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Ahn, Lee, Park, Noh, and Lee: Efficiency and Safety of Demineralized Bone Matrix for Posterolateral Fusion
Original Article

Journal of the Korean Orthopaedic Association 2016; 51(3): 207-213.

Published online: 22 June 2016

DOI: https://doi.org/10.4055/jkoa.2016.51.3.207

Efficiency and Safety of Demineralized Bone Matrix for Posterolateral Fusion

Jae-Sung Ahn, M.D., Ho-Jin Lee, M.D., Eugene Park, M.D., Chang-Kyun Noh, M.D., Ki Young Lee, M.D.

Department of Orthopaedic Surgery, Chungnam National University School of Medicine, Daejeon, Korea.

Correspondence to: Ho-Jin Lee, M.D. Department of Orthopaedic Surgery, Chungnam National University School of Medicine, 266 Munhwa-ro, Jung-gu, Daejeon 35015, Korea. TEL: +82-42-280-7353, FAX: +82-42-252-7098, leeleo98@gmail.com

Received 7 November 2015       Revised 20 December 2015       Accepted 26 January 2016

Copyright © 2016 by The Korean Orthopaedic Association

(open-access):

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Purpose

The purpose of this study is to analyze the effects of demineralized bone matrix on posterolateral lumbar fusion.

Materials and Methods

From 2009 to 2012, 30 patients who had undergone posterolateral fusions using demineralized bone matrix (group I) and 30 who had received autogenous posterior iliac bone grafts (group II) were investigated. Bone union was determined by evaluating serial simple lumbar radiographs taken during the 24 months after surgery. Bone status was classified according to Lenke's scale and the bone fusion was finally determined by flexion/extension lateral radiographs. We also examined halo signs around the pedicular screws evident on the radiographs, scored back pain using a visual analogue scale (VAS), and Oswestry disability index (ODI) score 2 years after surgery to evaluate clinical status of patients.

Results

In group I, 19 patients showed union and 11 patients did not; the values for group II were 22 and 8. These proportions did not differ significantly (p=0.57). Time to union was somewhat shorter in group II (25.3±7.9 weeks), but did not differ significantly from that of group I (p=0.097). No statistical significance in the periscrew Halo count, VAS for back pain, and ODI score was observed between the two groups.

Conclusion

The union rate after using demineralized bone matrix for lumbar posterolateral fusion is similar to that attained when autogenous bone grafts are employed, and lacks the morbidity associated with such grafts. Thus, demineralized bone matrix is an effective bone graft substitute when posterolateral fusion surgery of the lumbar spine is required.

Keywords: lumbar vertebrae, posterior vertebral fusion, demineralized bone matrix, fusion rate

Figures and Tables

Fig. 1

A 71-year-old female with degenerative lumbar disease underwent surgery with posterior decompression and posterolateral fusion using autogenous posterior iliac bone graft mixed with local bone. (A) Initial anteroposterior and lateral radiographs show degenerative lumbar disease with L4–5 anterolisthesis. (B) Postoperative anteroposterior and lateral radiographs show that the posterior laminectomy and posterolateral fusions were done on the level of L3–4–5–S1. (C) At 30 weeks after the operation, anteroposterior and lateral radiographs show that the fusion mass was formed bilaterally, which was defined as Lenke's scale A. (D) There was no significant translation and angulation on the flexion-extension lateral radiographs at 30 weeks after surgery.

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Table 1

Lenke's Scale*

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*Data from the article of Lenke et al. (J Bone Joint Surg Am. 1992;74:1056-67).25)

Table 2

Demographic Data

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Values are presented as mean±standard deviation, number (%), or number only. *Undergone posterolateral fusions using demineralized bone matrix (n=30). Received autogenous posterior iliac bone grafts (n=30).

Table 3

Results

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Values are presented as number (%) or mean±standard deviation. *Undergone posterolateral fusions using demineralized bone matrix (n=30). Received autogenous posterior iliac bone grafts (n=30). VAS, visual analog scale; ODI, Oswestry disability index.

Notes

CONFLICTS OF INTEREST The authors have nothing to disclose.

