Tissue engineering for osteochondral defects

Tissue Engineering and Regenerative Medicine

Volumn 5, Issue 4-6, 2008, Pages 552-558

  Im, Gun Il ^a  

^a Dongguk University Ilsan Hospital   (South Korea)

Author keywords

Biphasic scaffold; Osteochondral defect; Tissue engineering

Indexed keywords

EID: 84884570350     PISSN: 17382696     EISSN: 22125469     Source Type: Journal    
DOI: None     Document Type: Article

References (61)

1. X Wang, SP Grogan, F Rieser, et al., Tissue engineering of biphasic cartilage constructs using various biodegradable scaffolds: an in vitro study, Biomaterials, 25(17), 3681 (2004).
2. R Tuli, S Nandi, WJ Li, et al, Human mesenchymal progenitor cell-based tissue engineering of a singleunit osteochondral construct, Tissu e En g, 10(7-8), 1169 (2004).
3. D Schaefer, I Martin, P Shastri, et al., in vitro generation of osteochondral composites, Biomaterials, 21(24), 2599 (2000).
4. J Gao, JE Dennis, LA Solchaga, et al., Tissue-engineered fabrication of an osteochondral composite graft using rat bone marrow-derived mesenchymal stem cells, Tissue Eng, 7(4), 363 (2001).
5. WW Lee, JS Park, HJ Do, et al, Inducement of chondrogenic differentiation in injectable hydrogels embedded in mouse embryonic stem cells and growth factor for neocartilage formation, Tissue Eng Regen Med, 5(1), 103 (2008).
6. RM Schek, JM Taboas, SJ Segvich, et al., Engineered osteochondral grafts using biphasic composite solid free-form fabricated scaffolds, Tissue Eng, 10(9-10), 1376 (2004).
7. Z Park, S Kim, MJ Kim, et al., Chondrogenic differentiation of human embryonic stem cells by hSOX9 overexpression, Tissue Eng Regen Med, 5(1), 109 (2008).
8. T Cao, KH Ho, SH Teoh, Scaffold design and in vitro study of osteochondral coculture in a three-dimensional porous polycaprolactone scaffold fabricated by fused deposition modeling, Tissue Eng, 9(Suppl 1), S103(2003).
9. A Fukuda, K Kato, M Hasegawa, et al., Enhanced repair of large osteochondral defects using a combination of artificial cartilage and basic fibroblast growth factor, Biomaterials, 26(20), 4301 (2005).
10. JL Koh, K Wirsing, E Lautenschlager, et al., The effect of graft height mismatch on contact pressure following osteochondral grafting: a biomechanical study, Am J Sports Med, 32(2), 317 (2004).
11. N Adachi, M Ochi, Y Uchio, et al., Osteochondral lesion located at the lateral femoral condylereconstructed by the transplantation of tissue-engineered cartilage in combination with a periosteum with bone block: a case report, Knee Surgery, Sports Traumatology, Arthroscopy, 12(5), 444 (2004).
12. G Khang, SH Kim, MS Kim, et al., Recent and future directions of stem cells for the application of regenerative medicine, Tissue Eng Regen Med, 4, 441 (2007).
13. TB Woodfield, J Malda, J de Wijn, et al., Design of porous scaffolds for cartilage tissue engineering using a three-dimensional fiber-deposition technique, Biomaterials, 25(18), 4149 (2004).
14. SH Kim, AY Oh, JH Choi, et al, Recent advances in manufacturing method of smart scaffold for regenerative medicine, Tissue Eng Regen Med, 5(3), 351 (2008).
15. A Lendlein, R Langer, Biodegradable, elastic shape-memory polymers for potential biomedical applications, Science, 296(5573), 1673 (2002).
16. AJ Thornton, E Alsberg, M Albertelli, et al., Shape-defining scaffolds for minimally invasive tissue engineering, Transplantation, 77(12), 1798 (2004).
17. JY Lee, JS Lee, Y Son, Morphological and histological characteristics for various types of cartilages, Tissue Eng Regen Med, 3(4), 404 (2006).
18. A Chenite, C Chaput, D Wang, et al., Novel injectable neutral solutions of chitosan form biodegradable gels in situ, Biomaterials, 21, 2155 (2000).
19. M Sittinger, DW Hutmacher, MV Risbud, Current strategies for cell delivery in cartilage and bone regeneration, Current Opinion Biotech, 15(5), 411 (2004).
