Articular cartilage is critical for proper joint mobility as it provides a smooth and lubricated surface between articulating bones and allows for transmission of load to underlying bones. Extended wear or injury of this tissue can result in osteoarthritis, a degenerative disease affecting millions across the globe. Because of its low regenerative capacity, articular cartilage cannot heal on its own and effective treatments for injured joint restoration remain a challenge. Strategies in tissue engineering have been demonstrated as potential therapeutic approaches to regenerate and repair damaged articular cartilage. Although many of these strategies rely on the use of an exogenous three-dimensional scaffolds to regenerate cartilage, scaffold-free tissue engineering provides numerous advantages over scaffold-based methods. This review highlights the latest advancements in scaffold-free tissue engineering for cartilage and the potential for clinical translation.
Impact statement
Although scaffolds are often incorporated into cartilage tissue engineering strategies as a three-dimensional architecture conducive to tissue formation, scaffold-free approaches are increasingly recognized for their ability to better recapitulate the native tissue formation process. Recent advancements in scaffold-free tissue engineering and success in clinical trials demonstrate the potential of these techniques to serve as viable therapies for repairing and restoring damaged cartilage.
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References
1.
LangerR., and VacantiJ.P.Tissue engineering. Science, 260, 920, 1993.
2.
BerthiaumeF., MaguireT.J., and YarmushM.L.Tissue engineering and regenerative medicine: history, progress, and challenges. Annu Rev Chem Biomol Eng, 2, 403, 2011.
3.
Sophia FoxA.J., BediA., and RodeoS.A.The basic science of articular cartilage. Sports Health, 1, 461, 2009.
4.
BecerraJ., AndradesJ.A., GueradoE., et al.Articular Cartilage: structure and Regeneration. Tissue Eng B Rev, 16, 617, 2010.
5.
KloppenburgM., and BerenbaumF.Osteoarthritis year in review 2019: epidemiology and therapy. Osteoarthritis Cartilage, 28, 242, 2020.
6.
LespasioM.J., PiuzziN.S., HusniM.E., et al.Knee Osteoarthritis: A Primer. Perm J, 21, 16, 2017.
7.
RosetiL., DesandoG., CavalloC., et al.Articular cartilage regeneration in osteoarthritis. Cells, 8, 1305, 2019.
8.
DeFailA.J., ChuC.R., IzzoN., et al.Controlled release of bioactive TGF-β1 from microspheres embedded within biodegradable hydrogels. Biomaterials, 27, 1579, 2006.
9.
FrancisS.L., Di BellaC., WallaceG.G., et al.Cartilage tissue engineering using stem cells and bioprinting technology—barriers to clinical translation. Front Surg, 5, 70, 2018.
10.
LeahyA.A., EsfahaniS.A., FooteA.T., et al.Analysis of the trajectory of osteoarthritis development in a mouse model by serial near-infrared fluorescence imaging of matrix metalloproteinase activities. Arthritis Rheumatol (Hoboken, NJ), 67, 442, 2015.
11.
WescoeK.E., SchugarR.C., ChuC.R., et al.The role of the biochemical and biophysical environment in chondrogenic stem cell differentiation assays and cartilage tissue engineering. Cell Biochem Biophys, 52, 85, 2008.
12.
O'ConorC.J., CaseN., and GuilakF.Mechanical regulation of chondrogenesis. Stem Cell Res Ther, 4, 61, 2013.
13.
OvsianikovA., KhademhosseiniA., and MironovV.The synergy of scaffold-based and scaffold-free tissue engineering strategies. Trends Biotechnol, 36, 348, 2018.
14.
ShimomuraK., AndoW., FujieH., et al.Scaffold-free tissue engineering for injured joint surface restoration. J Exp Orthop, 5, 2, 2018.
15.
XuT., BinderK.W., AlbannaM.Z., et al.Hybrid printing of mechanically and biologically improved constructs for cartilage tissue engineering applications. Biofabrication, 5, 015001, 2012.
16.
AthanasiouK.A., EswaramoorthyR., HadidiP., et al.Self-organization and the self-assembling process in tissue engineering. Annu Rev Biomed Eng, 15, 115, 2013.
17.
DuRaineG.D., BrownW.E., HuJ.C., et al.Emergence of scaffold-free approaches for tissue engineering musculoskeletal cartilages. Ann Biomed Eng, 43, 543, 2015.
18.
