Introduction

Microfluidic paper-based analytical devices (μPADs) represent a newly emerging platform for applications such as diagnostic biosensing and environmental monitoring1. MicroPADs can be fabricated at low cost and used with ease in resource-limited settings by end users without professional skills2. These merits make them particularly 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 also 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. Many μPAD designs adopt electrochemical sensing mechanisms (which are thus called electrochemical microfluidic paper-based analytical devices or EμPADs) because of the quantitative nature, high accuracy and high sensitivity of these mechanisms35.

With rapid advances in the field of paper-based microfluidics, research efforts are shifting focus to the creation of fully functional μPADs with superior analytical performance for practical uses6, for which the introduction of biosensing nanomaterials to μPADs has shown remarkable potential. The benefits of using nanomaterials for biosensing primarily stem from their unique physical/chemical characteristics7. For instance, researchers have integrated multi-walled carbon nanotubes (MWCNTs) into μPADs to covalently immobilize probe antibodies and enhance the signal output of electrochemical immunoassays by utilizing MWCNT's high surface-to-volume ratio and superior electrical conductivity4. Graphene and gold nanorods have also been utilized on μPADs for electrochemical8 and optical biosensing9, respectively. Nevertheless, the preparation of these nanomaterials could be complex and costly, which may hinder the wide use of μPADs. In addition, the integration of these nanomaterials into the μPADs after synthesis may also raise concerns about the stability of the nanomaterials’ attachment to and the uniformity of their distribution on the paper substrates.

Zinc oxide nanowires (ZnO NWs) have shown outstanding capacities in biosensing10. They possess not only high surface-to-volume ratios but also high biocompatibility and fast electron transfer. Additionally, ZnO NWs have an isoelectric point (IEP) of approximately 9.5, which is much higher than that of many enzymes and therefore allows the ZnO NWs to immobilize enzymes with high efficiency via electrostatic attraction. As a result, ZnO NWs have been a popular option for enzymatic electrochemical sensing of targets such as glucose11, uric acid12, and phenol13. Another highly desirable property of ZnO NWs is that they can be synthesized on various substrates (e.g., plastics14 and cellulose paper15) through a low-cost hydrothermal process. To date, there is no previous work on the development of μPADs that use ZnO nanomaterials as the biosensing component.

Here, we report the first EμPAD with ZnO NWs synthesized in situ for electrochemical enzymatic detection of glucose in human serum. An array of circular paper channels (reaction zones) are formed on a paper substrate by wax patterning, and electrodes are patterned on top of the reaction areas by stencil printing of conductive inks. The EμPAD features a separate layer of working electrode (WE), which is formed by covering a paper piece with carbon ink and then growing ZnO NWs on the carbon ink through a low-cost hydrothermal process. Glucose oxidase (GOx) is immobilized on the ZnO NWs by simple addition and drying. The paper channel layer and the WE layer are stacked together to form a complete EμPAD with a three-electrode configuration. We characterize the device via a series of electrochemical measurements and demonstrate improved electrochemical responses of the device to the oxidation of glucose. The assay incubation time and the dose of pre-stored GOx are tuned to improve the sensing performance of the device. EμPADs configured with varied WE areas and ZnO-NW growth levels are calibrated; from these calibration data, a design for an EμPAD that covers the range of clinically relevant glucose concentrations is selected for final calibration with spiked phosphate-buffered saline (PBS) and human serum. The reported ZnO-NW EμPAD has a linear response within the clinically relevant range for glucose sensing and provides a sensitivity and a limit of detection (LOD) that are both superior to existing EμPADs and commercial meters.

