Abstract
AbstractThis paper reports an electrochemical microfluidic paper-based analytical device (EμPAD) for glucose detection, featuring a highly sensitive working electrode (WE) decorated with zinc oxide nanowires (ZnO NWs). In addition to the common features of μPADs, such as their low costs, high portability/disposability, and ease of operation, the reported EμPAD has three further advantages. (i) It provides higher sensitivity and a lower limit of detection (LOD) than previously reported μPADs because of the high surface-to-volume ratio and high enzyme-capturing efficiency of the ZnO NWs. (ii) It does not need any light-sensitive electron mediator (as is usually required in enzymatic glucose sensing), which leads to enhanced biosensing stability. (iii) The ZnO NWs are directly synthesized on the paper substrate via low-temperature hydrothermal growth, representing a simple, low-cost, consistent, and mass-producible process. To achieve superior analytical performance, the on-chip stored enzyme (glucose oxidase) dose and the assay incubation time are tuned. More importantly, the critical design parameters of the EμPAD, including the WE area and the ZnO-NW growth level, are adjusted to yield tunable ranges for the assay sensitivity and LOD. The highest sensitivity that we have achieved is 8.24 μA·mM−1·cm−2, with a corresponding LOD of 59.5 μM. By choosing the right combination of design parameters, we constructed EμPADs that cover the range of clinically relevant glucose concentrations (0−15 mM) and fully calibrated these devices using spiked phosphate-buffered saline and human serum. We believe that the reported approach for integrating ZnO NWs on EμPADs could be well utilized in many other designs of EμPADs and provides a facile and inexpensive paradigm for further enhancing the device performance.
Highlights
Microfluidic paper-based analytical devices represent a newly emerging platform for applications such as diagnostic biosensing and environmental monitoring[1]
The device is assembled from two layers of chromatography paper (Whatman 1 CHR, GE Healthcare, Little Chalfont, Buckinghamshire, UK): (i) a top layer consisting of a wax-patterned hydrophilic reaction zone, a carbon counter electrode (CE) and a Ag/AgCl reference electrode (RE) patterned on top of the reaction zone; and (ii) a bottom layer acting as a working electrode (WE), which is made by stencil-printing carbon ink on paper and hydrothermally growing zinc oxide nanowires (ZnO NWs) on the carbon electrode
We measured the distance between two edges to be 0.262 nm, which corresponds to the distance between adjacent (0002) planes in wurtzite ZnO crystal units
Summary
Microfluidic paper-based analytical devices (μPADs) represent a newly emerging platform for applications such as diagnostic biosensing and environmental monitoring[1]. MicroPADs can be fabricated at low cost and used with ease in resource-limited settings by end users without professional skills[2] These merits make them promising for promoting public health in developing countries, where the costs of diagnoses are a major concern and resources such as electricity and professional equipment are not always accessible. They may contribute to health care in the developed world because they could eventually enable users to conveniently self-monitor their health conditions in a point-of-care fashion.
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