Functional single-cell hybridoma screening using droplet-based microfluidics

Debs, Bachir El; Utharala, Ramesh; Balyasnikova, Irina V.; Griffiths, Andrew D.; Merten, Christoph A.

doi:10.1073/pnas.1204514109

Cited by 247 publications

(221 citation statements)

References 26 publications

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“…Much of the work thus far has been directed toward improving droplet manipulation capabilities (12)(13)(14)(15)(16). With these methods, droplets are mobile, and thus cytometry is performed under flow conditions (17), making continuous monitoring of single cells difficult. Continuous monitoring may be achieved by using stationary indexed droplets, but many current droplet immobilization techniques are limited by pressure coupling between droplet generation and capture events, as well as the requirement to adjust droplet volume to nanowell size (6,18,19).…”

mentioning

confidence: 99%

Stationary nanoliter droplet array with a substrate of choice for single adherent/nonadherent cell incubation and analysis

Shemesh

Ben-Arye

Avesar³

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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Microfluidic water-in-oil droplets that serve as separate, chemically isolated compartments can be applied for single-cell analysis; however, to investigate encapsulated cells effectively over prolonged time periods, an array of droplets must remain stationary on a versatile substrate for optimal cell compatibility. We present here a platform of unique geometry and substrate versatility that generates a stationary nanodroplet array by using wells branching off a main microfluidic channel. These droplets are confined by multiple sides of a nanowell and are in direct contact with a biocompatible substrate of choice. The device is operated by a unique and reversed loading procedure that eliminates the need for fine pressure control or external tubing. Fluorocarbon oil isolates the droplets and provides soluble oxygen for the cells. By using this approach, the metabolic activity of single adherent cells was monitored continuously over time, and the concentration of viable pathogens in blood-derived samples was determined directly by measuring the number of colony-formed droplets. The method is simple to operate, requires a few microliters of reagent volume, is portable, is reusable, and allows for cell retrieval. This technology may be particularly useful for multiplexed assays for which prolonged and simultaneous visual inspection of many isolated single adherent or nonadherent cells is required.single cell | nanoliter array | diagnostics C ommon single-cell analysis methods, such as flow cytometry and mass cytometry (1), offer high throughput and accurate single-cell marker quantification, yet they lack the ability to monitor large numbers of single cells continuously and simultaneously in performance-based assays (2, 3). Conventional microscopy may be used for these assays; however, in the case of single cells, they cannot analyze extracellular events, such as secretion. To achieve this, cells must be isolated in compartments that can sustain cell viability and growth while permitting conventional optical analysis over many hours to days. Dropletbased microfluidics, which enables single-cell encapsulation in nano-and subnanoliter droplets by surrounding microscopic aqueous medium with an immiscible carrier fluid (4-8), recently gained interest with the appearance of digital PCR (9-11). Much of the work thus far has been directed toward improving droplet manipulation capabilities (12-16). With these methods, droplets are mobile, and thus cytometry is performed under flow conditions (17), making continuous monitoring of single cells difficult. Continuous monitoring may be achieved by using stationary indexed droplets, but many current droplet immobilization techniques are limited by pressure coupling between droplet generation and capture events, as well as the requirement to adjust droplet volume to nanowell size (6,18,19). The vast majority of methods used to generate water-in-oil droplets begin by priming a continuous oil phase in a microfluidic channel followed by an injection of a dispersed (aqueous) medium (2...

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mentioning

confidence: 99%

Stationary nanoliter droplet array with a substrate of choice for single adherent/nonadherent cell incubation and analysis

Shemesh

Ben-Arye

Avesar³

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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“…This resulted in a 15-fold reduction in the experimental time needed for the analysis of four targets compared with traditional phage-display formats. 76 Other recent efforts in this area include the functional screening of hybridoma cells for the release of antibodies inhibiting a drug target at a screening rate of 300,000 cell clones per day 77 and chromatin immunoprecipitation on a chip to select for antibodies against specific proteins. 78 In 2007, Maerkl and Quake 79 introduced the MITOMI (Mechanically Induced Trapping of Molecular Interactions) platform (see Fig.…”

Section: Ligand-binding Assaysmentioning

confidence: 99%

Droplet-Based Microfluidics: Enabling Impact on Drug Discovery

et al. 2014

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Over the past two decades, the application of microengineered systems in the chemical and biological sciences has transformed the way in which high-throughput experimentation is performed. The ability to fabricate complex microfluidic architectures has allowed scientists to create new experimental formats for processing ultra-small analytical volumes in short periods and with high efficiency. The development of such microfluidic systems has been driven by a range of fundamental features that accompany miniaturization. These include the ability to handle small sample volumes, ultra-low fabrication costs, reduced analysis times, enhanced operational flexibility, facile automation, and the ability to integrate functional components within complex analytical schemes. Herein we discuss the impact of microfluidics in the area of high-throughput screening and drug discovery and highlight some of the most pertinent studies in the recent literature.

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“…Water-inoil microdroplets allow the generation of microreactors (pl to fl volume), which permits the compartmentalization of reactions for multiple chemical and biochemical applications such as protein crystallization, 1 organic molecule 2 or nanoparticle synthesis, 3 genome sequencing, 4 and single cell and single molecule analysis. [5][6][7] With respect to molecular biology operations, previous work showed the efficiency of reagents compartmentalization for polymerase chain reaction (PCR), 8,9 single cell analysis, [10][11][12] or transcriptome analysis. 13 Generation of monodisperse microdroplets 12 is one way to carry out high throughput analysis 14 and execute independent reactions in parallel.…”

Section: Introductionmentioning

confidence: 99%

A microfluidic device for on-chip agarose microbead generation with ultralow reagent consumption

et al. 2012

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Water-in-oil microdroplets offer microreactors for compartmentalized biochemical reactions with high throughput. Recently, the combination with a sol-gel switch ability, using agarose-in-oil microdroplets, has increased the range of possible applications, allowing for example the capture of amplicons in the gel phase for the preservation of monoclonality during a PCR reaction. Here, we report a new method for generating such agarose-in-oil microdroplets on a microfluidic device, with minimized inlet dead volume, on-chip cooling, and in situ monitoring of biochemical reactions within the gelified microbeads. We used a flow-focusing microchannel network and successfully generated agarose microdroplets at room temperature using the "push-pull" method. This method consists in pushing the oil continuous phase only, while suction is applied to the device outlet. The agarose phase present at the inlet is thus aspirated in the device, and segmented in microdroplets. The cooling system consists of two copper wires embedded in the microfluidic device. The transition from agarose microdroplets to microbeads provides additional stability and facilitated manipulation. We demonstrate the potential of this method by performing on-chip a temperature-triggered DNA isothermal amplification in agarose microbeads. Our device thus provides a new way to generate microbeads with high throughput and no dead volume for biochemical applications. V C 2012 American Institute of Physics. [http://dx

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Functional single-cell hybridoma screening using droplet-based microfluidics

Cited by 247 publications

References 26 publications

Stationary nanoliter droplet array with a substrate of choice for single adherent/nonadherent cell incubation and analysis

Stationary nanoliter droplet array with a substrate of choice for single adherent/nonadherent cell incubation and analysis

Droplet-Based Microfluidics: Enabling Impact on Drug Discovery

A microfluidic device for on-chip agarose microbead generation with ultralow reagent consumption

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