Rational design to control multipotent stromal cell migration for applications in bone tissue engineering and injury repair

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Biological Engineering, 2011. === Cataloged from PDF version of thesis. === Includes bibliographical references (p. 151-162). === Multipotent stromal cells derived from bone marrow hold great potential for tissue engineering applicatio...

Full description

Bibliographic Details
Main Author: Wu, Shan, Ph. D. Massachusetts Institute of Technology
Other Authors: Douglas A. Lauffenburger.
Format: Others
Language:English
Published: Massachusetts Institute of Technology 2011
Subjects:
Online Access:http://hdl.handle.net/1721.1/67198
id ndltd-MIT-oai-dspace.mit.edu-1721.1-67198
record_format oai_dc
spelling ndltd-MIT-oai-dspace.mit.edu-1721.1-671982019-05-02T15:38:44Z Rational design to control multipotent stromal cell migration for applications in bone tissue engineering and injury repair Wu, Shan, Ph. D. Massachusetts Institute of Technology Douglas A. Lauffenburger. Massachusetts Institute of Technology. Dept. of Biological Engineering. Massachusetts Institute of Technology. Dept. of Biological Engineering. Biological Engineering. Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Biological Engineering, 2011. Cataloged from PDF version of thesis. Includes bibliographical references (p. 151-162). Multipotent stromal cells derived from bone marrow hold great potential for tissue engineering applications because of their ability to home to injury sites and to differentiate along mesodermal lineages to become osteocytes, chondrocytes, and adipocytes to aid in tissue repair and regeneration. One key challenge, however, is the scarcity of MSC numbers isolated from in vivo, suggesting a role for biomimetic scaffolds in the cells' ex vivo expansion before reintegration into target tissue. Toward this end, immobilized epidermal growth factor (tEGF) has recently been found to promote MSC survival and proliferation and is a prime candidate to be incorporated into scaffolds to control MSC behavior. To rationally and effectively design scaffolds to drive MSC responses of survival, proliferation, migration, and differentiation, we must first understand these responses and the underlying protein signaling pathways that mediate them. While our knowledge of MSC behavior is limited as a field, MSC migration is particularly less studied despite being critical for tissue and scaffold infiltration. In this thesis, we quantitatively investigate the effects of tEGF and extracellular matrix (ECM) on MSC migration response and signaling. We take a systems level computational view to show a combined biomaterials and small molecule approach to control MSC migration. Cell migration is a delicately integrated biophysical process involving polarization and protrusions at the cell front, adhesion and translocation of the cell body through contractile forces, followed by disassembly of adhesion complexes at the cell rear to allow detachment and productive motility. This process is mediated by a multitude of crosstalking signaling pathways downstream of integrin and growth factor activation. Using a poly(methyl methacrylate)-grafted-poly(ethylene oxide) (PMMA-g-PEO) copolymer base, we modify the PEO sidechains with immobilized epidermal growth factor (tEGF) as a model system for biomimetic scaffolds. We systematically adsorb fibronectin, vitronectin, and collagen ECM proteins to alter surface adhesiveness and measure MSC migration responses of speed and directional persistence alongside intracellular activities of EGFR, ERK, Akt, and FAK phosphoproteins. While tEGF and ECM proteins differentially affected signaling and migration, univariate correlations between signals and responses were not informative, prompting the need for multivariate modeling to identify key patterns. Using decision tree "signal-response" modeling, we predicted that inhibiting ERK on collagen-adsorbed tEGF polymer surfaces would increase cell mean free path (MFP) by increasing directional persistence. We confirmed this experimentally, successfully demonstrating a two-layer approach-"coarse" biomaterials followed by small molecules "fine-tuning"-to precisely and differentially control MSC migration speed and persistence, setting the stage for combination therapies for bone tissue engineering. by Shan Wu. Ph.D. 2011-11-18T20:59:32Z 2011-11-18T20:59:32Z 2011 2011 Thesis http://hdl.handle.net/1721.1/67198 758677543 eng MIT theses are protected by copyright. They may be viewed, downloaded, or printed from this source but further reproduction or distribution in any format is prohibited without written permission. http://dspace.mit.edu/handle/1721.1/7582 171 p. application/pdf Massachusetts Institute of Technology
collection NDLTD
language English
format Others
