Achievement of viable engineered tissues through in vitro cultivation in bioreactor systems requires a thorough understanding of the complex interplay between hydrodynamic forces and biochemical cues such as serum. To this end, chondrocyte-seeded constructs were cultured under continuous fluid-induced shear forces with reduced serum content (0%–2%, v/v), which was partially or completely replaced by a potential substitute, insulin-transferrin-selenium, to minimize deleterious effects associated with the use of culture media containing high levels of serum (10%–20%). Low-serum cultures yielded constructs with similar biochemical properties to those cultivated with high-serum supplements, whereas the serum-free constructs exhibited poor cell proliferation, insufficient extracellular matrix production, and rapid degradation of and/or shear-induced damage to polyglycolic acid scaffolds. A fibrous outer capsule typically observed in hydrodynamic cultures and characterized by increased cell density and decreased (virtually none) glycosaminoglycan deposition was eliminated when serum concentration was equal to or<0.2% in the presence of hydrodynamic stimuli. Our findings suggest that serum is a requirement in insulin-transferrin-selenium-supplemented cultures in order for constructs to exhibit improved properties in response to hydrodynamic forces, and that mechanical and biochemical stimuli may synergistically modulate tissue properties and morphology through shear-responsive signals.
Get full access to this article
View all access options for this article.
References
1.
BilodeauK., MantovaniD.Bioreactors for tissue engineering: focus on mechanical constraints. A comparative review. Tissue Eng, 12:2367. 2006.
2.
BlunkT., SieminskiA.L., GoochK.J., CourterD.L., HollanderA.P., NahirA.M., LangerR., Vunjak-NovakovicG., FreedL.E.Differential effects of growth factors on tissue-engineered cartilage. Tissue Eng, 8:73. 2002.
NegishiM., LuD., ZhangY.-Q., SawadaY., SasakiT., KayoT., AndoJ., IzumiT., KurabayashiM., KojimaI., MasudaH., TakeuchiT.Upregulatory expression of furin and transforming growth factor-β by fluid shear stress in vascular endothelial cells. Arterioscler Thromb Vasc Biol, 21:785. 2001.
7.
KellyT.-A.N., FisherM.B., OswaldE.S., TaiT., MauckR.L., AteshianG.A., HungC.T.Low-serum media and dynamic deformational loading in tissue engineering of articular cartilage. Ann Biomed Eng, 36:769. 2008.
8.
LohmannC.H., SchwartzZ., NiederauerG.G., CarnesD.L., DeanD.D., BoyanB.D.Pretreatment with platelet derived growth factor-BB modulates the ability of costochondral resting zone chondrocytes incorporated into PLA/PGA scaffolds to form new cartilage in vivo. Biomaterials, 21:49. 2000.
9.
Vunjak-NovakovicG., MartinI., ObradovicB., TreppoS., GrodzinskyA.J., LangerR., FreedL.E.Bioreactor cultivation conditions modulate the composition and mechanical properties of tissue-engineered cartilage. J Orthop Res, 17:130. 1999.
BarronV., LyonsE., Stenson-CoxC., MchughP.E., PanditA.Bioreactors for cardiovascular cell and tissue growth: a review. Ann Biomed Eng, 31:1017. 2003.
12.
AngelidisI.K., ThorfinnJ., ConnollyI.D., LindseyD., PhamH.M., ChangJ.Tissue engineering of flexor tendons: the effect of a tissue bioreactor on adipoderived stem cell-seeded and fibroblast-seeded constructs. J Am Coll Surg, 209:S75. 2009.
13.
DutyA.O., OestM.E., GuldbergR.E.Cyclic mechanical compression increases mineralization of cell-seeded polymer scaffolds in vivo. J Biomech Eng, 129:531. 2007.
14.
CartmellS.H., PorterB.D., GarciaA.J., GuldbergR.E.Effects of medium perfusion rate on cell-seeded three-dimensional bone constructs in vitro. Tissue Eng, 9:1197. 2003.
15.
YuX., BotchweyE.A., LevineE.M., PollackS.R., LaurencinC.T.Bioreactor-based bone tissue engineering: the influence of dynamic flow on osteoblast phenotypic expression and matrix mineralization. Proc Natl Acad Sci USA, 101:11203. 2004.
16.
GemmitiC.V., GuldbergR.E.Fluid flow increases type II collagen deposition and tensile mechanical properties in bioreactor-grown tissue-engineered cartilage. Tissue Eng, 12:469. 2006.
17.
