A Capillary Flow Dynamics‐Based Sensing Modality for Direct Environmental Pathogen Monitoring

Toward ultra‐simple and field‐ready biosensors, we demonstrate a novel assay transducer mechanism based on interfacial property changes and capillary flow dynamics in antibody‐conjugated submicron particle suspensions. Differential capillary flow is tunable, allowing pathogen quantification as a function of flow rate through a paper‐based microfluidic device. Flow models based on interfacial and rheological properties indicate a significant relationship between the flow rate and the interfacial effects caused by target‐particle aggregation. This mechanism is demonstrated for assays of Escherichia coli K12 in water samples and Zika virus (ZIKV) in blood serum. These assays achieved very low limits of detection compared with other demonstrated methods (1 log CFU/mL E. coli and 20 pg/mL ZIKV whole virus) with an operating time of 30 s, showing promise for environmental and health monitoring. A novel assay transducer mechanism is demonstrated based on interfacial property changes and capillary flow dynamics in antibody‐conjugated submicron particle suspensions. Pathogens are quantified as a function of flow rate through a paper microfluidic device. Flow models based on interfacial and rheological properties indicate a significant relationship between the flow rate and the interfacial effects caused by target‐particle aggregation.