Materials and methods

Design and fabrication of ZnO-NW EμPADs

An exploded schematic of the ZnO-NW EμPAD is shown in Figure 1a. 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 WE, which is made by stencil-printing carbon ink on paper and then hydrothermally growing ZnO NWs on the carbon electrode. Instead of patterning all three electrodes on the same piece of paper (within the reaction zone), we chose to arrange the WE on a separate layer underneath the reaction zone. This design makes the hydrothermal growth of ZnO NWs on the carbon WE more straightforward. If the three electrodes were all patterned on top of the same reaction zone, one would need to selectively grow ZnO NWs on the WE only; this process requires the deposition of the ZnO-NP seeding solution onto the WE using techniques such as inkjet printing. This process is challenging and less consistent. Moreover, in our preliminary experiments, we found that the hydrothermal growth process compromised the hydrophobicity of the wax barrier of the paper reaction zone, making it impractical to selectively grow ZnO NWs on a WE patterned on top of a reaction zone. In addition, with a separate WE layer stacked underneath the reaction zone, we were able to achieve a large-sized WE without being limited by the sizes of the other two electrodes and the area of the reaction zone, and created an intimate contact between the ZnO NWs on the WE and the reaction zone; both the large WE and the close contact led to enhanced sensitivity in electrochemical detection with our ZnO-NW EμPAD.

Figure 1
figure 1

Design and fabrication of the ZnO-NW EμPAD. (a) Schematic of ZnO-NW EμPAD. Photographs of (b) an array of EμPADs and (c) a WE with ZnO NWs grown over its circular area (the gray color is from the ZnO NWs).

To fabricate the device, the reaction zone was patterned on the top layer via wax printing16,17. Solid wax was first printed on a piece of chromatography paper with a wax pinter (ColorQube 8570, Xerox, Wilsonville, OR, USA), and heated on a hot plate at 150 °C to form the hydrophilic paper reaction zones confined by hydrophobic wax barriers. A CE and an RE were then patterned on top of the reaction zone via stencil printing of carbon ink (E3456, Ercon, Wareham, MA, USA) and Ag/AgCl ink (E2414, Ercon, Wareham, MA, USA), respectively. A Ag/AgCl strip was printed to connect the CE and enhance the electrical conductivity between the CE and the potentiostat. The inks were dried on a hot plate at 65 °C for 20 min after each step of the stencil printing. Another piece of chromatography paper was cut into the shape of the WE layer (Figure 1a) using a CO2 laser cutter (VLS 2.30, Universal Laser Systems, Scottsdale, AZ, USA), and carbon ink was printed on the circular side of the WE layer (Figure 2a). After the ink was dry, pre-cured polydimethylsiloxane or PDMS (w/w ratio of base and curing agent: 10:1) was added to both surfaces of the CE layer to form thin films of hydrophobic barriers (Figure 1a) and confine liquids within the circular WE area during the ZnO-NW growth and diagnostic assays. A Ag/AgCl strip was patterned on the paper beam of the WE layer to create an electrical connection. The circular WE area was finally coated with ZnO NWs through a hydrothermal process, which will be described in detail in the Section of “Hydrothermal Growth of ZnO NWs on WE”. Two sizes of circular WEs were fabricated and tested in this study with radii of 1.5 mm (WE #1) and 2 mm (WE #2).

Figure 2
figure 2

Growth and characterization of ZnO NWs. (a) SEM image of carbon-ink WE surface before seeding of ZnO NPs. (b) Zoomed-in view of ZnO NWs grown on carbon-ink WE. (c) TEM image of ZnO-NW crystal lattice.

Figure 1b shows an array of four assembled ZnO-NW EμPADs, which were fabricated simultaneously from the same process. The top paper layer with the four reaction zones and four sets of CEs and REs were conveniently attached to the bottom paper layer with four WEs using adhesive tape. The distance between the centers of the adjacent reaction zones was based on the standard tip-to-tip pitch (9 mm) of a multichannel pipette, so multiple reactions can be performed in parallel on such a sensor array by simultaneously adding sample solutions to different reaction zones with a multi-channel pipette. Figure 1c shows a photograph of the WE layer after growth of the ZnO-NWs. The circular area of the carbon ink turned from black to gray after the growth, indicating uniform coverage by the ZnO NWs.

