Surface engineering to modulate human mesenchymal stem cell behavior

Surface micro-fabrication techniques have been widely used for spatial control of cells in culture and various types of biomolecules were immobilized onto the substrate to promote or resist cell attachment to surface. Through this technique (micropatterning), it is possible to fix cells onto target...

Full description

Bibliographic Details
Main Author: Wu, Yew Seng.
Other Authors: Tan Lay Poh
Format: Final Year Project (FYP)
Language:English
Published: 2010
Subjects:
Online Access:http://hdl.handle.net/10356/39773
_version_ 1826124279715987456
author Wu, Yew Seng.
author2 Tan Lay Poh
author_facet Tan Lay Poh
Wu, Yew Seng.
author_sort Wu, Yew Seng.
collection NTU
description Surface micro-fabrication techniques have been widely used for spatial control of cells in culture and various types of biomolecules were immobilized onto the substrate to promote or resist cell attachment to surface. Through this technique (micropatterning), it is possible to fix cells onto targeted locations and arrays separated by a defined distance thus dictating their shape which influence commitment of stem cells to their different specifics lineage. In this project, responses of bone marrow human derived stem cells (hMSCs) were modulated via surface engineering techniques. In the first stage of the study, 5 extracellular matrixes (ECMs) and 1 attachment factor (AF) were screened for their suitability as the “ink” for printing of micropattern islands onto the substrate. Gene expression study showed that the non bias fibronectin is the best candidate for micropatterning as its effects on target gene expression did not vary much from the control. Furthermore, the study also revealed trends of those ECMs and AF where collagen was identified to be a suitable candidate for up-regulating osteogenic genes, gelatin for myogenic genes and laminin for neurogenic genes and osteogenic genes. In the second phase of the study, techniques for casting of PDMS elastomeric stamps and micro contact printing of fibronectin micropattern islands onto poly lactide-co-glycolide (PLGA) scaffold were established. Different cytoskeleton organization between cell immobilized on different fibronectin micropattern islands and unpatterned control were also observed. The optimized protocol coupled with the observed modulation in cytoskeletal re-arrangement of hMSCs on the designed micropatterns makes it a powerful tool to direct stem cells fates on a biodegradable scaffold.
first_indexed 2024-10-01T06:18:04Z
format Final Year Project (FYP)
id ntu-10356/39773
institution Nanyang Technological University
language English
last_indexed 2024-10-01T06:18:04Z
publishDate 2010
record_format dspace
spelling ntu-10356/397732023-03-04T15:38:08Z Surface engineering to modulate human mesenchymal stem cell behavior Wu, Yew Seng. Tan Lay Poh School of Materials Science and Engineering DRNTU::Engineering::Materials::Biomaterials Surface micro-fabrication techniques have been widely used for spatial control of cells in culture and various types of biomolecules were immobilized onto the substrate to promote or resist cell attachment to surface. Through this technique (micropatterning), it is possible to fix cells onto targeted locations and arrays separated by a defined distance thus dictating their shape which influence commitment of stem cells to their different specifics lineage. In this project, responses of bone marrow human derived stem cells (hMSCs) were modulated via surface engineering techniques. In the first stage of the study, 5 extracellular matrixes (ECMs) and 1 attachment factor (AF) were screened for their suitability as the “ink” for printing of micropattern islands onto the substrate. Gene expression study showed that the non bias fibronectin is the best candidate for micropatterning as its effects on target gene expression did not vary much from the control. Furthermore, the study also revealed trends of those ECMs and AF where collagen was identified to be a suitable candidate for up-regulating osteogenic genes, gelatin for myogenic genes and laminin for neurogenic genes and osteogenic genes. In the second phase of the study, techniques for casting of PDMS elastomeric stamps and micro contact printing of fibronectin micropattern islands onto poly lactide-co-glycolide (PLGA) scaffold were established. Different cytoskeleton organization between cell immobilized on different fibronectin micropattern islands and unpatterned control were also observed. The optimized protocol coupled with the observed modulation in cytoskeletal re-arrangement of hMSCs on the designed micropatterns makes it a powerful tool to direct stem cells fates on a biodegradable scaffold. Bachelor of Engineering (Materials Engineering) 2010-06-04T01:43:58Z 2010-06-04T01:43:58Z 2010 2010 Final Year Project (FYP) http://hdl.handle.net/10356/39773 en Nanyang Technological University 52 p. application/pdf
spellingShingle DRNTU::Engineering::Materials::Biomaterials
Wu, Yew Seng.
Surface engineering to modulate human mesenchymal stem cell behavior
title Surface engineering to modulate human mesenchymal stem cell behavior
title_full Surface engineering to modulate human mesenchymal stem cell behavior
title_fullStr Surface engineering to modulate human mesenchymal stem cell behavior
title_full_unstemmed Surface engineering to modulate human mesenchymal stem cell behavior
title_short Surface engineering to modulate human mesenchymal stem cell behavior
title_sort surface engineering to modulate human mesenchymal stem cell behavior
topic DRNTU::Engineering::Materials::Biomaterials
url http://hdl.handle.net/10356/39773
work_keys_str_mv AT wuyewseng surfaceengineeringtomodulatehumanmesenchymalstemcellbehavior