Method of distracting an intervertebral space
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
A61F-002/44
A61F-002/46
A61B-017/02
A61F-002/30
출원번호
US-0622864
(2015-02-14)
등록번호
US-9913736
(2018-03-13)
발명자
/ 주소
To, John
Rao, Praveen Gopal
출원인 / 주소
INTEGRITY IMPLANTS INC.
대리인 / 주소
Boyer, Brian S.
인용정보
피인용 횟수 :
0인용 특허 :
66
초록▼
Systems and methods for distracting an intervertebral disc space are provided. The systems use a staged, bilaterally expandable trial. The systems and methods of distracting an intervertebral space are provided in a manner that addresses the problem of subsidence. The method includes inserting the t
Systems and methods for distracting an intervertebral disc space are provided. The systems use a staged, bilaterally expandable trial. The systems and methods of distracting an intervertebral space are provided in a manner that addresses the problem of subsidence. The method includes inserting the trial into the intervertebral space in a collapsed state and, once inserted, the trial is then used for distracting the intervertebral space using an expansion that includes a first stage and a second stage. The first stage includes expanding the trial laterally toward the peripheral zones of the top vertebral plate and the bottom vertebral plate, and the second stage includes expanding the trial vertically to distract the intervertebral space.
대표청구항▼
1. A staged, bilaterally-expandable trial for an intervertebral space, comprising: a bilaterally-expandable shell having a bilaterally-expandable head with 4 subheads, 4 flex rods, a slider guide, and a lumen, each of the 4 subheads operably connected to a respective flex rod, each of which operably
1. A staged, bilaterally-expandable trial for an intervertebral space, comprising: a bilaterally-expandable shell having a bilaterally-expandable head with 4 subheads, 4 flex rods, a slider guide, and a lumen, each of the 4 subheads operably connected to a respective flex rod, each of which operably attaches the slider-guide to it's respective subhead, the shell having a collapsed state and an expanded state; and,a shim configured for a proximal-to-distal axial translation in the lumen of the shell that induces a lateral force on the 4 subheads and a vertical force on the 4 subheads;wherein the shim hasa top wedge and a bottom wedge, each configured to laterally-expand the subheads;a first side wedge and a second side wedge, each configured to vertically-expand the subheads;the shim is configured to induce a lateral expansion followed by a vertical expansion; and,the distance, DSTAGING, of the axial translation between the onset of the lateral expansion and the onset of the vertical translation ranges from 2 mm to 10 mm. 2. A staged, bilaterally-expandable trial for an intervertebral space, comprising: a bilaterally-expandable shell having a bilaterally-expandable head with 4 subheads, 4 flex rods, a slider guide, and a lumen, each of the 4 subheads operably connected to a respective flex rod, each of which operably attaches the slider-guide to it's respective subhead, the shell having a collapsed state and an expanded state; and,a shim configured for a proximal-to-distal axial translation in the lumen of the shell that induces a lateral force on the 4 subheads and a vertical force on the 4 subheads;wherein the shim comprises a lateral-expansion wedge with angle θL ranging from 10° to 30° and a vertical-expansion wedge with angle θV ranging from 30° to 50°, the apex of the lateral-expansion wedge and the apex of the vertical-expansion wedge each at least substantially on a single plane that is orthogonal to the central axis of the shim, and the ratio of θV:θL ranges from 1:1.25 to 1:4 to stage the bilateral expansion of the head. 3. A staged, bilaterally-expandable trial for an intervertebral space, comprising: a bilaterally-expandable shell having a bilaterally-expandable head with 4 subheads, 4 flex rods, a slider guide, and a lumen, each of the 4 subheads operably connected to a respective flex rod, each of which operably attaches the slider-guide to it's respective subhead, the shell having a collapsed state and an expanded state; and,a shim configured for a proximal-to-distal axial translation in the lumen of the shell that induces a lateral force on the 4 subheads and a vertical force on the 4 subheads;wherein the wherein the shim comprises a lateral-expansion wedge with angle θL ranging from 10° to 90° and a vertical-expansion wedge with angle θV ranging from 10° to 90°, the apex of the lateral-expansion wedge on a first plane and the apex of the vertical expansion wedge on a second plane, both the first plane and the second plane being orthogonal to the central axis of the shim and separated on the central axis at a distance ranging from 2 mm to 10 mm to stage the bilateral expansion of the head. 4. A system for distracting an intervertebral space, the system comprising a bilaterally-expandable shell having a bilaterally-expandable head with 4 subheads, 4 flex rods, a slider guide, and a lumen, each of the 4 subheads operably connected to a respective flex rod, each of which operably attaches the slider-guide to it's respective subhead, the shell having a collapsed state and an expanded state;a shim configured for a proximal-to-distal axial translation in the lumen of the shell that induces a lateral force on the 4 subheads and a vertical force on the 4 subheads;an actuation bar, the actuation bar having a proximal portion with a proximal end, a distal portion with a distal end, and configured to transfer the axial proximal-to-distal force to the shim through the