Multiscale 3D phenotyping of human cerebral organoids

Multiscale 3D phenotyping of human cerebral organoids

Abstract Brain organoids grown from human pluripotent stem cells self-organize into cytoarchitectures resembling the developing human brain. These three-dimensional models offer an unprecedented opportunity to study human brain development and dysfunction. Characterization currently sacrifices spati...

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Main Authors: Alexandre Albanese, Justin M. Swaney, Dae Hee Yun, Nicholas B. Evans, Jenna M. Antonucci, Silvia Velasco, Chang Ho Sohn, Paola Arlotta, Lee Gehrke, Kwanghun Chung
Format: Article
Language:English
Published: Nature Publishing Group 2020-12-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-020-78130-7
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spelling doaj-fb1882f90ac742849d2c12265a68b9022020-12-13T12:34:24ZengNature Publishing GroupScientific Reports2045-23222020-12-0110111710.1038/s41598-020-78130-7Multiscale 3D phenotyping of human cerebral organoidsAlexandre Albanese0Justin M. Swaney1Dae Hee Yun2Nicholas B. Evans3Jenna M. Antonucci4Silvia Velasco5Chang Ho Sohn6Paola Arlotta7Lee Gehrke8Kwanghun Chung9Institute for Medical Engineering and Science, MITDepartment of Chemical Engineering, MITInstitute for Medical Engineering and Science, MITInstitute for Medical Engineering and Science, MITInstitute for Medical Engineering and Science, MITDepartment of Stem Cell and Regenerative Biology, Harvard UniversityInstitute for Medical Engineering and Science, MITDepartment of Stem Cell and Regenerative Biology, Harvard UniversityInstitute for Medical Engineering and Science, MITInstitute for Medical Engineering and Science, MITAbstract Brain organoids grown from human pluripotent stem cells self-organize into cytoarchitectures resembling the developing human brain. These three-dimensional models offer an unprecedented opportunity to study human brain development and dysfunction. Characterization currently sacrifices spatial information for single-cell or histological analysis leaving whole-tissue analysis mostly unexplored. Here, we present the SCOUT pipeline for automated multiscale comparative analysis of intact cerebral organoids. Our integrated technology platform can rapidly clear, label, and image intact organoids. Algorithmic- and convolutional neural network-based image analysis extract hundreds of features characterizing molecular, cellular, spatial, cytoarchitectural, and organoid-wide properties from fluorescence microscopy datasets. Comprehensive analysis of 46 intact organoids and ~ 100 million cells reveals quantitative multiscale “phenotypes" for organoid development, culture protocols and Zika virus infection. SCOUT provides a much-needed framework for comparative analysis of emerging 3D in vitro models using fluorescence microscopy.https://doi.org/10.1038/s41598-020-78130-7
collection DOAJ
language English
format Article
sources DOAJ
author Alexandre Albanese
Justin M. Swaney
Dae Hee Yun
Nicholas B. Evans
Jenna M. Antonucci
Silvia Velasco
Chang Ho Sohn
Paola Arlotta
Lee Gehrke
Kwanghun Chung
spellingShingle Alexandre Albanese
Justin M. Swaney
Dae Hee Yun
Nicholas B. Evans
Jenna M. Antonucci
Silvia Velasco
Chang Ho Sohn
Paola Arlotta
Lee Gehrke
Kwanghun Chung
Multiscale 3D phenotyping of human cerebral organoids
Scientific Reports
author_facet Alexandre Albanese
Justin M. Swaney
Dae Hee Yun
Nicholas B. Evans
Jenna M. Antonucci
Silvia Velasco
Chang Ho Sohn
Paola Arlotta
Lee Gehrke
Kwanghun Chung
author_sort Alexandre Albanese
title Multiscale 3D phenotyping of human cerebral organoids
title_short Multiscale 3D phenotyping of human cerebral organoids
title_full Multiscale 3D phenotyping of human cerebral organoids
title_fullStr Multiscale 3D phenotyping of human cerebral organoids
title_full_unstemmed Multiscale 3D phenotyping of human cerebral organoids
title_sort multiscale 3d phenotyping of human cerebral organoids
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2020-12-01
description Abstract Brain organoids grown from human pluripotent stem cells self-organize into cytoarchitectures resembling the developing human brain. These three-dimensional models offer an unprecedented opportunity to study human brain development and dysfunction. Characterization currently sacrifices spatial information for single-cell or histological analysis leaving whole-tissue analysis mostly unexplored. Here, we present the SCOUT pipeline for automated multiscale comparative analysis of intact cerebral organoids. Our integrated technology platform can rapidly clear, label, and image intact organoids. Algorithmic- and convolutional neural network-based image analysis extract hundreds of features characterizing molecular, cellular, spatial, cytoarchitectural, and organoid-wide properties from fluorescence microscopy datasets. Comprehensive analysis of 46 intact organoids and ~ 100 million cells reveals quantitative multiscale “phenotypes" for organoid development, culture protocols and Zika virus infection. SCOUT provides a much-needed framework for comparative analysis of emerging 3D in vitro models using fluorescence microscopy.
url https://doi.org/10.1038/s41598-020-78130-7
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