References

1. Cloward RB. Lesions of the intervertebral disks and their treatment by interbody fusion methods. The painful disk. Clin Orthop Relat Res. 1963; 27:51–77.
2. Bono CM, Lee CK. Critical analysis of trends in fusion for degenerative disc disease over the past 20 years: influence of technique on fusion rate and clinical outcome. Spine (Phila Pa 1976). 2004; 29:455–463. discussion Z5.
3. Dawson EG, Lotysch M 3rd, Urist MR. Intertransverse process lumbar arthrodesis with autogenous bone graft. Clin Orthop Relat Res. 1981; (154):90–96.
crossref
4. Dick HM, Strauch RJ. Infection of massive bone allografts. Clin Orthop Relat Res. 1994; (306):46–53.
5. Gupta AR, Shah NR, Patel TC, Grauer JN. Perioperative and long-term complications of iliac crest bone graft harvesting for spinal surgery: a quantitative review of the literature. Int Med J. 2001; 8:163–166.
6. Wiltberger BR. Intervertebral body fusion by the use of posterior bone dowel. Clin Orthop Relat Res. 1964; 35:69–79.
crossref
7. Summers BN, Eisenstein SM. Donor site pain from the ilium. A complication of lumbar spine fusion. J Bone Joint Surg Br. 1989; 71:677–680.
crossref
8. Bucholz RW, Carlton A, Holmes RE. Hydroxyapatite and tricalcium phosphate bone graft substitutes. Orthop Clin North Am. 1987; 18:323–334.
crossref
9. Lane JM, Bostrom MP. Bone grafting and new composite biosynthetic graft materials. Instr Course Lect. 1998; 47:525–534.
10. Lee SK, Kim CH, Cheong JH, Bak KH, Kim JM, Oh SJ. Efficacy of calcium sulfate pellets as bone graft substitute in lumbar posterolateral fusion. J Korean Neurosurg Soc. 2001; 30:605–610.
11. An HS, Simpson JM, Glover JM, Stephany J. Comparison between allograft plus demineralized bone matrix versus autograft in anterior cervical fusion. A prospective multicenter study. Spine (Phila Pa 1976). 1995; 20:2211–2216.
12. Vaccaro AR, Stubbs HA, Block JE. Demineralized bone matrix composite grafting for posterolateral spinal fusion. Orthopedics. 2007; 30:567–570.
crossref
13. Rosenthal RK, Folkman J, Glowacki J. Demineralized bone implants for nonunion fractures, bone cysts, and fibrous lesions. Clin Orthop Relat Res. 1999; 364:61–69.
crossref
14. Vaccaro AR, Chiba K, Heller JG, et al. Bone grafting alternatives in spinal surgery. Spine J. 2002; 2:206–215.
crossref
15. Schimandle JH, Boden SD. Bone substitutes for lumbar fusion: present and future. Oper Tech Orthop. 1997; 7:60–67.
16. Pacaccio DJ, Stern SF. Demineralized bone matrix: basic science and clinical applications. Clin Podiatr Med Surg. 2005; 22:599–606. vii
crossref
17. Girardi FP, Cammisa FP Jr. The effect of bone graft extenders to enhance the performance of iliac crest bone grafts in instrumented lumbar spine fusion. Orthopedics. 2003; 26:s545–s548.
crossref
18. c J, Murakami H, Kim HS, Minamide A, Boden SD. Evidence of osteoinduction by Grafton demineralized bone matrix in nonhuman primate spinal fusion. Spine (Phila Pa 1976). 2004; 29:360–366. discussion Z1.
19. Martin GJ Jr, Boden SD, Titus L, Scarborough NL. New formulations of demineralized bone matrix as a more effective graft alternative in experimental posterolateral lumbar spine arthrodesis. Spine (Phila Pa 1976). 1999; 24:637–645.
crossref
20. Helm GA, Sheehan JM, Sheehan JP, et al. Utilization of type I collagen gel, demineralized bone matrix, and bone morphogenetic protein-2 to enhance autologous bone lumbar spinal fusion. J Neurosurg. 1997; 86:93–100.
crossref
21. Sassard WR, Eidman DK, Gray PM, et al. Augmenting local bone with Grafton demineralized bone matrix for posterolateral lumbar spine fusion: avoiding second site autologous bone harvest. Orthopedics. 2000; 23:1059–1064. discussion 1064-5.
crossref
22. Wildemann B, Kadow-Romacker A, Haas NP, Schmidmaier G. Quantification of various growth factors in different demineralized bone matrix preparations. J Biomed Mater Res A. 2007; 81:437–442.
crossref
23. Intini G, Andreana S, Buhite RJ, Bobek LA. A comparative analysis of bone formation induced by human demineralized freeze-dried bone and enamel matrix derivative in rat calvaria critical-size bone defects. J Periodontol. 2008; 79:1217–1224.
crossref
24. Bae H, Zhao L, Zhu D, Kanim LE, Wang JC, Delamarter RB. Variability across ten production lots of a single demineralized bone matrix product. J Bone Joint Surg Am. 2010; 92:427–435.
crossref
25. Lenke LG, Bridwell KH, Baldus C, Blanke K, Schoenecker PL. Cotrel-Dubousset instrumentation for adolescent idiopathic scoliosis. J Bone Joint Surg Am. 1992; 74:1056–1067.
crossref
26. Peterson B, Whang PG, Iglesias R, Wang JC, Lieberman JR. Osteoinductivity of commercially available demineralized bone matrix. Preparations in a spine fusion model. J Bone Joint Surg Am. 2004; 86-A:2243–2250.
27. Choi DJ, Ahn DK, Lee S, et al. The effect of demineralized bone matrix as a graft enhancer in posterior lumbar interbody fusion using cage and local bone chips. J Korean Soc Spine Surg. 2008; 15:157–164.
crossref
28. Glowacki J. A review of osteoinductive testing methods and sterilization processes for demineralized bone. Cell Tissue Bank. 2005; 6:3–12.
crossref
29. Russell JL, Block JE. Clinical utility of demineralized bone matrix for osseous defects, arthrodesis, and reconstruction: impact of processing techniques and study methodology. Orthopedics. 1999; 22:524–531. quiz 532-3.
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