To prepare the ZnO-NW EμPADs for glucose sensing, GOx needs to be immobilized on the WE before assembly of the device. After a series of preliminary experiments, 5 µg of GOx (Aspergillus niger, 147.9 U·mg−1, Sigma-Aldrich, St. Louis, MO, USA) was chosen to be the enzyme dose added to each WE. GOx solutions (1 µL of 5 mg mL−1 for WE #1, and 2 µL of 2.5 mg mL−1 for WE #2) were dropped onto the circular area of the WE and dried at room temperature for 5 min. A drop of 0.5% (w/w) Nafion solution (1.3 µL for WE #1, and 2 µL for WE #2) was then added onto the circular area and dried at room temperature for 5 min. The Nafion coating over the WE stabilizes the GOx on the ZnO NWs11.

Hydrothermal growth of ZnO NWs on the WE

The synthesis of ZnO NWs includes two steps: (i) seeding of ZnO nanoparticles (NPs) on WE and (ii) hydrothermal growth of ZnO NWs on the seeded ZnO-NPs. In the first step, 40 mL of 2 mM zinc acetate dihydrate (ZAD) and 20 mL of 4 mM sodium hydroxide (SH) solutions were prepared separately in pure ethanol, and the solutions were stirred on a hotplate at 70 °C to completely dissolve the chemicals. The ZAD solution was heated in a 70 °C oven afterwards. After both the ZAD and SH solutions were cooled to 4 °C, the SH solution was slowly added to the ZAD solution with constant stirring, and the mixture was placed in a 60 °C oven for 2 h to obtain a colloidal solution of ZnO NPs. The synthesized ZnO NPs have a uniform size of 3.06 ± 0.58 nm (N = 50).

The paper beams of the WE layer (coated with carbon ink and a PDMS barrier) were clapped between two 1 mm thick glass slides and the circular WE was exposed. The PDMS barriers on both sides of the paper beams constrained the subsequent seeding and hydrothermal growth solutions to the WE only, and no ZnO NWs grew on the paper beams (as confirmed via SEM imaging). A drop of ZnO-NP seeding solution (2.25 µL for WE #1, and 4 µL for WE #2) was then added to each circular WE. The carbon-ink electrode printed on paper is relatively hydrophobic but has an affinity to ethanol, and the seeding ethanol solution can thus spread well over the whole area of the circular WE. The WE layer was dried on a hot plate at 100 °C for 3 min. For each WE, this seeding and drying process was repeated 6 times to achieve a uniform coating of ZnO-NP seeds on the WE surface. After seeding, 25 mL of aqueous growth solution, which includes 50 mM zinc nitrate hexahydrate, 25 mM hexamethylenetetramine, and 0.372 M ammonium hydroxide, was prepared in a 25 mL glass bottle, and two arrays of four interconnected WEs were immersed in growth solution in the same bottle (Supplementary Figure S1). The glass bottle was then sealed and heated in an 86 °C oven for a certain period of time to allow the ZnO-NW to grow. In principle, one could use as many bottles of growth solution as desired in a single run of ZnO-NW growth on a large number of WEs. The length and width of ZnO NWs grown on the WE can be controlled by adjusting the growth time15; thus, one can tune the total surface area of the ZnO NWs on the WE and thus the device's sensitivity. After growth, the WE layer was thoroughly washed in deionized water and then in pure ethanol, and was dried before final device assembly.

Electrochemical measurements

For glucose detection, the three electrodes of the EμPAD were connected by metal clips to a precision potentiostat (Autolab PGSTAT302N, Metrohm, Mississauga, ON, Canada). 5 μL of 1× PBS or human serum spiked with D-(+)-glucose (Sigma-Aldrich, St. Louis, MO, USA) was added to the reaction zone on the top of the sensor and wicked down to the WE. After incubation for 50 s, the potentiostat started measurements at 100 Hz.

Results

Electron microscopy analysis of ZnO NWs grown on the WE

We performed scanning electron microscopy (SEM) imaging of the WEs before and after hydrothermal growth. As shown in Figure 2a, the carbon WE before hydrothermal growth had a rough, plate-like surface morphology. After hydrothermal growth, a uniform layer of high-density ZnO NWs was formed on the entire WE (Figure 2b). Because of the rough surface of the carbon WE (Figure 2a), the synthesized ZnO NWs on the WE were not uniformly oriented in the same direction (Figure 2b). The average width of the obtained ZnO NWs was measured to be 298.72 ± 54.11 nm (N = 20). During SEM imaging, we conducted in-situ energy dispersive spectroscopy (EDS) analysis of the chemical composition of single ZnO NWs and observed clear peaks for zinc and oxygen in the obtained spectrum (Supplementary Figure S2), indicating that the NWs had the correct composition. Transmission electron microscopy (TEM) imaging of single ZnO NWs reveals lattice edges along the ZnO NW (Figure 2c). 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.

