Multidrug-eluting bi-layered microparticle-mesh scaffolds for musculoskeletal tissue regeneration
Stem cell-based tissue engineering necessitates the development of a biocompatible scaffold, as a structural support, that provides a continuous supply of bioactive molecules for specific lineage differentiation. While incorporating bioactive molecules within a scaffold to improve stem cell differen...
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sg-ntu-dr.10356-1407492020-06-02T00:49:24Z Multidrug-eluting bi-layered microparticle-mesh scaffolds for musculoskeletal tissue regeneration Chamundeswari, Vidya Narasimhan Chuah, Yon Jin Loo, Joachim Say Chye School of Materials Science and Engineering Singapore Centre for Environmental Life Sciences and Engineering Engineering::Materials Multidrug-eluting Microparticle-mesh Stem cell-based tissue engineering necessitates the development of a biocompatible scaffold, as a structural support, that provides a continuous supply of bioactive molecules for specific lineage differentiation. While incorporating bioactive molecules within a scaffold to improve stem cell differentiation has been reported in the literature, there is minimal evidence of any scaffold that can deliver a customized concoction of both hydrophobic and hydrophilic bioactive molecules to induce in situ lineage differentiation without any external supplements. In this study, we established a bioactive, drug-eluting bi-layered microparticle-mesh scaffold (BMMS) using the electrospinning technique. This BMMS was co-encapsulated with hydrophobic dexamethasone (in the mesh), hydrophilic ascorbic acid and β-glycerophosphate or proline (in the microparticles). We hypothesized that a sustained-releasing BMMS can direct in situ specific lineage differentiation of MSCs (e.g. osteogenic and chondrogenic) in a minimally supplemented culture environment into musculoskeletal tissues. The characterization of this BMMS revealed good encapsulation efficiencies of the bioactive molecules with sustained-releasing capabilities. The release kinetics of each drug was further analyzed using mathematical drug-releasing models. These scaffolds were subsequently shown to have potential for osteogenic or chondrogenic lineage differentiation from mesenchymal stem cells (MSCs) in a minimally supplemented culture medium. MOE (Min. of Education, S’pore) 2020-06-02T00:49:24Z 2020-06-02T00:49:24Z 2018 Journal Article Chamundeswari, V. N., Chuah, Y. J., & Loo, J. S. C. (2018). Multidrug-eluting bi-layered microparticle-mesh scaffolds for musculoskeletal tissue regeneration. Journal of Materials Chemistry B, 6(20), 3340-3347. doi:10.1039/c8tb00397a 2050-750X https://hdl.handle.net/10356/140749 10.1039/c8tb00397a 32254391 2-s2.0-85047480654 20 6 3340 3347 en Journal of Materials Chemistry B © 2018 The Royal Society of Chemistry. All rights reserved. |
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Engineering::Materials Multidrug-eluting Microparticle-mesh |
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Engineering::Materials Multidrug-eluting Microparticle-mesh Chamundeswari, Vidya Narasimhan Chuah, Yon Jin Loo, Joachim Say Chye Multidrug-eluting bi-layered microparticle-mesh scaffolds for musculoskeletal tissue regeneration |
| description |
Stem cell-based tissue engineering necessitates the development of a biocompatible scaffold, as a structural support, that provides a continuous supply of bioactive molecules for specific lineage differentiation. While incorporating bioactive molecules within a scaffold to improve stem cell differentiation has been reported in the literature, there is minimal evidence of any scaffold that can deliver a customized concoction of both hydrophobic and hydrophilic bioactive molecules to induce in situ lineage differentiation without any external supplements. In this study, we established a bioactive, drug-eluting bi-layered microparticle-mesh scaffold (BMMS) using the electrospinning technique. This BMMS was co-encapsulated with hydrophobic dexamethasone (in the mesh), hydrophilic ascorbic acid and β-glycerophosphate or proline (in the microparticles). We hypothesized that a sustained-releasing BMMS can direct in situ specific lineage differentiation of MSCs (e.g. osteogenic and chondrogenic) in a minimally supplemented culture environment into musculoskeletal tissues. The characterization of this BMMS revealed good encapsulation efficiencies of the bioactive molecules with sustained-releasing capabilities. The release kinetics of each drug was further analyzed using mathematical drug-releasing models. These scaffolds were subsequently shown to have potential for osteogenic or chondrogenic lineage differentiation from mesenchymal stem cells (MSCs) in a minimally supplemented culture medium. |
| author2 |
School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Chamundeswari, Vidya Narasimhan Chuah, Yon Jin Loo, Joachim Say Chye |
| format |
Article |
| author |
Chamundeswari, Vidya Narasimhan Chuah, Yon Jin Loo, Joachim Say Chye |
| author_sort |
Chamundeswari, Vidya Narasimhan |
| title |
Multidrug-eluting bi-layered microparticle-mesh scaffolds for musculoskeletal tissue regeneration |
| title_short |
Multidrug-eluting bi-layered microparticle-mesh scaffolds for musculoskeletal tissue regeneration |
| title_full |
Multidrug-eluting bi-layered microparticle-mesh scaffolds for musculoskeletal tissue regeneration |
| title_fullStr |
Multidrug-eluting bi-layered microparticle-mesh scaffolds for musculoskeletal tissue regeneration |
| title_full_unstemmed |
Multidrug-eluting bi-layered microparticle-mesh scaffolds for musculoskeletal tissue regeneration |
| title_sort |
multidrug-eluting bi-layered microparticle-mesh scaffolds for musculoskeletal tissue regeneration |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/140749 |
| _version_ |
1681057031561150464 |