A microfluidic perfusion platform for cultivation and screening study of motile microalgal cells

Eu, Young-Jae; Park, Hye-Sun; Kim, Dong‐Pyo; Hong, Jong Wook

doi:10.1063/1.4871522

Cited by 15 publications

(17 citation statements)

References 29 publications

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“…28,29 Recent microfluidic advances directed at algal cultures include microfluidic reactors that study microalgal growth in static droplet arrays 30 and multiplexed chemical environments. 31,32 Recently, Shih et al 24 demonstrated how the effect of irradiance conditions on the growth of algae could be studied within a digital microfluidic platform. Eight cultures were studied simultaneously, each grown using a separate LED light source.…”

Section: Introductionmentioning

confidence: 99%

Microalgae on display: a microfluidic pixel-based irradiance assay for photosynthetic growth

2015

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Microalgal biofuel is an emerging sustainable energy resource. Photosynthetic growth is heavily dependent on irradiance, therefore photobioreactor design optimization requires comprehensive screening of irradiance variables, such as intensity, time variance and spectral composition. Here we present a microfluidic irradiance assay which leverages liquid crystal display technology to provide multiplexed screening of irradiance conditions on growth. An array of 238 microreactors are operated in parallel with identical chemical environments. The approach is demonstrated by performing three irradiance assays. The first assay evaluates the effect of intensity on growth, quantifying saturating intensity. The second assay quantifies the influence of time-varied intensity and the threshold frequency for growth. Lastly, the coupled influence of red-blue spectral composition and intensity is assessed. Each multiplexed assay is completed within three days. In contrast, completing the same number of experiments using conventional incubation flasks would require several years. Not only does our approach enable more rapid screening, but the short optical path avoids self-shading issues inherent to flask based systems.

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Section: Introductionmentioning

confidence: 99%

Microalgae on display: a microfluidic pixel-based irradiance assay for photosynthetic growth

2015

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“…Insight into factors that affect and limit single-cell growth and behaviour might be applied to scale-up the growth of algae, both in flask culture in the laboratory, and at industrial scale for algal biotechnology. In fact, the behaviour of individual trapped microalgal cells has been studied using several different microfluidic approaches, trapping small numbers of cells in a range of devices, including microfluidic chambers [53][54][55][56][57][58][59][60] and capsules [61,62]. These are summarised in Table 1. Pan et al developed an experimental platform in which single microalgal cells were encapsulated into droplets and their growth tracked [51].…”

Section: Monitoring Individual Microalgal Cells Held In Dropletsmentioning

confidence: 99%

Applications of Microdroplet Technology for Algal Biotechnology

Best¹,

Abalde‐Cela²,

Abell³

et al. 2016

CBIOT

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BACKGROUND: Microfluidics allows manipulation of small volumes of fluids through channels with dimensions of tens to hundreds of micrometres. Microdroplet technology is a form of microfluidics in which small (10-200 µm diameter) monodisperses aqueous droplets are generated, manipulated and analysed in various ways. This multidisciplinary field provides an exciting new platform for single-cell studies of both eukaryotic microalgae and cyanobacteria, with considerable potential for enhancing algal biotechnology. METHODS: Growth of several species of microalgae has been studied in detail using microfluidics and microdroplets, and individual cells have been screened and sorted according to lipid content or ethanol production. Here we provide an overview of the devices, and the range of technological advances that are being pursued. CONCLUSIONS: Microdroplet technology is an exciting technology platform that can be used in a variety of applications, including monitoring of growth characteristics at the single-cell level and high-throughput screening of algal populations. Microdroplet platforms are being developed that will allow determination of individual cell characteristics to allow screening across a population, and thus to identify and select candidate cells for biotechnological feedstocks. As the potential of this emerging technical platform is recognized, the technology will become more accessible, so that it can soon be adopted and used by researchers, without the need for specialized prior knowledge of microfluidics or expensive equipment. The platform is amenable for use with species of both microalgae and cyanobacteria.

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Section: Effect Of Physical Stress On Morphology and Function Of Micrmentioning

confidence: 99%

“…Microalgae are photoautotrophic organisms and are generally more efficient converters of solar energy compared to terrestrial plants (Eu et al, 2014;Holcomb et al, 2011;Park et al, 2013). Microalgae can produce high energy biochemicals through photosynthesis using sunlight, H 2 O, and CO 2 (Eu et al, 2014).…”

Section: Effect Of Physical Stress On Morphology and Function Of Micrmentioning

confidence: 99%

“…Microalgae can produce high energy biochemicals through photosynthesis using sunlight, H 2 O, and CO 2 (Eu et al, 2014). Microalgae have therefore been recently proposed as a renewable energy alternative for the production of biofuels to meet the world's growing demand for fuels (Eu et al, 2014;Holcomb et al, 2011;Park et al, 2013). However, the production of biofuel from microalgae is currently too expensive using existing processing technology, so an efficient approach is urgently needed to reduce the development costs and time if this type of biofuel production is to become viable commercially.…”

Section: Effect Of Physical Stress On Morphology and Function Of Micrmentioning

confidence: 99%

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Design, Fabrication, and Application of a Microfluidic Device for Investigating Physical Stress-Induced Behavior in Yeast and Microalgae

Kim

Ryu

et al. 2014

Journal of Biosystems Engineering

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Purpose:The development of an efficient in vitro cell culture device to process various cells would represent a major milestone in biological science and engineering. However, the current conventional macro-scale in vitro cell culture platforms are limited in their capacity for detailed analysis and determination of cellular behavior in complex environments. This paper describes a microfluidic-based culture device that allows accurate control of parameters of physical cues such as pressure. Methods: A microfluidic device, as a model microbioreactor, was designed and fabricated to culture Saccharomyces cerevisiae and Chlamydomonas reinhardtii under various conditions of physical pressure stimulus. This device was compatible with live-cell imaging and allowed quantitative analysis of physical cue-induced behavior in yeast and microalgae. Results: A simple microfluidic-based in vitro cell culture device containing a cell culture channel and an air channel was developed to investigate physical pressure stress-induced behavior in yeasts and microalgae. The shapes of Saccharomyces cerevisiae and Chlamydomonas reinhardtii could be controlled under compressive stress. The lipid production by Chlamydomonas reinhardtii was significantly enhanced by compressive stress in the microfluidic device when compared to cells cultured without compressive stress. Conclusions: This microfluidic-based in vitro cell culture device can be used as a tool for quantitative analysis of cellular behavior under complex physical and chemical conditions.

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A microfluidic perfusion platform for cultivation and screening study of motile microalgal cells

Cited by 15 publications

References 29 publications

Microalgae on display: a microfluidic pixel-based irradiance assay for photosynthetic growth

Microalgae on display: a microfluidic pixel-based irradiance assay for photosynthetic growth

Applications of Microdroplet Technology for Algal Biotechnology

Design, Fabrication, and Application of a Microfluidic Device for Investigating Physical Stress-Induced Behavior in Yeast and Microalgae

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