Sage Journals: Discover world-class research

Abstract

Cell-based therapies offer great promise for repairing cartilage. Previous strategies often involved using a single cell population such as stem cells or chondrocytes. A mixed cell population may offer an alternative strategy for cartilage regeneration while overcoming donor scarcity. We have recently reported that adipose-derived stem cells (ADSCs) can catalyze neocartilage formation by neonatal chondrocytes (NChons) when mixed co-cultured in 3D hydrogels in vitro. However, it remains unknown how the biochemical and mechanical cues of hydrogels modulate cartilage formation by mixed cell populations in vivo. The present study seeks to answer this question by co-encapsulating ADSCs and NChons in 3D hydrogels with tunable stiffness (∼1–33 kPa) and biochemical cues, and evaluating cartilage formation in vivo using a mouse subcutaneous model. Three extracellular matrix molecules were examined, including chondroitin sulfate (CS), hyaluronic acid (HA), and heparan sulfate (HS). Our results showed that the type of biochemical cue played a dominant role in modulating neocartilage deposition. CS and HA enhanced type II collagen deposition, a desirable phenotype for articular cartilage. In contrast, HS promoted fibrocartilage phenotype with the upregulation of type I collagen and failed to retain newly deposited matrix. Hydrogels with stiffnesses of ∼7–33 kPa led to a comparable degree of neocartilage formation, and a minimal initial stiffness was required to retain hydrogel integrity over time. Results from this study highlight the important role of matrix cues in directing neocartilage formation, and they offer valuable insights in guiding optimal scaffold design for cartilage regeneration by using mixed cell populations.

Get full access to this article

View all access options for this article.

References

Allen

K.D.

, and Golightly

Y.M.

State of the evidence. Current opinion in rheumatology, 27, 276, 2015.

Griffin

T.M.

, and Guilak

The role of mechanical loading in the onset and progression of osteoarthritis. Exerc Sport Sci Rev, 33, 195, 2005.

Huey

D.J.

, Hu

J.C.

, and Athanasiou

K.A.

Unlike bone, cartilage regeneration remains elusive. Science, 338, 917, 2012.

Mobasheri

, Kalamegam

, Musumeci

, and Batt

M.E.

Chondrocyte and mesenchymal stem cell-based therapies for cartilage repair in osteoarthritis and related orthopaedic conditions. Maturitas, 78, 188, 2014.

Brittberg

, Peterson

, Sjogren-Jansson

, Tallheden

, and Lindahl

Articular cartilage engineering with autologous chondrocyte transplantation. A review of recent developments. J Bone Joint Surg Am, 85-A Suppl 3, 109, 2003.

Redman

S.N.

, Oldfield

S.F.

, and Archer

C.W.

Current strategies for articular cartilage repair. Eur Cells Mater, 9, 23, 2005; discussion 23.

Zuk

P.A.

, Zhu

, Mizuno

, Huang

, Futrell

J.W.

, Katz

A.J.

, et al. Multilineage cells from human adipose tissue: implications for cell-based therapies. Tissue Eng, 7, 211, 2001.

Estes

B.T.

, Diekman

B.O.

, Gimble

J.M.

, and Guilak

Isolation of adipose-derived stem cells and their induction to a chondrogenic phenotype. Nat Protoc, 5, 1294, 2010.

Awad

H.A.

, Wickham

M.Q.

, Leddy

H.A.

, Gimble

J.M.

, and Guilak

Chondrogenic differentiation of adipose-derived adult stem cells in agarose, alginate, and gelatin scaffolds. Biomaterials, 25, 3211, 2004.

10.

Peran

, Ruiz

, Kwiatkowski

, Marchal

J.A.

, Yang

S.L.

, Aranega

, et al. Activin/BMP2 chimeric ligands direct adipose-derived stem cells to chondrogenic differentiation. Stem Cell Res, 10, 464, 2013.

11.

Erickson

G.R.

, Gimble

J.M.

, Franklin

D.M.

