 P.卢 于 2018-06-04 设计创作，主要内容包括：本发明提供了一种可膨胀植入物,所述可膨胀植入物具有沿着第一方向彼此间隔开的第一板和第二板。所述板沿着第一方向限定相对的骨接触表面,所述相对的骨接触表面被构造成分别接触上椎体和下椎体。设置在所述板之间的致动构件限定第一轴线、第一端部和沿着所述轴线的第二方向与所述第一端部间隔开的第二端部。所述第二方向垂直于所述第一方向。所述植入物包括与所述板接合的所述致动构件上的第一楔形件和第二楔形件以及沿着第二轴线沿着第三方向间隔开的驱动构件,所述第三方向垂直于所述第一方向、沿着所述第二方向并且相对于所述第二方向偏离。所述驱动构件将力传送至所述致动构件以致使所述致动构件旋转,并且所述楔形构件中的一者响应于旋转而沿着所述第二方向平移以移动所述板中的一者。(The invention provides an expandable implant having a 0 th plate and a second plate spaced apart from each other in a direction, the plates defining opposing bone contacting surfaces along a 1 th direction, the opposing bone contacting surfaces configured to contact an upper vertebral body and a lower vertebral body, respectively, an actuation member disposed between the plates defining a th axis, a end, and a second end spaced apart from the th end along a second direction of the axis, the second direction being perpendicular to the direction, the implant including a wedge and a second wedge on the actuation member engaged with the plates and a drive member spaced apart along a second axis along a third direction, the third direction being perpendicular to the direction, along the second direction, and offset relative to the second direction, the drive member transmitting a force to the actuation member to cause the actuation member to rotate, and of the wedge members translating in the second direction in response to the rotation to move of the plates.)

An expandable implant of , comprising:

a first plate and a second plate, the first plate and the second plate being spaced apart from each other along a direction, the first plate defining a first bone contacting surface configured to contact a superior vertebral body, the second plate defining a second bone contacting surface opposite the first bone contacting surface along the direction, the second bone contacting surface configured to contact an inferior vertebral body;

an actuation member disposed at least partially between the plate and the second plate relative to the direction, the actuation member defining a axis, a end, and a second end spaced from the end along the axis along a second direction, wherein the second direction is perpendicular to the direction;

a th wedge member and a second wedge member, the th wedge member and the second wedge member being carried by the actuating member and engaging the th plate and the second plate, and

a drive member defining a second axis, a proximal end, and a distal end spaced from the proximal end along the second axis along a third direction that is perpendicular to the th direction and offset relative to the second direction,

wherein the drive member is configured to transmit a driving force to the actuation member so as to cause rotation of the actuation member about the th axis, and at least of the wedge member and the second wedge member is configured to translate in the second direction in response to rotation of the actuation member about the th axis so as to move at least of the th plate and the second plate in the th direction relative to the other of the th plate and the second plate.

2. The implant of claim 1, further comprising:

an th transmission member, the th transmission member being carried by the actuation member, and

a second transmission member carried by the drive member, wherein the th transmission member and the second transmission member are configured to engage one another so as to transfer at least the portion of the driving force to the actuation member so as to rotate the actuation member about the th axis.

3. The implant of claim 2 wherein the -th wedge member defines a -th wedge body, the -th wedge body defining a -th central wedge axis, a -th end, and a second end spaced apart from the -th end along the second direction, wherein the -th central wedge axis is parallel to the second direction.

4. The implant of claim 3, wherein the second wedge member defines a second wedge body, the second wedge body defines a second central wedge axis, and a th end and a second end of the second wedge body are spaced apart from each other along the second direction, wherein the second central wedge axis is parallel to the second direction.

5. The implant of claim 4, wherein the actuation member defines a rod including an th thread region and a second thread region spaced apart from each other along the second direction, the th wedge body defining a th thread configured to engage the th thread region, and the second wedge body defining a second thread configured to engage the second thread region.

6. The implant of claim 5, wherein the th wedge body defines a th central bore extending through the th wedge body along the th central wedge axis, the th central bore defines the th thread, and the second wedge body defines a second central bore extending through the second wedge body along the second central wedge axis, and the second central bore defines the second thread.

7. The implant of claim 6, wherein each of the wedge-shaped body and the second wedge-shaped body defines upper and lower inclined surfaces extending between the respective and second ends.

8. The implant of claim 7, wherein the second ends of the wedge-shaped bodies and the second wedge-shaped bodies face each other along the second direction, and the ends of the wedge-shaped bodies and the second wedge-shaped bodies face away from each other along the second direction.

9. The implant of claim 8 wherein the upper and lower inclined surfaces of the wedge body are oriented relative to each other such that 1) the end of the wedge body defines a maximum dimension along the direction, 2) the second end of the wedge body defines a second maximum dimension along the direction, and 3) the second maximum dimension is greater than the maximum dimension.

10. The implant of claim 9, wherein the upper and lower inclined surfaces of the wedge-shaped body are each oriented at an angle between about 15 degrees and about 30 degrees relative to the axis.

11. The implant of claim 10, wherein the acute angle is between about 21 and 25 degrees.

12. The implant of claim 8, wherein the upper and lower inclined surfaces of the second wedge body are oriented relative to each other such that 1) the th end of the second wedge body defines a third maximum dimension along the direction, 2) the second end of the second wedge body defines a fourth maximum dimension along the direction, and 3) the fourth maximum dimension is greater than the third maximum dimension.

13. The implant of claim 9, wherein the upper and lower angled surfaces of the second wedge body are each oriented at a second angle between about 30 degrees and about 60 degrees relative to the th axis.

14. The implant of claim 10, wherein the second acute angle is between about 40 degrees and 50 degrees.

15. The implant of claim 2, wherein the th transmission member is a th gear and the second transmission member is a second gear.

16. The implant of claim 15 wherein gear is configured to rotate about the axis and the second gear is configured to rotate about the second axis.

17. The implant of claim 16, wherein the th gear and the second gear are both bevel gears.

18. The implant of claim 16, wherein the th axis and the second axis are perpendicular to each other.

19. The implant of claim 18 wherein the th axis and the second axis are each perpendicular to the th direction.

20. The implant of claim 2 wherein the bone contacting surface and the second bone contacting surface are oriented at an angle of between about 5 and 10 degrees relative to each other in a plane coextensive with the direction and the second direction when the plate and the second plate are minimally spaced apart from each other along the direction.

21. The implant of claim 20 wherein the th and second bone contacting surfaces are oriented at an angle between about 12 and 18 degrees in the plane with respect to each other when at least of the th and second plates is moved along the th direction to a maximum distance with respect to the other of the th and second plates.

22. The implant of claim 2 wherein said actuation member is an th actuation member, said implant further comprising a second actuation member spaced apart from said th actuation member along said third direction.

23. The implant of claim 22 wherein the second actuation member defines a third axis extending along the second direction, the second actuation member further defining an th end and a second end spaced from the th end along the second direction.

24. The implant of claim 23, further comprising third and fourth wedge members carried by the second actuation member, wherein the third and fourth wedge members are engaged with the plate and the second plate, the third and fourth wedge members configured to at least one of translate toward and translate away from each other along the third axis in response to rotation of the second actuation member about the third axis so as to move the plate and the second plate at least partially away from each other in the direction.

25. The implant of claim 24, further comprising:

a third transmission member carried by the second actuation member;

a fourth transmission member carried by the drive member, wherein the third transmission member and the fourth transmission member are configured to engage one another to transfer at least a second portion of the driving force to the second actuation member to rotate the second actuation member about the third axis.

26. The implant of claim 25, wherein the transmission member is a gear, the second transmission member is a second gear, the third transmission member is a third gear, and the fourth transmission member is a fourth gear.

27. The implant of claim 26, wherein each of the gear, the second gear, the third gear, and the fourth gear is a bevel gear.

28. The implant of claim 27, wherein an th bevel gear is configured to rotate about the th axis, a third bevel gear is configured to rotate about the third axis, and a second bevel gear and a fourth bevel gear are each configured to rotate about the second axis.

Technical Field

The present invention relates to expandable intervertebral implants and related methods.

Background

If the disc degenerates, it is often desirable to remove the disc. Spinal fusion procedures can be used to treat such conditions and involve replacement of the degenerated intervertebral disc with a device, such as a cage or other spacer, that restores the height of the intervertebral space and allows bone growth through the device to fuse the adjacent vertebrae. Spinal fusion attempts to restore normal spinal alignment, stabilize spinal segments for proper fusion, create an optimal fusion environment, and allow early active activity by minimizing damage to spinal vasculature, dura mater, and neurons. When spinal fusion meets these goals, healing is accelerated and patient function, comfort and mobility are improved. Spacer devices that compact into the intervertebral space and allow bone growth from the adjacent vertebral bodies through the upper and lower surfaces of the implant are known in the art. However, there remains a need for a device that minimizes the invasiveness of the procedure, yet stabilizes the spinal segment and creates an optimal space for spinal fusion. There remains a need for a device that can be inserted laterally (i.e., in the medial-lateral direction) into the intervertebral space.

