Differentiation of mesenchymal stem cells in chitosan scaffolds with double micro and macroporosity

Cruz, Dunia M. García; Gomes, Manuela E.; Reis, Rui L.; Moratal, David; Salmerón‐Sánchez, Manuel; Ribelles, J.L. Gómez; Mano, João F.

doi:10.1002/jbm.a.32906

Cited by 43 publications

(18 citation statements)

References 59 publications

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“…Scaffolds S2 showed also the lowest growth of 3T3 fibroblasts on 6th day of cell cultivation. The values of cell viability estimated by XTT were similar to the values obtained in other experiments for study of cell growth in polymer scaffolds by other colorimetric assays for assessing cell metabolic activity (Zhang et al 2010;Cruz et al 2010;Ribeiro-Samy et al 2013).…”

Section: Cell Growth In Scaffoldssupporting

confidence: 84%

“…The observed data on the growth of cells on polymer scaffolds can be connected both with the properties of PHB/PEG composite and the morphology of these scaffolds. The physicochemical (e.g., mechanical) properties of polymer materials have a great influence on growth and differentiation of stem cells grown on them (Cruz et al 2010;Raucci et al 2012;Rumian et al 2013;Humpolicek et al 2015;Fraioli et al 2016;Zhang et al 2016;Kuznetsova et al 2016). Moreover, apparently PHB is an example of such biomaterial possessing osteoinductive properties: scaffolds based on PHB can induce spontaneous differentiation of stem cells and stimulate bone tissue regeneration in vivo (Wang et al 2004;Bonartsev et al 2008;Shishatskaya et al 2014;Lim et al 2017).…”

Section: Cell Growth In Scaffoldsmentioning

confidence: 99%

“…Scaffolds with mean pore sizes ranging from 20 to 1500 µm were used in bone tissue engineering applications (Richardson et al 2006;Oh et al 2007;Zhang et al 2010;Moisenovich et al 2015;Rumian et al 2013;Kuznetsova et al 2016). The minimum pore size for a significant bone growth and MSC cultivation is 40 µm with an optimal range of 100-200 µm (Klawitter et al 1976;Richardson et al 2006;Cruz et al 2010;Misra et al 2010;Zhang et al 2010;Murphy et al 2010;Ribeiro-Samy et al 2013;Shishatskaya et al 2014;Hadjicharalambous et al 2015). However, as shown in the study of growth of different kinds of cells (chondrocytes, osteoblasts, and fibroblasts) in cylindrical polycaprolactone scaffolds with gradually increasing pore size (from 88 to 405 µm) and porosity (from 80 to 94%), the difference in scaffold microstructure is relevant only for long-term cultivation of cells, while the growth of cells with a duration of their cultivation of less than 14 days was the same and did not depended on pore size and porosity (Oh et al 2007).…”

Section: Cell Growth In Scaffoldsmentioning

confidence: 99%

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Poly(3-hydroxybutyrate)/poly(ethylene glycol) scaffolds with different microstructure: the effect on growth of mesenchymal stem cells

et al. 2018

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Development of biocompatible 3D scaffolds is one of the most important challenges in tissue engineering. In this study, we developed polymer scaffolds of different design and microstructure to study cell growth in them. To obtain scaffolds of various microstructure, e.g., size of pores, we used double- and one-stage leaching methods using porogens with selected size of crystals. A composite of poly(3-hydroxybutyrate) (PHB) with poly(ethylene glycol) (PEG) (PHB/PEG) was used as polymer biomaterial for scaffolds. The morphology of scaffolds was analyzed by scanning electron microscopy; the Young modulus of scaffolds was measured by rheometry. The ability to support growth of mesenchymal stem cells (MSCs) in scaffolds was studied using the XTT assay; the phenotype of MSC was preliminarily confirmed by flow cytometry and the activity of alkaline phosphatase and expression level of CD45 marker was studied to test possible MSC osteogenic differentiation. The obtained scaffolds had different microstructure: the scaffolds with uniform pore size of about 125 µm (normal pores) and 45 µm (small pores) and scaffolds with broadly distributed pores size from about 50-100 µm. It was shown that PHB/PEG scaffolds with uniform pores of normal size did not support MSCs growth probably due to their marked spontaneous osteogenic differentiation in these scaffolds, whereas PHB/PEG scaffolds with diverse pore size promoted stem cells growth that was not accompanied by pronounced differentiation. In scaffolds with small pores (about 45 µm), the growth of MSC was the lowest and cell growth suppression was only partially related to stem cells differentiation. Thus, apparently, the broadly distributed pore size of PHB/PEG scaffolds promoted MSC growth in them, whereas uniform size of scaffold pores stimulated MSC osteogenic differentiation.

