期刊
ANALYTICAL CHEMISTRY
卷 92, 期 24, 页码 16043-16050出版社
AMER CHEMICAL SOC
DOI: 10.1021/acs.analchem.0c03667
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资金
- Australian Academy of Science on behalf of the Department of Industry, Innovation and Science
- Australian Government under the National Innovation and Science Agenda
- Australia's National Collaborative Research Infrastructure Strategy (NCRIS)
Microfluidic flow in lab-on-a-chip devices is typically very sensitive to the variable physical properties of complex samples, e.g., biological fluids. Here, evaporation-driven fluid transport (transpiration) is achieved in a configuration that is insensitive to interfacial tension, salinity, and viscosity over a wide range. Micropillar arrays (pillar cuvettes) were preloaded by wicking a known volatile fluid (water) and then adding a microliter sample of salt, surfactant, sugar, or saliva solution to the loading zone. As the preloaded fluid evaporates, the sample is reliably drawn from a reservoir through the pillar array at a rate defined by the evaporation of the preloaded fluid (typically nL/s). Including a reagent in the preloaded fluid allows photometric reactions to take place at the boundary between the two fluids. In this configuration, a photometric signal enhancement is observed and chemical analysis is independent of both humidity and temperature. The ability to reliably transport and sense an analyte in microliter volumes without concern over salt, surfactant, viscosity (in part), humidity, and temperature is a remarkable advantage for analytical purposes.
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