Disclosure of Invention

According to embodiments of the present disclosure, the expandable implant includes a 0 plate and a second plate spaced apart from each other along a th direction, the 1 plate defines a th bone-contacting surface configured to contact an upper vertebral body, and the second plate defines a second bone-contacting surface opposite the th bone-contacting surface along a th direction, the second bone-contacting surface is configured to contact a lower vertebral body the implant includes an actuation member disposed at least partially between the th plate and the second plate relative to a th direction, the actuation member defines a th axis, a th end, and a second end spaced apart from the th end along a th axis along a second direction, the second direction being perpendicular to the th direction, the implant includes a th wedge member and a second wedge member carried by the actuation member and engaged with the th plate and the second plate, and further includes a drive member defining a second axis, a proximal axis, the second axis and the second wedge member engaging the and the second plate along a second axis, and the third direction, the actuation member being configured to translate about the about the second axis, the and transmit a driving force about the second axis, in response to the actuation member being displaced in the second direction, the , and the actuation member being configured to cause the actuation member to be translated about the actuation member in the , the second direction, the actuation member being displaced in the third direction, the 3653, the actuation member being configured to be displaced in the actuation direction, the actuation member being perpendicular to cause the actuation member, the actuation member being displaced in the actuation direction.

Drawings

The foregoing summary, as well as the following detailed description of illustrative embodiments of the intervertebral implant of the present application, will be better understood when read in conjunction with the appended drawings. For the purpose of illustrating the expandable intervertebral implant of the present application, there is shown in the drawings exemplary embodiments. It should be understood, however, that the application is not limited to the precise arrangements and instrumentalities shown. In the drawings:

fig. 1 illustrates an implant positioned between vertebral bodies according to an embodiment of the present disclosure;

FIG. 2 is a perspective view of the implant shown in FIG. 1 in a collapsed configuration;

FIG. 3 is a perspective view of the implant shown in FIG. 1 in an expanded configuration;

FIG. 4 is a top view of the implant shown in FIG. 1 in a collapsed configuration;

FIG. 5 is a top view of the implant shown in FIG. 1 in an expanded configuration with the upper plate of the implant removed, showing the expansion mechanism of the implant;

FIG. 6A is an exploded perspective view of the expansion mechanism shown in FIG. 5;

FIG. 6B is a perspective view of the upper and lower plates of the implant shown in FIG. 1, with the upper and lower plates shown at different angles to show the inner surfaces of the plates;

FIG. 7 is a bottom plan view of the upper plate of the implant shown in FIG. 6B;

FIG. 8 is a cross-sectional end view of the upper plate of the implant of FIG. 7 taken along section line 8-8 of FIG. 4;

FIG. 9 is a cross-sectional end view of the base plate of the implant illustrated in FIG. 7, as taken along section line 8-8 of FIG. 4;

FIG. 10 is a cross-sectional view of the portion of the upper plate of the implant taken along section line 10-10 of FIG. 4;

FIG. 11 is a perspective view of a wedge member of the expansion mechanism shown in FIGS. 5 and 6A;

FIG. 12 is a side view of the wedge member shown in FIG. 11;

FIGS. 13 and 14 are opposite end views of the wedge member shown in FIG. 11;

FIG. 15 is a perspective view of another wedge member of the expansion mechanism shown in FIGS. 5 and 6A;

FIG. 16 is a side view of the wedge member shown in FIG. 15;

FIGS. 17 and 18 are opposite end views of the wedge member shown in FIG. 15;

FIG. 19 is an exploded perspective view of an actuating member of the expansion mechanism shown in FIGS. 5 and 6A;

FIG. 20 is a side view of the actuating member shown in FIG. 19;

FIG. 21 is a cross-sectional end view of the implant taken along section line 21-21 of FIG. 4, showing the implant in a collapsed configuration; and is

Fig. 22 is a cross-sectional end view of the implant shown in an expanded configuration.

Detailed Description

Referring to fig. 1, an upper vertebral body 2 and an adjacent lower vertebral body 4 define an intervertebral space 5 extending between the vertebral bodies 2, 4, the upper vertebral body 2 defines an upper vertebral surface 6, and the adjacent lower vertebral body 4 defines a lower vertebral surface 8, the vertebral bodies 2, 4 may be anatomically adjacent, or may be the remaining vertebral bodies after removal of the intermediate vertebral body from a position between the vertebral bodies 2, 4 the intervertebral space 5 is shown in fig. 1 after discectomy whereby disc material has been removed or at least partially removed in preparation for the intervertebral space 5 containing the expandable intervertebral implant 10, the implant 10 may be configured for lateral insertion (i.e., along a medial-lateral trajectory) within the intervertebral space 5 once inserted into the intervertebral space 5, the implant 10 may be expanded in a head-to-tail direction to achieve proper height restoration and lordosis, as discussed in more detail below the intervertebral space 5 may be disposed at any location as desired, including at the spinal, cervical, thoracic, and thoracic regions 1 it is to be understood that certain features of the implant 10 may be incorporated by reference in the entire us patent publication 2014/0243982 published as a published in the entire year 3628.

Certain terminology is used in the following description for convenience only and is not limiting. The words "right", "left", "lower" and "upper" designate directions in the drawings to which reference is made. The words "inner", "inner" and "inner" refer to directions toward the geometric center of the implant, while the words "outer", "outer" and "outer" refer to directions away from the geometric center of the implant. The words "anterior," "posterior," "upper," "lower," "medial," "lateral," and related words and/or phrases are used to refer to various positions and orientations within the human body to which reference is made. When these terms are used with respect to the implant 10 or components thereof, they should be understood to refer to the relative position of the implant 10 when implanted in vivo, as shown in fig. 1. The terminology includes the words above listed, derivatives thereof and words of similar import.

Referring now to fig. 2, implant 10 is described herein as extending horizontally along longitudinal direction "L" and transverse direction "T", and vertically along vertical direction "V". Unless otherwise indicated herein, the terms "longitudinal," "transverse," and "vertical" are used to describe orthogonal directional components of the respective implant components and the implant component axis. It should be understood that while the longitudinal direction L and the transverse direction T are shown as extending along and defining a horizontal plane (also referred to herein as a "longitudinal-transverse plane"), and the vertical direction is shown as extending along a vertical plane (such as referred to herein as a "vertical-longitudinal plane" or a "vertical-transverse plane," respectively), the planes encompassing the various directions may differ during use. For example, when the implant 10 is inserted into the intervertebral space 5, the vertical direction V generally extends along the superior-inferior (or caudal-cephalad) direction, while the horizontal plane generally lies in an anatomical plane defined by the anterior-posterior direction and the medial-lateral direction. Accordingly, the directional terms "vertical" and "horizontal" may be used to describe the implant 10 and its components, shown for clarity and illustration only.

In fig. 2, implant 10 is shown in a collapsed configuration C. implant 10 may extend between a proximal or posterior end 12 and a distal or anterior end 14 spaced from anterior end 14 along a longitudinal implant axis X1 extending along a longitudinal direction L. anterior end 12 and posterior end 14 may be referred to as such, respectively, as the anterior end of implant 10 may be first inserted into intervertebral space 5. posterior end 12 may be configured to couple with or more insertion instruments configured to support implant 10 and carry the implant into intervertebral space 5. implant 10 may also extend along a transverse direction T between anterior side 16 and posterior side 18.

The implant 10 may include an th or upper plate 100 and a second or lower plate 200 opposite the upper plate 100 along a vertical direction V, the upper plate 100 may define an upper plate body 102 defining an upper or th bone contacting surface 104 and the lower plate 200 may define a lower plate body 202 defining a lower or second bone contacting surface 204 spaced apart from the th bone contacting surface 104 along the vertical direction V, the upper and lower bone contacting surfaces 104, 204 may be configured to engage the opposing upper and lower vertebral bodies 4, 6, respectively, as shown, each bone contacting surface 104, 204 may extend in a generally planar manner, additionally, the upper and lower bone contacting surfaces 104, 204 may be angled relative to each other in a vertical-transverse plane so as to define an anterior-convex angle α of the implant 10.

While the upper and lower bone contacting surfaces 104, 204 are each shown as being generally planar, in other embodiments, each bone contacting surface 104, 204 may be, for example, generally convex or at least partially convex, or may define a convex portion and a planar other portion each bone contacting surface 104, 204 may also, for example, at least partially define a texture (not shown), such as spikes, ridges, cones, barbs, dimples, or knurls, configured to engage the respective vertebral body 4, 6 when the implant 10 is inserted into the intervertebral space 5.

As used herein, the term "distal" and derivatives thereof refer to a direction from the posterior end 12 toward the anterior end 14. As used herein, the term "proximal" and derivatives thereof refer to a direction from the anterior end 14 toward the posterior end 12. Thus, as used herein, the term "longitudinal direction L" is bidirectional and is defined by a unidirectional distal direction and an opposite proximal direction.

As used herein, the term "anterior" and derivatives thereof refer to a direction from the posterior side 18 of the implant 10 toward the anterior side 16 of the implant. As used herein, the term "posterior" and derivatives thereof refer to a direction from the anterior side 16 toward the posterior side 18. Thus, as used herein, the term "lateral direction L" is bi-directional and is defined by a unidirectional forward direction and an opposite rearward direction.

