Sage Journals: Discover world-class research

Abstract

Irregular defects at sites of degenerative cartilage often accompany osteoarthritis (OA). The development of novel cell-/biomaterial-based cartilage tissue engineering methods to address these defects may provide a durable approach to hinder the development of OA. In this study, we fabricated a neocartilage patch by fusing cell aggregates onto a biodegradable nanofiber film for degenerative cartilage repair. Human mesenchymal stem/stromal cell (MSC) aggregates were prepared and induced for chondrogenesis in a thermosensitive hydrogel, poly (N-isopropylacrylamide-co-acrylic acid (p(NIPAAm-AA)). Cell migration mediated the formation of cell aggregates in the thermosensitive hydrogel and led to a cell-dense hollow shell structure. The chondrocytes derived from MSC aggregates in the hydrogel were evidenced by the expression of chondrogenesis-related genes and extracellular matrices. They were fused onto an electrospun film by mechanical force and spatial confinement to generate a neo-cartilage patch. The fabricated neocartilage patches may be able to integrate into the irregular defects under compressive stresses and achieve cartilage regeneration in vivo.

Impact statement

The formation of human mesenchymal stem/stromal cells aggregates in thermosensitive hydrogels was mechanistically examined. These in situ formed cell aggregates with enhanced chondrogenesis were bioengineered into a neocartilage patch for regeneration of superficial irregular cartilage defects.

Get full access to this article

View all access options for this article.

References

Camarero-Espinosa

, Rothen-Rutishauser

, Foster

E.J.

, and Weder

Articular cartilage: from formation to tissue engineering. Biomater Sci, 4, 734, 2016.

Rai

, Dilisio

M.F.

, Dietz

N.E.

, and Agrawal

D.K.

Recent strategies in cartilage repair: a systemic review of the scaffold development and tissue engineering. J Biomed Mater Res A, 105, 2343, 2017.

Shimizu

, Kamei

, Adachi

, et al. Repair mechanism of osteochondral defect promoted by bioengineered chondrocyte sheet. Tissue Eng Part A, 21, 1131, 2014.

Pei

, He

, Li

, Tidwell

J.E.

, Jones

A.C.

, and McDonough

E.B.

Repair of large animal partial-thickness cartilage defects through intraarticular injection of matrix-rejuvenated synovium-derived stem cells. Tissue Eng Part A, 19, 1144, 2012.

Gong

, Zhou

, Wu

, et al. Proteomic analysis profile of engineered articular cartilage with chondrogenic differentiated adipose tissue-derived stem cells loaded polyglycolic acid mesh for weight-bearing area defect repair. Tissue Eng Part A, 20, 575, 2013.

Sivashanmugam

, Arun Kumar

, Vishnu Priya

, Nair

S.V.

, and Jayakumar

An overview of injectable polymeric hydrogels for tissue engineering. Eur Polym J, 72, 543, 2015.

Radhakrishnan

, Subramanian

, Krishnan

U.M.

, and Sethuraman

Injectable and 3D bioprinted polysaccharide hydrogels: from cartilage to osteochondral tissue engineering. Biomacromolecules, 18, 1, 2017.

Sébastien

, Ang-Chen

, Yan

, and Teng

Three-dimensional aggregates of mesenchymal stem cells: cellular mechanisms, biological properties, and applications. Tissue Eng Part B Rev, 20, 365, 2014.

Lee

Y.B.

, Kim

E.M.

, Byun

, et al. Engineering spheroids potentiating cell-cell and cell-ECM interactions by self-assembly of stem cell microlayer. Biomaterials, 165, 105, 2018.

10.

Yoon

H.H.

, Bhang

S.H.

, Shin

J.-Y.

, Shin

, and Kim

B.-S.

Enhanced cartilage formation via three-dimensional cell engineering of human adipose-derived stem cells. Tissue Eng Part A, 18, 1949, 2012.

11.

Hildebrandt

, Buth

, and Thielecke

A scaffold-free in vitro model for osteogenesis of human mesenchymal stem cells. Tissue Cell, 43, 91, 2011.

12.

Cheng

N.C.

, Wang

, and Young

T.H.

The influence of spheroid formation of human adipose-derived stem cells on chitosan films on stemness and differentiation capabilities. Biomaterials, 33, 1748, 2012.

13.

Souza

G.R.

, Molina

J.R.

, Raphael

R.M.

, et al. Three-dimensional tissue culture based on magnetic cell levitation. Nat Nanotechnol, 5, 291, 2010.

14.

Yang

, Xulin

, Ling

, et al. 3D printing human induced pluripotent stem cells with novel hydroxypropyl chitin bioink: scalable expansion and uniform aggregation. Biofabrication, 10, 044101, 2018.

15.

Wang

Y.-L.

, Lin

S.-P.

, Nelli

S.R.

, et al. Self-assembled peptide-based hydrogels as scaffolds for proliferation and multi-differentiation of mesenchymal stem cells. Macromol Biosci, 17, 1600192, 2017.