20. PD Benya, JD Shaffer, Dedifferentiated chondrocytes reexpress the differentiated collagen phenotype when cultured in agarose gels, Cell, 30(1), 215 (1982).
21. F Binette, DP McQuaid, DR Haudenschild, et al., Expression of a stable articular cartilage phenotype without evidence of hypertrophy by adult human articular chondrocytes in vitro, J Orthopaedic Res, 16(2), 207 (1998).
22. M Jakob, O Demarteau, D Schafer, et al., Specific growth factors during the expansion and redifferentiation of adult human articular chondrocytes enhance chondrogenesis and cartilaginous tissue formation in vitro, J Cellular Biochem, 81(2), 368 (2001).
23. M Jakob, O Demarteau, R Suetterlin, et al., Chondrogenesis of expanded adult human articular chondrocytes is enhanced by specific prostaglandins, Rheumatology, 43(7), 852 (2004).
24. CR Lee, AJ Grodzinsky, HP Hsu, et al., Effects of harvest and selected cartilage repair procedures on the physical and biochemical properties of articular cartilage in the canine knee, J Orthopaedic Res, 18(5), 790 (2000).
25. W Kafienah, M Jakob, O Demarteau, et al., Three-dimensional tissue engineering of hyaline cartilage: comparison of adult nasal and articular chondrocytes, Tissue Eng, 8(5), 817 (2002).
26. AG Tay, J Farhadi, R Suetterlin, et al., Cell yield, proliferation and postexpansion differentiationcapacity of human ear, nasal, and rib chondrocytes, Tissue Eng, 10(5-6), 762 (2004).
27. GJ Van Osch, EW Mandl, H Jahr, et al., Considerations on the use of ear chondrocytes as donor chondrocytes for cartilage tissue engineering, Biorheology, 41(3-4), 411 (2004).
28. RS Tuan, G Boland, R Tuli, et al., Adult mesenchymal stem cells and cell-based tissue engineering, Arthritis Res Therapy, 5(1), 32 (2003).
29. SR Park, BH Min, SH Park, et al., Application of mechanical stimulation for chondrogenesis, Tissue Eng Regen Med, 2(2), 77 (2005).
30. A Winter, S Breit, D Parsch, et al., Cartilage-like gene expression in differentiated human stem cell spheroids: a comparison of bone marrow-derived and adipose tissue-derived stromal cells, Arthritis Rheumatism, 48(2), 418 (2003).
31. A Muraglia, I Martin, R Cancedda, et al., A nude mouse model for human bone formation in unloaded conditions, Bone, 22(5 Suppl 1), 131S (1998).
32. Y Oshima, N Watanabe, K Matsuda, et al., Fate of transplanted bone-marrow-derived mesenchymal cells during osteochondral repair using transgenic rats to simulate autologous transplantation, Osteoarthritis Cartilage, 12(10), 811 (2004).
33. K Uematsu, K Hattori, Y Ishimoto, et al., Cartilage regeneration using mesenchymal stem cells and a three-dimensional polylactic-glycolic acid(PLGA) scaffold, Biomaterials, 26(20), 4273 (2005).
34. S Wakitani, T Mitsuoka, N Nakamura, et al., Autologous bone marrow stromal cell transplantation for repair of full-thickness articular cartilage defects in human patellae: two case reports, Cell Transplantation, 13(5), 595 (2004).
35. MD Buschmann, YA Gluzband, AJ Grodzinsky, et al., Mechanical compression modulates matrix biosynthesis in chondrocyte/agarose culture, J Cell Sci, 108(4), 1497 (1995).
36. T Davisson, S Kunig, A Chen, et al., Static and dynamic compression modulate matrix metabolism in tissue engineered cartilage, J Orthopaedic Res, 20(4), 842 (2002a).
37. CR Lee, AJ Grodzinsky, M Spector, Biosynthetic response of passaged chondrocytes in a type II collagen scaffold to mechanical compression, J Biomedical Mater Res A, 64(3), 560 (2003).
38. DA Lee, DL Bader, Compressive strains at physiological frequencies influence the metabolism of chondrocytes seeded in agarose, J Orthopaedic Res, 15(2), 181 (1997).
39. JD Kisiday, M Jin, MA DiMicco, et al., Effects of dynamic compressive loading on chondrocyte biosynthesis in self-assembling peptide scaffolds, J Biomechanics, 37(5), 595 (2004).