As used herein, the term "upper" and derivatives thereof refer to a direction from the second bone contacting surface 204 toward the th bone contacting surface 104 As used herein, the term "lower" and derivatives thereof refer to a direction from the th bone contacting surface 104 toward the second bone contacting surface 204.

Referring to fig. 2 and 3, implant 10 may include an expansion mechanism 300 interposed between portions of upper plate 100 and lower plate 200 and configured to separate upper plate 100 and lower plate 200 relative to each other in vertical direction V. for example, expansion mechanism 300 may be configured to actuate implant 10 from a collapsed configuration C as shown in fig. 2 to an expanded configuration E as shown in fig. 3 implant 10 may be configured to expand vertical height and anterior convex angle α of implant 10, each measured between upper bone contacting surface 104 and lower bone contacting surface 204. for example, when implant 10 is in the collapsed configuration (fig. 2), anterior height HA1 of implant 10 may be between about 4mm and about 18mm, post-collapsed height HP1 of implant 10 may be between about 3mm and about 17mm, and collapsed (i.e., "built-in") anterior convex angle α 1 of implant 10 may be between 0 degrees and about 15 degrees when implant 10 is in the expanded configuration E (fig. 3), anterior convex angle 2 may be between about 24 degrees and about 24 degrees, and expansion mechanism 2 degrees may be configured such that when implant 10 is in the expanded configuration E (fig. 3) E, the anterior convex angle HA1 may be between about 3877 mm and about 3877 mm, and about 12 mm, and about 4933 mm, and the posterior height of implant 10 may be between about 12 mm.

For example, as shown in fig. 2 and 3, the upper plate body 102 may define a third lumen 108 and a second lumen 110 spaced in a distal direction from the third lumen 108, thus, the first lumen 108 may be referred to as the "proximal" lumen and the second lumen 210 may be referred to as the "distal" lumen, further, although not visible in fig. 2 or 3, the lower plate body 202 may define a third lumen 208 and a fourth lumen 210 spaced in a distal direction from the third lumen 208, similarly, the third lumen 208 may be referred to as the "proximal" lumen and the fourth lumen 210 may be referred to as the "distal" lumen, in addition, although not visible in fig. 2 or 3, the fourth lumen 210 may be referred to as the "distal" lumen, the first 34 lumen 108 and the second lumen 110 of the upper plate 100 may be aligned with and opposed to the third lumen 208 and the fourth lumen 210 of the lower plate 200 along a vertical direction V, each , of the lumens 108, 110, 208, 210 may be aligned with and opposed to the third lumen 208 and the fourth lumen 210, as the implant 108, 110, 108a, 108a, 2, 200 may be configured to extend in a transverse direction V, and as the fourth lumen 210, such that each of the implant may be seen in a, and when the implant may also be disposed in a, and a, a configuration, and a.

Referring to fig. 4, the implant 10 may define an implant length L0 of between about 25mm and about 70mm, measured along a longitudinal direction L from the posterior end 12 to the anterior end 14 of the implant 10 the implant may further define an implant width W0 of between about 20mm and about 50mm, measured along a lateral direction T from the anterior side 16 to the posterior side 18 of the implant 10 may further define a central aperture 111 extending through the implant 10 along a vertical direction V (i.e., from the bone contacting surface 104 to the second bone contacting surface 204). relative to the longitudinal direction L, the central aperture 111 may be located between the fourth lumen 108 and the second lumen 110 of the upper plate 100 and between the third lumen 208 and the fourth lumen 210 of the lower plate 200. the central aperture 111 may define a side or anterior side 111a and a second side or posterior side 111b spaced from the anterior side along the lateral direction T. the central aperture 111 may further define a third or proximal side 111c and a second or posterior side 111b spaced from the anterior side along the longitudinal direction T. the central aperture 111a third or proximal side 111c and a proximal side 111d may be substantially filled with bone graft material so as to substantially obstruct the vertebral body 10, and may be inserted without substantial bone filling the vertebral body 10.

Referring now to fig. 5 and 6A, the expansion mechanism 300 may include a drive assembly 301 and or multiple actuation assemblies, such as a -actuation assembly 302a and a second actuation assembly 302b, which are configured to be driven by the drive assembly 301 and actuate at least of the upper and lower plates 100, 200 to move along the vertical direction V relative to the other 1 of the plates 100, 200. the second actuation assembly 302b may be spaced from the -actuation assembly 302a in the distal direction, therefore, the rd actuation assembly 302a may be referred to as a "proximal" actuation assembly and the second actuation assembly 302b may be referred to as a "distal" actuation assembly-the -actuation assembly 302a may include a -th pair of wedge members or a proximal pair of wedge members 303, and the second actuation assembly 302b may include a second or distal pair of wedge members 304-each pair of wedge members 303, 304 may include a -308 and a second pair of wedge members 308 may be located adjacent to each other wedge member or wedge member 304-308 in the transverse direction T-p-.

The th and second pairs 303, 304 of wedge members may be configured such that translation of the th wedge member 306 relative to the second wedge member 308 along the transverse direction T drives the upper and lower plates 100, 200 to expand away from each other in the vertical direction V as such, the implant 10 may be actuated from the collapsed configuration C to the expanded configuration e for illustrative purposes, fig. 5 shows the wedge members 306, 308 in each pair in a separated configuration, while the proximal pair 303 of wedge members of fig. 6A is shown in a contracted configuration, the upper and lower plates 100, 200 and the th and second wedge members 306, 308 in each pair 303, 304 may be shaped, oriented, and otherwise configured such that the contracted configuration of the wedge members 306, 308 corresponds to the collapsed configuration C of the implant 10 and such that the separated configuration of the wedge members 306, 308 corresponds to the expanded configuration e of the implant 10, however, it should be understood that in other embodiments, the separated configuration of the wedge members 306, 308 may correspond to the collapsed configuration of the implant 10 and the wedge members 306, 308 may correspond to the expanded configuration of the implant 10.

With continued reference to fig. 5 and 6A, the th actuation assembly 302a can include a th or proximal actuation member 310 coupled to the th pair of wedge members 303 and the second actuation assembly 302b can include a second or distal actuation member 312 coupled to the second pair of wedge members 304 the th and second actuation members 310, 312 can be similarly or even substantially identically configured to each other accordingly, it should be understood that the following descriptions and reference numerals shown below in connection with th actuation member 310 can also be used in connection with the second actuation member 312.

Each actuating member 310 may include an actuating rod 314 defining a central rod axis Y1 extending along the transverse direction T and a second end 318 spaced from the opposing second end 320 along the central rod axis Y1 the actuating rod 314 may also define an outer surface 321 extending between the second end 318 and the second end 320 each actuating rod 314 may also define a second 1 portion 322 extending from the second 0 end 318 toward the second end 320 and a second portion 324 extending from the second end 320 toward the second end 318 the second portion 322 and the second portion 324 may be separate and spaced from each other along the transverse direction T the second 634 end 318 and the fourth portion 322 may each be located adjacent the front side 16 and away from the rear side 18 of the implant 10, the second end 320 and the second portion 324 may each be located adjacent the rear side 18 and away from the front side 16 of the implant 10, the second end portion 318, the second portion 322, or any component associated therewith may be referred to as a "forward threaded region 335 and a threaded region 335, a" or "may be defined along the transverse direction T of the second actuating rod axis Y468 end portion 328, a between the threaded region of the second actuating rod 320 and the threaded region 328, the threaded region 324, may be defined along the transverse direction T324, may be defined between the second longitudinal direction T350, the second longitudinal axis Y468 end portion 328, the longitudinal axis Y468 end 328, the longitudinal axis 320, the threaded region of the second actuating rod 320, the threaded region 326, the threaded region of the second actuating rod 320, the threaded region may be defined between the threaded region 326, the threaded region of the second actuating rod 320, the threaded region may be defined along the threaded region, the threaded region 324, the threaded region of the second actuating rod 320, the threaded region of the second actuating rod 320, the threaded region may be defined between the second actuating rod 320, the threaded region of the actuating rod 320, the threaded region, the second actuating rod 320, the threaded region of the actuating rod 320, the threaded region of the actuating.

actuating assembly 302a may include a th transmission member, such as th gear 336 for converting at least a portion of the driving force applied by the physician-operated driving tool into a th rotational force of th actuating member 310 about its central rod axis Y1 similarly, second actuating assembly 302b may include a second transmission member, such as a second gear 338 for converting another portion of the driving force into a second rotational force of the second actuating member 312 about its central rod axis Y1.

The drive assembly 301 may include a drive member, such as a drive shaft 340, rotationally coupled to each of the third and second 312 actuation members, the drive shaft 340 may include an engagement feature, such as a socket 342, for receiving a drive tool operated by a physician, the drive shaft 340 may also include a third transmission member, such as a third gear 344 and a fourth transmission member, such as a fourth gear 346, for transmitting drive force to the respective and second 338 transmission members of the actuation assemblies 302a, 302b, the third and fourth gears 344, 346 may be coupled to the drive shaft 340 by welding, brazing, mechanical fasteners, or any other technique, in other embodiments, either or both of the third and fourth gears 344, 346 may be formed integrally with the drive shaft 340 .