, Rice

H.E.

, Awad

, and Guilak

Chondrogenic potential of adipose tissue-derived stromal cells in vitro and in vivo. Biochem Biophys Res Commun, 290, 763, 2002.

12.

Wang

, Lai

J.H.

, Han

L.H.

, Tong

, and Yang

Chondrogenic differentiation of adipose-derived stromal cells in combinatorial hydrogels containing cartilage matrix proteins with decoupled mechanical stiffness. Tissue Eng Part A, 20, 2131, 2014.

13.

Lai

J.H.

, Kajiyama

, Smith

R.L.

, Maloney

, and Yang

Stem cells catalyze cartilage formation by neonatal articular chondrocytes in 3D biomimetic hydrogels. Sci Rep, 3, 3553, 2013.

14.

Meretoja

V.V.

, Dahlin

R.L.

, Kasper

F.K.

, and Mikos

A.G.

Enhanced chondrogenesis in co-cultures with articular chondrocytes and mesenchymal stem cells. Biomaterials, 33, 6362, 2012.

15.

Hildner

, Concaro

, Peterbauer

, Wolbank

, Danzer

, Lindahl

, et al. Human adipose-derived stem cells contribute to chondrogenesis in coculture with human articular chondrocytes. Tissue Eng Part A, 15, 3961, 2009.

16.

Murphy

C.M.

, Matsiko

, Haugh

M.G.

, Gleeson

J.P.

, and O'Brien

F.J.

Mesenchymal stem cell fate is regulated by the composition and mechanical properties of collagen-glycosaminoglycan scaffolds. J Mech Behav Biomed Mater, 11, 53, 2012.

17.

Varghese

, Hwang

N.S.

, Canver

A.C.

, Theprungsirikul

, Lin

D.W.

, and Elisseeff

Chondroitin sulfate based niches for chondrogenic differentiation of mesenchymal stem cells. Matrix Biol, 27, 12, 2008.

18.

Wang

D.A.

, Varghese

, Sharma

, Strehin

, Fermanian

, Gorham

, et al. Multifunctional chondroitin sulphate for cartilage tissue-biomaterial integration. Nat Mater, 6, 385, 2007.

19.

Burdick

J.A.

, and Prestwich

G.D.

Hyaluronic acid hydrogels for biomedical applications. Adv Mater, 23, H41, 2011.

20.

Kirn-Safran

C.B.

, Gomes

R.R.

, Brown

A.J.

, and Carson

D.D.

Heparan sulfate proteoglycans: coordinators of multiple signaling pathways during chondrogenesis. Birth Defects Res C Embryo Today, 72, 69, 2004.

21.

Matsuo

, and Kimura-Yoshida

Extracellular distribution of diffusible growth factors controlled by heparan sulfate proteoglycans during mammalian embryogenesis. Philos Trans R Soc Lond B Biol Sci, 369, pii: 20130545, 2014.

22.

Jeon

, Bouhadir

K.H.

, Mansour

J.M.

, and Alsberg

Photocrosslinked alginate hydrogels with tunable biodegradation rates and mechanical properties. Biomaterials, 30, 2724, 2009.

23.

Baier Leach

, Bivens

K.A.

, Patrick

C.W.

Jr. , and Schmidt

C.E.

Photocrosslinked hyaluronic acid hydrogels: natural, biodegradable tissue engineering scaffolds. Biotechnol Bioeng, 82, 578, 2003.

24.

Suri

, and Schmidt

C.E.

Cell-laden hydrogel constructs of hyaluronic acid, collagen, and laminin for neural tissue engineering. Tissue Eng Part A, 16, 1703, 2010.

25.

Zuk

P.A.

, Zhu

, Ashjian

, De Ugarte

D.A.

, Huang

J.I.

, Mizuno

, et al. Human adipose tissue is a source of multipotent stem cells. Mol Biol Cell, 13, 4279, 2002.

26.

Neuman

R.E.

, and Logan

M.A.

