A Glucose-Responsive Enzymatic Electrode on Carbon Nanodots for Glucose Biosensor and Glucose/Air Biofuel Cell ()
1. Introduction
It is the essential groundwork to fabricate enzymatic electrodes for constructing enzyme-based electrochemical biosensors and enzymatic biofuel cells (BFCs) [1] [2] [3] [4] [5] . Glucose-responsive enzymatic electrodes, which are responsible for electrochemical glucose biosensors or bioanodes of glucose-based BFCs with glucose as fuels, have attracted much attention [6] [7] [8] [9] [10] . Two types of commercially available enzymes, glucose oxidase (GOx) and glucose dehydrogenases (GDH), are generally employed to construct glucose-responsive enzymatic electrodes [1] - [10] . The GDH family is classified into three different types on the basis of its cofactors, nicotinamide adenine dinucleotide-dependent GDH (NAD-GDH), flavin adenine dinucleotide-dependent GDH (FAD-GDH), and pyrroloquinoline quinone-dependent GDH (PQQ-GDH) [11] - [16] . Among these enzymes, NAD-GDH is widely favored to be chosen to construct enzymatic electrode because it is insensitive to oxygen and highly specific to glucose [11] - [16] . As a result, the NAD-GDH based enzymatic electrode is allowed to improve the accuracy and selectivity of electrochemical biosensor of glucose and reduce the cross-talk of glucose/O2 BFC. In order to expand the bioelectrochemical applications of NAD-GDH enzymatic electrode, extensive studies are focused on recycling the cofactor by regenerating NADH from the enzymatically produced NAD+ cofactor through electrochemistry methods [11] - [20] . However, direct electrochemical oxidation of NADH generally requires an applied potential as high as Ca. 0.75 V (versus Ag/AgCl) although the theoretical thermodynamic potential for NADH/NAD+ couple is as low as −0.32 V (versus NHE) [11] [12] [13] [14] [15] . Fast mediated oxidation of NADH using a redox enzyme and an electron mediator is required to lower the overpotential in order to reduce the interfering of glucose biosensor or improve the open-voltage of glucose/O2 BFC [11] - [20] . On the other hand, proper immobilizing materials for hosting enzymes are required to retain the bioactivity of the enzymatic electrodes [2] [3] [19] [20] [21] [22] . Up to now, various kinds of materials such as conducting polymers, metallic nanoparticles, carbon-based materials, and hybrid composites have been used as immobilizing materials to construct enzymatic electrodes [2] [3] [19] [20] [21] [22] . Among these immobilizing materials, carbon-based materials have been intrigued due to the good electric conductivity and biocompatibility [16] [18] [23] [24] [25] [26] .
In this study, a NAD-GDH based enzymatic electrode was fabricated, on which NAD-GDH was immobilized on carbon nanodots (CNDs) with in-situ electrochemical polymerized methylene green (polyMG) on CNDs as electro-oxidation electrocatalyst for NADH, to construct glucose electrochemical biosensor and the bioanode for glucose oxidation in glucose/air BFC.
2. Materials and Methods
Glucose Dehydrogenase (GDH, EC.1.1.1. 47, from Leuconostoc mesenteroides) and fungal laccase (EC 1.10.3.2) from Trametes Versicolor were obtained from Sigma Chemical Co. NADH, NAD+ (disodium hydrate) was purchased from Fluka. Methylene green (MG) were supplied by No. 3 Shanghai Chemical Reagent Company. 0.10 M phosphate buffer solution (pH 7.0) was prepared by mixing the stock solutions of 0.10 M Na2HPO4 and KH2PO4 and adjusting the desired pH values with 0.1 M NaOH or H3PO4. Real sample fruit juice used in this study was bought from a local supermarket. All other chemicals were of analytical grade and used without further purification. 0.10 M phosphate buffer solution (pH 7.0) was used as supporting electrolyte in all electrochemical measurements unless otherwise noted. All aqueous solutions were prepared with ultrapure water (≥18.25 MΩ∙cm) throughout the experiments.
