Enhanced microfiltration devices configured with hydrodynamic trapping and a rain drop bypass filtering architecture for microbial cells detection

Christophe Lay; Cheng Yong Teo; Liang Zhu; Xue Li Peh; Hong Miao Ji; Bi Rong Chew; Ramana Murthy; Han Hua Feng; Wen Tso Liu

doi:10.1039/b800015h

Enhanced microfiltration devices configured with hydrodynamic trapping and a rain drop bypass filtering architecture for microbial cells detection

Christophe Lay, Cheng Yong Teo, Liang Zhu, Xue Li Peh, Hong Miao Ji, Bi Rong Chew, Ramana Murthy, Han Hua Feng, Wen Tso Liu

Research output: Contribution to journal › Article › peer-review

Abstract

Ultra-fine (<1 μm) microfilters are required to effectively trap microbial cells. We designed microfilters featuring a rain drop bypass architecture, which significantly reduces the likelihood of clogging at the cost of limited cell loss. The new rain drop bypass architecture configuration has a substantially lower pressure drop and allows a better efficiency in trapping protozoan cells (Cryptosporidium parvum and Giardia lamblia) in comparison to our previous generation of a microfilter device. A modified version displaying sub-micron filter gaps was adapted to trap and detect bacterial cells (Escherichia coli), through a method of cells labeling, which aims to amplify the fluorescence signal emission and therefore the sensitivity of detection.

Original language	English (US)
Pages (from-to)	830-833
Number of pages	4
Journal	Lab on a chip
Volume	8
Issue number	5
DOIs	https://doi.org/10.1039/b800015h
State	Published - 2008
Externally published	Yes

ASJC Scopus subject areas

Bioengineering
Biochemistry
General Chemistry
Biomedical Engineering

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10.1039/b800015h

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title = "Enhanced microfiltration devices configured with hydrodynamic trapping and a rain drop bypass filtering architecture for microbial cells detection",

abstract = "Ultra-fine (<1 μm) microfilters are required to effectively trap microbial cells. We designed microfilters featuring a rain drop bypass architecture, which significantly reduces the likelihood of clogging at the cost of limited cell loss. The new rain drop bypass architecture configuration has a substantially lower pressure drop and allows a better efficiency in trapping protozoan cells (Cryptosporidium parvum and Giardia lamblia) in comparison to our previous generation of a microfilter device. A modified version displaying sub-micron filter gaps was adapted to trap and detect bacterial cells (Escherichia coli), through a method of cells labeling, which aims to amplify the fluorescence signal emission and therefore the sensitivity of detection.",

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doi = "10.1039/b800015h",

language = "English (US)",

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pages = "830--833",

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publisher = "Royal Society of Chemistry",

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T1 - Enhanced microfiltration devices configured with hydrodynamic trapping and a rain drop bypass filtering architecture for microbial cells detection

AU - Lay, Christophe

AU - Teo, Cheng Yong

AU - Zhu, Liang

AU - Peh, Xue Li

AU - Ji, Hong Miao

AU - Chew, Bi Rong

AU - Murthy, Ramana

AU - Feng, Han Hua

AU - Liu, Wen Tso

PY - 2008

Y1 - 2008

N2 - Ultra-fine (<1 μm) microfilters are required to effectively trap microbial cells. We designed microfilters featuring a rain drop bypass architecture, which significantly reduces the likelihood of clogging at the cost of limited cell loss. The new rain drop bypass architecture configuration has a substantially lower pressure drop and allows a better efficiency in trapping protozoan cells (Cryptosporidium parvum and Giardia lamblia) in comparison to our previous generation of a microfilter device. A modified version displaying sub-micron filter gaps was adapted to trap and detect bacterial cells (Escherichia coli), through a method of cells labeling, which aims to amplify the fluorescence signal emission and therefore the sensitivity of detection.

AB - Ultra-fine (<1 μm) microfilters are required to effectively trap microbial cells. We designed microfilters featuring a rain drop bypass architecture, which significantly reduces the likelihood of clogging at the cost of limited cell loss. The new rain drop bypass architecture configuration has a substantially lower pressure drop and allows a better efficiency in trapping protozoan cells (Cryptosporidium parvum and Giardia lamblia) in comparison to our previous generation of a microfilter device. A modified version displaying sub-micron filter gaps was adapted to trap and detect bacterial cells (Escherichia coli), through a method of cells labeling, which aims to amplify the fluorescence signal emission and therefore the sensitivity of detection.

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Enhanced microfiltration devices configured with hydrodynamic trapping and a rain drop bypass filtering architecture for microbial cells detection

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