Publikation: A human brain microphysiological system derived from induced pluripotent stem cells to study neurological diseases and toxicity
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Datum
2017
Autor:innen
Pamies, David
Barreras, Paula
Block, Katharina
Makri, Georgia
Kumar, Anupama
Wiersma, Daphne
Smirnova, Lenna
Zang, Ce
Bressler, Joseph
Christian, Kimberly M.
Herausgeber:innen
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ALTEX. 2017, 34(3), pp. 362-376. ISSN 1868-596X. eISSN 1868-8551. Available under: doi: 10.14573/altex.1609122
Zusammenfassung
Human in vitro models of brain neurophysiology are needed to investigate molecular and cellular mechanisms associated with neurological disorders and neurotoxicity. We have developed a reproducible iPSC-derived human 3D brain microphysiological system (BMPS), comprised of differentiated mature neurons and glial cells (astrocytes and oligodendrocytes) that reproduce neuronal-glial interactions and connectivity. BMPS mature over eight weeks and show the critical elements of neuronal function: synaptogenesis and neuron-to-neuron (e.g., spontaneous electric field potentials) and neuronal-glial interactions (e.g., myelination), which mimic the microenvironment of the central nervous system, rarely seen in vitro before. The BMPS shows 40% overall myelination after 8 weeks of differentiation. Myelin was observed by immunohistochemistry and confirmed by confocal microscopy 3D reconstruction and electron microscopy. These findings are of particular relevance since myelin is crucial for proper neuronal function and development. The ability to assess oligodendroglial function and mechanisms associated with myelination in this BMPS model provide an excellent tool for future studies of neurological disorders such as multiple sclerosis and other demyelinating diseases. The BMPS provides a suitable and reliable model to investigate neuron-neuroglia function as well as pathogenic mechanisms in neurotoxicology.
Zusammenfassung in einer weiteren Sprache
Fachgebiet (DDC)
570 Biowissenschaften, Biologie
Schlagwörter
3D culture, CNS, myelination, microphysiological system, brain
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PAMIES, David, Paula BARRERAS, Katharina BLOCK, Georgia MAKRI, Anupama KUMAR, Daphne WIERSMA, Lenna SMIRNOVA, Ce ZANG, Joseph BRESSLER, Kimberly M. CHRISTIAN, Thomas HARTUNG, 2017. A human brain microphysiological system derived from induced pluripotent stem cells to study neurological diseases and toxicity. In: ALTEX. 2017, 34(3), pp. 362-376. ISSN 1868-596X. eISSN 1868-8551. Available under: doi: 10.14573/altex.1609122BibTex
@article{Pamies2017human-40433,
year={2017},
doi={10.14573/altex.1609122},
title={A human brain microphysiological system derived from induced pluripotent stem cells to study neurological diseases and toxicity},
number={3},
volume={34},
issn={1868-596X},
journal={ALTEX},
pages={362--376},
author={Pamies, David and Barreras, Paula and Block, Katharina and Makri, Georgia and Kumar, Anupama and Wiersma, Daphne and Smirnova, Lenna and Zang, Ce and Bressler, Joseph and Christian, Kimberly M. and Hartung, Thomas}
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<dcterms:abstract xml:lang="eng">Human in vitro models of brain neurophysiology are needed to investigate molecular and cellular mechanisms associated with neurological disorders and neurotoxicity. We have developed a reproducible iPSC-derived human 3D brain microphysiological system (BMPS), comprised of differentiated mature neurons and glial cells (astrocytes and oligodendrocytes) that reproduce neuronal-glial interactions and connectivity. BMPS mature over eight weeks and show the critical elements of neuronal function: synaptogenesis and neuron-to-neuron (e.g., spontaneous electric field potentials) and neuronal-glial interactions (e.g., myelination), which mimic the microenvironment of the central nervous system, rarely seen in vitro before. The BMPS shows 40% overall myelination after 8 weeks of differentiation. Myelin was observed by immunohistochemistry and confirmed by confocal microscopy 3D reconstruction and electron microscopy. These findings are of particular relevance since myelin is crucial for proper neuronal function and development. The ability to assess oligodendroglial function and mechanisms associated with myelination in this BMPS model provide an excellent tool for future studies of neurological disorders such as multiple sclerosis and other demyelinating diseases. The BMPS provides a suitable and reliable model to investigate neuron-neuroglia function as well as pathogenic mechanisms in neurotoxicology.</dcterms:abstract>
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