An automation workflow for high-throughput manufacturing and analysis of scaffold-supported 3D tissue arrays

Cao, Ruonan; Li, Nancy T; Cadavid, Jose L.; Latour, Simon; Tan, Cassidy M; McGuigan, Alison P.

doi:10.1101/2022.08.20.504600

Cited by 3 publications

(3 citation statements)

References 49 publications

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“…The copyright holder for this preprint this version posted January 21, 2023. ; https://doi.org/10.1101/2023.01.20.524941 doi: bioRxiv preprint platform 18 , reported by our group, which we recently demonstrated is compatible with robotic liquid handler to enable massive increases in scale 19 .…”

Section: Discussionmentioning

confidence: 92%

“…This manual removal step, however would limit use of robots in fully automating our assay. If a larger scale screening capacity is desirable in the future, the MEndR assay could be further integrated with the SPOT platform 20 , reported by our group, which we recently demonstrated is compatible with robotic liquid handler to enable massive increases in scale 21 .…”

Section: Discussionmentioning

confidence: 99%

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mini-MEndR: A 96-well mixed species culture assay to co-evaluate human and mouse Pax7⁺cell-mediated skeletal muscle repair

Gulati

Davoudi

Rjaibi

et al. 2023

Preprint

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Functional evaluation of novel molecules that promote stem cell mediated endogenous repair often require multiplexed in vivo transplant studies that are low throughput and hinder the rate of discovery. Here, we optimized and miniaturized a previously developed muscle endogenous repair (MEndR) in vitro assay that captures significant events of in vivo muscle endogenous repair to offer greater throughput for functional validation studies. The mini-MEndR assay consists of miniaturized cellulose scaffolds designed to fit in 96-well plates, the pores of which are infiltrated with myoblasts encapsulated in a fibrin-based hydrogel to form engineered skeletal muscle tissues. Pre-adsorbing thrombin to the cellulose scaffolds facilitates in situ tissue polymerization, a critical modification that enables new users to rapidly acquire assay expertise. Following the generation of the 3D myotube template, muscle stem cells (MuSCs), prospectively isolated from mouse skeletal muscle tissue, are engrafted onto the engineered template. A regenerative milieu is then introduced by injuring the muscle tissue with a myotoxin. We evaluated two different commercially available human primary myoblast lines and were able to successfully generate miniaturized 3D muscle templates, as well as recapitulate the in vivo outcomes of a known modulator of MuSC mediated repair but only in the presence of both the stem cells and the regenerative milieu. Thus, the mini-MEndR culture assay captures the ability of different molecular treatments to modulate donor MuSC skeletal muscle production and niche repopulation. The miniaturized predictive assay offers a simple, scaled platform with which to investigate MuSC endogenous repair molecular modulators, and thus is a promising strategy to accelerate the muscle endogenous repair discovery pipeline.

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Section: Discussionmentioning

confidence: 92%

Section: Discussionmentioning

confidence: 99%

mini-MEndR: A 96-well mixed species culture assay to co-evaluate human and mouse Pax7⁺cell-mediated skeletal muscle repair

Gulati

Davoudi

Rjaibi

et al. 2023

Preprint

Self Cite

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show abstract

“…2 –4 Fortunately, advancements in tissue engineering technology have created more sophisticated in vitro 3D cellular models, such as microtissue arrays and 3D printing, which are becoming more commonly used. 5 –9 The widespread use of these 3D models provides a strong foundation for preclinical drug research. Among them, the microtissue array is a micro-scale three-dimensional bionic model carrying cells, 10,11 which can replicate the function of an organ at its most fundamental level.…”

Section: Introductionmentioning

confidence: 99%

Digital light processing-based bioprinting of microtissue hydrogel arrays using dextran-induced aqueous emulsion ink

Xu,

Liao,

Liu

et al. 2024

Journal of Bioactive and Compatible Polymers

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As a microscale three-dimensional bionic model, a microtissue array is a promising method for disease modeling and drug screening. Digital light processing (DLP) 3D bio-printing technology with the capabilities of excellent printing speed and resolution shows great potential for fabricating microtissue arrays. However, the outcomes of the microtissue arrays using DLP are limited by the shortage of biomaterials. In this work, we prepare hydrogel microtissues by combining DLP printing technology with biphasic bio-ink consisting of gelatin methacrylate (GelMA) and dextran. GelMA/ dextran is mixed to form bio-inks with different volume ratios, which can achieve high-precision printing of various patterns. Due to the presence of dextran, the bio-inks form the internal porous structure of the hydrogel in the printed patterns. The pore size is related to the proportion of dextran in bio-inks, and the pore size of hydrogel becomes smaller with the increase of dextran ratio. In addition, the adipose-derived stem cells (ADSCs) cells encapsulated in the porous hydrogels can maintain a high survival rate of 98.01% after 3 days of culture, and the larger pore size in the hydrogels promotes cell migration. Combining the DLP printing system with the porous hydrogel allows multiple micro-size geometric pattern hydrogels to be printed simultaneously to form microtissue arrays. In this study, a new bio-ink suitable for microtissue arrays is proposed, and a simple, accurate, and high-throughput biological manufacturing method for microtissue arrays is developed, thus providing a valuable tool for drug screening and tissue engineering.