Carbon nanodots were prepared with candle soot as starting material using the reported methods in our previous publications [18] [25] [26] . Typically, 4.0 mg of candle soot was suspended in 10.0 mL of mixed solvent (Vwater/Vethanol = 1:1) and sonicated for 20 min. Then the black mixture was centrifuged with 3000 rpm for 2 min to remove large-size particles. The supernatant was collected and centrifuged again for 6 min with 6000 rpm and then a black precipitate was obtained. The obtained dry carbon nanodots were dispersed in N, N-dimethylformamide (DMF) under sonication of 30 min. Finally, a black homogeneous solution with a concentration of 2.0 mg∙mL−1 was acquired for further use.
The electrochemical experiments were carried out on CHI 66˚C potentiostat (CHI, Shanghai) with a conventional three-electrode cell. A glassy carbon (GC) electrode or modified electrode was used as the working electrode, a Ag/AgCl as the reference electrode, and a platinum wire as the counter electrode. The electrochemical measurements were performed at room temperature and repeated minimum three times.
Glassy carbon electrodes (GC, 3-mm in diameter) surface were successively polished on polishing cloth using 0.3 and 0.05 μm alumina slurry, respectively. After polishing to mirror surface, the electrodes were rinsed thoroughly with water under sonication for 3 min and then let them dried at room temperature. A 20 μL of the CNDs dispersion was dropped on the GC electrodes. After dried under lamp, the CNDs modified electrodes (CNDs/GC electrode) were immersed into the aqueous solution of MG (0.15 mM) for 8 h. The electrodes were then thoroughly rinsed with distilled water to remove the adsorbed MG and polarized at +0.85 V vs. Ag/AgCl in 0.10 M phosphate solution (pH 7.0) for 1h for the electro-polymerization form polyMG/CNDs nanocomposites onto the electrodes (denoted as polyMG-CNDs/GC electrode). After that, the electrodes were taken out of the solution, thoroughly rinsed with distilled water and air-dried. The enzyme solution was prepared by dissolving 5 mg GDH in 1.0 mL 0.10 M pH 7.0 phosphate buffer solution. 20 μL aliquot of the enzyme solution dropped on the pretreated polyMG-CNDs/GC then let it dry at room temperature, and then 3 μL aqueous solution of nafion (0.5%, wt%) was further coated onto the electrodes to cross-link the enzyme onto modified electrodes.
For the assembly of glucose/air BFC, the GDH-polyMG-CNDs/GC and laccase-CNDs/GC electrode were used as bioande for glucose oxidation and biocathode for oxygen reduction, respectively. Fruit juice containing glucose was used as the fuel solution to characterize the performances of the as-prepared BFC at ambient air atmosphere. The real sample fruit juice was adjusted to pH 7.0 with 0.1 M PBS and the ratio for buffer solution and soft drinks was about 3:2 (v/v).
3. Result and Discussion
3.1. Typical SEM and TEM Images of Carbon Nanodots
CNDs were prepared according to previous reports [18] [25] [26] . Figure 1 shows the low magnification SEM (Figure 1(A)) and high magnification TEM (Figure 1(B)) images of the obtained CND. From the figures, we can see that the obtained products consist of a large amount of nanodots. The images reveal that the diameters of the nanodots are in the range of 40 - 60 nm. The uniform nanostructures provide a significant increase in effective electrode surface for loading enzymes and accelerating electron transfer.
3.2. Preparation and Catalytic Performances of Different Electrode
Figure 2(A) Displays the cyclic voltammograms (CVs) recorded the in-situ electropolymerization process of monomer MG at the CNDs confined onto bare GC electrode in 0.10 M phosphate buffer with different polymerizing time. As shown in this figure, upon being poised at +0.85 V for 60 min, the as-formed polyMG-CNDs nanocomposites show a pair of new redox wave at −0.10 V with a very small peak-to-peak separation. This redox wave is originated from the reversible redox process of the as-formed polyMG at CNDs [27] .
