Abstract
An enzyme-free sandwich amperometric immunosensor based on bimetallic Pt/Ag nanoparticle (Pt/AgNPs)-functionalized chitosan (Chi)-modified multiwalled carbon nanotubes (MWCNTs) as dual signal amplifiers and Chi-modified MWCNTs (MWCNTs-Chi) as substrate materials was developed for ultrasensitive detection of fowl adenovirus group I (FAdV-I). MWCNTs have a large specific surface area, and many accessible active sites were formed after modification with Chi. Hence, MWCNTs-Chi, as a substrate material for modifying glassy carbon electrodes (GCEs), could immobilize more antibodies (fowl adenovirus group I-monoclonal antibody, FAdV-I/MAb). Multiple Pt/AgNPs were attached to the surface of MWCNTs-Chi to generate MWCNTs-Chi-Pt/AgNPs with high catalytic ability for the reaction of H2O2 and modified active sites for fowl adenovirus group I-polyclonal antibody (FAdV-I/PAb) binding. Amperometric i–t measurements were employed to characterize the recognizability of FAdV-I. Under optimal conditions, and the developed immunosensor exhibited a wide linear range (100.93 EID50 mL−1 to 103.43 EID50 mL−1), a low detection limit (100.67 EID50 mL−1) and good selectivity, reproducibility and stability. This immunosensor can be used in clinical sample detection.
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Introduction
Avian adenoviruses were separated into 3 groups (I–III). Group I, the so-called fowl adenovirus group I (FAdV-I), comprises 12 serotypes (FAdV-1, FAdV-2, FAdV-3, FAdV-4, FAdV-5, FAdV-6, FAdV-7, FAdV-8a, FAdV-8b, FAdV-9, FAdV-10, and FAdV-11) and mainly infects turkeys, chickens, ducks, geese and pigeons1,2. FAdV-I can be transmitted horizontally and vertically through feces and progeny, respectively3. It has been demonstrated that infections caused by FAdV-I are associated with hydropericardium, hepatitis and runting-stunting, resulting in apathy, weight loss, and mortality4. FAdV-I has been reported in many countries, and FAdV-I infections cause enormous economic burdens in poultry farming 4,5. Therefore, rapid, specific and sensitive detection methods are needed to screen for and control FAdV-I infection. Methods such as virus isolation and identification, polymerase chain reaction (PCR)-based assays and loop-mediated isothermal amplification (LAMP) have been proposed6,7,8,9. However, these diagnostic methods require either highly qualified personnel or sophisticated instrumentation.
Amperometric immunosensors are particularly useful for detecting various diseases because of their rapid detection, small analyte volume, high specificity and low detection limits for analyzing complex clinical samples with relatively simple instruments and procedures10,11. Amperometric immunosensors mainly include label-free and sandwich amperometric immunosensors. Label-free amperometric immunosensors, that is, direct immunosensors, work by measuring the signal changes arising directly from immune reactions without requiring labeling; these immunosensors are used for fast, real-time detection12. However, when other proteins or antigens are present in a clinical sample, nonspecific binding of the other proteins or antigens on the surface of the substrate can occur, and a small signal is generated, leading to an increase in the background signal, which results in a decrease in sensitivity10. In sandwich immunosensors, the antigen is sandwiched between the primary and detection antibodies. The primary antibody, which is immobilized on a solid substrate surface and used to capture the antigen from the sample, is known as the capture antibody. Detection antibodies, known as labeled antibodies, are used to attach to labels such as enzymes and nanomaterials that can be used to amplify signals13. Sandwich immunosensors based on signals generated from labels have several advantages, such as decreased nonspecific adsorption and increased sensitivity14. In general, compared with label-free amperometric immunosensors, sandwich-type amperometric immunosensors result in more sensitive assays with a wide detection range because of signal amplification with detection antibody labels13,14. Sandwich-type amperometric immunosensors, which convert immune responses triggered by probe target immunocomplexes into readable current signals, are powerful analytical devices.