KwonH., PaschosN.K., HuJ.C., et al.Articular cartilage tissue engineering: the role of signaling molecules. Cell Mol Life Sci, 73, 1173, 2016.
19.
GründerT., GaissmaierC., FritzJ., et al.Bone morphogenetic protein (BMP)-2 enhances the expression of type II collagen and aggrecan in chondrocytes embedded in alginate beads. Osteoarthritis Cartilage, 12, 559, 2004.
20.
ColemanR.M., CaseN.D., and GuldbergR.E.Hydrogel effects on bone marrow stromal cell response to chondrogenic growth factors. Biomaterials, 28, 2077, 2007.
21.
PerettiG.M., Campo-RuizV., GonzalezS., et al.Tissue engineered cartilage integration to live and devitalized cartilage: a study by reflectance mode confocal microscopy and standard histology. Connect Tissue Res, 47, 190, 2006.
22.
MoranJ.M., PazzanoD., and BonassarL.J.Characterization of polylactic acid–polyglycolic acid composites for cartilage tissue engineering. Tissue Eng, 9, 63, 2003.
23.
ShahS.S., LiangH., PanditS., et al.Optimization of degradation profile for new scaffold in cartilage repair. Cartilage, 9, 438, 2018.
24.
KohY.-G., LeeJ.-A., KimY.S., et al.Optimal mechanical properties of a scaffold for cartilage regeneration using finite element analysis. J Tissue Eng, 10, 2041731419832133, 2019.
LiuH., ChengY., ChenJ., et al.Component effect of stem cell-loaded thermosensitive polypeptide hydrogels on cartilage repair. Acta Biomater, 73, 103, 2018.
27.
NixonA.J., FortierL.A., WilliamsJ., et al.Enhanced repair of extensive articular defects by insulin-like growth factor-I-laden fibrin composites. J Orthop Res, 17, 475, 1999.
28.
SharmaC.Cartilage tissue engineering: current scenario and challenges. AML, 2, 90, 2011.
29.
ChenR., CurranS.J., CurranJ.M., et al.The use of poly(l-lactide) and RGD modified microspheres as cell carriers in a flow intermittency bioreactor for tissue engineering cartilage. Biomaterials, 27, 4453, 2006.
30.
ChanB.P., and LeongK.W.Scaffolding in tissue engineering: general approaches and tissue-specific considerations. Eur Spine J, 17, 467, 2008.
31.
VelascoM.A., Narváez-TovarC.A., and Garzón-AlvaradoD.A.Design, materials, and mechanobiology of biodegradable scaffolds for bone tissue engineering. BioMed Res Int, 2015, 1, 2015.
32.
BryantS.J., AnsethK.S., LeeD.A., et al.Crosslinking density influences the morphology of chondrocytes photoencapsulated in PEG hydrogels during the application of compressive strain. J Orthop Res, 22, 1143, 2004.
33.
LiC., GuoC., FitzpatrickV., et al.Design of biodegradable, implantable devices towards clinical translation. Nat Rev Mater, 5, 61, 2020.
34.
RatnerB.Biomaterials: Been There, Done That, and Evolving into the Future | Annual Review of Biomedical Engineering. Annu Rev Biomed Eng, 21, 171, 2019.
35.
AlghuwainemA., AlshareedaA.T., and AlsowayanB.Scaffold-Free 3-D cell sheet technique bridges the Gap between 2-D cell culture and animal models. Int J Mol Sci, 20, 19, 2019.
HeringT.M.Regulation of chondrocyte gene expression. Front Biosci, 4, D743, 1999.
38.
ZhaoZ., LiY., WangM., et al.Mechanotransduction pathways in the regulation of cartilage chondrocyte homoeostasis. J Cell Mol Med, 24, 5408, 2020.
39.
ElderS.H., SandersS.W., McCulleyW.R., et al.Chondrocyte response to cyclic hydrostatic pressure in alginate versus pellet culture. J Orthop Res, 24, 740, 2006.
40.
LeeJ.K., LinkJ.M., HuJ.C.Y., et al. The self-assembling process and applications in tissue engineering. Cold Spring Harb Perspect Med, 7, a025668, 2017.
41.
KatakaiD., ImuraM., AndoW., et al.Compressive properties of cartilage-like tissues repaired in vivo with scaffold-free, tissue engineered constructs. Clin Biomech, 24, 110, 2009.
42.
