Proof of concept for brain organoid-on-a-chip to create multiple domains in forebrain organoids

Yuan Chen Tsai; Hajime Ozaki; Ango Morikawa; Kaori Shiraiwa; Andy Prosvey Pin; Aya Galal Salem; Kenneth Akady Phommahasay; Bret Kiyoshi Sugita; Christine Hein Vu; Saba Mamoun Hammad; Ken Ichiro Kamei; Momoko Watanabe

doi:10.1039/d4ra04194a

Proof of concept for brain organoid-on-a-chip to create multiple domains in forebrain organoids

Yuan Chen Tsai, Hajime Ozaki, Ango Morikawa, Kaori Shiraiwa, Andy Prosvey Pin, Aya Galal Salem, Kenneth Akady Phommahasay, Bret Kiyoshi Sugita, Christine Hein Vu, Saba Mamoun Hammad, Ken Ichiro Kamei, Momoko Watanabe

Biology

Research output: Contribution to journal › Article › peer-review

Abstract

Brain organoids are three-dimensionally reconstructed brain tissue derived from pluripotent stem cells in vitro. 3D tissue cultures have opened new avenues for exploring development and disease modeling. However, many physiological conditions, including signaling gradients in 3D cultures, have not yet been easily achieved. Here, we introduce brain organoid-on-a-chip platforms that generate signaling gradients that in turn enable the induction of topographic forebrain organoids. This creates a more continuous spectrum of brain regions and provides a more complete mimic of the human brain for evaluating neurodevelopment and disease in unprecedented detail.

Original language	English (US)
Pages (from-to)	3749-3755
Number of pages	7
Journal	RSC Advances
Volume	15
Issue number	5
DOIs	https://doi.org/10.1039/d4ra04194a
State	Published - Feb 5 2025

ASJC Scopus subject areas

General Chemistry
General Chemical Engineering

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10.1039/d4ra04194a

Cite this

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abstract = "Brain organoids are three-dimensionally reconstructed brain tissue derived from pluripotent stem cells in vitro. 3D tissue cultures have opened new avenues for exploring development and disease modeling. However, many physiological conditions, including signaling gradients in 3D cultures, have not yet been easily achieved. Here, we introduce brain organoid-on-a-chip platforms that generate signaling gradients that in turn enable the induction of topographic forebrain organoids. This creates a more continuous spectrum of brain regions and provides a more complete mimic of the human brain for evaluating neurodevelopment and disease in unprecedented detail.",

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AU - Tsai, Yuan Chen

AU - Ozaki, Hajime

AU - Morikawa, Ango

AU - Shiraiwa, Kaori

AU - Pin, Andy Prosvey

AU - Salem, Aya Galal

AU - Phommahasay, Kenneth Akady

AU - Sugita, Bret Kiyoshi

AU - Vu, Christine Hein

AU - Hammad, Saba Mamoun

AU - Kamei, Ken Ichiro

AU - Watanabe, Momoko

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AB - Brain organoids are three-dimensionally reconstructed brain tissue derived from pluripotent stem cells in vitro. 3D tissue cultures have opened new avenues for exploring development and disease modeling. However, many physiological conditions, including signaling gradients in 3D cultures, have not yet been easily achieved. Here, we introduce brain organoid-on-a-chip platforms that generate signaling gradients that in turn enable the induction of topographic forebrain organoids. This creates a more continuous spectrum of brain regions and provides a more complete mimic of the human brain for evaluating neurodevelopment and disease in unprecedented detail.

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Proof of concept for brain organoid-on-a-chip to create multiple domains in forebrain organoids

Abstract

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