Multiwalled carbon nanotubes (MWCNTs) have attracted the attention of researchers in recent decades because of their outstanding electrical conductivity and large specific surface areas; hence, they have been widely applied in catalysis, adsorption and energy storage systems15,16. In this work, MWCNTs with sufficient transport channels were employed to enhance the current response of a developed amperometric immunosensor. Metal nanoparticles have attracted interest because of their unique physical, chemical and electronic properties and potential applications in amperometric sensors17,18. The excellent conductivity of metal nanoparticles enhances the peak current by transferring electrons from the redox centers in target molecules to the electrode surfaces19. Among metal nanoparticles, noble metal nanoparticles (such as gold nanoparticles, platinum nanoparticles and silver nanoparticles), which have good biocompatibility, high catalytic activity and superior electrical conductivity, have been widely used in amperometric immunosensors13,20. In addition, bimetallic metal nanoparticles have attracted specific interest because they exhibit distinct unique characteristics, such as enhanced electrical conductivity, high catalytic ability and long-term stability, unlike single metal nanoparticles because of the synergistic effects between bimetallic metal nanoparticles21,22. Platinum nanoparticle and silver nanoparticle catalysts have been used in immunosensors in recent years because of their unique catalytic abilities. Platinum silver alloy nanoparticles, which are catalysts with synergistic effects between Ag and Pt nanoparticles, exhibit extraordinary electrocatalytic activity for H2O2 reduction23. In particular, MWCNTs with more active sites and a larger functional surface area were utilized to immobilize Pt/AgNPs to load more active probes bound to biomolecules24. Pt/AgNPs can combine with MWCNTs to form composites, which can prevent the agglomeration of Pt/AgNPs and ensure that the nanoparticle size is maintained. Furthermore, MWCNTs have a fast electron transfer rate and a large specific surface area, which can improve immunosensor properties15. Inspired by this, bimetallic Pt/AgNPs immobilized on the surface of MWCNTs were developed as a signal amplification label in this work, and the signal was effectively amplified based on the dual catalytic effect of Pt/AgNPs and MWCNTs on H2O2.
Another crucial factor in obtaining sensitive electrical signals is the immobilization of biomolecules on highly conductive substrates. MWCNTs, which have remarkable electron transfer capability, are promising substrate materials25. However, MWCNTs have poor solubility, which is a major barrier to developing immunosensors based on MWCNTs. To optimize the use of MWCNTs for immunosensor applications, it is necessary to functionalize MWCNTs with biomaterials. Among the various biomaterials, chitosan (Chi) is a popular matrix for immobilizing immunosensor elements due to its nontoxicity, excellent film properties, biocompatibility and availability of amine/hydroxyl groups; additionally, Chi can be used to immobilize biomolecules for biosensor applications26. However, due to the nonconductive nature of Chi, its use in the preparation of an electrochemical immunosensor has been limited. To increase the conductivity of Chi, a variety of nanomaterials with high conductivity have been incorporated with Chi27. Among them, MWCNTs have a low cost, large surface area and conductive properties. More importantly, Chi can covalently attach to MWCNTs via π–π interactions to form MWCNTs-Chi nanobiocomposites. This approach involves the incorporation of MWCNTs with a polymeric backbone, which is helpful for increasing the solubility of MWCNTs without decreasing their conductivity28; this approach can not only synergistically promote electron conduction but also effectively immobilize biomolecules such as antibodies and maintain their bioactivity29. Based on the above advantages, MWCNTs-Chi nanobiocomposites as substrates provide a suitable microenvironment for immunosensors.
In this study, bimetallic Pt/AgNPs immobilized on the surface of MWCNTs were used as a label to promote dual amplification of the current signal. MWCNTs-Chi were used as a substrate to provide a stable microenvironment for maintaining biomolecular activity and effectively increasing the electron transfer rate on the surface of the electrode. With good coordination of bimetallic Pt/AgNPs immobilized on the surface of MWCNTs-Chi, the established electrochemical immunosensor showed remarkable analytical performance and yielded convincing results in clinical sample assays, demonstrating its good potential for application in disease detection.
