Abstract
Spatially uniform reconstitution of dried reagents is critical to the function of paper microfluidic devices. Advancing fluid fronts in paper microfluidic devices drive (convect) and concentrate rehydrated reagents to the edges, causing steep chemical gradients and imperfect mixing. This largely unsolved problem in paper microfluidics is exacerbated by increasing device dimensions. In this article, we demonstrate that mixing of dried reagents with a rehydrating fluid in paper microfluidics may be significantly enhanced by stacking paper layers having different wicking rates. Compared to single-layer paper membranes, stacking reduced the “non-reactive area”, i.e. area in which the reconstituted reagents did not interact with the rehydrating fluid, by as much as 97% in large (8 cm × 2 cm) paper membranes. A paper stack was designed to collect ~0.9 ml liquid sample and uniformly mix it with dried reagents. Applications of this technology are demonstrated in two areas: (i) collection and dry storage of sputum samples for tuberculosis testing, and (ii) salivary glucose detection using an enzymatic assay and colorimetric readout. Maximizing the interaction of liquids with dried reagents is central to enhancing the performance of all paper microfluidic devices; this technique is therefore likely to find important applications in paper microfluidics.
Highlights
Paper microfluidic devices have become an important platform for conducting analytical chemistry, especially for applications in point-of-care diagnostics[1,2]
We demonstrate a technique designed to enhance mixing between reagents dried in paper microfluidic membranes and a rehydrating fluid
To demonstrate the versatility of this approach, we demonstrate how paper stacks can be used to enhance the sensitivity of a paper-based bienzymatic glucose detection assay
Summary
Paper microfluidic devices have become an important platform for conducting analytical chemistry, especially for applications in point-of-care diagnostics[1,2]. We demonstrate a technique designed to enhance mixing between reagents dried in paper microfluidic membranes and a rehydrating fluid. This is accomplished by stacking two paper membranes having significantly different wicking rates. In comparison to a www.nature.com/scientificreports single-layer paper membrane, this combination of materials a) significantly reduces gradients in concentration of rehydrated reagents across the dimensions of the device, b) increases volumetric capacity of the device, and c) reduces the time for rehydration This work presents a new approach for achieving uniform rehydration of dried reagents, critical to all paper-based analytical and stabilization devices
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