HerzogW., and FedericoS.Considerations on joint and articular cartilage mechanics. Biomech Model Mechanobiol, 5, 64, 2006.
43.
ResponteD.J., LeeJ.K., HuJ.C., et al.Biomechanics-driven chondrogenesis: from embryo to adult. FASEB J, 26, 3614, 2012.
44.
HuJ.C., and AthanasiouK.A.A self-assembling process in articular cartilage tissue engineering. Tissue Eng, 12, 969, 2006.
45.
NapolitanoA.P., ChaiP., DeanD.M., et al.Dynamics of the self-assembly of complex cellular aggregates on micromolded nonadhesive hydrogels. Tissue Eng, 13, 2087, 2007.
46.
LuY., ZhangW., WangJ., et al.Recent advances in cell sheet technology for bone and cartilage regeneration: from preparation to application. Int J Oral Sci, 11, 1, 2019.
OfekG., RevellC.M., HuJ.C., et al.Matrix development in self-assembly of articular cartilage. PLoS One, 3, e2795, 2008.
49.
MattaC., and MobasheriA.Regulation of chondrogenesis by protein kinase C: emerging new roles in calcium signalling. Cell Signal, 26, 979, 2014.
50.
BobickB.E., ChenF.H., LeA.M., et al.Regulation of the chondrogenic phenotype in culture. Birth Defects Res C Embryo Today Rev, 87, 351, 2009.
51.
MelloM.A., and TuanR.S.High density micromass cultures of embryonic limb bud mesenchymal cells: an in vitro model of endochondral skeletal development. In Vitro Cell Dev Biol Anim, 35, 262, 1999.
52.
StuartM.P., MatsuiR.A.M., SantosM.F.S., et al. Successful low-cost scaffold-free cartilage tissue engineering using human cartilage progenitor cell spheroids formed by micromolded nonadhesive hydrogel. Stem Cells Int, 2017, e7053465, 2017.
53.
RevellC.M., ReynoldsC.E., and AthanasiouK.A.Effects of initial cell seeding in self assembly of articular cartilage. Ann Biomed Eng, 36, 1441, 2008.
54.
FotyR.A., and SteinbergM.S.The differential adhesion hypothesis: a direct evaluation. Dev Biol, 278, 255, 2005.
55.
ZhangB., YangS., SunZ., et al.Human mesenchymal stem cells induced by growth differentiation factor 5: an improved self-assembly tissue engineering method for cartilage repair. Tissue Eng C Methods, 17, 1189, 2011.
56.
MakrisE.A., ResponteD.J., PaschosN.K., et al.Developing functional musculoskeletal tissues through hypoxia and lysyl oxidase-induced collagen cross-linking. Proc Natl Acad Sci USA, 111, E4832, 2014.
57.
WhiteJ.L., WalkerN.J., HuJ.C., et al.A comparison of bone marrow and cord blood mesenchymal stem cells for cartilage self-assembly. Tissue Eng A, 24, 1262, 2018.
58.
LeddyH.A., AwadH.A., and GuilakF.Molecular diffusion in tissue-engineered cartilage constructs: effects of scaffold material, time, and culture conditions. J Biomed Mater Res B Appl Biomater, 70, 397, 2004.
59.
GigoutA., BuschmannM.D., and JolicoeurM.Chondrocytes cultured in stirred suspension with serum-free medium containing pluronic-68 aggregate and proliferate while maintaining their differentiated phenotype. Tissue Eng A, 15, 2237, 2009.
60.
SuzukiS., MunetaT., TsujiK., et al.Properties and usefulness of aggregates of synovial mesenchymal stem cells as a source for cartilage regeneration. Arthritis Res Ther, 14, 1, 2012.
61.
JonnalagaddaU.S., HillM., MessaoudiW., et al.Acoustically modulated biomechanical stimulation for human cartilage tissue engineering. Lab Chip, 18, 473, 2018.
62.
TranS.C., CooleyA.J., and ElderS.H.Effect of a mechanical stimulation bioreactor on tissue engineered, scaffold-free cartilage. Biotechnol Bioeng, 108, 1421, 2011.
63.
CheukY.-C., WongM.W.-N., LeeK.-M., et al.Use of allogeneic scaffold-free chondrocyte pellet in repair of osteochondral defect in a rabbit model. J Orthop Res, 29, 1343, 2011.
64.
FurukawaK.S., ImuraK., TateishiT., et al.Scaffold-free cartilage by rotational culture for tissue engineering. J Biotechnol, 133, 134, 2008.