Results and discussion
Characterization of the nanomaterials
Transmission electron microscopy (TEM) was employed to characterize the features of the MWCNTs-Chi and MWCNTs-Chi-Pt/AgNPs. Figure 1a shows the typical tubular structure of MWCNTs. Figure 1b shows TEM images of the MWCNTs-Chi-Pt/AgNPs. Pt/AgNPs were uniformly distributed on the surface of MWCNTs-Chi. Moreover, energy dispersive X-ray spectroscopy (EDS) was employed to confirm the presence of Pt and Ag in the MWCNTs-Chi-Pt/AgNPs, and the results showed that the Pt/AgNPs were successfully loaded on the surface of the MWCNTs (Fig. 1c). Here, we suspect that Pt2+ and Ag+ ions in aqueous solution were adsorbed onto the MWCNTs-Chi nanocomposite via chelation and reduced to their corresponding metal nanomaterials by Chi30,31. Chi acted as a reducing agent and stabilizing agent. The MWCNTs acted as carriers to load more Pt/AgNPs and prevent the agglomeration of Pt/AgNPs to ensure that their size was consistent with that of the nanoparticles.
X-ray photoelectron spectroscopy (XPS) was employed to survey the surface features of the MWCNTs-Chi-Pt/AgNPs. The XPS spectrum revealed diffraction peaks at 367.62 (3d5/2) and 373.63 (3d3/2) eV (Fig. 1d), which corresponded well to Ag0, and no obvious peak attributed to Ag+ was observed, which indicated that metallic Ag0 was the predominant species32. The Ag 3d peak shifted to a lower value of 367.62 eV relative to that of pure Ag (368.3 eV)33 because of the modification of Ag by alloying with Pt. These results confirmed the formation of the Pt/AgNPs alloy during the synthesis of MWCNTs-Chi-Pt/AgNPs34.
As shown in Fig. 1e, the binding energies at 72.94 and 76.27 eV corresponded to Pt 4f7/2 and Pt 4f5/2, respectively, which were attributed to Pt0, while the binding energies at 74.64 and 78.25 eV were assigned to Pt2+. These results demonstrated that metallic Pt0 was formed and that the partial reduction of platinum atoms was incomplete35.
The high-resolution C 1 s XPS spectrum of the MWCNTs-Chi-Pt/AgNPs is shown in Fig. 1f. Four diffraction peaks were observed at 284.78, 286.08, 286.7 and 288.13 eV, which were assigned to the covalent C–C, C–O, C=O, and O–C=O bonds, respectively36. The diffraction peak intensity ratio of C–C was much higher for MWCNTs-Chi-Pt/AgNPs than for MWCNTs-Chi (Fig. S2), demonstrating the efficient reduction of MWCNTs-Chi37.
Electrochemical characterization of the immunosensor
In this study, EIS was employed to investigate the step-by-step assembly process of the immunosensor in a mixed solution of [Fe(CN)6]3−/4− (2.5 mM) and 0.1 M KCl with an amplitude of 10 mV at 0.2 V and frequencies ranging from 0.01 Hz to 100 kHz. The Nyquist plots obtained by the EIS method were fitted to the effective impedance of the electrode, which is usually expressed as the Nyquist diameter of the semicircle of the graph, which is also known as the electron transfer resistance (Ret). According to the EIS Nyquist plots, the low-frequency region usually appears as a line that reflects the diffusion process on the electrode surface. The high-frequency region appears as a semicircle that corresponds to Ret. Figure 2a shows the EIS Nyquist plots obtained during the step-by-step electrode assembly process. In these plots, a semicircle with an Ret of 1039 Ω (%RSD) = 3.29 was observed for the bare GCE (Fig. 2a, curve a-1 and b, column a-1), and a smaller semicircle with an Ret of 418 Ω (%RSD) = 2.47 was obtained after the GCE was modified with MWCNTs-Chi (Fig. 2a, curve -1 and b, column b-1) because the excellent conductivity of the MWCNTs promoted electron transfer on the surface of the electrode. Then, the electrode was modified by FAdV-I/MAb, BSA and 103.43 EID50/mL FAdV-I. The results (Fig. 2b, columns c-1-e-1) showed that the obtained relevant Ret values sequentially increased to 1575 Ω (%RSD = 3.14), 2630 Ω (%RSD = 2.91) and 3584 Ω (%RSD = 3.21) because FAdV-I/MAb, BSA and FAdV-I, respectively, have poor conductivity of protein molecules. These results revealed that each step of the electrode modification was successful. The Randles equivalent circuit model is shown in the illustration.