As shown, the drive shaft 340 may define a central shaft axis X2, a shaft proximal end 350, and a shaft distal end 352 spaced from the shaft proximal end 350 along a central shaft axis X2 along the longitudinal direction L the third gear 344 and the fourth gear 346 may include bevel gears configured to mesh with the respective gear 336 and the second gear 338 the fourth gear 346 may be spaced from the third gear 344 in a distal direction, thus the third gear 344 may be referred to as a "proximal" gear and the fourth gear 346 may be referred to as a "distal" gear when the gears 344, 346 are bevel gears, as shown, the gear 336 and the third gear 344 may be oriented 90 degrees relative to each other and the second gear 338 and the fourth gear 346 may be oriented 90 degrees relative to each other, although other relative orientations are within the scope of the disclosed embodiments.

The socket 342 may be recessed from the shaft proximal end 350 into the drive shaft 340. the socket 342 may be defined by a head 354 of the drive shaft 340 that extends in a distal direction from the shaft proximal end 350. the socket 342 may be any one of hexagonal, pentagonal, square, triangular, cross-shaped, plus-shaped, linear, star-shaped, or any other shape configured to engage a drive tool . the head 354 of the drive shaft 340 may define a outer shaft surface 356, and a portion of of the shaft distal to the head 354 may define a second shaft outer surface 358 such that the diameter of the outer shaft surface 356 is greater than the diameter of the second outer shaft surface 358.

The drive shaft 340 may also define a central bore 360 in fluid communication with the socket 342 and a plurality of bores 362 in fluid communication with the central bore 360. The plurality of apertures 362 may extend radially inward (i.e., in a radial direction perpendicular to the central axis X2) from the second outer surface 358 to the central aperture 360 such that the socket 342, the central aperture 360, and the apertures 362 define a continuous fluid pathway. The plurality of apertures 362 may be positioned adjacent the central aperture 111 of the implant 10 such that additional bone growth material may be injected into the socket 342 (optionally with a funnel), through the central aperture 360 and out of the plurality of apertures of the drive shaft 340 and into the central aperture 111 of the implant 10, particularly when the implant is in the expanded configuration E.

Once the implant 10 is inserted into the intervertebral space 5 as desired, the physician may actuate the implant 10 from the collapsed configuration C to the expanded configuration E by inserting a drive tool into the socket 342 of the drive shaft 340 and rotating the drive tool, which in turn rotates the drive shaft 340 and the third and fourth gears 344, 346, and in turn rotates the and second gears 336, 338 and the actuation rod 314 coupled thereto As the actuation rod 314 rotates, the wedge member 306 and the second wedge member 308 of each pair 303, 304 move away from each other along the respective and second threaded regions 328, 330 of the actuation rods 310, 312 in the transverse direction T, forcing the upper and lower plates 100, 200 apart from each other in the vertical direction V.

The expansion mechanism 300 may include a th mounting element, such as a th bracket or a proximal bracket 364, and a second mounting element, such as a second bracket or a distal bracket 366, for coupling the drive shaft 340 to the actuating member 310 and the second actuating member 312, respectively, for example, the th bracket 364 and the second bracket 366 may each be square (i.e., "right angle") brackets about a horizontal plane, specifically, each bracket 364, 366 may define a th bracket portion 368 that is configured to extend in a forward direction from the rear bracket end 370 to a bend 372 that is spaced from the rear bracket end 370, each bracket 364, 366 may further define a second bracket portion 374 that extends in a longitudinal direction L from the bend 372 to a retaining element 376 that is spaced from the bend 372, as shown more clearly in fig. 6A, the th bracket portion 368 may define an aperture coupling 378 adjacent the rear bracket end 370, and that is sized and configured to receive a second outer surface 378 of the drive shaft 340, the aperture coupling axis 358 may define a central coupling axis 3 that is configured to abut the central coupling axis 2 of the drive shaft 340 when the central coupling axis 364 is positioned adjacent the central axis 2.

The retaining element 376 of each bracket 364, 366 may be configured to engage the retaining feature 326 of the associated actuating member 310, 312 in a manner that at least partially retains the actuating member 310, 312 in position relative to the drive shaft 340. the retaining element 376 may define a pair of opposed arms 380a, 380b extending in the longitudinal direction L and spaced from each other in the vertical direction V. the inner surfaces 381a, 381b of the arms 380a, 380b may extend within the annular recess 326 of the associated actuating member 310, 312. the inner arm surfaces 381a, 381b may each be substantially linear and parallel to the longitudinal direction L. the arms 380a, 380b may further define curved and convex outer arm surfaces 382a, 382b in the vertical-longitudinal plane in common to define a C-shape. the retaining element 376 may further define a curved and concave intermediate surface 381a vertical direction V that engages the curved and concave inner arm surfaces 381a, 381 b. the intermediate surface 383 may have a profile to match the profile of the outer surface 321, 314 of the associated actuating rod 326 when the actuating rod 314 acts as a bearing element for retaining the associated axial direction V-axis of the actuating rod 314, and may be configured to at least slightly retain the associated axial direction V-axis of the inner surface 383, V-axis of the associated actuating rod, and to be at least partially retain the associated longitudinal bearing 121 b in the axial direction V-the associated inner surface 383 of the associated actuating rod 121, 314-retaining element 366, 314-retaining element, 314-n-axial bearing element 366, 383-n-axial.

As depicted, the proximal and distal cradles 364, 366 may be positioned on the drive shaft 340 such that the th and second actuating members 310, 312 are positioned between the respective th cradle portions 368 relative to the longitudinal direction L in such embodiments, the arms 380a, 380b of the retention element 376 of the proximal cradle 364 may open in the distal direction and the arms 380a, 380b of the retention element 376 of the distal cradle 366 may open in the proximal direction, thus, during assembly of the implant 10, the arms 380a, 380b of each retention element 376 may be received on opposite vertical sides of the outer surface 321 of the rod 314 within the recess 326. alternatively, the proximal and distal cradles 364, 366 may be positioned on the drive shaft 340 such that the respective th cradle portions 368 are positioned between the respective actuating members 310, 312 relative to the longitudinal direction L.

Referring now to fig. 6B, the upper plate body 102 may define a first interior face 112 spaced apart from and positioned opposite to the first bone-contacting surface 104 along a vertical direction V, and the lower plate body 202 may define a second interior face 212 spaced apart from and positioned opposite to the second bone-contacting surface 204 along the vertical direction V, the first interior surface 112 and the second interior surface 212 may be positioned opposite to each other and may substantially face each other along the vertical direction V, the second interior face 112 and the second interior face 212 may each extend from the posterior end 12 to the anterior end 14 of the implant 10, and from the anterior side 16 to the posterior side 18 of the implant 10, the first interior face 112 and the second interior face 212 may each be configured to couple with the wedge members 306, 308, as set forth in more detail below.

The inner face 112 may define a inner plate contact surface 114 and the second inner face 212 may define a second inner plate contact surface 214 the inner plate contact surface 114 and the second inner plate contact surface 214 may be configured to abut one another when the implant 10 is in the collapsed configuration C each of the inner plate contact surface 114 and the second inner plate contact surface 214 may include a plurality of contact surfaces that are spaced apart from one another along the longitudinal direction L and the transverse direction T.

The fifth interior face 112 of the upper plate body 102 may define a fifth cavity 116 and a second cavity 118 spaced from the fourth cavity 116 in the distal direction, therefore, the cavity 116 may be referred to as the "proximal" cavity, and the second cavity 118 may be referred to as the "distal" cavity, the and second cavities 118 may each extend along the vertical direction V from the interior plate contact surface 114 toward the bone contact surface 104, and may each extend along the lateral direction T from a location adjacent to or adjacent to the anterior side 16 of the implant 10 to a location adjacent to the posterior side 18 of the implant 10, the fifth cavity 116 may be adjacent to the fifth interior cavity 108, and the second cavity 118 may be adjacent to the second interior cavity 110, the second interior face 212 of the lower plate body 202 may define a third cavity 216 and a fourth cavity 218 spaced from the third cavity 216 in the distal direction, and the fourth cavity 218 may be referred to as the "proximal" cavity "and the fourth cavity 218 may be referred to as the" third cavity 216 and the fourth cavity 218 may extend along the lateral direction V adjacent to or adjacent to the anterior side 204 of the implant 10.

The and 216 cavities may be opposite one another and face one another along a vertical direction V such that the and 216 cavities may collectively receive at least portions of the pairs of wedge members 303, actuating members 310, and brackets 364 at least when the implant 10 is in the collapsed configuration C similarly, the second and fourth cavities 118 and 218 may face one another along a vertical direction V so as to collectively receive at least portions of the second pairs of wedge members 304, second actuating members 312, and second brackets 366 at least when the implant 10 is in the collapsed position C.