Characterization of ZnO-NW EμPADs

To demonstrate the enhanced electrochemical performance of the ZnO-NW EμPADs, we compared the cyclic voltammetry (CV) responses of EμPADs with and without ZnO NWs, both of which have the same WE dimensions (1.5 mm and 2 mm in radius) and GOx dose. We added 5 mL of pure PBS and 5 mM glucose solution to the two types of devices and performed CV measurement after 50 s incubation. As shown in Figure 3, for both types of EμPADs, the presence of glucose in the solution led to an increase in the peak magnitude of measured CV current, which was caused by the GOx-catalyzed oxidation of glucose. In the non-NW EμPADs, a clear increase in the CV current, in response to the presence of glucose, was observed at a CV potential of ~0.8 V for both WE sizes. In contrast, the CV current response of the ZnO-NW EμPADs started to increase at a CV potential as low as 0.3 V for both WE sizes. In addition, the peak values of the current responses of the ZnO-NW EμPADs were much higher than those of the non-NW EμPADs (3.7 times higher for WE #1, and 4.3 times higher for WE #2).

Figure 3
figure 3

CV characterization of EμPADs with or without ZnO NWs. (a) CV responses of EμPADs (with and without ZnO NWs) using PBS or glucose, with WE #1 (1.5 mm in radius). (b) CV responses of EμPADs (with and without ZnO NWs) using PBS or glucose, with WE #2 (2 mm in radius).

Thus, we confirmed that ZnO NWs can improve the performance of glucose sensing, by both lowering the electrical potential required for the device to generate an electrochemical response and increasing the electrochemical current response. The ability to lower the potential for generating a current response is attributed to the low redox potential of ZnO NWs, which is close to the oxidation potential of glucose (0.124 mV or higher)11. The ZnO NWs on WE can increase the device's current response and thus its sensitivity for glucose detection primarily because they significantly increase the surface-to-volume ratio of the WE and thus enhance electron transfer at the electrode surface18. Moreover, the ZnO NWs are n-type semiconductor and has excellent electron mobility and surface charge transport efficiency, which also contributes to the enhanced current response of the ZnO-NW EμPADs18. Additionally, in many other electrochemical glucose sensors (including paper-based sensors) that use GOx as the catalyst, electron mediators (typically Fe(CN)63−/Fe(CN)64−) are used to lower the working voltage and increase the current response5,1921. However, electron mediators are usually sensitive to light, and this sensitivity could cause biosensing instability. The integration of ZnO NWs into EμPADs eliminates the need for electron mediators and thus can potentially improve the device stability.

We conducted CV characterization of the ZnO-NW EμPADs using an aqueous solution of 10 mM K3[Fe(CN)6] in 1 M KCl. The CV response of the device shows typical redox peaks (Figure 4). The anodic current peak of the cyclic voltammogram was proportional to the square root of the CV scan rate for both WE sizes. These results indicate good electrochemical characteristics of the developed EμPAD. However, we noticed that the distance between the redox peaks increased as the scan rate increased. This result is an indication of a slow electrochemical reaction, which is usually caused by limited mass transfer in an electrochemical cell and correspondingly, a thick diffusion layer. It is possible that the porous paper structure interferes with the mass transport in the paper reaction zone. Although the peak shift existed in the CV measurements and the shift level slightly varied from device to device, the device calibration results using chronoamperometry (CA), to be presented later in the paper, reveal small device-to-device deviations. Therefore, the peak shift observed in multiple CV scans is less of a concern for one-time use of the device in glucose sensing.