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Mini-MEndR: a miniaturized 96-well predictive assay to evaluate muscle stem cell-mediated repair

Gulati,

Davoudi,

et al. 2024

BMC Methods

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Background Functional evaluation of molecules that are predicted to promote stem cell mediated endogenous repair often requires in vivo transplant studies that are low throughput and hinder the rate of discovery. To offer greater throughput for functional validation studies, we miniaturized, simplified and expanded the functionality of a previously developed muscle endogenous repair (MEndR) in vitro assay that was shown to capture significant events of in vivo muscle endogenous repair. Methods The mini-MEndR assay consists of miniaturized cellulose scaffolds designed to fit in 96-well plates, the pores of which are infiltrated with human myoblasts encapsulated in a fibrin-based hydrogel to form engineered skeletal muscle tissues. Pre-adsorbing thrombin to the cellulose scaffolds facilitates in situ tissue polymerization, a critical modification that enables new users to rapidly acquire assay expertise. Following the generation of the 3D myotube template, muscle stem cells (MuSCs), enriched from digested mouse skeletal muscle tissue using an improved magnetic-activated cell sorting protocol, are engrafted within the engineered template. Murine MuSCs are fluorescently labeled, enabling co-evaluation of human and mouse Pax7+ cell responses to drug treatments. A regenerative milieu is introduced by injuring the muscle tissue with a myotoxin to initiate endogenous repair “in a dish”. Phenotypic data is collected at endpoints with a high-content imaging system and is analyzed using ImageJ-based image analysis pipelines. Results The miniaturized format and modified manufacturing protocol cuts reagent costs in half and hands-on seeding time ~ threefold, while the image analysis pipelines save 40 h of labour. By evaluating multiple commercially available human primary myoblast lines in 2D and 3D culture, we establish quality assurance metrics for cell line selection that standardizes myotube template quality. In vivo outcomes (enhanced muscle production and Pax7+ cell expansion) to a known modulator of MuSC mediated repair (p38/β MAPK inhibition) are recapitulated in the miniaturized culture assay, but only in the presence of stem cells and the regenerative milieu. Discussion The miniaturized predictive assay offers a simple, scaled platform to co-investigate human and mouse skeletal muscle endogenous repair molecular modulators, and thus is a promising strategy to accelerate the muscle endogenous repair discovery pipeline.

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An automation workflow for high-throughput manufacturing and analysis of scaffold-supported 3D tissue arrays

Cited by 3 publications

References 49 publications

mini-MEndR: A 96-well mixed species culture assay to co-evaluate human and mouse Pax7⁺cell-mediated skeletal muscle repair

mini-MEndR: A 96-well mixed species culture assay to co-evaluate human and mouse Pax7⁺cell-mediated skeletal muscle repair

Digital light processing-based bioprinting of microtissue hydrogel arrays using dextran-induced aqueous emulsion ink

Mini-MEndR: a miniaturized 96-well predictive assay to evaluate muscle stem cell-mediated repair

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An automation workflow for high-throughput manufacturing and analysis of scaffold-supported 3D tissue arrays

Cited by 3 publications

References 49 publications

mini-MEndR: A 96-well mixed species culture assay to co-evaluate human and mouse Pax7+cell-mediated skeletal muscle repair

mini-MEndR: A 96-well mixed species culture assay to co-evaluate human and mouse Pax7+cell-mediated skeletal muscle repair

Digital light processing-based bioprinting of microtissue hydrogel arrays using dextran-induced aqueous emulsion ink

Mini-MEndR: a miniaturized 96-well predictive assay to evaluate muscle stem cell-mediated repair

Contact Info

Product

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About

mini-MEndR: A 96-well mixed species culture assay to co-evaluate human and mouse Pax7⁺cell-mediated skeletal muscle repair

mini-MEndR: A 96-well mixed species culture assay to co-evaluate human and mouse Pax7⁺cell-mediated skeletal muscle repair