Referring to fig. 6B and 7, the th and second cavities 116, 118 of the upper plate body 102 may be similarly shaped, the th and second cavities 116, 118 may be configured similarly or even substantially identically to each other, furthermore, the third and fourth cavities 216, 218 may be configured within the lower plate body 202 in a manner similar or substantially identical to the manner in which the th and second cavities 116, 118 are configured within the upper plate body 102, it should be understood, therefore, that the following descriptions and reference numerals illustrated below in connection with the th cavity 116 may also be used in connection with any of the second, third and fourth cavities 118, 216, 218.

Referring to fig. 7, each lumen 116, 118 may extend along a central lumen axis Y2 from a th or anterior lumen end 120 to a second or posterior lumen end 122, the central lumen axis extending along a transverse direction T, the anterior lumen end 120 may be contiguous with the anterior side 16 of the implant 10, and the posterior lumen end 122 may be positioned adjacent the posterior side 18 of the implant 10. each lumen 116, 118 may further define a th or lateral side 124 and an opposing second or medial side 126 spaced from the th side along the longitudinal direction L the th and second sides of each lumen 116 may face each other along the longitudinal direction L.

Each of upper and lower plates 100, 200 may include or more engagement elements configured to engage corresponding engagement elements of expansion mechanism 300 in a manner that allows expansion mechanism 300 to separate plates 100, 200 along vertical direction V, for example, within each of cavities 116, plate body 102 may define engagement elements, such as pairs of ramp surfaces configured to be allocated with and slide along respective portions of wedge member 306 and second wedge member 308. the pair of ramp surfaces may include a -th or front ramp surface 130 and a second or rear ramp surface 132 spaced from a -th ramp surface 130 along lateral direction T. the -th and second ramp surfaces 130, 132 may be positioned on opposite sides 108a, 108b of the cavities 108, 110 in communication with cavity 116 relative to lateral direction T. the -th ramp surface 130 may extend from the front cavity end 120 to the front side 108a of the cavity, and the second ramp surface 132 may extend from the rear side 108b of the cavity to the rear cavity end 122.

The first ramp surface 130 is inclined to abut and slidingly receive the 0 portion of the first wedge member 306 and the second ramp surface 132 is inclined to abut and slidingly receive the 1 portion of the second wedge member 308 the th ramp surface 130 may be inclined such that the vertical distance measured from the inner plate contact surface 114 of the associated plate body 102 to the th ramp surface 130 increases from the leading ramp end to the trailing ramp end along the transverse direction T the second ramp surface 132 may be inclined such that the vertical distance measured from the inner plate contact surface of the associated plate body to the second ramp surface 132 decreases from the leading ramp end to the trailing ramp end along the transverse direction T as shown in fig. 8 with respect to the upper plate body 102, the th ramp surface 130 may be inclined at an acute angle S1 relative to the inner plate contact surface 114 of between about 10 degrees degrees and about 40 degrees relative to the inner plate contact surface 114 as shown in fig. 8 with respect to the upper plate body 102 the second ramp surface 202, the second ramp surface 132 may be inclined at an acute angle of between about 10 degrees and about 593 degrees as shown in fig. 16, the inner plate contact surface 202, the associated second ramp surface may be inclined at an acute angle 3614, 3614 degrees as understood by the angle 597 degrees, the angle of the associated inner plate contact surface of the lower plate contact surface of the 3614, the associated ramp surface of the inner plate contact surface of the lower plate body 202, the inner plate body 202, the 3614 may be inclined at an acute angle 597, the angle of the inner plate contact angle 597, the 3614, the , the angle of the inner ramp surface 202, the inner ramp surface of the inner plate contact angle of the lower plate contact surface 202, the 3614, the angle of the lower plate contact angle of the inner plate 202, the inner ramp surface of the.

The plate body 102 may further define within each cavity 116, 118 a curved portion 134 disposed at the anterior side 16 of the implant 10 and in communication with the -th ramp surface 130, and a second curved portion 136 disposed at the posterior end 122 of the cavity 116 and in communication with the second ramp surface 132. the curved portion 134 and the second curved portion 136 may be recessed from the ramp surface 130 and the second ramp surface 132, respectively, along the vertical direction V toward the bone-contacting surface 104 of the plate body 102. the curved portion 134 and the second curved portion 136 may each define a curved profile in the vertical-longitudinal plane when the upper plate 100 and the lower plate 200 are in the collapsed configuration C, the vertically opposed curved portions 134 of the upper plate body 102 and the lower plate body 202 may collectively define a access or anterior access to the portion 322 of the associated actuation member 310, 312, and the vertically opposed second curved portion 136 of the plate body 102, 202 may collectively define a second access or posterior access to the second portion 324 of the associated actuation member 310, 312.

At each of the lateral 124 and medial 126 sides of the cavity 116, the plate body 102 may define or more protrusions 138 projecting inwardly along the longitudinal direction L towards the central cavity axis Y2 the protrusions 138 may at least partially define 0 or more channels 140, said 1 or more channels being positioned vertically within the cavity 116 between the 2 or more protrusions 138 and the associated ramp surfaces 130, 132. the protrusions 138 and channels 140 may be defined by various surfaces within the cavity 116. for example, as shown in fig. 10, at each 3 of the lateral 124 and medial 126 sides of the cavity 116, the plate body 102 may define surfaces 142 and second surfaces 144 extending in the vertical direction V and the transverse direction T, respectively, at each 465 surfaces 142 and 120 a fifth surface 142 and a sixth surface 144 of the plate body 102. the surfaces may abut the inner contact surfaces 114 of the plate body 102. the second surfaces 144 may abut the inner contact surfaces 114 of the second surfaces 6334, may be defined by at least one of the second surfaces 120 and fifth surfaces 34 and fifth surfaces 130, sixth surfaces 120, 35, 26, 120, 142 may be defined by at least one of the longitudinal direction L, 120, 35, 120, 103, 120, 103, and/or by at least one of the second surfaces may be defined by a third surfaces 34, 35, 120, 35, 150, 120, 35, 150, 35, and 35, 150, and 35, 150, 35, and 120, and 35, and 120, and 35, may be positioned in a surface, and/or similar direction L, and/or similar to be positioned in a surface, and/or similar.

On each side of the cavity 116, the or more projections 138 may include a th or forward projection 138a that partially overlaps the 0146 th ramp surface 130 in the longitudinal direction L, and a second or rearward projection 138b that partially overlaps the second ramp surface 132 in the longitudinal direction L. additionally, the 2 or more channels 140 may include a second or forward channel 140a positioned vertically between the th and th ramp surfaces 138a, 130, and a second or rearward channel 140b positioned vertically between the second projection 138b and the second ramp surface 132, as such, the channel 140a and the second channel 140b may be characterized as being positioned "below" the second projections 138a, 138b of the fourth and fifth projections 138b , respectively, on each side of the cavity 116, the second channel 140b may be in contact with the second inner plate 140a, the tiltable 18 b so as to be parallel to the second ramp surface 130, and the tiltable channel 140b may be in contact with the second ramp surface 138a, 18 b, 18, and 18, respectively.

It should be understood that the projections 138 and channels 140 on the medial side 126 of the cavity 116 may be sized, shaped, and oriented similarly to those on the lateral side 124 of the cavity 116. In other words, the features on the lateral side 124 and the medial side 126 of the cavity 116 may actually be mirror images of each other with respect to a vertical plane extending along the central cavity axis Y2.

In association with each cavity 116, 118, the plate body 102 may further define a or outer longitudinal slot 148 and a second or inner longitudinal slot 150 aligned with one another on opposite sides 124, 126 of the cavity, the slot 148 may extend from the exterior of the plate body 102 to the cavity along the longitudinal direction L, and the second slot 150 may extend from the cavity toward the interior of the plate body 102 along the longitudinal direction L, the front and rear projections 138a, 138b on the exterior side 124 of each cavity 116 may be separated from one another along the transverse direction T by the slot 148, and the front and rear projections 138a, 138b on the interior side 126 of each cavity 116 may be separated from one another along the transverse direction T by the second slot 150.

The plate body may further define a th or proximal landing surface 152 associated with the th cavity 116, and a second or distal landing surface 154 associated with the second cavity 118 the th and second landing surfaces 152, 154 may each be recessed into the plate body 102 in the vertical direction V from its inner plate contact surface 114. the second landing surface 154 may be spaced apart in the distal direction from the th landing surface 152 such that both the th and second cavities 118 are positioned along the longitudinal direction L between the th and second landing surfaces 152, 154. the th landing surface 152 may be adjacent to and optionally abutting the posterior end 12 of the implant 10, and the second landing surface 154 may be adjacent to and optionally abutting the anterior end 14 of the implant 10. the th and second landing surfaces 152, 154 may each extend from the associated outer cavity 118, 118 in the posterior direction adjacent to and away from the posterior side 18 of the implant 10. the second th and second landing surfaces 152, 154 may each extend from the associated slots 118 in the posterior direction.

With respect to the longitudinal direction L, the th landing surface 152 may be separated from the outboard side 124 of the th cavity 116 by a th wall 156 defined by the plate body 102, and the second landing surface 154 may be separated from the outboard side 124 of the second cavity 118 by a second wall 158 defined by the plate body 102.