MauckR.L., SoltzM.A., WangC.C.B., WongD.D., ChaoP.-H.G., ValhmuW.B., HungC.T., AteshianG.A.Functional tissue engineering of articular cartilage through dynamic loading of chondrocyte-seeded agarose gels. J Biomech Eng, 122:252. 2000.
18.
DarlingE.M., AthanasiouK.A.Articular cartilage bioreactors and bioprocesses. Tissue Eng, 9:9. 2003.
19.
ElderB.D., AthanasiouK.A.Effects of temporal hydrostatic pressure on tissue-engineered bovine articular cartilage constructs. Tissue Eng Part A, 15:1151. 2009.
20.
KisidayJ.D., JinM., DimiccoM.A., KurzB., GrodzinskyA.J.Effects of dynamic compressive loading on chondrocyte biosynthesis in self-assembling peptide scaffolds. J Biomech, 37:595. 2004.
21.
BuenoE.M., LaevskyG., BarabinoG.A.Enhancing cell seeding of scaffolds in tissue engineering through manipulation of hydrodynamic parameters. J Biotechnol, 129:516. 2007.
22.
BuenoE.M., BilgenB., BarabinoG.A.Wavy-walled bioreactor supports increased cell proliferation and matrix deposition in engineered cartilage constructs. Tissue Eng, 11:1699. 2005.
23.
BuenoE.M., BilgenB., CarrierR.L., BarabinoG.A.Increased rate of chondrocyte aggregation in a wavy-walled bioreactor. Biotechnol Bioeng, 88:767. 2004.
24.
BuenoE.M., BilgenB., BarabinoG.A.Hydrodynamic parameters modulate biochemical, histological, and mechanical properties of engineered cartilage. Tissue Eng Part A, 15:773. 2009.
25.
FreedL.E., MarquisJ.C., NohriaA., EmmanualJ., MikosA.G., LangerR.Neocartilage formation in vitro and in vivo using cells cultured on synthetic biodegradable polymers. J Biomed Mater Res, 27:11. 1993.
26.
ZhangE., LiX., ZhangS., ChenL., ZhengX.Cell cycle synchronization of embryonic stem cells: Effect of serum deprivation on the differentiation of embryonic bodies in vitro. Biochem Biophys Res Commun, 333:1171. 2005.
27.
PacherníkJ., BryjaV., EšnerM., KubalaL., DvořákP., HamplA.Neural differentiation of pluripotent mouse embryonal carcinoma cells by retinoic acid: inhibitory effect of serum. Physiol Res, 54:115. 2005.
28.
SuryawanA., HuC.Y.Effect of serum on differentiation of porcine adipose stromal-vascular cells in primary culture. Comp Biochem Physiol Comp Physiol, 105:485. 1993.
BilgenB., OrsiniE., AaronR.K., CiomborD.M.Fetal bovine serum suppresses transforming growth factor-β1-induced chondrogenesis in synoviocyte pellet cultures while dexamethasone and dynamic stimuli are beneficial. J Tissue Eng Regen Med, 1:436. 2007.
31.
VenkateswaranV., KlotzL.H., FleshnerN.E.Selenium modulation of cell proliferation and cell cycle biomarkers in human prostate carcinoma cell lines. Cancer Res, 62:2540. 2002.
32.
ShapiroL.E., WagnerN.Transferrin is an autocrine growth factor secreted by reuber H-35 cells in serum-free culture. In Vitro Cell Dev Biol Anim, 25:650. 1989.
33.
ShapiroL.E., WagnerN.Growth of H-35 rat hepatoma cells in unsupplemented serum-free media: effect of transferrin, insulin and cell density. In Vitro Cell Dev Biol Anim, 24:299. 1988.
34.
McquillanD.J., HandleyC.J., CampbellM.A., BolisS., MilwayV.E., HeringtonA.C.Stimulation of proteoglycan biosynthesis by serum and insulin-like growth factor-I in cultured bovine articular cartilage. Biochem J, 240:423. 1986.
35.
KisidayJ.D., KurzB., DimiccoM.A., GrodzinskyA.J.Evaluation of medium supplemented with insulin-transferrin-selenium for culture of primary bovine calf chondrocytes in three-dimensional hydrogel scaffolds. Tissue Eng, 11:141. 2005.
36.
MandlE.W., Van Der VeenS.W., VerhaarJ.A.N., Van OschG.J.V.M.Serum-free medium supplemented with high-concentration fibroblast growth factor-2 for cell expansion culture of human ear chondrocytes promotes redifferentiation capacity. Tissue Eng, 8:573. 2002.