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Section: Cell Growth In Scaffoldssupporting

confidence: 84%

Section: Cell Growth In Scaffoldsmentioning

confidence: 99%

Section: Cell Growth In Scaffoldsmentioning

confidence: 99%

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Poly(3-hydroxybutyrate)/poly(ethylene glycol) scaffolds with different microstructure: the effect on growth of mesenchymal stem cells

et al. 2018

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“…Chitosan solution concentration affects pore diameter, pore wall thickness and thus scaffold mechanical properties whereby higher concentrations correlate with smaller pores and thicker pore walls. 84 Whereas lyophilization can be time and energy intensive, freeze gelation can be a more efficient process that also minimizes the presence of residual acetic acid in scaffolds. 85 Care must be taken, however, to optimize the freeze gelation system to minimize local melting during gelation.…”

Section: Scaffold Fabrication Methodsmentioning

confidence: 99%

Chitosan-based scaffolds for bone tissue engineering

2014

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Bone defects requiring grafts to promote healing are frequently occurring and costly problems in health care. Chitosan, a biodegradable, naturally occurring polymer, has drawn considerable attention in recent years as scaffolding material in tissue engineering and regenerative medicine. Chitosan is especially attractive as a bone scaffold material because it supports the attachment and proliferation of osteoblast cells as well as formation of mineralized bone matrix. In this review, we discuss the fundamentals of bone tissue engineering and the unique properties of chitosan as a scaffolding material to treat bone defects for hard tissue regeneration. We present the common methods for fabrication and characterization of chitosan scaffolds, and discuss the influence of material preparation and addition of polymeric or ceramic components or biomolecules on chitosan scaffold properties such as mechanical strength, structural integrity, and functional bone regeneration. Finally, we highlight recent advances in development of chitosan-based scaffolds with enhanced bone regeneration capability.

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“…Chitosan scaffolds with hierarchical pore structure were prepared by a combination of freeze gelation and leaching out technique of PEMA microspheres, used as porogen as described in previous work 23. Briefly, CHT solutions with concentration of 4 wt % were poured into a cylindrical mold (7 mm diameter and 25 mm thickness), mixed with 70 wt % of PEMA microspheres and frozen in liquid nitrogen (−196°C).…”

Section: Methodsmentioning

confidence: 99%

Stirred flow bioreactor modulates chondrocyte growth and extracellular matrix biosynthesis in chitosan scaffolds

Cruz

Salmerón‐Sánchez

Ribelles

2012

J Biomedical Materials Res

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The aim of this study is to show the favorable effect of simple dynamic culture conditions on chondrogenesis of previously expanded human chondrocytes seeded in a macroporous scaffold with week cell-pore walls adhesion. We obtained enhanced chondrogenesis by the combination of chitosan porous supports with a double micro- and macro-pore structure and cell culture in a stirring bioreactor. Cell-scaffold constructs were cultured under static or mechanically stimulated conditions using an intermittent stirred flow bioreactor during 28 days. In static culture, the chondrocytes were homogeneously distributed throughout the scaffold pores; cells adhered to the scaffold pore walls, showed extended morphology and were able to proliferate. Immunofluorescense and biochemical assays showed abundant type I collagen deposition at day 28. However, the behavior of chondrocytes submitted to mechanical stimuli in the bioreactor was completely different. Mechanical loading influenced cell morphology and extracellular matrix composition. Under dynamic conditions, chondrocytes kept their characteristic phenotype and tended to form cell aggregates surrounded by a layer of the main components of the hyaline cartilage extracellular matrix, type II collagen, and aggrecan. An enhanced aggrecan and collagen type II production was observed in engineered cartilage constructs cultured under stirred flow compared with those cultured under static conditions.

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Differentiation of mesenchymal stem cells in chitosan scaffolds with double micro and macroporosity

Cited by 43 publications

References 59 publications

Poly(3-hydroxybutyrate)/poly(ethylene glycol) scaffolds with different microstructure: the effect on growth of mesenchymal stem cells

Poly(3-hydroxybutyrate)/poly(ethylene glycol) scaffolds with different microstructure: the effect on growth of mesenchymal stem cells

Chitosan-based scaffolds for bone tissue engineering

Stirred flow bioreactor modulates chondrocyte growth and extracellular matrix biosynthesis in chitosan scaffolds

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