65.
FurukawaK.S., SuenagaH., ToitaK., et al.Rapid and large-scale formation of chondrocyte aggregates by rotational culture. Cell Transplant, 12, 475, 2003.
66.
KolettasE., BuluwelaL., BaylissM.T., et al.Expression of cartilage-specific molecules is retained on long-term culture of human articular chondrocytes. J Cell Sci, 108(Pt 5), 1991, 1995.
67.
ZhangZ., McCafferyJ.M., SpencerR.G.S., et al. Hyaline cartilage engineered by chondrocytes in pellet culture: histological, immunohistochemical and ultrastructural analysis in comparison with cartilage explants. J Anat, 205, 229, 2004.
68.
BaburB.K., GhanaviP., LevettP., et al.The interplay between chondrocyte redifferentiation pellet size and oxygen concentration. PLoS One, 8, e58865, 2013.
69.
AndererU., and LiberaJ.In vitro engineering of human autogenous cartilage. J Bone Miner Res, 17, 1420, 2002.
70.
KobayashiJ., KikuchiA., AoyagiT., et al.Cell sheet tissue engineering: cell sheet preparation, harvesting/manipulation, and transplantation. J Biomed Mater Res A, 107, 955, 2019.
71.
OhkiT., YamatoM., MurakamiD., et al.Treatment of oesophageal ulcerations using endoscopic transplantation of tissue-engineered autologous oral mucosal epithelial cell sheets in a canine model. Gut, 55, 1704, 2006.
72.
TsumanumaY., IwataT., WashioK., et al.Comparison of different tissue-derived stem cell sheets for periodontal regeneration in a canine 1-wall defect model. Biomaterials, 32, 5819, 2011.
YoshikawaY., MiyagawaS., TodaK., et al.Myocardial regenerative therapy using a scaffold-free skeletal-muscle-derived cell sheet in patients with dilated cardiomyopathy even under a left ventricular assist device: a safety and feasibility study. Surg Today, 48, 200, 2018.
75.
KaneshiroN., SatoM., IshiharaM., et al.Bioengineered chondrocyte sheets may be potentially useful for the treatment of partial thickness defects of articular cartilage. Biochem Biophys Res Commun, 349, 723, 2006.
76.
GreenH., KehindeO., and ThomasJ.Growth of cultured human epidermal cells into multiple epithelia suitable for grafting. Proc Natl Acad Sci U S A, 76, 5665, 1979.
77.
ItoA., InoK., KobayashiT., et al.The effect of RGD peptide-conjugated magnetite cationic liposomes on cell growth and cell sheet harvesting. Biomaterials, 26, 6185, 2005.
78.
Guillaume-GentilO., AkiyamaY., SchulerM., et al.Polyelectrolyte coatings with a potential for electronic control and cell sheet engineering. Adv Mater, 20, 560, 2008.
79.
OwakiT., ShimizuT., YamatoM., et al.Cell sheet engineering for regenerative medicine: current challenges and strategies. Biotechnol J, 9, 904, 2014.
80.
OkanoT., YamadaN., OkuharaM., et al.Mechanism of cell detachment from temperature-modulated, hydrophilic- hydrophobic polymer surfaces. Biomaterials, 16, 7, 1995.
81.
MatsudaN., ShimizuT., YamatoM., et al.Tissue engineering based on cell sheet technology. Adv Mater, 19, 3089, 2007.
82.
EbiharaG., SatoM., YamatoM., et al.Cartilage repair in transplanted scaffold-free chondrocyte sheets using a minipig model. Biomaterials, 33, 3846, 2012.
83.
MitaniG., SatoM., LeeJ.I., et al.The properties of bioengineered chondrocyte sheets for cartilage regeneration. BMC Biotechnol, 9, 17, 2009.
84.
FujieH., NansaiR., AndoW., et al.Zone-specific integrated cartilage repair using a scaffold-free tissue engineered construct derived from allogenic synovial mesenchymal stem cells: biomechanical and histological assessments. J Biomech, 48, 4101, 2015.
85.
ItokazuM., WakitaniS., MeraH., et al.Transplantation of scaffold-free cartilage-like cell-sheets made from human bone marrow mesenchymal stem cells for cartilage repair. Cartilage, 7, 361, 2016.
86.
