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Archives of Orthopaedic and Trauma Surgery
Published in: Archives of Orthopaedic and Trauma Surgery 4/2006

01-05-2006 | Original Article

Second generation of meniscus transplantation: in-vivo study with tissue engineered meniscus replacement

Authors: V. Martinek, P. Ueblacker, K. Bräun, S. Nitschke, R. Mannhardt, K. Specht, B. Gansbacher, A. B. Imhoff

Published in: Archives of Orthopaedic and Trauma Surgery | Issue 4/2006

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Abstract

Introduction: The options available after meniscus loss offer only limited chances for a long-term success. In the following experimental study, we investigated the effect of meniscus tissue engineering on properties of the collagen meniscus implant (CMI). Methods: Autologous fibrochondrocytes, obtained per biopsy from adult Merino sheep (n=25), were released from the matrix, cultured in-vitro and seeded into CMI scaffolds (n=10, group 1). Following a 3-week in-vitro culture, the tissue engineered menisci were used for autologous transplantation. Macroscopical and histological evaluation were performed in comparison with non-seeded CMI controls (n=10, group 2) and with meniscus-resected controls (n=5, group 3) after 3 weeks (each 1 animal group 1 and 2) and 3 months. Results: The lameness score did not show any difference between the groups. Meniscus tissue was found in seven knee joints (group 1), in five knee joints (group 2) and in two knee joints (group 3). The size of the transplants reduced from 25.9±4.5 to 20.1±10.8 mm (group 1) and from 25.9±1.5 to 14.4±12.5 mm (group 2). Histologically, enhanced vascularisation, accelerated scaffold re-modelling, higher content of extra-cellular matrix and lower cell number were noted in the pre-seeded menisci in comparison with non-seeded controls. Dense high-cellular fibrous scar tissue was found in two of five cases in the resection control group. Conclusion: Tissue engineering of meniscus with autologous fibrochondrocytes demonstrates a macroscopic and histological improvement of the transplants. However, further development of the methods, especially of the scaffold and of the cell-seeding procedure must prove the feasibility of this procedure for human applications.
Literature
1.
Arnoczky SP (1999) Building a meniscus. Biologic considerations. Clin Orthop 367(Suppl):S244–S253PubMed
2.
Arnoczky SP, Warren RF, Spivak JM (1988) Meniscal repair using an exogenous fibrin clot. An experimental study in dogs. J Bone Joint Surg [Am] 70(8):1209–1217
3.
Bruns J, Kahrs J, Kampen J, Behrens P, Plitz W (1998) Autologous perichondral tissue for meniscal replacement. J Bone Joint Surg [Br] 80(5):918–923CrossRef
4.
Cook JL, Tomlinson JL, Kreeger JM, Cook CR (1999) Induction of meniscal regeneration in dogs using a novel biomaterial. Am J Sports Med 27(5):658–665PubMed
5.
de Boer HH, Koudstaal J (1994) Failed meniscus transplantation. A report of three cases. Clin Orthop 306:155–162PubMed
6.
Fink C, Fermor B, Weinberg JB, Pisetsky DS, Misukonis MA, Guilak F (2001) The effect of dynamic mechanical compression on nitric oxide production in the meniscus. Osteoarthritis Cartilage 9(5):481–487PubMedCrossRef
7.
Gastel JA, Muirhead WR, Lifrak JT, Fadale PD, Hulstyn MJ, Labrador DP (2001) Meniscal tissue regeneration using a collagenous biomaterial derived from porcine small intestine submucosa. Arthroscopy 17(2):151–159PubMedCrossRef
8.
