Goat bone tissue engineering: Comparing an intramuscular with a posterolateral lumbar spine location

Tissue Engineering - Part A

Volumn 16, Issue 2, 2010, Pages 685-693

  Van Gaalen, Steven M ^a   Dhert, Wouter J A ^a,b   Kruyt, Moyo C ^a   Yuan, Huipin ^c   Oner, F Cumhur ^a   Van Blitterswijk, Clemens A ^c   Verbout, Abraham J ^a   De Bruijn, Joost D ^d,e  

^a UNIVERSITY MEDICAL CENTER UTRECHT   (Netherlands)

^b UTRECHT UNIVERSITY   (Netherlands)

^c UNIVERSITY OF TWENTE   (Netherlands)

^d QUEEN MARY UNIVERSITY OF LONDON   (United Kingdom)

^e Progentix Orthobiology BV   (Netherlands)

Author keywords

[No Author keywords available]

Indexed keywords

BONE; CALCIUM; CALCIUM ALLOYS; CALCIUM PHOSPHATE; LOCATION; PHOSPHATES; SCAFFOLDS; TISSUE ENGINEERING;

BIPHASIC CALCIUM PHOSPHATES; BONE FORMATION; BONE MARROW; BONE TISSUE ENGINEERING; CALCIUM PHOSPHATE SCAFFOLDS; CELL-BASED; CONTROL GROUPS; CONTROL SAMPLES; FLUOROCHROMES; IMPLANT LOCATION; LUMBAR SPINES; PARASPINAL; PARASPINAL MUSCLES; POROUS BLOCKS; SPINE FUSION; STROMAL CELLS; UP TIME;

CELLS;

CAPRA HIRCUS;

ANIMAL; ARTICLE; COMPARATIVE STUDY; CYTOLOGY; GOAT; IMPLANT; INTRAMUSCULAR DRUG ADMINISTRATION; LUMBAR VERTEBRA; METHODOLOGY; MUSCLE; PHYSIOLOGY; STROMA CELL; THREE DIMENSIONAL IMAGING; TIME; TISSUE ENGINEERING; TRANSPLANTATION;

ANIMALS; GOATS; IMAGING, THREE-DIMENSIONAL; IMPLANTS, EXPERIMENTAL; INJECTIONS, INTRAMUSCULAR; LUMBAR VERTEBRAE; MUSCLES; STROMAL CELLS; TIME FACTORS; TISSUE ENGINEERING;

EID: 77049115035     PISSN: 19373341     EISSN: 1937335X     Source Type: Journal    
DOI: 10.1089/ten.tea.2009.0073     Document Type: Conference Paper

References (47)