Each cavity 116, 118 and its associated fourth slot 148 and second slot 150 and associated landing surface 152, 154 are configured to receive an associated bracket 364, 366. for example, with respect to the cavity 116, the portion 368 of the bracket 364 may extend across the landing surface 152 in the transverse direction T, and the second portion 374 of the bracket 364 may extend across the cavity 116 along the longitudinal direction L and may extend within its associated outer and inner slots 148, 150. similarly, the portion 368 of the second bracket 366 may extend across the second landing surface 154 in the transverse direction T, and the second portion 374 of the bracket 366 may extend across the second cavity 118 along the longitudinal direction L, and may extend within its associated outer and inner slots 148, 150. as such, the brackets 366 may be at least partially held in place, for example, with respect to the associated plate body 102, as shown in fig. 5. the inner slots 150 may each have a curved and concave profile in the vertical-longitudinal plane, so that the outer and inner slots 364, 382 of the associated plate body 364 may be adjusted in position relative to the transverse direction T, E, with the transverse direction E, and transverse direction E of the expanded profile of the associated bracket 364, such that the bracket 364, E, may be adjusted in the transverse direction E, and the configuration such that the transverse direction E, the transverse direction of the implant, E, and the bracket's transverse direction of the bracket's associated plate body, E, and the bracket's.

The inner surface 112 of the plate body 102 may further define a third landing surface 160 adjacent to and optionally abutting the posterior side 18 of the implant 10. the third landing surface 160 may extend along the longitudinal direction L from the proximal end 12 to the distal end 14 of the implant 10, and may extend in the posterior direction from the th cavity 116 and the second cavity 118 to the posterior side 18 of the implant 10. the third landing surface 160 may abut one or more of the th cavity 116 and the second cavity 118, the th landing surface 152 and the second landing surface 154, and the th wall 156 and the second wall 158 of the plate body 102. the third landing surface 160 may be configured to at least partially house the drive shaft 340 and the th transmission member 336 and the second transmission member 338 of the expansion mechanism 300. accordingly, the third landing surface 160 may be inclined such that the vertical distance measured from the third landing surface 160 to the bone contacting surface 104 of the plate body 102 decreases along the posterior direction. the third landing surface 160 abutting the cavity 118 and the second cavity 118 may also define a vertical inclination of the second landing surface 116 and the second transmission member 122 in the transverse plane of the plate body 102 and the second landing surface 116 and the second cavity 118, respectively so that the vertical distance measured from the landing surface 116 and the second landing surface 120 may define an inclination of the second landing surface .

The lower plate 200 and the upper plate 100 may be similarly configured, for example, as shown in the illustrated embodiment, the upper plate body 102 and the lower plate body 202 may be mirror images of each other with respect to a horizontal plane extending through the geometric center of the implant 10. accordingly, the lower plate 200 may include structural features corresponding to those described above with respect to the upper plate 100. accordingly, reference numerals for features of the upper plate body 102 may be used in conjunction with corresponding features of the lower plate body 202. for example, the third and fourth cavities 216 and 218 defined by the lower plate body 202 and the fourth cavity 116 and the second cavity 118 of the upper plate body 102 may be similarly configured.

Referring now to fig. 11-14, which show various views of the th or forward wedge member 306 the th wedge member 306 of each of the proximal and distal pairs 303, 304 may be similarly configured the th wedge member 306 may define a th wedge body 400 extending along a th central wedge axis Y3 between the outer end 402 and the inner end 404 spaced from the outer end 402 relative to a th central wedge axis Y3, the outer end 402 may define an outer face 406 and the inner end 404 may define an inner face 408, and each face 406, 408 may optionally be flat and oriented perpendicular to a th central wedge axis Y3 the th central wedge axis Y3 is generally aligned with a central rod axis Y2 carrying the actuating rod 314 of the th wedge member 306, thus, the th central wedge axis Y3 and the central rod axis Y2 may each extend along the transverse direction T, as shown in fig. 5 and 6A, the fourth wedge member 306 may be positioned between the front wedge body 402 and the inner end 845, the rear wedge body 400 may be positioned between the transverse direction T845 and the inner end 845, the inner end 845 and the inner end 842.

The wedge body 400 may define one or more engagement elements that are configured to engage corresponding engagement elements of the upper and lower plates 100, 200 in a manner that drives separation between the plates 100, 200 in the vertical direction V. the or more engagement elements of the 1 wedge body 400 may include a or upper inclined surface 410 and a second or lower inclined surface 412 that are opposite and spaced from each other along the vertical direction V. the upper and lower inclined surfaces 410, 412 may extend in the lateral direction T from the outer end 402 to the inner end 404 of the wedge body 400. the upper and lower inclined surfaces 410, 412 may each be inclined relative to a central wedge axis Y3 such that the outer end is narrower in the vertical direction V than the inner end, providing the wedge body 400 with its wedge shape, the height H1 of the outer end 402 of the wedge body 400 in the vertical direction V may be in the range of about 2mm to about 6315 mm, and the height H1 of the second wedge body 400 in the vertical direction V may slidably mate with the associated second inclined surface 116, 18mm of the lower plate 102, 18, and 80, 18 mm.

The wedge body 400 may also define a side surface 414 and an opposing second side surface 416 that are spaced apart from each other along the longitudinal direction L the side surface 414 and the second side surface 416 may extend along the transverse direction T from the outer end 402 to the inner end 404 of the wedge body 400 and extend along the vertical direction V between the upper inclined surface 410 and the lower inclined surface 412 the side surface 414 and the second side surface 416 may each be flat and parallel to each other, although other orientations are within the scope of the present disclosure.

The wedge body 400 may also define or more ridges 420 that protrude from the side surface 414 and the second side surface 416 along the longitudinal direction L these ridges 420 are configured to interlock the wedge member 306 with or both of the upper plate 100 and the lower plate 200 in order to couple the upper plate 100 and the lower plate 200 at , for example, the or more ridges 420 are configured to be slidably received within or more of the front channels 140a within the associated cavity 116. thus, each of the ridges 420 of the wedge body 400 may be generally parallel with the associated channel 140a that receives them.

The or more ridges 420 may include a 1 ridge 420a and a second ridge 420b projecting outwardly from the 0 side surface 414 of the 464 th wedge body 400 along the longitudinal direction L, and may also include a third ridge 420c and a fourth ridge 420d projecting outwardly from the second side surface 416 of the th wedge body 400 along the longitudinal direction L. the 3 ridge 420a and the third ridge 420 may each be positioned adjacent to or optionally abut the upper inclined surface 410 of the th wedge body 400. thus, the 5 and third ridges 420c may each be referred to as upper ridges the second and fourth ridges 420b and 420d may each be positioned adjacent to or optionally abut the lower inclined surface 412 of the th wedge body 400 and may thus each be referred to as lower ridges or both of the and third ridges 420c may each extend from the inner end 404 of the to the outer end 402 and may be parallel to the outer end of the wedge body 400 and may extend parallel to the inner end of the second and fourth ridges 410 d of the wedge body 400, the inner end of the wedge body 400 may extend from the inner end of the second and the fourth ridge 420b, and the third ridge 420b may extend parallel to the inner end of the wedge body 400.

Each of the ridges 420a, 420b, 420c, 420d may define an upper ridge surface 422, an opposing lower ridge surface 424, and an outer ridge surface 426 extending in the vertical direction V between the upper and lower ridge surfaces 422, 424 the upper ridge surface 422 of the second ridge 420a and third ridge 420c may be adjacent to, abut against, or, as shown in the illustrated embodiment, may define a portion of 1 of the upper inclined surface b and fourth ridge 420d similarly, the lower ridge surface 424 of the second 420b and fourth ridge 420d may be adjacent to, abut against, or, as shown in the illustrated embodiment, define a portion of the lower inclined surface wedge body 400, it should be understood that the upper inclined surface 410 and lower inclined surface 412 of the b 4 wedge body 400 may be flat, or, as shown in fig. 6A and 11-14, may define 385 or more curved profiles a in the vertical-lateral plane, such as for example, and a curved region of the upper inclined surface 410 and lower inclined surface may define a curved region of the same transverse curvature as the upper inclined surface 120 b and lower inclined surface 410, a curved region of the upper inclined surface of the second ridge surface, a curved region, a curved surface 424, a curved surface, a curved region of the upper inclined surface 410 b, a lower inclined surface, a curved surface 410, a curved surface 420b, a curved surface 410, a curved surface.

The curved profile of the region 428 and the second region 430 of each of the upper and lower inclined surfaces 410, 412 may reduce friction between the wedge-shaped body 400 and the upper and lower plate bodies 102, 202 during translation of the wedge-shaped body 400 along the transverse direction T the curved profile may also provide a smoother transition between the respective anterior horns α of the upper and lower bone contacting surfaces 104, 204 and reduce internal stresses applied to the wedge-shaped body 400 and the plate bodies 102, 202, respectively, during expansion of the implant 10.