Figure 4
figure 4

CV characterization of ZnO-NW EμPADs at varied scanning rates. (a) CV responses of the EμPAD using 10 mM K3[Fe(CN)6] in 1 M KCl aqueous solution at various scan rates, with WE #1 (1.5 mm in radius). (b) CV responses of the EμPAD using 10 mM K3[Fe(CN)6] in 1 M KCl aqueous solution at various scan rates, with WE #2 (2 mm in radius). Insets: The linear relationship between the anodic peak current and the square root of the scan rate, measured from the CV (N = 5).

Tuning the design parameters of the ZnO-NW EμPAD

The CV characterization results (Figures 3 and 4) imply the feasibility of operating the ZnO-NW EμPAD at voltage higher than 0.3 V. In the following experiments, we chose 0.8 V to be the working voltage for CA as a voltage of 0.8 V was widely used in previous ZnO-NW glucose sensors11,22. As shown in typical CA curves (Figure 5a), the capacitive current quickly dropped after applying a 0.8 V voltage, and the Faradaic current eventually dominated the CA current response. After the current stabilized, we took the average of current values at 79–80 s to be the signal readout.

Figure 5
figure 5

Results of CA measurements of ZnO-NW EμPADs for parameter tuning. (a) Typical CA responses from ZnO-NW EμPADs with WE #2 (2 mm in radius), ZnO NWs grown for 8 h and 5 μg of GOx. (b) CA responses to different glucose concentrations which were obtained from differently configured ZnO-NW EμPADs with 5 μg of GOx (N = 3).

We conducted a series of experiments to select the proper design parameters for the device. First, we compared the preliminary CA calibration curves obtained with different incubation times (Supplementary Figure S3). At longer incubation times, the enzymatic detection of glucose generates a higher current, but the evaporation of the solution with time also decreases the current level. As shown in Supplementary Figure S3, an incubation time of 50 s generates a CA response which is similar to that measured at 70 s and higher than the responses at incubation times of 10 s and 30 s. Therefore, we chose 50 s to be the incubation time for the final calibration experiments.

The second parameter we tuned is the dose of GOx added to the WE. We obtained preliminary CA calibration curves with GOx amounts between 1.25 and 20 μg. The results (Supplementary Figure S4) indicate that 5 μg of GOx led to a high current response level and 10 μg and 20 μg of GOx did not generate appreciably higher current responses. This effect occurs probably because 5 μg of GOx is already enough to cover the whole range of glucose concentrations we tested on our EμPADs. We thus added 5 μg of GOx to all of the EμPADs used in the subsequent experiments.

The third parameter we investigated is the amount of ZnO NWs grown on the WE. It is well accepted that the length of ZnO NWs increases with growth time in the hydrothermal process2325. In our study, it is difficult to measure the length of individual ZnO NWs because they are not uniformly aligned and their roots are hard to identify without sacrificing the WE layer. Instead, we measured the increases in masses of the WE pieces after hydrothermal growth for a certain period of time, which reflects the amount of ZnO NWs synthesized. The results are organized in Supplementary Figure S5. In consistency with previous observations2325, the mass of the synthesized ZnO NWs increased over the first 8 h of growth. Subsequently, further increases in the mass are marginal because of the depletion of chemicals in the growth solution. Thus, we grew ZnO NWs for no more than 8 h to prepare the devices for calibration. Another notable observation is that although WE #1 has a smaller increase in mass than WE #2 because of its smaller size (Supplementary Figure S5a), the increase in mass per area of WE #1 is higher than that of WE #2 after 4 h of growth (Supplementary Figure S5b). One possible explanation of this effect is that the larger area of WE #2 consumed chemicals more effectively than the smaller area of WE #1, making the ZnO-NW growth per area of WE #2 slow down earlier than that of WE #1.

