Bio‐assembling Macro‐Scale, Lumenized Airway Tubes of Defined Shape via Multi‐Organoid Patterning and Fusion

Ye Liu; Catherine Dabrowska; Antranik Mavousian; Bernhard Strauss; Fanlong Meng; Corrado Mazzaglia; Karim Ouaras; Callum Macintosh; Eugene Terentjev; Joo‐Hyeon Lee; Yan Yan Shery Huang

doi:10.1002/advs.202003332

Advanced Science (May 2021)

Bio‐assembling Macro‐Scale, Lumenized Airway Tubes of Defined Shape via Multi‐Organoid Patterning and Fusion

Ye Liu,
Catherine Dabrowska,
Antranik Mavousian,
Bernhard Strauss,
Fanlong Meng,
Corrado Mazzaglia,
Karim Ouaras,
Callum Macintosh,
Eugene Terentjev,
Joo‐Hyeon Lee,
Yan Yan Shery Huang

Affiliations

Ye Liu: Department of Engineering University of Cambridge Cambridge CB2 1PZ UK
Catherine Dabrowska: Wellcome – MRC Cambridge Stem Cell Institute University of Cambridge Cambridge CB2 0AW UK
Antranik Mavousian: Wellcome – MRC Cambridge Stem Cell Institute University of Cambridge Cambridge CB2 0AW UK
Bernhard Strauss: Department of Biochemistry University of Cambridge Cambridge CB2 1QW UK
Fanlong Meng: CAS Key Laboratory of Theoretical Physics Institute of Theoretical Physics Chinese Academy of Sciences Beijing 100190 China
Corrado Mazzaglia: Department of Engineering University of Cambridge Cambridge CB2 1PZ UK
Karim Ouaras: Department of Engineering University of Cambridge Cambridge CB2 1PZ UK
Callum Macintosh: Department of Engineering University of Cambridge Cambridge CB2 1PZ UK
Eugene Terentjev: Cavendish Laboratory University of Cambridge Cambridge CB3 0HE UK
Joo‐Hyeon Lee: Wellcome – MRC Cambridge Stem Cell Institute University of Cambridge Cambridge CB2 0AW UK
Yan Yan Shery Huang: Department of Engineering University of Cambridge Cambridge CB2 1PZ UK

DOI: https://doi.org/10.1002/advs.202003332
Journal volume & issue: Vol. 8, no. 9
pp. n/a – n/a

Abstract

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Abstract Epithelial, stem‐cell derived organoids are ideal building blocks for tissue engineering, however, scalable and shape‐controlled bio‐assembly of epithelial organoids into larger and anatomical structures is yet to be achieved. Here, a robust organoid engineering approach, Multi‐Organoid Patterning and Fusion (MOrPF), is presented to assemble individual airway organoids of different sizes into upscaled, scaffold‐free airway tubes with predefined shapes. Multi‐Organoid Aggregates (MOAs) undergo accelerated fusion in a matrix‐depleted, free‐floating environment, possess a continuous lumen, and maintain prescribed shapes without an exogenous scaffold interface. MOAs in the floating culture exhibit a well‐defined three‐stage process of inter‐organoid surface integration, luminal material clearance, and lumina connection. The observed shape stability of patterned MOAs is confirmed by theoretical modelling based on organoid morphology and the physical forces involved in organoid fusion. Immunofluorescent characterization shows that fused MOA tubes possess an unstratified epithelium consisting mainly of tracheal basal stem cells. By generating large, shape‐controllable organ tubes, MOrPF enables upscaled organoid engineering towards integrated organoid devices and structurally complex organ tubes.

Published in Advanced Science

ISSN: 2198-3844 (Online)
Publisher: Wiley
Country of publisher: Germany
LCC subjects: Science
Website: https://onlinelibrary.wiley.com/journal/21983844

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