Furthermore, cyclic voltammetry (CV) is another valid technique for verifying the modification of electrodes. The CV data of the GCE electrode demonstrated the effectively reversible redox properties of Fe(CN)64−/3− (Fig. 2c,d, curve and column a-1), and the peak current of the GCE-MWCNTs-Chi increased due to the good conductivity of the MWCNTs (Fig. 2c,d, curve and column b-1). After FAdV-I/MAb, BSA and FAdV-I (103.43 EID50/mL) were successively adsorbed on the modified electrode, the corresponding peak currents decreased (Fig. 2c,d, curve and columns c-1–e-1). These results are consistent with the EIS results, indicating that the FAdV-I immunosensor was successfully constructed.
Amperometric i–t curve measurements were used to evaluate the electrocatalytic performance of the developed immunosensor. The results showed that the electrocatalytic activity of MWCNTs-Chi-FAdV-I/MAb-BSA (Fig. 2e,f, curve and column a-1) could be ignored because it was much weaker than that of MWCNTs-Chi-Pt/AgNPs-FAdV-I/PAb (Fig. 2e,f, curve and column e-1). In addition, the electrocatalytic performance of MWCNTs-Chi-PtNPs-FAdV-I/PAb, MWCNTs-Chi-AgNPs-FAdV-I/PAb, Chi-Pt/AgNPs-FAdV-I/PAb, and MWCNTs-Chi-Pt/AgNPs-FAdV-I/PAb as labels during the detection process were compared. The immunosensor using MWCNTs-Chi-Pt/AgNPs-FAdV-I/PAb (Fig. 2e,f, curve and column e-1) as the label had a much higher current change response than did that using MWCNTs-Chi-PtNPs-FAdV-I/PAb (Fig. 2e,f, curve and column b-1), MWCNTs-Chi-AgNPs-FAdV-I/PAb (Fig. 2e,f, curve and column c-1) and Chi-Pt/AgNPs-FAdV-I/PAb (Fig. 2e,f, curve d-1) as the labels. The higher current change response obtained from MWCNTs-Chi-Pt/AgNPs-FAdV-I/PAb was attributed mainly to the excellent catalytic activity of Pt/AgNPs and the excellent electrical conductivity and large specific surface area of the MWCNTs. When the electrode was not immobilized with FAdV-I/MAb and was directly blocked with BSA, the obtained peak current (Fig. 2e,f, curve and column f-1) was similar to the background signal (Fig. 2e,f, curve and column a-1); after it was reacted with 103.43 EID50/mL FAdV-I and MWCNTs-Chi-Pt/AgNPs-FAdV-I/PAb, the obtained peak current (Fig. 2e,f, curve and column g-1) was also similar to the background signal. These results indicate that the developed immunosensor has excellent selectivity.
Optimization of the method
MWCNTs-Chi, which are conductive substrates, are important for enhancing electron transfer between the surface of the electrode and electrolyte and immobilizing FAdV-I/MAb. Hence, the concentration of MWCNTs-Chi was optimized because it affects the amperometric response. GCEs were modified with different concentrations of MWCNTs-Chi to detect 103.43 EID50/mL FAdV-I. The currents obtained from the amperometric i–t curve are shown in Fig. 3a. The results showed that the current response increased as the MWCNTs-Chi concentration increased from 0.1 to 1.0 mg/mL. Here, the current response increased due to the increase in the MWCNTs-Chi concentration, directly resulting in an increase in the number of FAdV-I/MAb anchoring sites on the electrode. When the concentration of MWCNTs-Chi increased from 1 to 2 mg/mL, the current response signal reached a plateau. Therefore, 1.0 mg/mL MWCNTs-Chi was the optimal concentration.