In a more systematic series of experiments, we obtained the CA calibration curves for glucose detection with different combinations of WE sizes and ZnO-NW amounts, which are organized in Figure 5b. EμPADs with different combinations of parameters produced very different calibration curves in terms of sensitivity and linear range (Figure 5b). We recognized two major trends in the curves. First, a longer ZnO-NW growth time leads to higher sensitivity, primarily because longer ZnO NWs (corresponding to a larger amount of ZnO NWs) boost the current response to higher levels. Second, ZnO-NW EμPADs with WE #1 have smaller linear ranges than devices with WE #2 because the current responses become saturated more easily for the devices with smaller WE #1 than for the ones with larger WE #2, and this easier saturation leads to smaller linear ranges. Among the obtained calibration curves, devices with WE #1 after growth of ZnO NWs for 8 h provide the highest sensitivity of 8.24 μA·mM−1·cm−2 (Figure 5b), with a corresponding LOD as low as 59.5 μM. However, its linear range is limited to 0−5 mM (R2 = 0.9877 in linear fitting). This systematic investigation illustrates the feasibility of finely tuning the LOD and sensitivity of our ZnO-NW EμPADs by selecting the right combination of WE size and ZnO-NW amount. We chose WE #2 (2 mm in radius) and 8 h of ZnO NW growth to fabricate the devices used for the final calibration experiments on serum samples. Devices with this configuration have a linear range up to 15 mM. Considering the medically relevant range of glucose concentrations (up to 3.89−6.67 mM)5, we believe this configuration covers the range related to medical applications.

Calibration of ZnO-NW EμPADs for glucose detection

Finally, we completed calibration experiments on both spiked PBS and human serum samples, using ZnO-NW EμPADs with the previously determined parameters (the 2 mm radius WE #2, 8 h of ZnO NW growth, addition of 5 µg of GOx, and 50 s of incubation time). The calibration results from the spiked PBS reveal a linear range of 0−15 mM (Figure 6a), and the corresponding sensitivity and LOD are 2.88 μA·mM−1·cm−2 and 94.7 μM, respectively. The calibration experiments on spiked human serum show the performance of our devices for real glucose detection in a complex serum environment that contains various large molecules. To detect glucose in human serum, we re-performed the CV characterization to compare the responses of ZnO-NW EμPAD and non-NW EμPAD (Supplementary Figure S6), and confirmed that it is valid to use the same working voltage of 0.8 V in the CA-based calibration. The calibration results from the spiked serum samples revealed a linear range of 5.1−15.1 mM, and a sensitivity of 2.36 μA·mM−1·cm−2 (Figure 6b). The initial concentration of 5.1 mM on the serum calibration curve reflects the original glucose level of the un-spiked human serum, which was measured using a commercial glucose meter. The linear range of the ZnO-NW EμPADs covers the major clinically relevant range of glucose in human blood. We compared the performance of our devices with those of previously reported EμPADs and commercial meters (all obtained with spiked PBS samples), and the sensitivities and LODs are summarized in Table 1. One can see that the sensitivities and LODs provided by our devices are superior to the commercial glucose meters and the previously reported EμPADs3,5,19. Although we used human serum rather than whole blood in this work, it is totally feasible to integrate a layer of filtering paper/membrane on top of the device's reaction zone to filter out blood cells26. The above results prove the effectiveness of our ZnO-NW EμPADs for the detection of glucose in real blood samples.

Figure 6
figure 6

Calibration results for ZnO-NW μPAD with WE #2 (2 mm in radius), 8 h of ZnO NW growth and 5 μg of GOx. (a) Calibration of ZnO-NW μPAD in PBS (N = 5). (b) Calibration of ZnO-NW μPAD in human serum (N = 5).

Table 1 Comparison of analytical performance of glucose sensors. Configuration #1 has a working electrode with a radius of 1.5 mm and ZnO NWs grown for 8 h. Configuration #2 has a working electrode with a radius of 2 mm and ZnO NWs grown for 8 h

We used 0.8 V as the working potential and obtained superior glucose sensing performance in spiked human serum. To further develop the ZnO-NW EμPAD for practical applications, more experiments with patient samples need to be performed to examine any potential interference of other molecules with the electrochemical reaction used for glucose detection. We also need to study the stability of our device during long-term storage. For instance, ZnO NWs are sensitive to ultraviolet (UV) light, and their surface chemistry might be altered by long-term exposure to light. On the other hand, ZnO NWs become hydrophobic after stored in dark for long time, and become hydrophilic after exposed to UV irradiation27. Generally, hydrophilicity is desired for biosensing because the liquid samples can be better absorbed by a hydrophilic ZnO-NW electrode. Therefore, several optically induced phenomena might affect the biosensing performance of ZnO NWs, and an effective storage method needs to be identified. The GOx also need to be stabilized through certain biochemical processes for room-temperature storage.

