Modular 3D printed platform for fluidically connected human brain organoid culture

Babak Rezaei; Jessica Giacomoni; Fredrik Nilsson; Edoardo Sozzi; Alessandro Fiorenzano; Malin Parmar; Stephan S. Keller; Janko Kajtez

doi:10.1088/1758-5090/ad0c2c

Modular 3D printed platform for fluidically connected human brain organoid culture

Babak Rezaei, Jessica Giacomoni, Fredrik Nilsson, Edoardo Sozzi, Alessandro Fiorenzano, Malin Parmar, Stephan S. Keller, Janko Kajtez

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

Abstract

Brain organoid technology has transformed both basic and applied biomedical research and paved the way for novel insights into developmental processes and disease states of the human brain. While the use of brain organoids has been rapidly growing in the past decade, the accompanying bioengineering and biofabrication solutions have remained scarce. As a result, most brain organoid protocols still rely on commercially available tools and culturing platforms that had previously been established for different purposes, thus entailing suboptimal culturing conditions and excessive use of plasticware. To address these issues, we developed a 3D printing pipeline for the fabrication of tailor-made culturing platforms for fluidically connected but spatially separated brain organoid array culture. This all-in-one platform allows all culturing steps—from cellular aggregation, spheroid growth, hydrogel embedding, and organoid maturation—to be performed in a single well plate without the need for organoid manipulation or transfer. Importantly, the approach relies on accessible materials and widely available 3D printing equipment. Furthermore, the developed design principles are modular and highly customizable. As such, we believe that the presented technology can be easily adapted by other research groups and fuel further development of culturing tools and platforms for brain organoids and other 3D cellular systems.

Original language	English
Article number	015014
Journal	Biofabrication
Volume	1
Issue number	15014
DOIs	https://doi.org/10.1088/1758-5090/ad0c2c
Publication status	Published - 2024 Jan 1

Bibliographical note

Funding Information:
The authors would like to thank Bengt Mattsson for the creation of 3D models and illustrations. Lund University Bioimaging Centre (LBIC) is gratefully acknowledged for providing experimental resources for electron and fluorescence microscopy. B R and S S K acknowledge the financial support from the European Research Council under the Horizon 2020 framework program (Grant No. 772370-PHOENEEX). J K and M P acknowledge the financial support from The Swedish Research Council (2021-02967) and HORIZON-EIC-2021-PATHFINDEROPEN-01 project OpenMIND (101047177). A F is supported by Swedish Research Council (2022-01432) and Italian Ministry of Health (B53C22007860001).

Publisher Copyright:
© 2023 The Author(s). Published by IOP Publishing Ltd.

Subject classification (UKÄ)

Cell and Molecular Biology

Free keywords

3D culture
3D printing
brain organoids
modular design
neuroscience
stereolithography

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1088/1758-5090/ad0c2c

Cite this

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title = "Modular 3D printed platform for fluidically connected human brain organoid culture",

abstract = "Brain organoid technology has transformed both basic and applied biomedical research and paved the way for novel insights into developmental processes and disease states of the human brain. While the use of brain organoids has been rapidly growing in the past decade, the accompanying bioengineering and biofabrication solutions have remained scarce. As a result, most brain organoid protocols still rely on commercially available tools and culturing platforms that had previously been established for different purposes, thus entailing suboptimal culturing conditions and excessive use of plasticware. To address these issues, we developed a 3D printing pipeline for the fabrication of tailor-made culturing platforms for fluidically connected but spatially separated brain organoid array culture. This all-in-one platform allows all culturing steps—from cellular aggregation, spheroid growth, hydrogel embedding, and organoid maturation—to be performed in a single well plate without the need for organoid manipulation or transfer. Importantly, the approach relies on accessible materials and widely available 3D printing equipment. Furthermore, the developed design principles are modular and highly customizable. As such, we believe that the presented technology can be easily adapted by other research groups and fuel further development of culturing tools and platforms for brain organoids and other 3D cellular systems.",

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note = "Funding Information: The authors would like to thank Bengt Mattsson for the creation of 3D models and illustrations. Lund University Bioimaging Centre (LBIC) is gratefully acknowledged for providing experimental resources for electron and fluorescence microscopy. B R and S S K acknowledge the financial support from the European Research Council under the Horizon 2020 framework program (Grant No. 772370-PHOENEEX). J K and M P acknowledge the financial support from The Swedish Research Council (2021-02967) and HORIZON-EIC-2021-PATHFINDEROPEN-01 project OpenMIND (101047177). A F is supported by Swedish Research Council (2022-01432) and Italian Ministry of Health (B53C22007860001). Publisher Copyright: {\textcopyright} 2023 The Author(s). Published by IOP Publishing Ltd.",

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AU - Rezaei, Babak

AU - Giacomoni, Jessica

AU - Nilsson, Fredrik

AU - Sozzi, Edoardo

AU - Fiorenzano, Alessandro

AU - Parmar, Malin

AU - Keller, Stephan S.

AU - Kajtez, Janko

N1 - Funding Information: The authors would like to thank Bengt Mattsson for the creation of 3D models and illustrations. Lund University Bioimaging Centre (LBIC) is gratefully acknowledged for providing experimental resources for electron and fluorescence microscopy. B R and S S K acknowledge the financial support from the European Research Council under the Horizon 2020 framework program (Grant No. 772370-PHOENEEX). J K and M P acknowledge the financial support from The Swedish Research Council (2021-02967) and HORIZON-EIC-2021-PATHFINDEROPEN-01 project OpenMIND (101047177). A F is supported by Swedish Research Council (2022-01432) and Italian Ministry of Health (B53C22007860001). Publisher Copyright: © 2023 The Author(s). Published by IOP Publishing Ltd.

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N2 - Brain organoid technology has transformed both basic and applied biomedical research and paved the way for novel insights into developmental processes and disease states of the human brain. While the use of brain organoids has been rapidly growing in the past decade, the accompanying bioengineering and biofabrication solutions have remained scarce. As a result, most brain organoid protocols still rely on commercially available tools and culturing platforms that had previously been established for different purposes, thus entailing suboptimal culturing conditions and excessive use of plasticware. To address these issues, we developed a 3D printing pipeline for the fabrication of tailor-made culturing platforms for fluidically connected but spatially separated brain organoid array culture. This all-in-one platform allows all culturing steps—from cellular aggregation, spheroid growth, hydrogel embedding, and organoid maturation—to be performed in a single well plate without the need for organoid manipulation or transfer. Importantly, the approach relies on accessible materials and widely available 3D printing equipment. Furthermore, the developed design principles are modular and highly customizable. As such, we believe that the presented technology can be easily adapted by other research groups and fuel further development of culturing tools and platforms for brain organoids and other 3D cellular systems.

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SN - 1758-5082

VL - 1

JO - Biofabrication

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ER -

Modular 3D printed platform for fluidically connected human brain organoid culture

Abstract

Bibliographical note

Subject classification (UKÄ)

Free keywords

UN SDGs

Access to Document

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Cite this