Goble EM, Kohn D, Verdonk R, Kane SM (1999) Meniscal substitutes-human experience. Scand J Med Sci Sports 9(3):146–157PubMed
9.
10.
Guilak F, Meyer BC, Ratcliffe A, Mow VC (1994) The effects of matrix compression on proteoglycan metabolism in articular cartilage explants. Osteoarthritis Cartilage 2(2):91–101PubMedCrossRef
11.
Ibarra C, Jannetta C, Vacanti CA, Cao Y, Kim TH, Upton J, Vacanti JP (1997) Tissue engineered meniscus: a potential new alternative to allogeneic meniscus transplantation. Transplant Proc 29(1–2):986–988PubMedCrossRef
12.
Ibarra C, Koski JA, Warren RF (2000) Tissue engineering meniscus: cells and matrix. Orthop Clin North Am 31(3):411–418PubMedCrossRef
13.
Jackson DW, McDevitt CA, Simon TM, Arnoczky SP, Atwell EA, Silvino NJ (1992) Meniscal transplantation using fresh and cryopreserved allografts. An experimental study in goats. Am J Sports Med 20(6):644–656PubMedCrossRef
14.
Kasemkijwattana C, Menetrey J, Goto H, Niyibizi C, Fu FH, Huard J (1999) The use of growth factors, gene therapy and tissue engineering to improve meniscal healing. Trans Orthop Res Soc 45
15.
Klompmaker J, Jansen HW, Veth RP, de Groot JH, Nijenhuis AJ, Pennings AJ (1991) Porous polymer implant for repair of meniscal lesions: a preliminary study in dogs. Biomaterials 12(9):810–816PubMedCrossRef
16.
Kohn D, Rudert M, Wirth CJ, Plitz W, Reiss G, Maschek H (1997) Medial meniscus replacement by a fat pad autograft. An experimental study in sheep. Int Orthop 21(4):232–238PubMedCrossRef
17.
Kohn D, Wirth CJ, Reiss G, Plitz W, Maschek H, Erhardt W, Wulker N (1992) Medial meniscus replacement by a tendon autograft. Experiments in sheep. J Bone Joint Surg [Br] 74(6):910–917
18.
Kuhn JE, Wojtys EM (1996) Allograft meniscus transplantation. Clin Sports Med 15(3):537–546PubMed
19.
Maitra RS, Miller MD, Johnson DL (1999) Meniscal reconstruction. Part II: Outcome, potential complications, and future directions. Am J Orthop 28(5):280–286PubMed
20.
Martinek V, Fu F, Huard J (1999) Gene therapy and tissue engineering in sports medicine. The Physician and Sportsmedicine 28(2):34–51
21.
Martinek V, Martinek S, Pelinkovic D, Hendi P, Celechovsky C, Fu FH, Huard J (2001) Proliferative stimulation of human fibrochondrocytes originating from the avascular zone wtih IGF-1, TGF-alpha and VEGF. J Jpn Orthop Assoc 75(2)
22.
Martinek V, Ueblacker P, Imhoff AB (2003) Collagen Meniscus Implant (CMI) in combined knee surgery procedures. A clinical follow-up. Book of abstracts ACL study group meeting 2002, Vails, Colorado
23.
Martinek V, Usas A, Pelinkovic D, Robbins P, Fu FH, Huard J (2002) Genetic engineering of meniscal allografts. Tissue Eng 8(1):107–117PubMedCrossRef
24.
Messner K (1999) Indications for meniscal transplantation. Who and how many need a meniscus substitute? A personal view. Scand J Med Sci Sports 9(3):184–188PubMed
25.
Messner K (1999) Meniscal regeneration or meniscal transplantation? Scand J Med Sci Sports 9(3):162–167PubMed
26.
Messner K, Kohn D, Verdonk R (1999) Future research in meniscal replacement. Scand J Med Sci Sports 9(3):181–183PubMed
27.
Milachowski KA, Kohn D, Wirth CJ (1994) Transplantation of allogeneic menisci. Orthopade 23(2):160–163PubMed
28.
Milachowski KA, Weismeier K, Wirth CJ (1989) Homologous meniscus transplantation. Experimental and clinical results. Int Orthop 13(1):1–11PubMedCrossRef
29.
Noyes FR (1995) A histological study of failed human meniscal allograft. Oral presentation, speciality day 1995, arhroscopy association of North America, Orlando
30.
