The temporomandibular joint (TMJ) disc is a specialized fibrocartilaginous tissue. When the disc becomes an obstacle and becomes damaged, surgeons have no choice but to perform a discectomy. Tissue engineering may provide a novel treatment modality for TMJ disorder patients who undergo discectomy. No studies have been conducted on the most favourable media for TMJ disc cells. The objective of the current study was to examine the effects on biochemical and biomechanical properties of varying ascorbic acid concentrations (0, 25, or 50 μg/ml) on TMJ disc cells seeded on non-woven PGA scaffolds. The ascorbic acid concentration of the 25 μg/ml group resulted in more effective cell seeding of the scaffolds, with 1.53 million cells per construct, by comparison with the 0 and 50 μg/ml groups which had 1.20 million and 1.32 million cells per scaffold respectively. At week 4, the 25 μg/ml group had a higher collagen content than the 0 μg/ml group, with 30.4 ± 2.7 and 24.9 ± 3.3 μg of collagen per construct respectively. The 25 μg/ml group had a higher aggregate modulus than the 50 μg/ml group, with values of 6.1 ± 1.3 and 4.0 ± 0.9 kPa respectively at week 4. The results of this study indicate that the use of 25 μg/ml of ascorbic acid in culture media is effective for the tissue engineering of the TMJ disc, significantly outperforming media without or with 50 μg/ml of ascorbic acid.
ErikssonL.WestessonP. L.Discectomy as an effective treatment for painful temporomandibular joint internal derangement: A 5-year clinical and radiographic follow-upJ. Oral Maxillofacial Surg., 2001, 59 (7), 750–758; discussion 758–759.
3.
GundlachK.K.Long-term results following surgical treatment of internal derangement of the temporomandibular jointJ. Craniomaxillofacial Surg., 1990, 18 (5), 206–209.
4.
HolmlundA.B.GyntherG.AxelssonS.Discectomy in treatment of internal derangement of the temporomandibular joint. Follow-up at 1, 3, and 5 years, Oral Surg. Oral Med. Oral Pathol., 1993, 76 (3), 266–271.
5.
DolwickM.F.Surgical managementRadiol. Res. and Educ. Foundation, 1983, 167–192.
6.
IoannidesC.FreihoferH. P.Replacement of the damaged interarticular disc of the TMJJ. Craniomaxillofacial Surg., 1988, 16 (6), 273–278.
7.
BergR.Contribution to the applied and topographical anatomy of the temporomandibular joint of some domestic mammals with particular reference to the partial resp. total resection of the articular discFolia Morphol., 1973, 21 (2), 202–204.
8.
StrömD.HolmS.ClemenssonE.HaraldsonT.CarlssonG. E.Gross anatomy of the mandibular joint and masticatory muscles in the domestic pig (Sus scrofa)Arch. Oral Biol., 1986, 31 (11), 763–768.
9.
BermejoA.GonzalezO.GonzalezJ. M.The pig as an animal model for experimentation on the temporomandibular articular complexOral Surg. Oral Med. Oral Pathol., 1993, 75 (1), 18–23.
10.
CarvalhoR.S.YenE. H.SugaD. M.Glycosaminoglycan synthesis in the rat articular disk in response to mechanical stressAm. J. Orthod. Dentofacial Orthop., 1995, 107 (4), 401–410.
11.
LandesbergR.TakeuchiE.PuzasJ. E.Cellular, biochemical and molecular characterization of the bovine temporomandibular joint discArch. Oral. Biol., 1996, 41 (8–9), 761–767.
12.
MilamS.B.KlebeR. J.TriplettR. G.HerbertD.Characterization of the extracellular matrix of the primate temporomandibular jointJ. Oral Maxillofacial Surg., 1991, 49 (4), 381–391.
13.
MillsD.K.FiandacaD. J.ScapinoR. P.Morphologic, microscopic, and immunohistochemical investigations into the function of the primate TMJ discJ. Orofacial Pain, 1994, 8 (2), 136–154.
14.
MinarelliA.M.LibertiE. A.A microscopic survey of the human temporomandibular joint discJ. Oral Rehabil., 1997, 24 (11), 835–840.
15.
AlmarzaA.J.AthanasiouK. A.Design characteristics for the tissue engineering of cartilaginous tissuesAnn. Biomed. Engng, 2004, 32 (1), 2–17.
16.
KimK.W.WongM. E.HelfrickJ. F.ThomasJ. B.AthanasiouK. A.Biomechanical characterization of the superior joint space of the porcine temporomandibular jointAnn. Biomed. Engng, 2003, 31, 924–930.
17.
DetamoreM.S.AthanasiouK. A.Tensile properties of the porcine temporomandibular joint discJ. Biomech. Engng, 2003, 125, 558–565.
18.