sources NDLTD
topic Biological Engineering.
spellingShingle Biological Engineering.
Wu, Shan, Ph. D. Massachusetts Institute of Technology
Rational design to control multipotent stromal cell migration for applications in bone tissue engineering and injury repair
description Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Biological Engineering, 2011. === Cataloged from PDF version of thesis. === Includes bibliographical references (p. 151-162). === Multipotent stromal cells derived from bone marrow hold great potential for tissue engineering applications because of their ability to home to injury sites and to differentiate along mesodermal lineages to become osteocytes, chondrocytes, and adipocytes to aid in tissue repair and regeneration. One key challenge, however, is the scarcity of MSC numbers isolated from in vivo, suggesting a role for biomimetic scaffolds in the cells' ex vivo expansion before reintegration into target tissue. Toward this end, immobilized epidermal growth factor (tEGF) has recently been found to promote MSC survival and proliferation and is a prime candidate to be incorporated into scaffolds to control MSC behavior. To rationally and effectively design scaffolds to drive MSC responses of survival, proliferation, migration, and differentiation, we must first understand these responses and the underlying protein signaling pathways that mediate them. While our knowledge of MSC behavior is limited as a field, MSC migration is particularly less studied despite being critical for tissue and scaffold infiltration. In this thesis, we quantitatively investigate the effects of tEGF and extracellular matrix (ECM) on MSC migration response and signaling. We take a systems level computational view to show a combined biomaterials and small molecule approach to control MSC migration. Cell migration is a delicately integrated biophysical process involving polarization and protrusions at the cell front, adhesion and translocation of the cell body through contractile forces, followed by disassembly of adhesion complexes at the cell rear to allow detachment and productive motility. This process is mediated by a multitude of crosstalking signaling pathways downstream of integrin and growth factor activation. Using a poly(methyl methacrylate)-grafted-poly(ethylene oxide) (PMMA-g-PEO) copolymer base, we modify the PEO sidechains with immobilized epidermal growth factor (tEGF) as a model system for biomimetic scaffolds. We systematically adsorb fibronectin, vitronectin, and collagen ECM proteins to alter surface adhesiveness and measure MSC migration responses of speed and directional persistence alongside intracellular activities of EGFR, ERK, Akt, and FAK phosphoproteins. While tEGF and ECM proteins differentially affected signaling and migration, univariate correlations between signals and responses were not informative, prompting the need for multivariate modeling to identify key patterns. Using decision tree "signal-response" modeling, we predicted that inhibiting ERK on collagen-adsorbed tEGF polymer surfaces would increase cell mean free path (MFP) by increasing directional persistence. We confirmed this experimentally, successfully demonstrating a two-layer approach-"coarse" biomaterials followed by small molecules "fine-tuning"-to precisely and differentially control MSC migration speed and persistence, setting the stage for combination therapies for bone tissue engineering. === by Shan Wu. === Ph.D.
author2 Douglas A. Lauffenburger.
author_facet Douglas A. Lauffenburger.
Wu, Shan, Ph. D. Massachusetts Institute of Technology
author Wu, Shan, Ph. D. Massachusetts Institute of Technology
author_sort Wu, Shan, Ph. D. Massachusetts Institute of Technology
title Rational design to control multipotent stromal cell migration for applications in bone tissue engineering and injury repair
title_short Rational design to control multipotent stromal cell migration for applications in bone tissue engineering and injury repair
title_full Rational design to control multipotent stromal cell migration for applications in bone tissue engineering and injury repair
title_fullStr Rational design to control multipotent stromal cell migration for applications in bone tissue engineering and injury repair
title_full_unstemmed Rational design to control multipotent stromal cell migration for applications in bone tissue engineering and injury repair
title_sort rational design to control multipotent stromal cell migration for applications in bone tissue engineering and injury repair
publisher Massachusetts Institute of Technology
publishDate 2011
url http://hdl.handle.net/1721.1/67198
work_keys_str_mv AT wushanphdmassachusettsinstituteoftechnology rationaldesigntocontrolmultipotentstromalcellmigrationforapplicationsinbonetissueengineeringandinjuryrepair
_version_ 1719025689383927808