slider-guide; the shim configured to receive an axial proximal-to-distal force through the actuation bar for the axial translation; and,an actuation means operably attached to the proximal end of the actuation bar to transfer the axial proximal-to-distal force to the shim through the distal end of the actuation bar; wherein the shim has a top wedge and a bottom wedge, each configured to laterally-expand the subheads; a first side wedge and a second side wedge, each configured to vertically-expand the subheads; the shim is configured to induce a lateral expansion followed by a vertical expansion; and, the distance, DSTAGING, of the axial translation between the onset of the lateral expansion and the onset of the vertical translation ranges from 2 mm to 10 mm. 5. A system for distracting an intervertebral space, the system comprising a bilaterally-expandable shell having a bilaterally-expandable head with 4 subheads, 4 flex rods, a slider guide, and a lumen, each of the 4 subheads operably connected to a respective flex rod, each of which operably attaches the slider-guide to it's respective subhead, the shell having a collapsed state and an expanded state;a shim configured for a proximal-to-distal axial translation in the lumen of the shell that induces a lateral force on the 4 subheads and a vertical force on the 4 subheads;an actuation bar, the actuation bar having a proximal portion with a proximal end, a distal portion with a distal end, and configured to transfer the axial proximal-to-distal force to the shim through the slider-guide; the shim configured to receive an axial proximal-to-distal force through the actuation bar for the axial translation; and,an actuation means operably attached to the proximal end of the actuation bar to transfer the axial proximal-to-distal force to the shim through the distal end of the actuation bar;wherein the shim comprises a lateral-expansion wedge with angle θL ranging from 10° to 30° and a vertical-expansion wedge with angle θV ranging from 30° to 50°, the apex of the lateral-expansion wedge and the apex of the vertical-expansion wedge each at least substantially on a single plane that is orthogonal to the central axis of the shim, and the ratio of θV:θL ranges from 1:1.25 to 1:4 to stage the bilateral expansion of the head. 6. A system for distracting an intervertebral space, the system comprising a bilaterally-expandable shell having a bilaterally-expandable head with 4 subheads, 4 flex rods, a slider guide, and a lumen, each of the 4 subheads operably connected to a respective flex rod, each of which operably attaches the slider-guide to it's respective subhead, the shell having a collapsed state and an expanded state;a shim configured for a proximal-to-distal axial translation in the lumen of the shell that induces a lateral force on the 4 subheads and a vertical force on the 4 subheads;an actuation bar, the actuation bar having a proximal portion with a proximal end, a distal portion with a distal end, and configured to transfer the axial proximal-to-distal force to the shim through the slider-guide; the shim configured to receive an axial proximal-to-distal force through the actuation bar for the axial translation; and,an actuation means operably attached to the proximal end of the actuation bar to transfer the axial proximal-to-distal force to the shim through the distal end of the actuation bar;wherein the shim comprises a lateral-expansion wedge with angle θL ranging from 10° to 90° and a vertical-expansion wedge with angle θV ranging from 10° to 90°, the apex of the lateral-expansion wedge on a first plane and the apex of the vertical expansion wedge on a second plane, both the first plane and the second plane being orthogonal to the central axis of the shim and separated on the central axis at a distance ranging from 2 mm to 10 mm to stage the bilateral expansion of the head. 7. The trial of claim 1, wherein the head has a transverse cross-section in the collapsed state having a maximum dimension ranging from 5 mm to 18 mm for placing the frame in an intervertebral space through an annular opening for expansion in the intervertebral space; and,a transverse cross-section in the expanded state having a maximum dimension ranging from 6.5 to 28 mm in the intervertebral space;and,the shim has a transverse cross-section with a maximum dimension ranging from 5 mm to 18 mm for translating the shim in the lumen of the shell. 8. The trial of claim 1, wherein the shell is a single-unit formed from a single body of material, and the slider-guide, head, and flex rods are monolithically integral. 9. The trial of claim 1, wherein each subhead is operably connected to an adjacent subhead with a telescopic beam stabilizer. 10. The system of claim 4, each subhead is operably connected to an adjacent subhead with a telescopic beam stabilizer. 11. The system of claim 4, wherein the head has a transverse cross-section in the collapsed state having a maximum dimension ranging from 5 mm to 18 mm for placing the frame in an intervertebral space through an annular opening for expansion in the intervertebral space; and,a transverse cross-section in the expanded state having a maximum dimension ranging from 6.5 to 28 mm in the intervertebral space;and,the shim has a transverse cross-section with a maximum dimension ranging from 5 mm to 18 mm for translating the shim in the lumen of the shell. 12. The system of claim 4, wherein the shell is a single-unit formed from a single body of material, and the slider-guide, head, and flex rods are monolithically integral. 