1. Bauer, T.W., and Muschler, G.F. Bone graft materials. An overview of the basic science. Clin Orthop 371, 10, 2000.
2. Boden, S.D. Overview of the biology of lumbar spine fusion and principles for selecting a bone graft substitute. Spine 27, S26, 2002.
3. Meijer, G.J., de Bruijn, J.D., Koole, R., and Van Blitterswijk, C.A. Cell-based bone tissue engineering. PLoS Med 4, 260, 2007.
4. Marcacci, M., Kon, E., Moukhachev, V., Lavroukov, A., Kutepov, S., Quarto, R., Mastrogiacomo, M., and Cancedda, R. Stem cells associated with macroporous bioceramics for long bone repair: 6-to 7-year outcome of a pilot clinical study. Tissue Eng 13, 947, 2007.
5. Shang, Q., Wang, Z., Liu, W., Shi, Y., Cui, L., and Cao, Y. Tissue-engineered bone repair of sheep cranial defects with autologous bone marrow stromal cells. J Craniofac Surg 12, 586-593; discussion 94-95, 2001.
6. Schliephake, H., Knebel, J.W., Aufderheide, M., and Tau-scher, M. Use of cultivated osteoprogenitor cells to increase bone formation in segmental mandibular defects: an experimental pilot study in sheep. Int J Oral Maxillofac Surg 30, 531, 2001.
7. Yuan, J., Cui, L., Zhang, W.J., Liu, W., and Cao, Y. Repair of canine mandibular bone defects with bone marrow stromal cells and porous beta-tricalcium phosphate. Biomaterials 28, 1005, 2007.
8. Zhu, L., Liu, W., Cui, L., and Cao, Y. Tissue-engineered bone repair of goat-femur defects with osteogenically induced bone marrow stromal cells. Tissue Eng 12, 423, 2006.
9. Kon, E., Muraglia, A., Corsi, A., Bianco, P., Marcacci, M., Martin, I., Boyde, A., Ruspantini, I., Chistolini, P., Rocca, M., Giardino, R. Cancedda, R., and Quarto, R. Autologous bone marrow stromal cells loaded onto porous hydroxyapatite ceramic accelerate bone repair in critical-size defects of sheep long bones. J Biomed Mater Res 49, 328, 2000.
10. Mastrogiacomo, M., Corsi, A., Francioso, E., Di Comite, M., Monetti, F., Scaglione, S., Favia, A., Crovace, A., Bianco, P., and Cancedda, R. Reconstruction of extensive long bone defects in sheep using resorbable bioceramics based on silicon stabilized tricalcium phosphate. Tissue Eng 12, 1261, 2006.
11. Petite, H., Viateau, V., Bensaid, W., Meunier, A., de Pollak, C., Bourguignon, M., Oudina, K., Sedel. L., and Guillemin, G. Tissue-engineered bone regeneration. Nat Biotechnol 18, 959, 2000.
12. Viateau, V., Guillemin, G., Yang, Y.C., Bensaid, W., Reviron, T., Oudina, K., Meunier, A., Sedel, L., and Petite, H. A technique for creating critical-size defects in the metatarsus of sheep for use in investigation of healing of long-bone defects. Am J Vet Res 65, 1653, 2004.
13. Bensaid, W., Oudina, K., Viateau, V., Potier, E., Bousson, V., Blanchat, C., Sedel, L., Guillemin, G., and Petite, H. De novo reconstruction of functional bone by tissue engineering in the metatarsal sheep model. Tissue Eng 11, 814, 2005.
14. Muschler, G.F., Nitto, H., Matsukura, Y., Boehm, C., Val-devit, A., Kambic, H., Davros, W., Powell, K., and Easley, K. Spine fusion using cell matrix composites enriched in bone marrow-derived cells. Clin Orthop Relat Res 407, 102, 2003.
15. Gupta, M.C., Theerajunyaporn, T., Maitra, S., Schmidt, M.B., Holy, C.E., Kadiyala, S., and Bruder, S.P. Efficacy of mes-enchymal stem cell enriched grafts in an ovine posterolateral lumbar spine model. Spine 32, 720-726; discussion 7, 2007.
16. Morone, M.A., Boden, S.D., Hair, G., Martin, G.J., Jr., Racine, M., Titus, L., and Hutton, W.C. The Marshall R. Urist Young Investigator Award. Gene expression during autograft lumbar spine fusion and the effect of bone morphogenetic protein 2. Clin Orthop 351, 252, 1998.
17. Sandhu, H.S., and Khan, S.N. Animal models for preclinical assessment of bone morphogenetic proteins in the spine. Spine 27, S32, 2002.
18. Reichert, J.C., Saifzadeh, S., Wullschleger, M.E., Epari, D.R., Schutz, M.A., Duda, G.N., Schell, H., van Griensven, M., Redl, H., and Hutmacher, D.W. The challenge of establishing preclinical models for segmental bone defect research. Biomaterials 30, 2149, 2009.
19. Kruyt, M.C., de Bruijn, J.D., Wilson, C.E., Oner, F.C., van Blitterswijk, C.A., Verbout, A.J., and Dhert, W.J. Viable os-teogenic cells are obligatory for tissue-engineered ectopic bone formation in goats. Tissue Eng 9, 327, 2003.
20. Kruyt, M.C., de Bruijn, J.D., Yuan, H., van Blitterswijk, C.A., Verbout, A.J., Oner, F.C., and Dhert, W.J. Optimization of bone tissue engineering in goats: a perioperative seeding method using cryopreserved cells and localized bone formation in calcium phosphate scaffolds. Transplantation 77, 359, 2004.
21. Kruyt, M.C., Dhert, W.J., Yuan, H., Wilson, C.E., van Blit-terswijk, C.A., Verbout, A.J., and de Bruijn, J.D. Bone tissue engineering in a critical size defect compared to ectopic implantations in the goat. J Orthop Res 22, 544, 2004.
22. Kruyt, M.C., Dhert, W.J., Oner, F.C., van Blitterswijk, C.A., Verbout, A.J., and de Bruijn, J.D. Analysis of ectopic and orthotopic bone formation in cell-based tissue-engineered constructs in goats. Biomaterials 28, 1798, 2007.