AlmarzaA.J.AthanasiouK. A.Seeding techniques and scaffolding choice for the tissue engineering of the temporomandibular joint discTissue Engng, 2004, 10 (11–12), 1787–1795.
19.
AlmarzaA.J.AthanasiouK. A.Evaluation of three growth factors in combinations of two for TMJ disc tissue engineeringArch. Oral Biol., 2005.
20.
DetamoreM.S.AthanasiouK. A.Evaluation of three growth factors for the TMJ disc tissue engineeringAnn. Biomed. Engng, 2005, 33 (3), 383–390.
21.
DetamoreM.S.AthanasiouK. A.Use of a rotating bioreactor toward tissue engineering the temporomadibular joint discTissue Engng, 2005, 11(7–8), 1188–1197.
22.
AlmarzaA.J.AthanasiouK. A.Effects of initial cell seeding density for the tissue engineering of the temporomandibular joint discAnn. Biomed. Engng, 2005, 33 (7), 943–950.
23.
SpringerI.N.FleinerB.JepsenS.AcilY.Culture of cells gained from temporomandibular joint cartilage on non-absorbable scaffoldsBio-materials, 2001, 22 (18), 2569–2577.
24.
ThomasM.GrandeD.HaugR. H.Development of an in vitro temporomandibular joint cartilage analogJ. Oral Maxillofacial Surg., 1991, 49 (8), 854–856; discussion 857.
25.
DetamoreM.S.AthanasiouK. A.Effects of growth factors on temporomandibular joint disc cellsArch. Oral Biol., 2004, 49 (7), 577–583.
26.
BerkovitzB.K.PacyJ.Age changes in the cells of the intra-articular disc of the temporomandibular joints of rats and marmosetsArch. Oral Biol., 2000, 45 (11), 987–995.
27.
DetamoreM.S.AthanasiouK. A.Motivation, characterization, and strategy for tissue engineering the temporomandibular joint discTissue Engng, 2003, 9 (6), 1065–1087.
28.
HuJ.C.AthanasiouK. A.Low-density cultures of bovine chondrocytes: Effects of scaffold material and culture systemBiomaterials, 2005, 26 (14), 2001–2012.
29.
DetamoreM.S.AthanasiouK. A.Use of a rotating bioreactor toward tissue engineering the temporomandibular joint discTissue Engng, 2005, 11 (7–8), 1188–1197.
BergR.A.ProckopD. J.The thermal transition of a non-hydroxylated form of collagen. Evidence for a role for hydroxyproline in stabilizing the triple-helix of collagen, Biochem. Biophys. Res. Commun., 1973, 52 (1), 115–120.
32.
JimenezS.HarschM.RosenbloomJ.Hydroxyproline stabilizes the triple helix of chick tendon collagenBiochem. Biophys. Res. Commun., 1973, 52 (1), 106–114.
33.
PuchtlerH.WaldropF. S.ValentineL. S.Polarization microscopic studies of connective tissue stained with picro-sirius red FBABeitr Pathol., 1973, 150 (2), 174–187.
34.
MovatH.Z.Demonstration of all connective tissue elements in a single section; pentachrome stainsAMA Arch. Pathol., 1955, 60 (3), 289–295.
35.
DetamoreM.S.OrfanosJ. G.AlmarzaA. J.FrenchM. M.WongM. E.AthanasiouK. A.Quantitative analysis and comparative regional investigation of the extracellular matrix of the porcine temporomandibular joint discMatrix Biol., 2004, 24, 45–57.
36.
PooleC.A.GlantT. T.SchofieldJ. R.Chondrons from articular cartilage. IV Immuno-localization of proteoglycan epitopes in isolated canine tibial chondronsJ. Histochem. Cytochem., 1991, 39 (9), 1175–1187.
37.
AlmarzaA.J.BeanA. C.BaggettL. S.AthanasiouK. A.Biochemical analysis of the temporomandibular joint discBr. J. Oral and Maxillofacial Surg., 2005.
38.
KorvickD.AthanasiouK. A.Variations in the mechanical properties of cartilage from the canine scapulohumeral jointAm. J. Vet. Res., 1997, 58 (9), 949–953.
39.
MowV.C.GibbsM. C.LaiW. M.ZhuW. B.AthanasiouK. A.Biphasic indentation of articular cartilage. II. A numerical algorithm and an experimental studyJ. Biomech., 1989, 22 (8–9), 853–861.
40.
AthanasiouK.A.AgarwalA.DzidaF. J.Comparative study of the intrinsic mechanical properties of the human acetabular and femoral head cartilageJ. Orthop. Res., 1994, 12 (3), 340–349.
41.
MauckR.L.WangC. C.OswaldE. S.AteshianG. A.HungC. T.The role of cell seeding density and nutrient supply for articular cartilage tissue engineering with deformational loadingOsteoarthritis Cartilage, 2003, 11 (12), 879–890.