The concentrations of FAdV-I/MAb and FAdV-I/PAb were investigated, and the results are shown in Fig. 3b,c. The corresponding response currents gradually increased with increasing FAdV-I/MAb and FAdV-I/PAb concentrations, and the corresponding response currents reached maximum values at 10 µg/mL and 1.0 µg/mL, respectively. As the concentrations of FAdV-I/MAb and FAdV-I/PAb continued to increase, the corresponding response currents reached a plateau, indicating that the concentrations of FAdV-I/MAb and FAdV-I/PAb were oversaturated. Therefore, the optimal concentrations of FAdV-I/MAb and FAdV-I/PAb were 10 µg/mL and 1.0 µg/mL, respectively.
In this work, the MWCNTs-Chi-Pt/AgNPs-FAdV-I/PAb nanocomposite was used as a signal label, and the response current was affected by the ratio of MWCNT, Ag and Pt (MWCNT:Ag:Pt). The results are shown in Fig. 3d,e. When Ag was present, the corresponding signal increased as the ratio of MWCNT to Ag to Pt increased from 30:1:0 to 30:3:0. When Pt was present, the corresponding signal increased as the ratio of MWCNT to Ag and Pt increased from 30:0:1 to 30:0:3. When both Ag and Pt were present, the corresponding signal increased as the ratio of MWCNT to Ag to Pt increased from 30:1:1 to 30:1:2, and the corresponding signal decreased as the ratio of MWCNT to Ag to Pt increased to 30:2:2. Furthermore, the presence of Ag and Pt resulted in a greater catalytic ability for H2O2 than for single metal nanoparticles because of the synergistic effects between Ag and Pt. Hence, a MWCNT:Ag:Pt ratio of 30:1:2 was the best choice in this study.
The signal of electrochemical immunosensors is usually affected by the pH of the electrolyte. In this work, the pH in the electrolyte was optimized, and the results are shown in Fig. 3f. The corresponding currents increased as the pH increased from 6.0 to 7.4, and the corresponding currents decreased when the pH of the electrolyte was above 7.4. Hence, pH = 7.4 was the optimal electrolyte. The stability of the antigen‒antibody combination may be affected by acidic or alkaline solutions, leading to changes in the signal.
The concentration of H2O2 was optimized, and the results are shown in Fig. 4a,b. The corresponding currents increased when the concentration of H2O2 increased from 1 to 5 mM, and the corresponding currents plateaued as the concentration of H2O2 continued to increase because H2O2 reached saturation. Hence, 5 mM H2O2 was chosen as the optimal concentration for addition to the electrolyte.
Furthermore, the incubation time of the sample (FAdV-I) and signal label materials (MWCNTs-Chi-Pt/AgNPs-FAdV-I/PAb nanocomposite) considerably influenced the immunosensor. The corresponding currents increased with increasing incubation time for 30 min and 40 min for FAdV-I and MWCNTs-Chi-Pt/AgNPs-FAdV-I/PAb, respectively, (Fig. 4c,d). The corresponding currents plateaued as the incubation time of FAdV-I and MWCNTs-Chi-Pt/AgNPs-FAdV-I/PAb was extended because the immunoreaction was complete. Hence, the optimal incubation times for FAdV-I and MWCNTs-Chi-Pt/AgNPs-FAdV-I/PAb were 30 min and 40 min, respectively.
Detection of FAdV-I with the immunosensor
The selected immunosensor was used to detect FAdV-I at concentrations ranging from 103.93 to 100.93 EID50 mL−1 to evaluate its detection capability. Figure 5a shows that the corresponding signal intensity increased with increasing concentrations of FAdV-I. Furthermore, the current signal of the blank (curve a-1) was significantly lower than the current signal of FAdV-I (curves b-1–h-1), indicating that the background current of MWCNTs-Chi-FAdV-I/MAb-BSA and nonspecific adsorption on the surface of the immunosensor were negligible. The calibration plot shown in Fig. 5b shows a good linear relationship between the logarithm values of the FAdV-I concentration and the change in the current signal. The linear regression equation I (mA) = 2.1521 lg EID50 mL−1—1.1852 (correlation coefficient of R = 0.9916) and a low detection limit (100.67 EID50 mL−1 (S/N = 3)) were obtained. The excellent analytical performance of the exploited immunosensor was attributed to the following factors: (1) MWCNTs-Chi, which has remarkable electroconductivity and a large specific surface area, were used to modify the electrode and not only promoted electron transfer between the surface of the electrode and electrolyte but also provided enough active sites for FAdV-I/MAb binding; (2) the MWCNTs-Chi-Pt/AgNPs-FAdV-I/PAb nanocomposite had excellent electrocatalytic capability for H2O2 reduction due to electron–electron correlation assistance; (3) FAdV-I/MAb, which has good specificity, was used as a capture antibody to ensure the specificity of the developed immunosensor; and (4) FAdV-I/PAb, which has more antigen-binding sites as a detection antibody, can enhance the sensitivity of the proposed immunosensor.
