Modelling neurodegenerative diseases in vitro: recent advances in 3D iPSC technologies
Modelling neurodegenerative diseases in vitro: recent advances in 3D iPSC technologies
The discovery of induced pluripotent stem cells (iPSC) 12 years ago has fostered the development of innovative patient-derived in vitro models for better understanding of disease mechanisms. This is particularly relevant to neurodegenerative diseases, where availability of live human brain tissue for research is limited and post-mortem interval changes influence readouts from autopsy-derived human tissue. Hundreds of iPSC lines have now been prepared and banked, thanks to several large scale initiatives and cell banks. Patient- or engineered iPSC-derived neural models are now being used to recapitulate cellular and molecular aspects of a variety of neurodegenerative diseases, including early and pre-clinical disease stages. The broad relevance of these models derives from the availability of a variety of differentiation protocols to generate disease-specific cell types and the manipulation to either introduce or correct disease-relevant genetic modifications. Moreover, the use of chemical and physical three-dimensional (3D) matrices improves control over the extracellular environment and cellular organization of the models. These iPSC-derived neural models can be utilised to identify target proteins and, importantly, provide high-throughput screening for drug discovery. Choosing Alzheimer’s disease (AD) as an example, this review describes 3D iPSC-derived neural models and their advantages and limitations. There is now a requirement to fully characterise and validate these 3D iPSC-derived neural models as a viable research tool that is capable of complementing animal models of neurodegeneration and live human brain tissue. With further optimization of differentiation, maturation and aging protocols, as well as the 3D cellular organisation and extracellular matrix to recapitulate more closely, the molecular extracellular-environment of the human brain, 3D iPSC-derived models have the potential to deliver new knowledge, enable discovery of novel disease mechanisms and identify new therapeutic targets for neurodegenerative diseases.
1-23
Siney, Elodie
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Kurbatskaya, Ksenia
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Chatterjee, Shreyasi
8794dd52-b2da-42cb-ac03-374fe00214d6
., Preeti, Prasannan
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Mudher, Amritpal
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Willaime-Morawek, Sandrine
24a2981f-aa9e-4bf6-ad12-2ccf6b49f1c0
6 March 2018
Siney, Elodie
8be7cefb-b63f-4c92-a275-b0495e75e4b2
Kurbatskaya, Ksenia
11d25414-e10d-413a-aaf3-fb6b6c2cf890
Chatterjee, Shreyasi
8794dd52-b2da-42cb-ac03-374fe00214d6
., Preeti, Prasannan
0ae26d12-47e6-43b4-8fa2-9b2b78ee4a6a
Mudher, Amritpal
ce0ccb35-ac49-4b6c-92b4-8dd5e78ac119
Willaime-Morawek, Sandrine
24a2981f-aa9e-4bf6-ad12-2ccf6b49f1c0
Siney, Elodie, Kurbatskaya, Ksenia, Chatterjee, Shreyasi, ., Preeti, Prasannan, Mudher, Amritpal and Willaime-Morawek, Sandrine
(2018)
Modelling neurodegenerative diseases in vitro: recent advances in 3D iPSC technologies.
AIMS Cell and Tissue Engineering, 2 (1), .
(doi:10.3934/celltissue.2018.1.1).
Abstract
The discovery of induced pluripotent stem cells (iPSC) 12 years ago has fostered the development of innovative patient-derived in vitro models for better understanding of disease mechanisms. This is particularly relevant to neurodegenerative diseases, where availability of live human brain tissue for research is limited and post-mortem interval changes influence readouts from autopsy-derived human tissue. Hundreds of iPSC lines have now been prepared and banked, thanks to several large scale initiatives and cell banks. Patient- or engineered iPSC-derived neural models are now being used to recapitulate cellular and molecular aspects of a variety of neurodegenerative diseases, including early and pre-clinical disease stages. The broad relevance of these models derives from the availability of a variety of differentiation protocols to generate disease-specific cell types and the manipulation to either introduce or correct disease-relevant genetic modifications. Moreover, the use of chemical and physical three-dimensional (3D) matrices improves control over the extracellular environment and cellular organization of the models. These iPSC-derived neural models can be utilised to identify target proteins and, importantly, provide high-throughput screening for drug discovery. Choosing Alzheimer’s disease (AD) as an example, this review describes 3D iPSC-derived neural models and their advantages and limitations. There is now a requirement to fully characterise and validate these 3D iPSC-derived neural models as a viable research tool that is capable of complementing animal models of neurodegeneration and live human brain tissue. With further optimization of differentiation, maturation and aging protocols, as well as the 3D cellular organisation and extracellular matrix to recapitulate more closely, the molecular extracellular-environment of the human brain, 3D iPSC-derived models have the potential to deliver new knowledge, enable discovery of novel disease mechanisms and identify new therapeutic targets for neurodegenerative diseases.
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celltissue-02-01-001
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Accepted/In Press date: 2 March 2018
e-pub ahead of print date: 6 March 2018
Published date: 6 March 2018
Identifiers
Local EPrints ID: 418387
URI: http://eprints.soton.ac.uk/id/eprint/418387
ISSN: 2574-0105
PURE UUID: 5723e0f2-4f29-47e7-8342-f6fd738ea2ad
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Date deposited: 06 Mar 2018 17:30
Last modified: 16 Mar 2024 04:29
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Contributors
Author:
Elodie Siney
Author:
Shreyasi Chatterjee
Author:
Preeti, Prasannan .
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