Microfibrous Scaffolds Guide Stem Cell Lumenogenesis and Brain Organoid Engineering
Abstract: 3D organoids are widely used as tractable in vitro models capable of elucidating aspects of human development and disease. However, the manual and low‐throughput culture methods, coupled with a low reproducibility and geometric heterogeneity, restrict the scope and application of organoid research. Combining expertise from stem cell biology and bioengineering offers a promising approach to address some of these limitations. Here, melt electrospinning writing is used to generate tuneable grid scaffolds that can guide the self‐organization of pluripotent stem cells into patterned arrays of embryoid bodies. Grid geometry is shown to be a key determinant of stem cell self‐organization, guiding the position and size of emerging lumens via curvature‐controlled tissue growth. Two distinct methods for culturing scaffold‐grown embryoid bodies into either interconnected or spatially discrete cerebral organoids are reported. These scaffolds provide a high‐throughput method to generate, culture, and analyze large numbers of organoids, substantially reducing the time investment and manual labor involved in conventional methods of organoid culture. It is anticipated that this methodological development will open up new opportunities for guiding pluripotent stem cell culture, studying lumenogenesis, and generating large numbers of uniform organoids for high‐throughput screening.
- Location
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Deutsche Nationalbibliothek Frankfurt am Main
- Extent
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Online-Ressource
- Language
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Englisch
- Bibliographic citation
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Microfibrous Scaffolds Guide Stem Cell Lumenogenesis and Brain Organoid Engineering ; day:08 ; month:09 ; year:2023 ; extent:14
Advanced materials ; (08.09.2023) (gesamt 14)
- Creator
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Ritzau‐Reid, Kaja I.
Callens, Sebastien J. P.
Xie, Ruoxiao
Cihova, Martina
Reumann, Daniel
Grigsby, Christopher L.
Prados‐Martin, Lino
Wang, Richard
Moore, Axel C.
Armstrong, James P. K.
Knoblich, Jürgen
Stevens, Molly
- DOI
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10.1002/adma.202300305
- URN
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urn:nbn:de:101:1-2023090815304407213638
- Rights
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Open Access; Der Zugriff auf das Objekt ist unbeschränkt möglich.
- Last update
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14.08.2025, 11:01 AM CEST
Data provider
Deutsche Nationalbibliothek. If you have any questions about the object, please contact the data provider.
Associated
- Ritzau‐Reid, Kaja I.
- Callens, Sebastien J. P.
- Xie, Ruoxiao
- Cihova, Martina
- Reumann, Daniel
- Grigsby, Christopher L.
- Prados‐Martin, Lino
- Wang, Richard
- Moore, Axel C.
- Armstrong, James P. K.
- Knoblich, Jürgen
- Stevens, Molly
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Elektrogesponnene aktive Scaffolds für das neurale Tissue Engineering
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Adipose-derived mesenchymal stem cell seeded Atelocollagen scaffolds for cardiac tissue engineering
Bone Tissue Engineering Scaffolds: Function of Multi‐Material Hierarchically Structured Scaffolds
Engineering bone and cartilage like tissue using human mesenchymal stem cells and protein scaffolds
Porous polymeric bioresorbable scaffolds for tissue engineering
Nanoenabled Immunomodulatory Scaffolds for Cartilage Tissue Engineering
Type II collagen scaffolds for tissue engineering
Surface modified cellulose scaffolds for tissue engineering
Trophoblast stem cell-based organoid models of the human placental barrier
Mesenchymal Stem Cells Increase Alveolar Differentiation in Lung Progenitor Organoid Cultures
Biodegradable polymer-based scaffolds for bone tissue engineering
Elektrogesponnene aktive Scaffolds für das neurale Tissue Engineering
A Droplet Microfluidic System to Fabricate Hybrid Capsules Enabling Stem Cell Organoid Engineering
Adipose-derived mesenchymal stem cell seeded Atelocollagen scaffolds for cardiac tissue engineering
Bone Tissue Engineering Scaffolds: Function of Multi‐Material Hierarchically Structured Scaffolds
Engineering bone and cartilage like tissue using human mesenchymal stem cells and protein scaffolds
Porous polymeric bioresorbable scaffolds for tissue engineering
Nanoenabled Immunomodulatory Scaffolds for Cartilage Tissue Engineering
Type II collagen scaffolds for tissue engineering
Surface modified cellulose scaffolds for tissue engineering
Trophoblast stem cell-based organoid models of the human placental barrier
Mesenchymal Stem Cells Increase Alveolar Differentiation in Lung Progenitor Organoid Cultures
Biodegradable polymer-based scaffolds for bone tissue engineering