Silicon Matrix Calcium Phosphate as a Bone Substitute: Early Clinical and Radiological Results in a Prospective Study With 12-Month Follow-up

SAS Journal

Volumn 2, Issue 2, 2008, Pages 62-68

  Pimenta, Luiz ^a   Pesántez, Carlos Fernando Arias ^a   Oliveira, Leonardo ^a  

^a Santa Rita Hospital   (Brazil)

Author keywords

bone substitute; silicon matrix calcium phosphate; Spinal fusion graft

Indexed keywords

APATITE; CALCIUM PHOSPHATE; NANOCRYSTAL; RECOMBINANT BONE MORPHOGENETIC PROTEIN 2; SILICON;

ADULT; AGED; ARTICLE; BONE PROSTHESIS; CLINICAL ARTICLE; COMPUTER ASSISTED TOMOGRAPHY; CONTROLLED STUDY; DEGENERATIVE DISEASE; FOLLOW UP; HUMAN; IMPLANTATION; LUMBAR SPINE; NUCLEAR MAGNETIC RESONANCE IMAGING; OUTCOME ASSESSMENT; PHYSIOLOGY; POSTOPERATIVE PERIOD; PREOPERATIVE PERIOD; PRIORITY JOURNAL; PROSPECTIVE STUDY; RADIOGRAPHY; RADIOLOGIST; SPINE FUSION; VISUAL ANALOG SCALE; X RAY;

EID: 77949851472     PISSN: 19359810     EISSN: None     Source Type: Journal    
DOI: 10.1016/S1935-9810(08)70020-3     Document Type: Article

References (25)

1. Becker S., Maissen O., Ponomarev I., Stoll T., Rahn B., and Wilke I. Osteopromotion by a beta-tricalcium phosphate/bone marrow hybrid implant for use in spine surgery. Spine 31 1 (2006) 11-17
2. McConnell J.R., Freeman B.J., Debnath U.K., Grevitt M.P., Prince H.G., and Webb J.K. A prospective randomized comparison of coralline hydroxyapatite with autograft in cervical interbody fusion. Spine 28 4 (2003) 317-323
3. Delecrin J., Takahashi S., Gouin F., and Passuti N. A synthetic porous ceramic as a bone graft substitute in the surgical management of scoliosis: a prospective, randomized study. Spine 25 5 (2000) 563-569
4. Whang P., and Wang J. Bone graft substitutes for spinal fusion. Spine J 3 2 (2003) 155-156
5. Hing K.A., Merry J.C., Gibson I.R., Di-Silvio L., Best S.M., and Bonfield W. In: Ohgushi H., Hastings G.W., and Yoshikawa T. (Eds). Bioceramics Volume 12 (1999), World Scientific, Singapore 195-198
6. Gibson I., Huang J., Best S.M., and Bonfield W. In: Ohgushi H., Hastings G.W., and Yoshikawa T. (Eds). Bioceramics Volume 12 (1999), World Scientific, Singapore 191-194
7. El-Ghannam A.R. Advanced bioceramic composite for bone tissue engineering: design principles and structure-bioactivity relationship. J Biomed Mater Res A 69 3 (2004) 490-501
8. Bohner M. Physical and chemical aspects of calcium phosphates used in spinal surgery. In: Gunzburg R., Szpaliski M., Passuti N., and Aebi M. (Eds). The Use of Bone Substitutes in Spine Surgery (2001), Springer, Warren, MI 30-37
9. Hing K.A., Gibson I.R., Revell P.A., Best S.M., and Bonfield W. In: Giannini S., and Moroni A. (Eds). Bioceramics Volume 13 (2000), Trans Tech, Stafa-Zurich, Switzerland 373-376
10. Yuan H., De Bruijn J.D., Li Y., et al. Bone formation induced by calcium phosphate ceramics in soft tissue of dogs: a comparative study between porous alpha-TCP and beta-TCP. J Mater Sci Mater Med 12 1 (2001) 7-13
11. Fairbank J.C., and Pynsent P.B. The Oswestry Disability Index. Spine 25 (2000) 2940-2952
12. Boden S.D., Zdeblick T.A., Sandhu H.S., and Heim S.E. The use of rhBMP-2 in interbody fusion cages. Definitive evidence of osteoinduction in humans: a preliminary report. Spine 25 3 (2000) 376-381
13. Langstaff S., Sayer M., Smith T.J., and Pugh S.M. Resorbable bioceramics based on stabilized calcium phosphates. Part II: evaluation of biological response. Biomaterials 22 2 (2001) 135-150
14. El-Ghannam A., and Ning C.Q. Effect of bioactive ceramic dissolution on the mechanism of bone mineralization and guided tissue growth in vitro. J Biomed Mater Res A 76 2 (2006) 386-397
15. Wheeler D.L., Jenis L.G., Kovach M.E., Marini J., and Turner A.S. Efficacy of silicated calcium phosphate graft in posterolateral lumbar fusion in sheep. Spine J 7 3 (2007) 308-317
16. Carlisle E.M. Silicon: a requirement in bone formation independent of vitamin D1. Calc Tiss Int 33 (1981) 27-34
17. Carlisle E.M. Silicon: a possible factor in bone calcification. Science 167 (1970) 279-280
18. Ackerman S.J., Mafilios M.S., and Polly Jr. D.W. Economic evaluation of bone morphogenetic protein versus autogenous iliac crest bone graft in singlelevel anterior lumbar fusion: an evidence-based modeling approach. Spine 27 16 Suppl 1 (2002) S94-S99
19. Polly Jr. D.W., Ackerman S.J., Shaffrey C.I., et al. A cost analysis of bone morphogenetic protein versus autogenous iliac crest bone graft in singlelevel anterior lumbar fusion. Orthopedics 26 10 (2003) 1027-1037
20. Gibson I.R., Best S.M., and Bonfield W. Chemical characterization of siliconsubstituted hydroxyapatite. J Biomed Mat Res 44 4 (1999) 422-428
21. Korovessis P., Koureas G., Zacharatos S., Papazisis Z., and Lambiris E. Correlative radiological, self-assessement and clinical analysis of evolution in instrumented dorsal and lateral fusion for degenerative lumbar spine disease. Autograft versus coralline hydroxapatite. Eur Spine J 14 7 (2005) 630-638
22. Montgomery D.M., Aronson D.D., Lee C.L., and LaMont R.L. Posterior spinal fusion: allograft versus autograft bone. J Spinal Disord 3 4 (1990) 370-375
23. Li P., Ohtsuki C., Kokubo T., et al. Apatite formation induced by silica gel in simulated body fluid. J Am Ceram Soc 75 8 (1992) 2094-2097
24. Radin S., Falazie S., Lee M.H., and Ducheyne O. In vitro bioactivity and degradation behavior of silica xerogels intended as controlled release materials. Biomaterials 23 15 (2002) 3113-3122
25. Burkus J.K., Heim S.E., Gornet M.F., and Zdeblick T.A. Is INFUSE bone graft superior to autograft bone? An integrated analysis of clinical trials using the LT-CAGE lumbar tapered fusion device. J Spinal Disorders Tech 16 2 (2003) 113-122