The Poisson distribution and beyond: methods for microfluidic droplet production and single cell encapsulation

Collins, Dave; Neild, Adrian; deMello, Andrew J.; Liu, Ai Qun; Ai, Ye

doi:10.1039/c5lc00614g

Cited by 417 publications

(385 citation statements)

References 202 publications

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“…To improve these statistics, various active and more controlled encapsulation methods are being developed. 61 An interesting approach is to use droplet microfluidics and a simple motorized system to streak droplets with a single cell on agar plates (Fig. 3b).…”

Section: Droplet Screeningmentioning

confidence: 99%

Droplet microfluidics for synthetic biology

et al. 2017

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Section: Droplet Screeningmentioning

confidence: 99%

Droplet microfluidics for synthetic biology

et al. 2017

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“…An advantage of this technique over microwells is the speed of droplet generation and the ease of automation, which allows high-throughput assembly of cell aggregates (Allazetta and Lutolf, 2015;Chan et al, 2013;Tumarkin et al, 2011). In contrast to microwells, which rely on probabilistic cell loading, recent advances in droplet-based microfluidics can achieve singlecell droplet loading and can load droplets with combinations of cell types with a precision that exceeds Poisson limitations (Collins et al, 2015;Edd et al, 2008;Schoeman et al, 2014). These devices can also be used to capture precise cell pairs, facilitating the dynamic dissection of cell-cell interactions from the initiation of contact (Dura et al, 2016).…”

Section: Microfluidics Approaches Guide Organoid Size and Shapementioning

confidence: 99%

Dissecting the stem cell niche with organoid models: an engineering-based approach

2017

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For many tissues, single resident stem cells grown in vitro under appropriate three-dimensional conditions can produce outgrowths known as organoids. These tissues recapitulate much of the cell composition and architecture of the in vivo organ from which they derive, including the formation of a stem cell niche. This has facilitated the systematic experimental manipulation and single-cell, highthroughput imaging of stem cells within their respective niches. Furthermore, emerging technologies now make it possible to engineer organoids from purified cellular and extracellular components to directly model and test stem cell-niche interactions. In this Review, we discuss how organoids have been used to identify and characterize stem cell-niche interactions and uncover new niche components, focusing on three adult-derived organoid systems. We also describe new approaches to reconstitute organoids from purified cellular components, and discuss how this technology can help to address fundamental questions about the adult stem cell niche.

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“…Furthermore, cells suspended at high concentrations (410 6 cells per mL) tend to aggregate, which can lead to incomplete cell encapsulation as well as increased microgel diameters. Therefore, low concentration cell suspensions (10 4 -10 5 cells per mL) are typically used, often resulting in a high percentage of empty microgels according to the Poisson distribution 25 , which is undesirable for in vivo efficacy and limits applications of encapsulation. Microgels containing cells can be purified by sorting or can be selectively crosslinked 7,24,26,27 , but encapsulating clinically relevant numbers of cells in these very small microgels is highly challenging, since several tens of millions of cells may be required for therapeutic efficacy 28,29 .…”

Section: Introductionmentioning

confidence: 99%

Parallel droplet microfluidics for high throughput cell encapsulation and synthetic microgel generation

2018

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Cells can be microencapsulated in synthetic hydrogel microspheres (microgels) using droplet microfluidics, but microfluidic devices with a single droplet generating geometry have limited throughput, especially as microgel diameter decreases. Here we demonstrate microencapsulation of human mesenchymal stem cells (hMSCs) in small ( o100 μm diameter) microgels utilizing parallel droplet generators on a two-layer elastomer device, which has 600% increased throughput vs. single-nozzle devices. Distribution of microgel diameters were compared between products of parallel vs. single-nozzle configurations for two square nozzle widths, 35 and 100 μm. Microgels produced on parallel nozzles were equivalent to those produced on single nozzles, with substantially the same polydispersity. Microencapsulation of hMSCs was compared for parallel nozzle devices of each width. Thirty five micrometer wide nozzle devices could be operated at twice the cell concentration of 100 μm wide nozzle devices but produced more empty microgels than predicted by a Poisson distribution. Hundred micrometer wide nozzle devices produced microgels as predicted by a Poisson distribution. Polydispersity of microgels did not increase with the addition of cells for either nozzle width. hMSCs encapsulated on 35 μm wide nozzle devices had reduced viability (~70%) and a corresponding decrease in vascular endothelial growth factor (VEGF) secretion compared to hMSCs cultured on tissue culture (TC) plastic. Encapsulating hMSCs using 100 μm wide nozzle devices mitigated loss of viability and function, as measured by VEGF secretion.

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The Poisson distribution and beyond: methods for microfluidic droplet production and single cell encapsulation

Cited by 417 publications

References 202 publications

Droplet microfluidics for synthetic biology

Droplet microfluidics for synthetic biology

Dissecting the stem cell niche with organoid models: an engineering-based approach

Parallel droplet microfluidics for high throughput cell encapsulation and synthetic microgel generation

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