37.
ChuaK.H., AminuddinB.S., FuzinaN.H., RuszymahB.H.I.Insulin-transferrin-selenium prevent human chondrocyte dedifferentiation and promote the formation of high quality tissue engineered human hyaline cartilage. Eur Cell Mater, 9:58. 2005.
38.
GigoutA., BuschmannM.D., JolicoeurM.Chondrocytes cultured in stirred suspension with serum-free medium containing pluronic-68 aggregate and proliferate while maintaining their differentiated phenotype. Tissue Eng Part A, 15:2237. 2009.
39.
BianL., LimaE.G., AngioneS.L., NgK.W., WilliamsD.Y., XuD., StokerA.M., CookJ.L., AteshianG.A., HungC.T.Mechanical and biochemical characterization of cartilage explants in serum-free culture. J Biomech, 41:1153. 2008.
40.
FitzsimmonsJ.S., SanyalA., GonzalezC., FukumotoT., ClemensV.R., O'driscollS.W., ReinholzG.G.Serum-free media for periosteal chondrogenesis in vitro. J Orthop Res, 22:716. 2004.
41.
KisidayJ., JinM., KurzB., HungH., SeminoC., ZhangS., GrodzinskyA.J.Self-assembling peptide hydrogel fosters chondrocyte extracellular matrix production and cell division: Implications for cartilage tissue repair. Proc Natl Acad Sci USA, 99:9996. 2002.
42.
BilgenB., BarabinoG.A.Location of scaffolds in bioreactors modulates the hydrodynamic environment experienced by engineered tissues. Biotechnol Bioeng, 98:282. 2007.
43.
KimY.-J., SahR.L.Y., DoongJ.-Y.H., GrodzinskyA.J.Fluorometric assay of DNA in cartilage explants using Hoechst 33258. Anal Biochem, 174:168. 1988.
44.
FarndaleR.W., ButtleD.J., BarrettA.J.Improved quantitation and discrimination of sulphated glycosaminoglycans by use of dimethylmethylene blue. Biochim Biophys Acta, 883:173. 1986.
45.
WoessnerJ.F.The determination of hydroxyproline in tissue and protein samples containing small proportions of this imino acid. Arch Biochem Biophys, 93:440. 1961.
46.
BilgenB., Chang-MateuI.M., BarabinoG.A.Characterization of mixing in a novel wavy-walled bioreactor for tissue engineering. Biotechnol Bioeng, 92:907. 2005.
47.
BilgenB., SucoskyP., NeitzelP.G., BarabinoG.A.Flow characterization of a wavy-walled bioreactor for cartilage tissue engineering. Biotechnol Bioeng, 95:1009. 2006.
48.
MohtaiM., GuptaM.K., DonlonB., EllisonB., CookeJ., GibbonsG., SchurmanD.J., SmithR.L.Expression of interleukin-6 in osteoarthritic chondrocytes and effects of fluid-induced shear on this expression in normal human chondrocytes in vitro. J Orthop Res, 14:67. 1996.
49.
YokotaH., GoldringM.B., SunH.B.Cited2-mediated regulation of MMP-1 and MMP-13 in human chondrocytes under flow shear. J Biol Chem, 278:47275. 2003.
50.
AgrawalC.M., AthanasiouK.A., HeckmanJ.D.Biodegradable pla-pga polymers for tissue engineering in orthopaedics. Mater Sci Forum, 250:115. 1997.
51.
AgrawalC.M., MckinneyJ.S., LanctotD., AthanasiouK.A.Effects of fluid flow on the in vitro degradation kinetics of biodegradable scaffolds for tissue engineering. Biomaterials, 21:2443. 2000.
52.
IgnotzR.A., MassaguéJ.Transforming growth factor-β stimulates the expression of fibronectin and collagen and their incorporation into the extracellular matrix. J Biol Chem, 261:4337. 1986.
53.
FujisatoT., SajikiT., LiuQ., IkadaY.Effect of basic fibroblast growth factor on cartilage regeneration in chondrocyte-seeded collagen sponge scaffold. Biomaterials, 17:155. 1996.
54.
VinardellT., ThorpeS., BuckleyC., KellyD.Chondrogenesis and integration of mesenchymal stem cells within an in vitro cartilage defect repair model. Ann Biomed Eng, 37:2556. 2009.
55.
FreedL.E., Vunjak-NovakovicG.Cultivation of cell-polymer tissue constructs in simulated microgravity. Biotechnol Bioeng, 46:306. 1995.