16.

Maia

F.R.

, Lourenço

A.H.

, Granja

P.L.

, Gonçalves

R.M.

, and Barrias

C.C.

Effect of cell density on mesenchymal stem cells aggregation in rgd-alginate 3D matrices under osteoinductive conditions. Macromol Biosci, 14, 759, 2014.

17.

Mellati

, Kiamahalleh

M.V.

, Madani

S.H.

, et al. Poly(N-isopropylacrylamide) hydrogel/chitosan scaffold hybrid for three-dimensional stem cell culture and cartilage tissue engineering. J Biomed Mater Res A, 104, 2764, 2016.

18.

Mellati

, Dai

, Bi

, Jin

, and Zhang

A biodegradable thermosensitive hydrogel with tuneable properties for mimicking three-dimensional microenvironments of stem cells. RSC Adv, 4, 63951, 2014.

19.

Mellati

, Fan

C.-M.

, Tamayol

, et al. Microengineered 3D cell-laden thermoresponsive hydrogels for mimicking cell morphology and orientation in cartilage tissue engineering. Biotechnol Bioeng, 114, 217, 2017.

20.

Bidarra

S.J.

, Barrias

C.C.

, and Granja

P.L.

Injectable alginate hydrogels for cell delivery in tissue engineering. Acta Biomater, 10, 1646, 2014.

21.

Zhang

, Zhang

, and Xu

CHAPTER 17: smart materials to regulate the fate of stem cells. In: Wang

, ed. Smart Materials for Tissue Engineering: Applications. Cambridge, United Kingdom: The Royal Society of Chemistry, 2017. p. 473.

22.

Zhang

, Yun

, Bi

, et al. Enhanced multi-lineage differentiation of human mesenchymal stem/stromal cells within poly(N-isopropylacrylamide-acrylic acid) microgel-formed three-dimensional constructs. J Mater Chem B, 6, 1799, 2018.

23.

Zhang

, Zhang

, Lin

, et al. Allogeneic primary mesenchymal stem/stromal cell aggregates within poly(N-isopropylacrylamide-co-acrylic acid) hydrogel for osteochondral regeneration. Appl Mater Today, 18, 100487, 2019.

24.

Wang

D.-A.

, Varghese

, Sharma

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

25.

Sharma

, Fermanian

, Gibson

, et al. Human cartilage repair with a photoreactive adhesive-hydrogel composite. Sci Transl Med, 5, 167, 2013.

26.

Gomoll

A.H.

, Probst

, Farr

, Cole

B.J.

, and Minas

Use of a type i/iii bilayer collagen membrane decreases reoperation rates for symptomatic hypertrophy after autologous chondrocyte implantation. Am J Sports Med, 37, 20, 2009.

27.

Guan

, and Zhang

PNIPAM microgels for biomedical applications: from dispersed particles to 3D assemblies. Soft Matter, 7, 6375, 2011.

28.

Liu

Y.-J.

, Le Berre

, Lautenschlaeger

, et al. Confinement and low adhesion induce fast amoeboid migration of slow mesenchymal cells. Cell, 160, 659, 2015.

29.

Vanden Berg-Foels

W.S.

In situ tissue regeneration: chemoattractants for endogenous stem cell recruitment. Tissue Eng Part B Rev, 20, 28, 2014.

30.

Laird

D.J.

, von Andrian

U.H.

, and Wagers

A.J.

Stem cell trafficking in tissue development, growth, and disease. Cell, 132, 612, 2008.

31.

Chaudhuri

, Gu

, Klumpers

, et al. Hydrogels with tunable stress relaxation regulate stem cell fate and activity. Nat Mater, 15, 326, 2015.

32.

Poole

C.A.

Articular cartilage chondrons: form, function and failure. J Anat, 191, 1, 1997.

33.

Edmondson

, Broglie

J.J.

, Adcock

A.F.

, and Yang

Three-dimensional cell culture systems and their applications in drug discovery and cell-based biosensors. Assay Drug Dev Technol, 12, 207, 2014.

34.

Friedl

, and Gilmour

Collective cell migration in morphogenesis, regeneration and cancer. Nat Rev Mol Cell Biol, 10, 445, 2009.

35.

Fahy

, Alini

, and Stoddart

M.J.

Mechanical stimulation of mesenchymal stem cells: implications for cartilage tissue engineering. J Orthop Res, 36, 52, 2018.

36.

Bhumiratana

, Eton

R.E.

, Oungoulian

S.R.

, Wan

L.Q.

, Ateshian

G.A.

, and Vunjak-Novakovic

Large, stratified, and mechanically functional human cartilage grown in vitro by mesenchymal condensation. Proc Natl Acad Sci U S A, 111, 6940, 2014.

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.

0.61 MB

0.00 MB

Fabrication of a Cartilage Patch by Fusing Hydrogel-Derived Cell Aggregates onto Electrospun Film

Abstract

Impact statement

Get full access to this article

References

Supplementary Material