Microfluidic droplet platform for ultrahigh-throughput single-cell screening of biodiversity

Terekhov, Stanislav S.; Смирнов, Иван; Stepanova, A. V.; Бобик, Т. В.; Mokrushina, Yuliana A.; Ponomarenko, N. A.; Belogurov, Alexey A.; Rubtsova, Maria P.; Kartseva, Olga V.; Gomzikova, Marina O.; Московцев, А. А.; Bukatin, Anton; Dubina, Michael; Kostryukova, Elena S.; Babenko, Vladislav V.; Vakhitova, Maria T.; Manolov, Alexander I.; Malakhova, Maja V.; Kornienko, Maria A.; Tyakht, Alexander V.; Vanyushkina, Anna; Ilina, Elena N.; Masson, Patrick; Gabibov, Alexander; Altman, Sidney

doi:10.1073/pnas.1621226114

Cited by 191 publications

(178 citation statements)

References 30 publications

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“…This paper describes interfacial nanoinjection (INJ), a simple microfluidic droplet‐handling system developed for multistep nanoliter assays on standard 96‐ or 384‐well plates, and a simple pipeline that couples INJ and fluorescence‐activated cell sorting (FACS) for single‐cell analyses with high versatility, high throughput, and low cost. Recent research advances have promoted the study of biological systems with respect to their physiological phenotypes, genomics, transcriptomics, epigenomics, proteomics, multiomics, and biodiversity at the single‐cell level. Single‐cell analysis allows the fundamental understanding of cell‐to‐cell heterogeneity and provides unprecedented resolution in complex biological systems, especially those from rare cell types or uncultivated microbes .…”

Section: Introductionmentioning

confidence: 99%

“…However, these systems are limited to certain cell types or confined to only one specific application or workflow. Microfluidic devices enable ultrahigh throughput isolation, reaction, and analysis of single cells . However, most microfluidic devices lack standardization which affects its world‐to‐chip interconnections and flexibility in coping with changes in applications.…”

Section: Introductionmentioning

confidence: 99%

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Interfacial Nanoinjection‐Based Nanoliter Single‐Cell Analysis

Yun

Zheng

et al. 2019

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Single‐cell analysis offers unprecedented resolution for the investigation of cellular heterogeneity and the capture of rare cells from large populations. Here, described is a simple method named interfacial nanoinjection (INJ), which can miniaturize various single‐cell assays to be performed in nanoliter water‐in‐oil droplets on standard microwell plates. The INJ droplet handler can adjust droplet volumes for multistep reactions on demand with high precision and excellent monodispersity, and consequently enables a wide range of single‐cell assays. Importantly, INJ can be coupled with fluorescence‐activated cell sorting (FACS), which is currently the most effective and accurate single‐cell sorting and isolation method. FACS‐INJ pipelines for high‐throughput plate well‐based single‐cell analyses, including single‐cell proliferation, drug‐resistance testing, polymerase chain reaction (PCR), reverse‐transcription PCR, and whole‐genome sequencing are introduced. This FACS‐INJ pipeline is compatible with a wide range of samples and can be extended to various single‐cell analysis applications in microbiology, cell biology, and biomedical diagnostics.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Interfacial Nanoinjection‐Based Nanoliter Single‐Cell Analysis

Yun

Zheng

et al. 2019

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“…The state‐of‐the‐art FC systems are capable of simultaneously measuring up to 12 fluorescence colors, have at least an order of magnitude higher sorting rates (i.e., 40 kHz) than FADS, and more easily accessible to users than custom microfluidic sorters. Since oil carrier fluid is not compatible with FC systems, double water‐in‐oil‐in‐water (w/o/w) emulsions have been developed, enabling directed enzyme evolution and single‐cell screening . However, the generation of double emulsions is more complex than one‐step emulsification, and its applications are limited, as the surfactants and oil solution prevent new reagents from entering into the stable compartments for multistep reactions …”

Section: Introductionmentioning

confidence: 99%

A Gelatin Microdroplet Platform for High‐Throughput Sorting of Hyperproducing Single‐Cell‐Derived Microalgal Clones

Zee

Riche

et al. 2018

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Microalgae are an attractive feedstock organism for sustainable production of biofuels, chemicals, and biomaterials, but the ability to rationally engineer microalgae to enhance production has been limited. To enable the evolution‐based selection of new hyperproducing variants of microalgae, a method is developed that combines phase‐transitioning monodisperse gelatin hydrogel droplets with commercial flow cytometric instruments for high‐throughput screening and selection of clonal populations of cells with desirable properties, such as high lipid productivity per time traced over multiple cell cycles. It is found that gelatin microgels enable i) the growth and metabolite (e.g., chlorophyll and lipids) production of single microalgal cells within the compartments, ii) infusion of fluorescent reporter molecules into the hydrogel matrices following a sol–gel transition, iii) selection of high‐producing clonal populations of cells using flow cytometry, and iv) cell recovery under mild conditions, enabling regrowth after sorting. This user‐friendly method is easily integratable into directed cellular evolution pipelines for strain improvement and can be adopted for other applications that require high‐throughput processing, e.g., cellular secretion phenotypes and intercellular interactions.

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“…Well-developed methods for culturing bacteria and eukaryotic cells (Clausell-Tormos et al, 2008;Jakiela et al, 2013;Moffitt et al, 2012), allowed for rapid investigation on the level of single cells. Assays detecting single biomolecules (Hughes et al, 2004;Rissin et al, 2010;Shim et al, 2013) can be performed at a very high throughput (Agresti et al, 2010;Cheng et al, 2016;Lim and Abate, 2013;Lim et al, 2015;Terekhov et al, 2017).…”

Section: Biological and Biochemical Assays In High Throughputmentioning

confidence: 99%

Droplet Microfluidics as a Tool for the Generation of Granular Matters and Functional Emulsions

Opalski

Kamiński

Garstecki

2019

KONA

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Emulsion-a liquid dispersed in another liquid-is in many respects very similar to granular matter. In the early 2000s a new technology-droplet microfluidics-began emerging from the wider field of microfluidics. Droplet microfluidics was quickly established as a discipline of science and engineering and has been used for the generation of highly uniform emulsions. The last few years have brought significant advances to the field, directed towards a wide range of applications in material sciences-from synthesis of nanoparticles in droplets to assembling complex droplets and using droplets as templates for ordered materials, with applications in food, cosmetic and diagnostic industries. Droplet microfluidic platforms are also successfully used as analytical tools in molecular biology and biochemistry, in e.g. high-throughput screening, digital assays, encapsulation of single cells, sequencing technologies, and in point-of-care diagnostic applications. This article provides an accessible overview of the physical phenomena observed in multiphase flow at the microscale and the techniques in droplet microfluidics systems. We also present the most interesting applications and potential further directions of research in this fascinating young field of science and engineering.

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Microfluidic droplet platform for ultrahigh-throughput single-cell screening of biodiversity

Cited by 191 publications

References 30 publications

Interfacial Nanoinjection‐Based Nanoliter Single‐Cell Analysis

Interfacial Nanoinjection‐Based Nanoliter Single‐Cell Analysis

A Gelatin Microdroplet Platform for High‐Throughput Sorting of Hyperproducing Single‐Cell‐Derived Microalgal Clones

Droplet Microfluidics as a Tool for the Generation of Granular Matters and Functional Emulsions

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