Selectivity, reproducibility and stability of the immunosensor
The specificity of the immunosensor plays an important role in the analysis of clinical samples. Interfering substances that may be present in the clinical sample, including IBV (104.79 EID50 mL−1), CIAV (105.31 EID50 mL−1), NDV (106.73 EID50 mL−1), EDSV (105.17 EID50 mL−1), ARV (107.18 EID50 mL−1), AIV H9 (106.47 EID50 mL−1), BSA (1.0 μg/mL), glucose (1.0 μg/mL) and vitamin C (1.0 μg/mL), were employed to evaluate the specificity of the exploited immunosensor (Fig. 5c). The current responses of the abovementioned interfering substances were similar to those of the blank solution but markedly lower than those of FAdV-I (including 12 serotypes FAdV-1 (105.75 EID50 mL−1), FAdV-2 (104.38 EID50 mL−1), FAdV-3 (106.21 EID50 mL−1), FAdV-4 (104.92 EID50 mL−1), FAdV-5 (105.47 EID50 mL−1), FAdV-6 (106.35 EID50 mL−1), FAdV-7 (104.63 EID50 mL−1), FAdV-8a (106.27 EID50 mL−1), FAdV-8b (107.35 EID50 mL−1), FAdV-9 (105.79 EID50 mL−1), FAdV-10 (106.24 EID50 mL−1), and FAdV-11 (105.62 EID50 mL−1). The current responses of the mixtures of FAdV-4 (103.43 EID50 mL−1) with possible interfering substances (such as NDV, ARV and BSA) were similar to those of FAdV-I. These results indicated that the applied immunosensor had high specificity for FAdV-I detection.
The reproducibility of the developed immunosensor was evaluated by using different batches of the immunosensor to detect the same concentrations of 103.43 EID50 mL−1 FAdV-I. The results (Fig. 5d) showed that the intra- and interassay RSD values were all less than 5.0%, as shown by the error bars, and these results indicated that the applied immunosensor had good reproducibility.
The storage life of the developed immunosensor was surveyed by storing GCE-MWCNTs-Chi-FAdV-I/MAb-BSA and MWCNTs-Chi-Pt/AgNPs-FAdV-I/PAb nanocomposites at 4 °C until use. Then, GCE-MWCNTs-Chi-FAdV-I/MAb-BSA were successively incubated with 103.43 EID50 mL−1 FAdV-I and MWCNTs-Chi-Pt/AgNPs-FAdV-I/PAb nanocomposites. As shown in Fig. 5e, the current response remained at 90.01% of that of the new preparation after storage for 7 weeks. Therefore, the storage life of the developed immunosensor was acceptable.
Clinical sample analysis
The developed immunosensor was used to analyze 125 clinical samples collected from chickens in small poultry flocks in Guangxi, China, that were suspected to be infected with adenoviruses, and the results were 100% consistent with the results of real-time PCR and 98.3% consistent with the results of loop-mediated isothermal amplification (LAMP), which were both developed by our group38,39, to prove that the developed immunosensor can be used for real samples. The results are shown in Table 1. Fifty-nine of the 125 samples (cloacal swab samples) were identified as positive by the proposed immunosensor, which was consistent with the results of real-time PCR, whereas 58 of the 125 samples were identified as positive by LAMP.