McCormickF., ColeB.J., NwachukwuB., et al.Treatment of focal cartilage defects with a juvenile allogeneic 3-dimensional articular cartilage graft. Oper Tech Sports Med, 21, 95, 2013.
87.
SatoM., YamatoM., HamahashiK., et al.Articular cartilage regeneration using cell sheet technology. Anat Record, 297, 36, 2014.
SchnabelM., MarlovitsS., EckhoffG., et al.Dedifferentiation-associated changes in morphology and gene expression in primary human articular chondrocytes in cell culture. Osteoarthritis Cartilage, 10, 62, 2002.
90.
ThorpH., KimK., KondoM., et al.Fabrication of hyaline-like cartilage constructs using mesenchymal stem cell sheets. Sci Rep, 10, 20869, 2020.
91.
ShimomuraK., AndoW., MoriguchiY., et al.Next generation mesenchymal stem cell (MSC)–based cartilage repair using scaffold-free tissue engineered constructs generated with synovial mesenchymal stem cells. Cartilage, 6, 13S, 2015.
92.
BartzC., MeixnerM., GiesemannP., et al.An ex vivo human cartilage repair model to evaluate the potency of a cartilage cell transplant. J Transl Med, 14, 317, 2016.
93.
BecherC., LauteV., FickertS., et al.Safety of three different product doses in autologous chondrocyte implantation: results of a prospective, randomised, controlled trial. J Orthop Surg Res, 12, 71, 2017.
94.
MurataD., AkiedaS., MisumiK., et al.Osteochondral regeneration with a scaffold-free three-dimensional construct of adipose tissue-derived mesenchymal stromal cells in pigs. Tissue Eng Regen Med, 15, 101, 2018.
95.
LeeJ.K., HuweL.W., PaschosN., et al.Tension stimulation drives tissue formation in scaffold-free systems. Nat Mater, 16, 864, 2017.
96.
ScalzoneA., WangX.N., DalgarnoK., et al. A chondrosphere-based scaffold free approach to manufacture an in vitro articular cartilage model. Tissue Eng Part A 2021 [Epub ahead of print]; DOI: 10.1089/ten.tea.2021.0061.
97.
GroganS.P., DorthéE.W., GlembotskiN.E., et al.Cartilage tissue engineering combining microspheroid building blocks and microneedle arrays. Connect Tissue Res, 61, 229, 2020.
98.
SriwatananukulkitO., TawonsawatrukT., RattanapinyopitukK., et al. Scaffold-free cartilage construct from infrapatellar fat pad stem cells for cartilage restoration. Tissue Eng Part A 2020 [Epub ahead of print]; DOI: 10.1089/ten.tea.2020.0167.
99.
KimuraT., YamashitaA., OzonoK., et al.Limited immunogenicity of human induced pluripotent stem cell-derived cartilages. Tissue Eng Part A, 22, 1367, 2016.
100.
VapniarskyN., KwonH., PaschosN.K., et al.Adult Dermal Stem Cells for Scaffold-Free Cartilage Tissue Engineering: exploration of Strategies. Tissue Eng C Methods, 26, 598, 2020.
101.
KoizumiK., EbinaK., HartD.A., et al.Synovial mesenchymal stem cells from osteo- or rheumatoid arthritis joints exhibit good potential for cartilage repair using a scaffold-free tissue engineering approach. Osteoarthritis Cartilage, 24, 1413, 2016.
102.
YasuiY., ChijimatsuR., HartD.A., et al.Preparation of scaffold-free tissue-engineered constructs derived from human synovial mesenchymal stem cells under low oxygen tension enhances their chondrogenic differentiation capacity. Tissue Eng Part A, 22, 490, 2016.
103.
ShimomuraK., YasuiY., KoizumiK., et al.First-in-human pilot study of implantation of a scaffold-free tissue-engineered construct generated from autologous synovial mesenchymal stem cells for repair of knee chondral lesions. Am J Sports Med, 46, 2384, 2018.
104.
SatoM., YamatoM., MitaniG., et al.Combined surgery and chondrocyte cell-sheet transplantation improves clinical and structural outcomes in knee osteoarthritis. npj Regen Med, 4, 1, 2019.
105.
ParkI.-S., JinR.L., OhH.J., et al.Sizable scaffold-free tissue-engineered articular cartilage construct for cartilage defect repair. Artif Organs, 43, 278, 2019.
106.