13. A method of distracting an intervertebral space, the method comprising: using a staged, bilaterally-expandable trial for an intervertebral space, comprising: a bilaterally-expandable shell having a bilaterally-expandable head with 4 subheads, 4 flex rods, a slider guide, and a lumen, each of the 4 subheads operably connected to a respective flex rod, each of which operably attaches the slider-guide to it's respective subhead, the shell having a collapsed state and an expanded state; and,a shim configured for a proximal-to-distal axial translation in the lumen of the shell that induces a lateral force on the 4 subheads and a vertical force on the 4 subheads;creating a point of entry into an intervertebral disc, the intervertebral disc having a nucleus pulposus surrounded by an annulus fibrosis, and the point of entry having the maximum lateral dimension created through the annulus fibrosis;removing the nucleus pulposus from within the intervertebral disc through the point of entry, leaving the intervertebral space for expansion of the head of the trial of claim 1 within the annulus fibrosis, the intervertebral space having the top vertebral plate and the bottom vertebral plate;inserting the head in the collapsed state through the point of entry into the intervertebral space; and,distracting the intervertebral space using a staged, bilateral expansion that includes a first stage and a second stage, the first stage including expanding the head laterally toward the peripheral zones of the top vertebral plate and the bottom vertebral plate; and,the second stage including expanding the head vertically to distract the intervertebral space. 14. The method of claim 13 further comprising retaining the trial with a retractable retention plunger and retracting the plunger to expand the trial. 15. The method of claim 13, wherein the lateral dimension of the point of entry ranges from about 5 mm to about 18 mm. 16. The method of claim 13, wherein the distracting includes selecting an amount of lateral expansion independent of an amount of vertical expansion. 17. The method of claim 13, wherein the distracting includes measuring the amount of lateral expansion independent of the amount of vertical expansion. 18. The trial of claim 2, wherein the head has a transverse cross-section in the collapsed state having a maximum dimension ranging from 5 mm to 18 mm for placing the frame in an intervertebral space through an annular opening for expansion in the intervertebral space; and,a transverse cross-section in the expanded state having a maximum dimension ranging from 6.5 to 28 mm in the intervertebral space;and,the shim has a transverse cross-section with a maximum dimension ranging from 5 mm to 18 mm for translating the shim in the lumen of the shell. 19. The trial of claim 3, wherein the head has a transverse cross-section in the collapsed state having a maximum dimension ranging from 5 mm to 18 mm for placing the frame in an intervertebral space through an annular opening for expansion in the intervertebral space; and,a transverse cross-section in the expanded state having a maximum dimension ranging from 6.5 to 28 mm in the intervertebral space;and,the shim has a transverse cross-section with a maximum dimension ranging from 5 mm to 18 mm for translating the shim in the lumen of the shell. 20. The trial of claim 2, wherein the shell is a single-unit formed from a single body of material, and the slider-guide, head, and flex rods are monolithically integral. 21. The trial of claim 3, wherein the shell is a single-unit formed from a single body of material, and the slider-guide, head, and flex rods are monolithically integral. 22. The trial of claim 2, wherein each subhead is operably connected to an adjacent subhead with a telescopic beam stabilizer. 23. The trial of claim 3, wherein each subhead is operably connected to an adjacent subhead with a telescopic beam stabilizer. 24. The system of claim 5, wherein the head has a transverse cross-section in the collapsed state having a maximum dimension ranging from 5 mm to 18 mm for placing the frame in an intervertebral space through an annular opening for expansion in the intervertebral space; and,a transverse cross-section in the expanded state having a maximum dimension ranging from 6.5 to 28 mm in the intervertebral space;and,the shim has a transverse cross-section with a maximum dimension ranging from 5 mm to 18 mm for translating the shim in the lumen of the shell. 25. The system of claim 6, wherein the head has a transverse cross-section in the collapsed state having a maximum dimension ranging from 5 mm to 18 mm for placing the frame in an intervertebral space through an annular opening for expansion in the intervertebral space; and,a transverse cross-section in the expanded state having a maximum dimension ranging from 6.5 to 28 mm in the intervertebral space;and,the shim has a transverse cross-section with a maximum dimension ranging from 5 mm to 18 mm for translating the shim in the lumen of the shell. 26. The system of claim 5, wherein the shell is a single-unit formed from a single body of material, and the slider-guide, head, and flex rods are monolithically integral. 27. The system of claim 6, wherein the shell is a single-unit formed from a single body of material, and the slider-guide, head, and flex rods are monolithically integral. 28. The system of claim 5, each subhead is operably connected to an adjacent subhead with a telescopic beam stabilizer. 29. The system of claim 6, each subhead is operably connected to an adjacent subhead with a telescopic beam stabilizer.
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