The determination of hydroxyproline. J Biol Chem, 184, 299, 1950.

27.

Liu

S.Q.

, Tian

, Hedrick

J.L.

, Po Hui

J.H.

, Ee

P.L.

, and Yang

Y.Y.

Biomimetic hydrogels for chondrogenic differentiation of human mesenchymal stem cells to neocartilage. Biomaterials, 31, 7298, 2010.

28.

Nicodemus

G.D.

, Skaalure

S.C.

, and Bryant

S.J.

Gel structure has an impact on pericellular and extracellular matrix deposition, which subsequently alters metabolic activities in chondrocyte-laden PEG hydrogels. Acta Biomater, 7, 492, 2011.

29.

Bryant

S.J.

, Bender

R.J.

, Durand

K.L.

, and Anseth

K.S.

Encapsulating chondrocytes in degrading PEG hydrogels with high modulus: engineering gel structural changes to facilitate cartilaginous tissue production. Biotechnol Bioeng, 86, 747, 2004.

30.

Bian

, Hou

, Tous

, Rai

, Mauck

R.L.

, and Burdick

J.A.

The influence of hyaluronic acid hydrogel crosslinking density and macromolecular diffusivity on human MSC chondrogenesis and hypertrophy. Biomaterials, 34, 413, 2013.

31.

Chen

W.C.

, Wei

Y.H.

, Chu

I.M.

, and Yao

C.L.

Effect of chondroitin sulphate C on the in vitro and in vivo chondrogenesis of mesenchymal stem cells in crosslinked type II collagen scaffolds. J Tissue Eng Regen Med, 7, 665, 2013.

32.

Coburn

J.M.

, Gibson

, Monagle

, Patterson

, and Elisseeff

J.H.

Bioinspired nanofibers support chondrogenesis for articular cartilage repair. Proc Natl Acad Sci U S A, 109, 10012, 2012.

33.

Bian

, Guvendiren

, Mauck

R.L.

, and Burdick

J.A.

Hydrogels that mimic developmentally relevant matrix and N-cadherin interactions enhance MSC chondrogenesis. Proc Natl Acad Sci U S A, 110, 10117, 2013.

34.

, Jha

A.K.

, Harrington

D.A.

, Farach-Carson

M.C.

, and Jia

Hyaluronic acid-based hydrogels: from a natural polysaccharide to complex networks. Soft Matter, 8, 3280, 2012.

35.

Kim

I.L.

, Mauck

R.L.

, and Burdick

J.A.

Hydrogel design for cartilage tissue engineering: a case study with hyaluronic acid. Biomaterials, 32, 8771, 2011.

36.

Guimond

S.E.

, and Turnbull

J.E.

Fibroblast growth factor receptor signalling is dictated by specific heparan sulphate saccharides. Curr Biol, 9, 1343, 1999.

37.

Cool

S.M.

, and Nurcombe

The osteoblast-heparan sulfate axis: control of the bone cell lineage. Int J Biochem Cell Biol, 37, 1739, 2005.

38.

Ornitz

D.M.

FGFs, heparan sulfate and FGFRs: complex interactions essential for development. Bioessays, 22, 108, 2000.

39.

Roberts

J.J.

, Nicodemus

G.D.

, Greenwald

E.C.

, and Bryant

S.J.

Degradation improves tissue formation in (un)loaded chondrocyte-laden hydrogels. Clin Orthop Relat Res, 469, 2725, 2011.

40.

Rice

M.A.

, and Anseth

K.S.

Encapsulating chondrocytes in copolymer gels: bimodal degradation kinetics influence cell phenotype and extracellular matrix development. J Biomed Mater Res Part A, 70, 560, 2004.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.09 MB

0.02 MB

0.00 MB

Effects of Hydrogel Stiffness and Extracellular Compositions on Modulating Cartilage Regeneration by Mixed Populations of Stem Cells and Chondrocytes In Vivo

Abstract

Get full access to this article

References

Supplementary Material