FrerkerN., KarlsenT.A., LilledahlM.B., et al. Scaffold-free engineering of human cartilage implants. Cartilage 2021 [Epub ahed of print]; DOI: 10.1177/19476035211007923.
107.
SivadasV.P., DhawanS., BabuJ., et al.Glutamic acid-based dendritic peptides for scaffold-free cartilage tissue engineering. Acta Biomater, 99, 196, 2019.
108.
WhitneyG.A., KeanT.J., FernandesR.J., et al.Thyroxine increases collagen type II expression and accumulation in scaffold-free tissue-engineered articular cartilage. Tissue Eng Part A, 24, 369, 2017.
109.
MasudaK., SahR.L., HejnaM.J., et al.A novel two-step method for the formation of tissue-engineered cartilage by mature bovine chondrocytes: the alginate-recovered-chondrocyte (ARC) method. J Orthop Res, 21, 139, 2003.
110.
BornesT.D., AdesidaA.B., and JomhaN.M.Mesenchymal stem cells in the treatment of traumatic articular cartilage defects: a comprehensive review. Arthritis Res Ther, 16, 432, 2014.
111.
LeH., XuW., ZhuangX., et al.Mesenchymal stem cells for cartilage regeneration. J Tissue Eng, 11, 2041731420943839, 2020.
112.
SakaguchiY., SekiyaI., YagishitaK., et al.Comparison of human stem cells derived from various mesenchymal tissues: superiority of synovium as a cell source. Arthritis Rheum, 52, 2521, 2005.
113.
HanY., LiX., ZhangY., et al.Mesenchymal stem cells for regenerative medicine. Cells, 8, 886, 2019.
114.
VonkL.A., Link to external site this link will open in a new windowRoël, G., et al. Role of matrix-associated autologous chondrocyte implantation with spheroids in the treatment of large chondral defects in the knee: a systematic review. Int J Mol Sci, 22, 7149, 2021.
115.
NiemeyerP., LauteV., ZinserW., et al.A prospective, randomized, open-label, multicenter, Phase III noninferiority trial to compare the clinical efficacy of matrix-associated autologous chondrocyte implantation with spheroid technology versus arthroscopic microfracture for cartilage defects of the knee. Orthop J Sports Med, 7, 2325967119854442, 2019.
116.
RainbowR., RenW., and ZengL.Inflammation and joint tissue interactions in oa: implications for potential therapeutic approaches. Arthritis, 2012, 1, 2012.
117.
RainbowR.S., KwonH., FooteA.T., et al.Muscle cell-derived factors inhibit inflammatory stimuli-induced damage in hMSC-derived chondrocytes. Osteoarthritis Cartilage, 21, 990, 2013.
118.
ElderB.D., and AthanasiouK.A.Systematic assessment of growth factor treatment on biochemical and biomechanical properties of engineered articular cartilage constructs. Osteoarthritis Cartilage, 17, 114, 2009.
119.
MoorL.D., FernandezL., VercruysseC., et al.Hybrid bioprinting of chondrogenically induced human mesenchymal stem cell spheroids. Front Bioeng Biotechnol, 8, 484, 2020.
120.
YuY., MoncalK.K., LiJ., et al.Three-dimensional bioprinting using self-assembling scalable scaffold-free “tissue strands” as a new bioink. Sci Reports, 6, 28714, 2016.
121.
WuY., AyanB., MoncalK.K., et al.Hybrid bioprinting of zonally stratified human articular cartilage using scaffold-free tissue strands as building blocks. Adv Healthcare Mater, 9, 2001657, 2020.
122.
WuY., KennedyP., BonazzaN., et al.Three-dimensional bioprinting of articular cartilage: a systematic review. Cartilage, 12, 76, 2021.
123.
LiaoI.-C., MoutosF.T., EstesB.T., et al.Composite three-dimensional woven scaffolds with interpenetrating network hydrogels to create functional synthetic articular cartilage. Adv Funct Mater, 23, 5833, 2013.
124.
DanielsA.U., AndrianoK.P., SmutzW.P., et al.Evaluation of absorbable poly(ortho esters) for use in surgical implants. J Appl Biomater, 5, 51, 1994.
125.
BadylakS.F., and GilbertT.W.Immune response to biologic scaffold materials. Semin Immunol, 20, 109, 2008.
126.
YoonD.M., and FisherJ.P.Chondrocyte signaling and artificial matrices for articular cartilage engineering. Adv Exp Med Biol, 585, 67, 2006.