From the calibration results obtained with the spiked human serum, we were not able to quantify the LOD of our device. The human serum that we used has an initial glucose concentration of 5.1 mM and thus does not allow us to measure the zero-concentration background noise (i.e., the standard deviation of the readout signal from serum without glucose). Consequently, we were not able to accurately determine the LOD value, which should be the glucose concentration that generates an output signal 3 times the standard deviation of the signal from the zero-concentration serum. Nevertheless, one can notice that most of the standard deviation values of the output signals from human serum samples are similar in magnitude to those from PBS. Thus, using the standard deviation value of the signal from zero-concentration PBS, we estimated the LOD of our device for human serum to be 115.2 µM.

Discussion

Based on the systematic experimental results, we validated the superior analytical performance of our ZnO-NW EμPADs for glucose detection resulting from the hydrothermal growth of ZnO NWs on the WE. This improved performance relies on the following advantages of ZnO NWs for enzymatic sensing. (i) They have high surface-to-volume ratios, which significantly expand the surface of the electrode involved in the electrochemical reaction. Figure 5b shows that the sensitivity increases with extended ZnO-NW growth time, which leads to longer ZnO NWs and thus a larger effective surface area on the WE. (ii) They immobilize enzymes more efficiently and stably due to their strong electrostatic attraction with the GOx. (iii) They are n-type semiconductor with a high carrier mobility and a high surface charge transfer efficiency28, which improves the device's electrochemical response to the GOx-catalyzed oxidation of glucose and eliminates the requirement for a light-sensitive electron mediator. (iv) From a practical point of view, the facile and low-cost hydrothermal growth process allows us to directly integrate ZnO NWs into the μPAD with high consistency, and no post hoc process is required.

We expect this novel means of direct ZnO-NW synthesis on EμPAD to play a powerful role in further explorations of using paper-based microfluidic platforms for highly sensitive electrochemical biosensing and point-of-care diagnoses. In addition to enzymatic glucose detection, ZnO NWs could also be surface-functionalized to covalently immobilize probe proteins29 or deoxyribonucleic acid (DNAs)30 and to perform antigen/antibody and DNA detection. The high sensitivity and high surface-to-volume ratio of ZnO NWs promise improved biosensing performance of the EμPADs. In addition, the ease and low cost of direct ZnO-NW integration on the EμPADs will lower the technological and economic barriers for popularizing these devices and will exert an even bigger impact on applications in the real world.

Conclusion

We developed a novel EμPAD with ZnO NWs directly grown on the paper-based, carbon-ink WE, for high-sensitivity glucose detection. The synthesis of the ZnO NWs was completed through a low-cost, facile hydrothermal process. The integration of the ZnO NWs on the EμPAD lowered the working voltage and boosted the device's current response in electrochemical detection, and the ZnO-NW EμPAD retained its proper characteristics as an electrochemical system. We conducted a series of experiments and determined the proper parameters of the ZnO-NW EμPADs, such as the dose of GOx and the incubation time. More importantly, we compared different combinations of ZnO-NW growth levels and WE sizes, and demonstrated tunable analytical performance (sensitivity and LOD). Of the tested combinations of parameters, the 1.5 mm WE with ZnO NWs grown for 8 h reached the highest sensitivity of 8.24 μA·mM−1·cm−2 and a corresponding LOD of 59.5 μM. The EμPADs with a 2 mm radius WE and ZnO NWs grown for 8 h were selected for detailed calibration using both spiked PBS and human serum and were demonstrated to have a linear range up to 15 mM (covering the clinically relevant range of glucose concentrations in serum). The selected ZnO-NW EμPAD provided a sensitivity of 2.88 μA·mM−1·cm−2 and a LOD of 94.7 μM in PBS. These results showed tunable biosensing performance that is superior to that of commercial glucose meters and previously reported EμPADs. Footnote 1