Defined hydrogel microenvironments for optimized neuronal culture

Three-dimensional (3D) in vitro culture systems that provide controlled, biomimetic microenvironments would be a significant technological advance for both basic cell biology research and the development of clinical therapeutics (e.g., as in vivo cell delivery constructs). A variety of signals deter...

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Main Author: Seidlits, Stephanie Kristin
Format: Others
Published: 2015
Subjects:
Online Access:http://hdl.handle.net/2152/28463
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spelling ndltd-UTEXAS-oai-repositories.lib.utexas.edu-2152-284632015-09-20T17:29:51ZDefined hydrogel microenvironments for optimized neuronal cultureSeidlits, Stephanie KristinHydrogelsHyaluronic acidNeuronal cultureThree-dimensional (3D) in vitro culture systems that provide controlled, biomimetic microenvironments would be a significant technological advance for both basic cell biology research and the development of clinical therapeutics (e.g., as in vivo cell delivery constructs). A variety of signals determine cell phenotype, including those from soluble factors, immobilized biomolecules, mechanical substrates, and culture geometry. My research seeks to create hydrogel culture systems that incorporate these signals in a defined, controllable manner. Specifically, I have focused on developing hydrogels based on the extracellular matrix (ECM) component hyaluronic acid (HA) with precisely specified mechanical, chemical and geometrical microenvironments. For example, the mechanical environment presented by HA hydrogels was tuned to span the threefold range measured for neonatal brain and adult spinal cord by modifying HA with varying numbers of photocrosslinkable methacrylate groups. These hydrogels were used to evaluate the effects of mechanical properties of a 3D culture paradigm on the differentiation of ventral midbrain-derived neural progenitor cells (NPCs) and results demonstrated that the mechanical properties of these scaffolds can assert a defining influence on differentiation. In addition, whole fibronectin was incorporated into HA hydrogels as an adhesive factor to encourage angiogenesis in 3D cultures, as interplay between endothelial cells and neurons is an important determining factor during NPC development and axonal regeneration after injury. To create spatially defined neuronal cultures in three-dimensions, multiphoton excitation (MPE) was used to photocrosslink protein microstructures within HA hydrogels. This method can be used to create complex, 3D architectures that provide both chemical and topographical cues to direct cell adhesion and guidance on size scales relevant to in vivo environments. Using this approach, both dorsal root ganglion cells (DRGs) and hippocampal NPCs could be guided along user-defined, 3D paths. In future studies, these strategies can be combined into a single hydrogel to create a culture microenvironment with multiple types of highly specified cues (i.e., chemical, topographical, and mechanical).text2015-02-16T14:14:52Z2010-052010-06-23May 20102015-02-16T14:14:52ZThesisapplication/pdfhttp://hdl.handle.net/2152/28463
collection NDLTD
format Others
sources NDLTD
topic Hydrogels
Hyaluronic acid
Neuronal culture
spellingShingle Hydrogels
Hyaluronic acid
Neuronal culture
Seidlits, Stephanie Kristin
Defined hydrogel microenvironments for optimized neuronal culture
description Three-dimensional (3D) in vitro culture systems that provide controlled, biomimetic microenvironments would be a significant technological advance for both basic cell biology research and the development of clinical therapeutics (e.g., as in vivo cell delivery constructs). A variety of signals determine cell phenotype, including those from soluble factors, immobilized biomolecules, mechanical substrates, and culture geometry. My research seeks to create hydrogel culture systems that incorporate these signals in a defined, controllable manner. Specifically, I have focused on developing hydrogels based on the extracellular matrix (ECM) component hyaluronic acid (HA) with precisely specified mechanical, chemical and geometrical microenvironments. For example, the mechanical environment presented by HA hydrogels was tuned to span the threefold range measured for neonatal brain and adult spinal cord by modifying HA with varying numbers of photocrosslinkable methacrylate groups. These hydrogels were used to evaluate the effects of mechanical properties of a 3D culture paradigm on the differentiation of ventral midbrain-derived neural progenitor cells (NPCs) and results demonstrated that the mechanical properties of these scaffolds can assert a defining influence on differentiation. In addition, whole fibronectin was incorporated into HA hydrogels as an adhesive factor to encourage angiogenesis in 3D cultures, as interplay between endothelial cells and neurons is an important determining factor during NPC development and axonal regeneration after injury. To create spatially defined neuronal cultures in three-dimensions, multiphoton excitation (MPE) was used to photocrosslink protein microstructures within HA hydrogels. This method can be used to create complex, 3D architectures that provide both chemical and topographical cues to direct cell adhesion and guidance on size scales relevant to in vivo environments. Using this approach, both dorsal root ganglion cells (DRGs) and hippocampal NPCs could be guided along user-defined, 3D paths. In future studies, these strategies can be combined into a single hydrogel to create a culture microenvironment with multiple types of highly specified cues (i.e., chemical, topographical, and mechanical). === text
author Seidlits, Stephanie Kristin
author_facet Seidlits, Stephanie Kristin
author_sort Seidlits, Stephanie Kristin
title Defined hydrogel microenvironments for optimized neuronal culture
title_short Defined hydrogel microenvironments for optimized neuronal culture
title_full Defined hydrogel microenvironments for optimized neuronal culture
title_fullStr Defined hydrogel microenvironments for optimized neuronal culture
title_full_unstemmed Defined hydrogel microenvironments for optimized neuronal culture
title_sort defined hydrogel microenvironments for optimized neuronal culture
publishDate 2015
url http://hdl.handle.net/2152/28463
work_keys_str_mv AT seidlitsstephaniekristin definedhydrogelmicroenvironmentsforoptimizedneuronalculture
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