The fast and reliable detection of NADH at a low potential is of great importance in fabricating amperometric biosensors and biofuel cells based on NAD-dependent dehydrogenases [13] [14] [15] [16] . The cyclic voltammetric responses at polyMG-CNDs/GC electrodes obtained in pH 7.0 phosphate buffer in the presence of different concentrations of NADH at a scan rate of 20 mV∙s−1
Figure 1. Low magnification SEM (A) and high magnification TEM (B) images of the obtained CNDs.
Figure 2. (A) CVs of in-situ electropolymerization of MG on CNDs/GC electrode with different time; (B) CVs obtained at the polyMG-CNDs/GC electrode in 0.10 M pH 7.0 buffer solution containing 0, 1.0, 2.0, and 3.0 mM NADH with a scan rate of 20 mV∙s−1; (C) CVs obtained at the GDH-polyMG-CNDs/GC electrode in 0.10 M pH 7.0 buffer solution with 20 mM NAD+ containing 0, 10, 20, and 30 mM glucose with a scan rate of 20 mV∙s−1.
are presented in Figure 2(B). As shown in this figure, the potential for NADH oxidation at the polyMG-CNDs/GC electrode was observed at −0.10 V, which has a good agreement with the value reported previously [27] . These results indicate that the presence of polyMG-CNDs resulted in a substantial decrease of the overpotential to about 650 mV for NADH oxidation at conventional bare GC electrode. From Figure 2(B), we also can clearly see that the peak current increases significantly with the addition of an increasing amount of NADH. These results demonstrate that the polyMG-CNDs composites show excellent electrocatalytic activity to NADH oxidation and could be further fabricated NAD-dependent dehydrogenase based enzymatic electrodes.
In order to construct a biosensor of glucose and a bioanode of glucose/O2 BFC, GDH was further immobilized on polyMG-CNDs composites to obtain GDH-polyMG-CNDs/GC electrode. Figure 2(C) displays the typical CVs recorded at the GDH-polyMG-CNDs/GC electrode in the presence of different concentrations of glucose with a scan rate of 20 mV∙s−1. From this figure, it is can be seen that glucose oxidation occurs at −0.1 V and the catalytic oxidation current increases with the increasing concentrations of glucose.
3.3. Real Applications of the Fabricated GDH-PolyMG-CNDs/GC Electrode
Based on the catalytic currents dependent on the glucose concentrations, a glucose biosensor was fabricated. As shown in Figure 3(A), when GDH-polyMG- CNDs/GC electrode was polarized at −0.1 V, successive addition of glucose to the stirring 0.10 M PBS (pH 7.0) aqueous solution results in results in remarkable increases in the oxidation currents, and the time required to reach the steady-state current response is less than 4 s. This amperometric response to glucose demonstrates that the GDH-polyMG-CNDs/GC modified electrode shows good sensitivity detection of glucose. Under the optimal conditions, the enzymatic electrode exhibits a wide linear dynamic range from 0 to 8 mM with a low detection limit of 0.02 μM (S/N = 3).
Figure 3. (A) Amperometric responses of GDH-polyMG-CNDs/GC electrode at an applied potential of −0.1 V to successive addition of different concentrations of glucose in 0.1 M pH 7.0 stirring buffer solution containing 20 mM NAD+; (B) Polarization curve (black square dots) and the dependence of power density of the assembled glucose/air BFC on current density (blue circle dots) in quiescent 0.1 M pH 7.0 buffer solution containing 20 mM NAD+ under air atmosphere.
To investigate the practical applications of the proposed GDH-based glucose biosensor in real samples, the glucose concentrations in human serum samples obtained from the Hospital attached to this University were monitored. Before measuring, the fresh serum samples were diluted using phosphate buffer solution. The determination results with the proposed biosensor and RSD values (n = 5) were summarized in Table 1. From this Table, it can be seen that the determination results are good agreement with the results provided by the hospital and the RSD values are smaller than 2.97%, indicating that the proposed glucose biosensor displays good accuracy and repeatability in complex samples and therefore shows potentially practical applications.
