Efficient derivation of neural cells from human embryonic stem cells (hESCs) remains an unmet need for the treatment of neurological disorders. The limiting factors for current methods include being labor-intensive, time-consuming and expensive. In this study, we hypothesize that the substrate topography, with optimal geometry and dimension, can modulate the neural fate of hESCs and enhance the efficiency of differentiation. A multi-architectural chip (MARC) containing fields of topographies varying in geometry and dimension was developed to facilitate high-throughput analysis of topography-induced neural differentiation in vitro. The hESCs were subjected to “direct differentiation”, in which small clumps of undifferentiated hESCs were cultured directly without going through the stage of embryoid body formation, on the \MARC\ with \N2\ and \B27\ supplements for 7 days. The gene and protein expression analysis indicated that the anisotropic patterns like gratings promoted neuronal differentiation of hESCs while the isotropic patterns like pillars and wells promoted the glial differentiation of hESCs. This study showed that optimal combination of topography and biochemical cues could shorten the differentiation period and allowed derivation of neurons bearing longer neurites that were aligned along the grating axis. The \MARC\ platform would enable high-throughput screening of topographical substrates that could maximize the efficiency of neuronal differentiation from pluripotent stem cells.
Description
Substrate topography and size determine the fate of human embryonic stem cells to neuronal or glial lineage
%0 Journal Article
%1 ankam2013substrate
%A Ankam, Soneela
%A Suryana, Mona
%A Chan, Lesley Y.
%A Moe, Aung Aung Kywe
%A Teo, Benjamin K.K.
%A Law, Jaslyn B.K.
%A Sheetz, Michael P.
%A Low, Hong Yee
%A Yim, Evelyn K.F.
%D 2013
%J Acta Biomaterialia
%K biomaterial htsc literature nextgen screening stemcell topography
%N 1
%P 4535--4545
%R http://dx.doi.org/10.1016/j.actbio.2012.08.018
%T Substrate topography and size determine the fate of human embryonic stem cells to neuronal or glial lineage
%U http://www.sciencedirect.com/science/article/pii/S1742706112003935
%V 9
%X Efficient derivation of neural cells from human embryonic stem cells (hESCs) remains an unmet need for the treatment of neurological disorders. The limiting factors for current methods include being labor-intensive, time-consuming and expensive. In this study, we hypothesize that the substrate topography, with optimal geometry and dimension, can modulate the neural fate of hESCs and enhance the efficiency of differentiation. A multi-architectural chip (MARC) containing fields of topographies varying in geometry and dimension was developed to facilitate high-throughput analysis of topography-induced neural differentiation in vitro. The hESCs were subjected to “direct differentiation”, in which small clumps of undifferentiated hESCs were cultured directly without going through the stage of embryoid body formation, on the \MARC\ with \N2\ and \B27\ supplements for 7 days. The gene and protein expression analysis indicated that the anisotropic patterns like gratings promoted neuronal differentiation of hESCs while the isotropic patterns like pillars and wells promoted the glial differentiation of hESCs. This study showed that optimal combination of topography and biochemical cues could shorten the differentiation period and allowed derivation of neurons bearing longer neurites that were aligned along the grating axis. The \MARC\ platform would enable high-throughput screening of topographical substrates that could maximize the efficiency of neuronal differentiation from pluripotent stem cells.
@article{ankam2013substrate,
abstract = {Efficient derivation of neural cells from human embryonic stem cells (hESCs) remains an unmet need for the treatment of neurological disorders. The limiting factors for current methods include being labor-intensive, time-consuming and expensive. In this study, we hypothesize that the substrate topography, with optimal geometry and dimension, can modulate the neural fate of hESCs and enhance the efficiency of differentiation. A multi-architectural chip (MARC) containing fields of topographies varying in geometry and dimension was developed to facilitate high-throughput analysis of topography-induced neural differentiation in vitro. The hESCs were subjected to “direct differentiation”, in which small clumps of undifferentiated hESCs were cultured directly without going through the stage of embryoid body formation, on the \{MARC\} with \{N2\} and \{B27\} supplements for 7 days. The gene and protein expression analysis indicated that the anisotropic patterns like gratings promoted neuronal differentiation of hESCs while the isotropic patterns like pillars and wells promoted the glial differentiation of hESCs. This study showed that optimal combination of topography and biochemical cues could shorten the differentiation period and allowed derivation of neurons bearing longer neurites that were aligned along the grating axis. The \{MARC\} platform would enable high-throughput screening of topographical substrates that could maximize the efficiency of neuronal differentiation from pluripotent stem cells. },
added-at = {2016-09-05T21:37:22.000+0200},
author = {Ankam, Soneela and Suryana, Mona and Chan, Lesley Y. and Moe, Aung Aung Kywe and Teo, Benjamin K.K. and Law, Jaslyn B.K. and Sheetz, Michael P. and Low, Hong Yee and Yim, Evelyn K.F.},
biburl = {https://www.bibsonomy.org/bibtex/265e38164ca564251e09cef5ff79f5730/bkoch},
description = {Substrate topography and size determine the fate of human embryonic stem cells to neuronal or glial lineage},
doi = {http://dx.doi.org/10.1016/j.actbio.2012.08.018},
interhash = {b0dc2c4a18dd3451d6f8436a43e2e943},
intrahash = {65e38164ca564251e09cef5ff79f5730},
issn = {1742-7061},
journal = {Acta Biomaterialia },
keywords = {biomaterial htsc literature nextgen screening stemcell topography},
number = 1,
pages = {4535--4545},
timestamp = {2016-09-05T21:37:22.000+0200},
title = {Substrate topography and size determine the fate of human embryonic stem cells to neuronal or glial lineage },
url = {http://www.sciencedirect.com/science/article/pii/S1742706112003935},
volume = 9,
year = 2013
}