As best shown in fig. 13 and 14, the th wedge body 400 can define a th maximum wedge width w1 measured along the longitudinal direction L from the outer surface 426 of the th and third ridges 420a and 420c (or the second and fourth ridges 420b and 420d) of between about 4mm and about 7mm in addition, the upper inclined surface 410 can optionally define a linear profile in the vertical-longitudinal plane with respect to each position along the central wedge axis Y3.

With particular reference to fig. 12, a th edge 434a between an outer ridge surface 426 and a lower ridge surface 424 of a third ridge a and a second edge 434b between an outer surface 426 and an upper surface 422 of a second ridge 420b may each define a linear profile in the vertical-lateral plane similarly, a corresponding third edge 434c between the outer ridge surface 426 and the lower ridge surface 424 of the third ridge 420c and a fourth edge 434d between an outer surface 426 and an upper surface 422 of the fourth ridge 420d, respectively, may each define a linear profile in the vertical-lateral plane, each of these edges 434a, 434b, 434c, 434d may extend parallel to the respective channel 140a in which it is received, it should be understood that the first edge 434a, the second edge 434b, the third edge 434c and the fourth edge 434d of the first ridge 420a, the second ridge 420b, the third ridge 420c and the fourth ridge 420c may be angled about a, a central axis 20a, a central axis 2b, a central axis 2b, a central axis b, a central axis b, a central axis of the central post 420b, a central post, a post, a post.

the lower ridge surface 424 of the third ridge 420a and the upper ridge surface 422 of the second ridge 420b may each be adjacent or contiguous with the first side surface 414 of the th wedge body 400, and the lower ridge surface 424 of the third ridge 420c and the upper ridge surface 422 of the fourth ridge 420d may each be adjacent or contiguous with the second side surface 416 of the th wedge body 400. the outer ridge surfaces 426 of the th and third ridges 420a, 420c may be opposite each other along the longitudinal direction L, and the outer ridge surfaces 426 of the second and fourth ridges 420b, 420d may be opposite each other along the longitudinal direction L. the lower ridge surface 424 of the th ridge 420a and the upper ridge surface 422 of the second ridge 420b may face each other relative to the vertical direction V, such that the central wedge axis Y3 of the third ridge 420c is positioned between the lower ridge surface 424 of the third ridge 420a and the upper ridge surface 422 of the second ridge 420b relative to the vertical direction V.

The lower spine surface 424 of the -th spine 420a, the upper spine surface 422 of the second spine 420b, and the -th side surface 424 may collectively define a 1-recessed portion 436 of the -th wedge body 400, which -recessed portion may collectively receive the forward projections 138a defined on the associated sides 124, 126 of the associated cavities 116, 216 of the upper and lower plate bodies 102, 202, respectively, similarly, the lower spine surface 424 of the third spine 420c, the upper spine surface 422 of the fourth spine 420d, and the second side surface 416 may collectively define a second recessed portion 438 of the -th wedge body 400, which may collectively receive the forward projections 138a defined on the associated opposite sides 126, 124 of the associated cavities 116, 216 of the upper and lower plate bodies 102, 202, respectively, while the -th and third spines 420a, 420c may be received in the forward channel 140a of the upper plate body 102, and the second and fourth spines 420b, 420d may be received in the forward channels 202 of the lower plate body 202, while the associated ridges 420a and upright projections 434 may be coupled between the upper and lower plate body 202 in a longitudinal direction 102, 200, 400 may be in a manner that the upper and lower plate body 202 may be longitudinally extending along the longitudinal direction 102, 200 may be in a, 200, 2, or 2.

The first wedge body 400 may also define a th bore 440, which th bore extends from the outer end 402 through the inner end 404 along a th central wedge axis Y3 the th bore 440 may be configured to receive at least portion of the associated actuating member 310 for example, the th bore 440 may be internally threaded to mate with the th or front threaded region 328 of the actuating member 310.

15-18, which illustrate various views of a second or rear wedge member 308, it is also understood that the second wedge member 308 may be configured substantially similarly or optionally nearly identically to the second wedge member 306 of the proximal and distal pairs 303, 304. accordingly, it is understood that each of the features and reference numerals described above with respect to the wedge member 306 may be duplicated with respect to the second wedge member 308, which is indicated herein with an "apostrophe" symbol when used in conjunction with the second wedge member 308. accordingly, the second wedge body 400' may define or more engagement elements, such as upper and lower inclined surfaces 410', 412', which or more engagement elements are configured to engage corresponding engagement elements of the upper and lower plates 100, 200 in a manner that separates between the upper and lower plates 100, 200 along the vertical direction V drive the separation between the plates 100, 200. for the sake of brevity, the following description of the second wedge body 400' will focus on the differences between the second wedge member 308 and the second wedge member 82 of the wedge member embodiment of the wedge body 400 '.

The upper and lower inclined surfaces 410', 412' of the second wedge body 400' may each define a linear profile in a vertical-lateral plane from the outer end 402' to the inner end 404 '. The upper and lower inclined surfaces 410', 412' of the second wedge body 400' may each be oriented from the second central wedge axis Y3' (or from the central rod axis Y1 of the actuation member 310 on which the second wedge body 400' is received) to the respective upper and lower inclined surfaces 410', 412' at an inclination angle θ S ', θ I ' of between about 10 degrees and about 60 degrees. The second wedge body 400' may define a second wedge length L1' of between about 1.5mm and about 10mm, a second maximum wedge width W1' of between about 4mm and about 7mm, an outer end height H1' of between about 2mm and about 15mm, and an inner end height H2' of between about 3.5mm and about 17.5 mm. The upper ramped surface 410 'may slidably engage with the second ramped or rear ramped surface 132 within the associated cavity 116, 118 of the upper plate body 102, and the second lower ramped surface 412' may slidably engage with the second ramped or rear ramped surface 132 within the associated cavity 216, 218 of the lower plate body 202.

The or more ridges 420 'of the second wedge body 400' are configured to be slidably received within and substantially parallel to the corresponding rear channels 140b within the associated cavities 116, 118, 216, 218 of the upper and lower plate bodies 102, 202 on the second wedge body 400', the upper inclined surface 410' may be parallel to each of the upper and lower surfaces 422', 424' and the edges 434a ', 434c' of the (upper) and third (upper) ridges 420a ', 420c', while the lower inclined surface 412 'may be parallel to each of the upper and lower surfaces 422', 424 'and the edges 434a', 434c 'of the second and fourth (lower) ridges 420b', 420 d.

The second recess portions 436 'of the second wedge body 400' may receive the rear projections 138b defined on the associated sides 124, 126 of the associated cavities 116, 118, 216, 218 of the upper and lower plate bodies 102, 202, and the second recess portions 438 'of the second wedge body 400' may receive the rear projections 138b defined on the associated opposing sides 126, 124 of the associated cavities 116, 118, 216, 218 of the upper and lower plate bodies 102, 202, respectively, while the ridges 420 'of the second wedge body 400' may be received within the rear channels 140b of the associated cavities 116, 118, 216, 218, accordingly, the projections 138 of the plate bodies 102, 202 may overlap the associated ridges 420 'of the second wedge body 400' in the longitudinal direction L to interlock the second wedge body 400 'with each of the upper and lower plates 100, 200. the second aperture 440' defined by the second wedge body 400 'may be internally threaded to engage the second thread region of the associated actuation member 310 or the rear thread region of the second wedge body 400' may include indicia or fasteners (not shown).

Referring now to fig. 19 and 20, the th and second (i.e., proximal and distal) actuating members 310, 312 are configured to couple the th and second wedge members 306, 308 of each pair 303, 304 together with while also providing stability to the upper and lower plates 100, 200 during expansion of the implant 10. the th and second actuating members 310, 312 can be configured substantially similar to each other or even optionally nearly identical.

threaded or forward threaded region 328 may have a length L2 that is approximately 1.5 to 4 times greater than length L6 of second or rearward threaded region 330 unthreaded or forward unthreaded region 332 may have a length L3 that is less than length L1 of forward wedge 306 similarly second or rearward unthreaded region 334 may have a length L5 that is less than length L1' of second or rearward wedge 308 similarly in embodiments unthreaded region 332 and second unthreaded region 334 may each have a length L3 and L5 that is as small as zero, annular recess 326 may have a length L4 in the range of about 0.25mm to about 2mm third unthreaded region 335 may have a length L7377 of at least about 3mm, actuation rod 85314 may have a total length L326 mm and about 48mm, and a diameter of actuation rod 858-L8 per Y45 of actuation rod 89314 may be greater than about 36 mm diameter D1D 82314 as measured along axis Y25.