O’Driscoll SW (2001) Preclinical cartilage repair: current status and future perspectives. Clin Orthop 391(Suppl):S397–S401PubMed
31.
Renstrom P, Johnson RJ (1990) Anatomy and biomechanics of the menisci. Clin Sports Med 9(3):523–538PubMed
32.
Rodeo SA (2001) Meniscal allografts–where do we stand?. Am J Sports Med 29(2):246–261PubMed
33.
Rodeo SA, Seneviratne A, Suzuki K, Felker K, Wickiewicz TL, Warren RF (2000) Histological analysis of human meniscal allografts. A preliminary report. J Bone Joint Surg [Am] 82-A(8):1071–1082
34.
Rodkey WG (2002) Collagen meniscus implant (CMI): multicenter clinical trials update. ACL Study Group Meeting, March 2–8, Big Sky, Montana
35.
Rodkey WG, Steadman JR, Li ST (1999) A clinical study of collagen meniscus implants to restore the injured meniscus. Clin Orthop 367(Suppl):S281–S292PubMed
36.
Shin SJ, Fermor B, Weinberg JB, Pisetsky DS, Guilak F (2003) Regulation of matrix turnover in meniscal explants: role of mechanical stress, interleukin-1, and nitric oxide. J Appl Physiol 95(1):308–313PubMed
37.
Stone KR, Ayala G, Goldstein J, Hurst R, Walgenbach A, Galili U (1998) Porcine cartilage transplants in the cynomolgus monkey. III. Transplantation of alpha-galactosidase-treated porcine cartilage. Transplantation 65(12):1577–1583PubMedCrossRef
38.
Stone KR, Rodkey WG, Webber R, McKinney L, Steadman JR (1992) Meniscal regeneration with copolymeric collagen scaffolds. In vitro and in vivo studies evaluated clinically, histologically, and biochemically. Am J Sports Med 20(2):104–111PubMedCrossRef
39.
Stone KR, Steadman JR, Rodkey WG, Li ST (1997) Regeneration of meniscal cartilage with use of a collagen scaffold. Analysis of preliminary data. J Bone Joint Surg [Am] 79(12):1770–1777
40.
Sweigart MA, Athanasiou KA (2001) Toward tissue engineering of the knee meniscus. Tissue Eng 7(2):111–129PubMedCrossRef
41.
Szomor ZL, Martin TE, Bonar F, Murrell GA (2000) The protective effects of meniscal transplantation on cartilage. An experimental study in sheep. J Bone Joint Surg [Am] 82(1):80–88
42.
van Arkel ER, de Boer HH (2002) Survival analysis of human meniscal transplantations. J Bone Joint Surg [Br] 84(2):227–231CrossRef
43.
Veltri DM, Warren RF, Wickiewicz TL, O’Brien SJ (1994) Current status of allograft meniscal transplantation. Clin Orthop 303:44–55PubMed
44.
Veth RP, Jansen HW, Leenslag JW, Pennings AJ, Hartel RM, Nielsen HK (1986) Experimental meniscal lesions reconstructed with a carbon fiber-polyurethane-poly(L-lactide) graft. Clin Orthop 202:286–293PubMed
45.
Walsh CJ, Goodman D, Caplan AI, Goldberg VM (1999) Meniscus regeneration in a rabbit partial meniscectomy model. Tissue Eng 5(4):327–337PubMedCrossRef
46.
Webber RJ, Harris MG, Hough AJ (1985) Cell culture of rabbit meniscal fibrochondrocytes: proliferative and synthetic response to growth factors and ascorbate. J Orthop Res 3(1):36–42PubMedCrossRef
47.
Webber RJ, Zitaglio T, Hough AJ Jr (1988) Serum-free culture of rabbit meniscal fibrochondrocytes: proliferative response. J Orthop Res 6(1):13–23PubMedCrossRef
Metadata
Title
Second generation of meniscus transplantation: in-vivo study with tissue engineered meniscus replacement
Authors
V. Martinek
P. Ueblacker
K. Bräun
S. Nitschke
R. Mannhardt
K. Specht
B. Gansbacher
A. B. Imhoff
Publication date
01-05-2006
Publisher
Springer-Verlag
Published in
Archives of Orthopaedic and Trauma Surgery / Issue 4/2006
Print ISSN: 0936-8051
Electronic ISSN: 1434-3916
DOI
https://doi.org/10.1007/s00402-005-0025-1

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