It has been attracted much attention to develop NAD+-dependent dehydrogenase based bioanodes for constructing BFCs because more than 300 dehydrogenases have been known today and therefore different substrates of dehydrogenases can be employed for biofuels [17] [18] [19] . Glucose, as a most active fuel of enzymatic BFCs, is also a common ambient fuel which exists widely in human, animals, plants, various foods. Many kinds of soft drinks, which are rich in glucose, are suitable fuels for BFCs owing to the advantages of green fuel, cheapness and availability. In this study, by using GDH-polyMG-CNDs composites as the bioelectrocatalysts for the catalytic electrooxidation of glucose at the bioanode and laccase-CNDs composites as the direct bioelectrocatalyst for oxygen reduction at the biocathode, a membrane-less glucose/air BFC was successfully constructed. The investigations on the direct electron transfer (DET) of blue-copper oxidases including bilirubin oxidase and laccase on CNDs have been studied in our previous studies [18] [26] . These studies have demonstrated that CNDs can efficiently facilitate the DET behaviours of bilirubin oxidase and laccase, and also retain their bioactivity for bio-catalyzing oxygen reduction. Based on previous studies, a laccase-CNDs enzymatic electrode was prepared as before and used as the biocathode for oxygen reduction [18] [26] .
Table 1. Glucose determination in serum samples with the proposed glucose biosenor.
In this study, the performances of the constructed glucose/air BFC was further investigated in glucose-containing fruit juice in order to demonstrate its suitability for implantable applications. Figure 3(B) shows the polarization curve and power curve of the assembled glucose/air BFC in the quiescent fruit juice containing 20 mM NAD+ under ambient air atmosphere in 0.1 M, pH 7.0 phosphate buffer solution. The open-circuit voltage (OCV) of the BFC is ca. 0.48 V and the power density reaches 0.31 µW/cm2 at 0.22 V. This result is quite comparable to that of glucose/oxygen BFC reported recently [28] . Therefore, the assembled miniature BFC can directly generate energy from soft drinks. When the cell operated continuously with an external loading resistance of 1 MΩ in a quiescent 0.1 M, pH 7.0 buffer solution containing 20 mM NAD+ under ambient air, it lost ca. 9.8% of its original power in the first day and the power output remained ca. 73.4% of its original power after a week continuous work. The performance of the assembled CNDs-based glucose/air BFC is dominated by the current density of the laccase-CNDs/GC biocathode. The decreased OCV and power density may be explained by the deactivation of enzymes by some compounds within fruit juice, and low glucose and oxygen concentration in fruit juice under air atmosphere.
4. Conclusion
In this work, we have synthesized and characterized a carbon-based material, carbon nanodots. Using carbon nanodots as supporting matrixes, GDH-polyMG-CNDs and laccase-CNDs were prepared and used for glucose oxidation and oxygen reduction. A glucose biosensor was fabricated with the GDH-polyMG-CNDs/GC electrode and also used for blood glucose determination in serum samples. Moreover, the GDH-polyMG-CNDs/GC electrode as a promising bioanode and DET-type laccase-CNDs /GC electrode for as biocathode four-electron reduction of oxygen were used to construct glucose/air BFC. The bioelectrocatalytic performances of the prepared enzyme electrodes using carbon nanodots as supporting matrixes were studied systematically and therefore a novel glucose/air BFC is assembled by using GDH-polyMG-CNDs/ GC electrode as bioanode and laccase-CNDs/GC as biocathode. In all, the present studies indicate that CNDs can be employed as promising immobilizing materials and electrochemical transducer in bioelectrochemistry area.
Acknowledgements
The funds from the Natural Science Foundation of China (Grant Nos. 21874001, 21575004, 21175002), Program for New Century Excellent Talents in University (NCET-12-0599), and the Foundation for Innovation Team of Bioanalytical Chemistry of Anhui Province are acknowledged for financial supporting this work.