The rear threaded region 330 may be positioned adjacent to the associated fifth transmission member 336 or the second transmission member 338. for example, in the illustrated embodiment, the rear threaded region 330 may abut the rear face 384 of the associated bevel gear 336. additionally, the third unthreaded region 335 of the actuation rod 310 may define a mounting structure such as a keyed connector 386 that is configured to be matingly received within a central keyed slot 388 defined in the rear face 384 of the bevel gear 336. thus, to assemble at least the second or rear wedge member 308 on the actuation rod 314, a technician may insert the second threaded region 330 into the second bore 440 'of the second wedge member 308 and rotate the actuation rod 314 relative to the second wedge member 308 until the second wedge member 308 translates along the second threaded portion 330 until the outer face 402' of the second wedge body 400 'is positioned in a forward direction away from the abutment surface 335a, or at least spaced therefrom, the second wedge member 308 is positioned on the actuation rod 314 such that the keyed connector 386 may be inserted into the central keyed slot 336 of the bevel gear 336, until the rear face of the rear keyed surface 335a of the second wedge body 400' is positioned adjacent to the abutment surface 335a, or at least spaced apart therefrom, the central keyed connector may be positioned on the actuation rod 314 a rear face of the actuation rod 314, so that the bevel gear may be welded to the bevel gear 336, the rear face of the bevel gear may be aligned with the bevel gear 310 a rear face of the bevel gear 310, the bevel gear interface 336, whereby the bevel gear may be welded to be substantially aligned with the bevel gear connector 336, the bevel gear interface 336, the bevel gear may be welded to be substantially aligned with the bevel gear connector 336, the bevel gear connector 320, the bevel gear connector 388, the rear face of the bevel gear connector 336, the bevel gear connector, the.

Each actuation rod 314 is configured to extend through the and second holes 440', 440 of the -th and second wedge bodies 400, 400', respectively, and into the curve portions 134 and second curve portions 136 of the associated vertically opposed cavities 116, 216 and 118, 218 of the upper and lower plates 100, 200 when the implant 10 is in the collapsed configuration C.

The th threaded region 328 of the actuation rod 314 may have a thread pattern that is oriented in an opposite direction than the thread pattern formed on the second threaded region 330. accordingly, the internal threads of the th and second bores 440, 440' may be in an opposite orientation such that, as the actuation rod 314 is rotated, the first and second wedge members 306, 308 translate toward or away from each other along the actuation rod 314, depending on the direction of rotation of the actuation rod 314. the thread patterns on each threaded region 328, 330 may have different thread pitches such that the th and second wedge members 306, 308 translate along the th and second threaded regions 328, 330 at different respective rates.

It should be understood, however, that the lordotic angle of implant 10 may also be increased during expansion of implant 10 by adjusting any or a combination of additional factors such as the respective angles of inclination θ S, θ I, θ S ', θ I' of the upper and lower inclined surfaces 410, 412 of the th and second wedge bodies 400, 400', the ramp angles β S1, β I1, β S2, β I2 of the anterior and posterior ramps 130, 132 within the vertically opposed cavities 116, 216 and 118, 218 of the upper and lower plate bodies 102, 202, as non-limiting examples, the relative heights H1, H2, H1', H2 'of the outer and inner ends 402, 404 of the th and second wedge bodies 400', alone or in combination, may be adjusted or customized as needed to provide a predetermined lordotic distraction when implant 10 is in the expanded configuration E. it should be understood that the implant 10 may be inserted around the longitudinal lordotic axis of the intervertebral body 10 as desired, or otherwise as desired.

Referring to fig. 21 and 22, a cross-sectional end view of the implant 10 provides both a collapsed configuration C (fig. 21) and an expanded configuration E (fig. 22), each view taken along the outside 124 of the (i.e., proximal) cavity 116 and the third (i.e., proximal) cavity 216 of the bone plate 100, 200 and facing in a distal direction, although fig. 21 and 22 illustrate various aspects, features and relative positions of the th and third cavities 116, 216, th actuating member 310, to each of the wedge members 303 and brackets 364, it should be understood that the following description thereof may also be consistent with the second and fourth cavities 118, 218, second actuating member 312, second pair of wedge members 304 and second bracket 366 .

Referring now to fig. 21, in the collapsed configuration C, the inner plate contact surfaces 114, 214 of the upper and lower plates 100, 200 may abut each other the third cavity 116 and the third cavity 216 may provide sufficient space to accommodate at least portions of the third actuation member 310, the fourth 0 pair of wedge members 303, and the retaining element 376 of the fifth 1 bracket 364, the inner ends 404, 404' of the third wedge member 306 and the second wedge member 308 face each other and are spaced apart from each other to define a gap therebetween the retaining element 376 of the bracket 364 may be positioned between the inner ends 404, 404' of the third wedge member 306 and the second wedge member 308 along the transverse direction T, at least of the inner ends 404, 404' may be adjacent to or may optionally abut the retaining element 376, although not visible in fig. 21, the threaded region 344 of the actuation rod 314 may be disposed within the aperture 440 of the fifth wedge member 306, and the second threaded region 330 of the rod 314 may be disposed within the outer body portion 160 of the second wedge member 308, the third landing gear plate 102 may conform to the radius of the third wedge member 102.

Additionally, when the implant 10 is in the collapsed configuration C, the upper inclined surfaces 410, 410' of the wedge members 306, 308 may be adjacent or abut the respective third and second ramp surfaces 130, 132 within the cavity 116 of the , while the lower inclined surfaces 412, 412' of the wedge members 306, 308 may be adjacent or abut the respective third and second ramp surfaces 130, 132 within the third cavity 216 the th ridges 420a, 420a ' of the wedge may be disposed in the respective anterior and posterior channels 140a, 140b within the cavity 116 of the , and the second ridges 420b, 420b ' may be disposed in the respective anterior and posterior channels 140a, 140b within the third cavity 216, although not visible in fig. 21, it should be understood that the third and fourth ridges 420C, 420d ', 420C, 420d ' of the wedge members 306, 308 may also be disposed within the channels 140a, 140b associated therewith, with continued reference to fig. 21, the third and fourth ridges 420d, 420d ' of the wedge members 306, 308 may extend into the transverse implant 108 and facilitate the compact intervertebral implant 108 with the additional beneficial growth of the third and fourth intervertebral space 108.

During expansion of the implant 10 (i.e., between the respective configurations shown in fig. 21 and 22), the drive shaft 340 may rotate about a central shaft axis X2 which rotates the third 344 and fourth 346 gears which in turn rotate the 336 and second 338 gears and the actuation rod 314 about their central rod axis Y1. rotation of the actuation rod 314 causes the second wedge members 306 in each pair 302, 304 to translate in the forward direction (i.e., toward the anterior side 16 of the implant 10) along the third threaded region 328, and causes the second wedge members 308 in each pair 302, 304 to translate in the rearward direction (i.e., toward the posterior side 18 of the implant 10) along the second threaded region 330. the upper inclined surfaces 410, 412' and 412' of the second wedge members 306, 308 bear against the associated ramp surfaces 130, 132 of the plate bodies 102, 202 to space the upper plate body 102 from the body 202 along the vertical direction V. the upper wedge surfaces 420 and lower wedge surfaces 410, 412' of the wedge members 306, 412' and the actuation rod bodies 202, 412' are configured to maintain the expansion of the upper plate body 202 along the outer end of the wedge members 420, 140a, 120 a, 120, 300, 120 a, 300, 120 a, 300 a, b, c.

For example, the longitudinal length L0 of implant 10 may be -derived whether implant 10 is in the collapsed configuration C or the expanded configuration E in embodiments where the th wedge member 306 does not protrude from the anterior side 16 of implant 10 in the expanded configuration E, the width W0 of implant 10 may also be -derived whether implant 10 is in the collapsed configuration C or the expanded configuration E.

It should be understood that portions of any of the upper and lower plate bodies 102, 202 and/or any components of the expansion mechanism 300 may include features configured to engage or more tools for inserting, positioning and/or expanding the implant 10 the upper and lower plate bodies 102, 202 may each include or more radiographic markers (not shown) aligned with one another along a vertical direction such that the degree of plate separation may be determined or indicated by observing the relative vertical positions of the aligned radiographic markers through image analysis.

It should also be understood that the relative orientation of the actuation members 310, 312 and drive shaft 340 with respect to each other and with respect to the upper and lower plates 100, 200. for example, the central rod axis Y1 of each actuation member 310, 312 may be oriented at an obtuse angle with respect to the central axis X2 of the drive shaft 340. additionally, in other embodiments, the implant may include only actuation members 310 and for the associated wedge members 303.

It should also be understood that the features of the implant 10 disclosed herein may be modified such that, for example, during expansion of the implant 10, only of the wedge members 306, 308 translate in a lateral direction in response to rotation of the drive shaft 340, or only of the upper and lower plates 100, 200 move in a vertical direction.

It should also be understood that the dimensions shown above for the various components of the implant 10 are merely representative of examples of the dimensions of the aforementioned components. The dimensions of the aforementioned components can be adjusted as desired. Further, the implant 10 and its various components may also be scaled larger or smaller than the dimensions disclosed herein.

Every of the components described herein may be formed of a biocompatible metal such as titanium, steel, or any alloy thereof such as a titanium molybdenum alloy, or any biocompatible polymeric material such as Polyetheretherketone (PEEK) or any other suitable biocompatible material.

Although the present disclosure has been described in detail, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims. Furthermore, the scope of the present disclosure is not intended to be limited to the specific embodiments described in the specification. One of ordinary skill in the art will readily appreciate from the disclosure that processes, machines, manufacture, compositions of matter, means, methods, or steps, presently existing or later to be developed that perform substantially the same function or achieve substantially the same result as the corresponding embodiments described herein may be utilized according to the present disclosure.