Retinal organoids on-a-chip: a micro-millifluidic bioreactor for long-term organoid maintenance

Retinal degeneration is a leading cause of vision impairment and blindness worldwide and medical care for advanced disease does not exist. Stem cell-derived retinal organoids (RtOgs) became an emerging tool for tissue replacement therapy. However, existing RtOg production methods are highly heteroge...

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Bibliographic Details
Published in:Lab on a chip 2021-09, Vol.21 (17), p.3361-3377
Main Authors: Xue, Yuntian, Seiler, Magdalene J, Tang, William C, Wang, Jasmine Y, Delgado, Jeffrey, McLelland, Bryce T, Nistor, Gabriel, Keirstead, Hans S, Browne, Andrew W
Format: Article
Language:English
Subjects:
Bioreactors
Blindness
Degeneration
Design optimization
Fluorescence
Gene expression
Gene sequencing
Lithography
Maintenance
Mass transfer
Medical imaging
Microscopy
Morphology
Nicotinamide adenine dinucleotide
Phase contrast
Polydimethylsiloxane
Polymerase chain reaction
Production methods
Qualitative analysis
Shear stress
Stem cells
Three dimensional printing
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Summary:Retinal degeneration is a leading cause of vision impairment and blindness worldwide and medical care for advanced disease does not exist. Stem cell-derived retinal organoids (RtOgs) became an emerging tool for tissue replacement therapy. However, existing RtOg production methods are highly heterogeneous. Controlled and predictable methodology and tools are needed to standardize RtOg production and maintenance. In this study, we designed a shear stress-free micro-millifluidic bioreactor for nearly labor-free retinal organoid maintenance. We used a stereolithography (SLA) 3D printer to fabricate a mold from which Polydimethylsiloxane (PDMS) was cast. We optimized the chip design using in silico simulations and in vitro evaluation to optimize mass transfer efficiency and concentration uniformity in each culture chamber. We successfully cultured RtOgs at three different differentiation stages (day 41, 88, and 128) on an optimized bioreactor chip for more than 1 month. We used different quantitative and qualitative techniques to fully characterize the RtOgs produced by static dish culture and bioreactor culture methods. By analyzing the results from phase contrast microscopy, single-cell RNA sequencing (scRNA seq), quantitative polymerase chain reaction (qPCR), immunohistology, and electron microscopy, we found that bioreactor-cultured RtOgs developed cell types and morphology comparable to static cultured ones and exhibited similar retinal genes expression levels. We also evaluated the metabolic activity of RtOgs in both groups using fluorescence lifetime imaging (FLIM), and found that the outer surface region of bioreactor cultured RtOgs had a comparable free/bound NADH ratio and overall lower long lifetime species (LLS) ratio than static cultured RtOgs during imaging. To summarize, we validated an automated micro-millifluidic device with significantly reduced shear stress to produce RtOgs of comparable quality to those maintained in conventional static culture. We described an automated microfluidic bioreactor manufactured using soft lithography from 3D printed molds, and optimized for long-term retinal organoid maintenance with functional imaging.
ISSN:1473-0197
1473-0189
DOI:10.1039/d1lc00011j