40. CT Hung, RL Mauck, CC Wang, et al., A paradigm for functional tissue engineering of articular cartilage via applied physiologic deformational loading, Ann Biomed Eng, 32(1), 35 (2004).
41. J Malda, J Rouwkema, DE Martens, et al., Oxygen gradients in tissue-engineered PEGT/PBT cartilaginous constructs: measurement and modeling, Biotech Bioeng, 86(1), 9 (2004).
42. MC Lewis, BD Macarthur, J Malda, et al., Heterogeneous proliferation within engineered cartilaginous tissue: the role of oxygen tension, Biotech Bioeng, 91(5), 607 (2005).
43. I Martin, B Obradovic, LE Freed, et al., Method for quantitative analysis of glycosaminoglycan distribution in cultured natural and engineered cartilage, Ann Biomed Eng, 27(5), 656 (1999).
44. G Vunjak-Novakovic, I Martin, B Obradovic, et al., Bioreactor cultivation conditions modulate the composition and mechanical properties of tissue-engineered cartilage, J Orthopaedic Res, 17(1), 130 (1999).
45. CH Chang, FH Lin, CC Lin, et al., Cartilage tissue engineering on the surface of a novel gelatincalcium-phosphate biphasic scaffold in a double-chamber bioreactor, J Biomed Mater Res, 71B(2), 313 (2004).
46. T Davisson, RL Sah, A Ratcliffe, Perfusion increases cell content and matrix synthesis in chondrocyte three-dimensional cultures, Tissue Eng, 8(5), 807 (2002b).
47. D Pazzano, KA Mercier, JM Moran, et al., Comparison of chondrogenesis in static and perfused bioreactor culture, Biotechnology Progress, 16(5), 893 (2000).
48. D Wendt, S Stroebel, M Jakob, et al., Uniform tissues engineered by seeding and culturing cells in 3D scaffolds under perfusion at defined oxygen tensions, Biorheology, 43(3-4), 481 (2006).
49. P Sucosky, DF Osorio, JB Brown, et al., Fluid mechanics of a spinner-flask bioreactor, Biotech Bioeng, 85(1), 34 (2004).
50. KA Williams, S Saini, TM Wick, Computational fluid dynamics modeling of steady-state momentum and mass transport in a bioreactor for cartilage tissue engineering, Biotech Progress, 18(5), 951 (2002).
51. M Cioffi, F Boschetti, MT Raimondi, et al., Modeling evaluation of the fluid-dynamic microenvironment in tissueengineered constructs: A micro-CT based model, Biotech Bioeng, 93(3), 500 (2006).
52. B Porter, R Zauel, H Stockman, et al., Guldberg 3-D computational modeling of media flow through scaffolds in a perfusion bioreactor, J Biomechanics, 38(3), 543 (2005).
53. MT Raimondi, F Boschetti, L Falcone, et al., Mechanobiology of engineered cartilage cultured under a quantified fluid-dynamic environment, Biomechanics Modeling in Mechanobiology, 1(1), 69 (2002).
54. MT Raimondi, F Boschetti, L Falcone, et al., The effect of media perfusion on threedimensional cultures of human chondrocytes: integration of experimental and computational approaches, Biorheology, 41(3-4), 401 (2004).
55. S Lee, Y Son, TGF-beta stimulates conversion of fibrocartilage phenotype of costal chondrocytes, Tissue Eng Regen Med, 1(2), 171 (2004).
56. O Demarteau, D Wendt, A Braccini, et al., Dynamic compression of cartilage constructs engineered from expanded human articular chondrocytes, Biochem Biophy Res Comm, 310(2), 580 (2003).
57. B Obradovic, I Martin, RF Padera, et al., Integration of engineered cartilage, J Orthopaedic Res, 19(6), 1089 (2001).
58. M Moretti, D Wendt, D Schaefer, et al., Structural characterization and reliable biomechanical assessment of integrative cartilage repair, J Biomechanics, 38(9), 1846 (2005b).
59. A Ratcliffe, LE Niklason, Bioreactors and bioprocessing for tissue engineering, Ann New York Acad Sci, 961, 210 (2002).
60. I Martin, D Wendt, M Heberer, The role of bioreactors in tissue engineering, Trends Biotech, 22(2), 80 (2004).
61. M Kino-Oka, N Ogawa, R Umegaki, et al., Bioreactor design for successive culture of anchorage-dependent cells operated in an automated manner, Tissue Eng, 11(3/4), 535 (2005).