23. Johnston, C.E., 2nd, Ashman, R.B., Baird, A.M., and Allard, R.N. Effect of spinal construct stiffness on early fusion mass incorporation. Experimental study. Spine 15, 908, 1990.
24. Kotani, Y., Cunningham, B.W., Cappuccino, A., Kaneda, K., and McAfee, P.C. The role of spinal instrumentation in augmenting lumbar posterolateral fusion. Spine 21, 278, 1996.
25. Yuan, H., van Blitterswijk, C.A., de Groot, K., and de Bruijn, J.D. A comparison of bone formation in biphasic calcium phosphate (BCP) and hydroxyapatite (HA) implanted in muscle and bone of dogs at different time periods. J Biomed Mater Res A 78, 139, 2006.
26. Yuan, H., Van Den Doel, M., Li, S., Van Blitterswijk, C.A., De Groot, K., and De Bruijn, J.D. A comparison of the osteoinductive potential of two calcium phosphate ceramics implanted intramuscularly in goats. J Mater Sci Mater Med 13, 1271, 2002.
27. Yuan, H., van Blitterswijk, C.A., de Groot, K., and de Bruijn, J.D. Cross-species comparison of ectopic bone formation in biphasic calcium phosphate (BCP) and hydroxyapatite (HA) scaffolds. Tissue Eng 12, 1607, 2006.
28. de Bruijn, J.D., van den Brink, I., Bovell, Y.P., and van Blit-terswijk, C.A. Tissue engineering of goat bone: osteogenic potential of goat bone marrow cells. In: LeGeros, R., ed. Bioceramics. World Scientific Publishing Corporation Pte. Ltd., Singapore, 1998, pp. 497-500.
29. Freshney, R. Culture of Animal Cells: A Manual of Basic Technique. New York: Alan R. Liss, Inc., 1987.
30. Boden, S.D., Schimandle, J.H., Hutton, W.C., and Chen, M.I. Volvo Award in basic sciences. The use of an osteoinductive growth factor for lumbar spinal fusion. Part I: biology of spinal fusion. Spine 20, 2626, 1995.
31. Kruyt, M.C., Wilson, C.E., de Bruijn, J.D., van Blitterswijk, C.A., Oner, C.F., Verbout, A.J., and Dhert, W.J. The effect of cell-based bone tissue engineering in a goat transverse process model. Biomaterials 27, 5099, 2006.
32. Parfitt, A.M., Drezner, M.K., Glorieux, F.H., Kanis, J.A., Malluche, H., Meunier, P.J., Ott, S.M., and Reckcr, R.R. Bone histomorphometry: standardization of nomenclature, symbols, and units. Report of the ASBMR Histomorphometry Nomenclature Committee. J Bone Miner Res 2, 595, 1987.
33. Patel, N., Best, S.M., Bonfield, W., Gibson, I.R., Hing, K.A., Damien, E., and Revell, P.A. A comparative study on the in vivo behavior of hydroxyapatite and silicon substituted hydroxyapatite granules. J Mater Sci Mater Med 13, 1199, 2002.
34. Kruyt, M.C., Delawi, D., Habibovic, P., Oner, F.C., van Blitterswijk, C.A., and Dhert, W.J. Relevance of bone graft viability in a goat transverse process model. J Orthop Res 27, 1055, 2009.
35. Toribatake, Y., Hutton, W.C., Tomita, K., and Boden, S.D. Vascularization of the fusion mass in a posterolateral inter-transverse process fusion. Spine 23, 1149, 1998.
36. Stevenson, S., Emery, S.E., and Goldberg, V.M. Factors affecting bone graft incorporation. Clin Orthop Relat Res 324, 66, 1996.
37. Feiertag, M.A., Boden, S.D., Schimandle, J.H., and Norman, J.T. A rabbit model for nonunion of lumbar intertransverse process spine arthrodesis. Spine 21, 27, 1996.
38. Emery, S.E., Brazinski, M.S., Koka, A., Bensusan, J.S., and Stevenson, S. The biological and biomechanical effects of irradiation on anterior spinal bone grafts in a canine model. J Bone Joint Surg Am 76, 540, 1994.
39. Boden, S.D., Schimandle, J.H., and Hutton, W.C. An experimental lumbar intertransverse process spinal fusion model. Radiographic, histologic, and biomechanical healing characteristics. Spine 20, 412, 1995.
40. An, H.S., Lynch, K., and Toth, J. Prospective comparison of autograft vs. allograft for adult posterolateral lumbar spine fusion: differences among freeze-dried, frozen, and mixed grafts. J Spinal Disord 8, 131, 1995.
41. Azuma, T., Yasuda, H., Okagaki, K., and Sakai, K. Compressed allograft chips for acetabular reconstruction in revision hip arthroplasty. J Bone Joint Surg Br 76, 740, 1994.
42. Schreurs, B.W., Arts, J.J., Verdonschot, N., Buma, P., Slooff, T.J., and Gardeniers, J.W. Femoral component revision with use of impaction bone-grafting and a cemented polished stem. Surgical technique. J Bone Joint Surg Am 88 Suppl 1 Pt 2, 259, 2006.
43. Bear, J. Dynamics of Fluids in Porous Media. Dover Publications, Inc., Mineola, N.Y. 1988.
44. Hurley, L.A., Stinchfield, F.E., and Bassett, A.L. The role of soft tissues in osteogenesis. J Bone Joint Surg Am 41A, 1243, 1959.
45. Boden, S.D., Martin, G.J., Jr., Morone, M.A., Ugbo, J.L., and Moskovitz, P.A. Posterolateral lumbar intertransverse process spine arthrodesis with recombinant human bone morphoge-netic protein 2=hydroxyapatite-tricalcium phosphate after laminectomy in the nonhuman primate. Spine 24, 1179, 1999.
46. Ripamonti, U., Crooks, J., Khoali, L., and Roden, L. The induction of bone formation by coral-derived calcium carbonate=hydroxyapatite constructs. Biomaterials 30, 1428, 2009.
47. Minamide, A., Yoshida, M., Kawakami, M., Yamasaki, S., Kojima, H., Hashizume, H., and Boden, S.D. The use of cultured bone marrow cells in type I collagen gel and porous hydroxyapatite for posterolateral lumbar spine fusion. Spine 30, 1134, 2005.