A novel microfluidic module for rapid detection of airborne and waterborne pathogens

[Display omitted] •We designed a simple microfilter module that conveniently integrates semiporous membranes into PDMS with leakage-free bonding.•The module is able to rapidly enrich and concentrate ∼10−1μm-scale particles.•Using this module, microfluidic chips can rapid enrich and analyze airborne...

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Bibliographic Details
Published in:Sensors and actuators. B, Chemical Chemical, 2018-04, Vol.258, p.1138-1145
Main Authors: Liu, Qi, Zhang, Xinlian, Yao, Yuhan, Jing, Wenwen, Liu, Sixiu, Sui, Guodong
Format: Article
Language:English
Subjects:
Antimicrobial agents
Body fluids
Cysts
Drinking water
Enrichment
Immunofluorescence
Membranes
Microfilter
Microfluidics
Microparticle
Pathogen detection
Pathogens
Polydimethylsiloxane
Portable equipment
Silicone resins
Studies
Substrates
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Summary:[Display omitted] •We designed a simple microfilter module that conveniently integrates semiporous membranes into PDMS with leakage-free bonding.•The module is able to rapidly enrich and concentrate ∼10−1μm-scale particles.•Using this module, microfluidic chips can rapid enrich and analyze airborne pathogens, pathogens in body fluid, and waterborne parasites. Different microfluidic design or function modules are the key for the microfluidic chip to fullfill various functions. We herein report a simple microfilter module that conveniently integrates semiporous membranes into polydimethylsiloxane (PDMS) substrates with leakage-free bonding, which achieves the efficient enrichment of airborne and waterborne pathogens on microfluidic chips. The microfilter is able to rapidly enrich and concentrate ∼10−1μm-scale particles with high efficiency due to the complementary advantages of microfluidics (microliter-scale fluid control) and the nature of polyester (or polycarbonate) membranes (high precision and density of pores, and high hydrophilicity). Fabrication can be conveniently performed by effective loading control of the sealing agent. For further studies on different pathogen concentrations and detections, the module was integrated with loop-mediated isothermal amplification (LAMP) on a PDMS chip for enrichment and visual analysis of pathogens from body fluid samples with limited volume and low concentration. It was also capable of collection and in-situ immunofluorescence detection of parasite oocysts (cysts) in drinking water with recovery rates of ∼90%. Besides, by integration of the microfilter and a LAMP chip on a portable device, we successfully established a point-of-care system for enrichment and analysis of airborne pathogens.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2017.11.113