Barrier-Free Microfluidic Paper Analytical Devices for Multiplex Colorimetric Detection of Analytes
In recent years, microfluidic paper analytical devices (μPADs) have been extensively utilized to conduct multiplex colorimetric assays. Despite their simple and user-friendly operation, the need for patterning paper with wax or other physical barriers to create flow channels makes large scale manufacturing cumbersome. Moreover, convection of rehydrated reagents in the test zones leads to non-uniform colorimetric signals, which makes quantification challenging. To overcome these challenges, we present a new device design called barrier-free μPAD (BF-μPAD) that consists of a stack of two paper membranes having different wicking rates – the top layer acting as a fluid distributing layer and the bottom layer containing reagents for colorimetric detection. Multiple analytes can be detected using this assembly without the need to pattern either layer with wax or other barriers. In one embodiment, a device is capable of delivering the sample fluid to 20 distinct dried reagent spots stored on an 8cm x 2cm membrane in as few as 30 seconds. The multiplexing feature of BF-μPAD is demonstrated for colorimetric detection of salivary thiocyanate, protein, glucose, and nitrite. Most importantly, the device improves the limit of detection of colorimetric assays performed on conventional μPADs by more than 3.5x. To understand fluid imbibition in the paper assembly, the device geometry is modelled in COMSOL Multiphysics using Richards equation; the results obtained provide insights into the non-intuitive flow pattern producing perfectly uniform signals in the barrier-free assembly.
To enable diagnosis of infectious diseases in remote locations by developing a device that protects DNA in sputum, urine, and blood samples from degradation during transport to laboratories
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