Furthermore, the proposed immunosensor was used to monitor the recovery of cloacal swab samples after treatment with different concentrations of FAdV-I to evaluate its accuracy and practicality. A series of different concentrations of FAdV-I were added by standard addition methods to the six aforementioned clinical samples that were identified as FAdV-I-positive samples; these concentrations were chosen randomly and detected by the fabricated immunosensor. The results are summarized in Table 2. The recoveries, which were calculated as the ratio between the amount of FAdV-I found and the amount added, ranged from 98.37 to 104.41%, with an RSD ranging from 2.63 to 4.71% (n = 5). These results indicated that the fabrication method was appropriate for FAdV-I detection in the samples.
Conclusions
In this work, an enzyme-free sandwich amperometric immunosensor was developed for the detection of FAdV-I by using MWCNTs-Chi, which has ideal conductivity and efficient antibody immobilization, as the matrix platform and a MWCNTs-Chi-Pt/AgNPs-FAdV-I/PAb nanocomposite, which has excellent electrocatalytic activity toward H2O2 reduction, as the signal amplification label. The developed amperometric immunosensor showed high specificity, good sensitivity, accuracy, reproducibility and stability and was capable of detecting FAdV-I in clinical samples. More importantly, the developed method not only enables the application of MWCNTs-Chi-Pt/AgNPs nanocomposites in amperometric electrochemical immunosensors but also provides a new enzyme-free method for the determination of other biomolecules in clinical diagnosis.
Materials and methods
Reagents and instruments
Chloroplatinic acid hexahydrate (H2PtCl6·6H2O), silver nitrite (AgNO3), bovine serum albumin (BSA, 98% purity) and MWCNTs were purchased from Sigma‒Aldrich Chemical Co. (St. Louis, MO, USA). Chi (Mw 1.5 × 10–5, deacetylation degree ≥ 90%), NaNO3, H2SO4 and KMnO4 were obtained from Guoyao Group Chemical Reagents Co., Ltd. (Shanghai, China). Deionized water (ddH2O, ~ 18 MΩ resistance) prepared by a Millipore water purification system was used to prepare the buffers and solutions. All the chemicals were of analytical reagent grade. Phosphate-buffered saline (PBS) was prepared with 10 mmol/L Na2HPO4, 10 mmol/L NaH2PO4 and 0.9% NaCl.
Apparatus
All the electrochemical measurements were conducted with a PARSTAT 4000A instrument (Princeton Applied Research, USA) in this work. A glassy carbon electrode (GCE, Ø = 3 mm), a saturated calomel electrode (SCE) and a platinum wire electrode were used as the working electrode, reference electrode and counter electrode, respectively, composing a standard three-electrode system. Energy-dispersive X-ray spectroscopy (EDS) elemental analysis and transmission electron microscopy (TEM, Tecnai G2 F30 S-TWIN, FIE, USA) were employed to characterize the nanomaterials.
Viruses and antibodies
Fowl adenovirus group I-monoclonal antibody (FAdV-I/MAb) and fowl adenovirus group I-polyclonal antibody (FAdV-I/PAb) were prepared by our research group40. In brief, codon optimization was performed on the Fiber-2 gene sequence, and a sequence fragment encoding a truncated Fiber-2 protein with strong antigenicity was amplified by PCR and cloned into pET-32a(+) to construct the vector for prokaryotic expression. The recombinant protein was purified. Following the immunization of BALB/c mice with the recombinant protein, the serum was collected as a polyclonal antibody. Splenocytes were harvested and fused with SP2/0 cells, and the positive cell lines were screened by indirect enzyme-linked immunosorbent assay (ELISA) and used to prepare monoclonal antibodies. The hybridoma cell line corresponding to FAdV-I/MAb was obtained from the China Center for Type Culture Collection (CCTCC NO: C2022177). FAdV-1, FAdV-2, FAdV-3, FAdV-4, FAdV-5, FAdV-6, FAdV-7, FAdV-8a, FAdV-8b, FAdV-9, FAdV-10 and FAdV-11 were purchased from the China Institute of Veterinary Drugs Control. Chicken infectious anemia virus (CIAV), infectious bronchitis virus (IBV), Newcastle disease virus (NDV), egg drop syndrome virus (EDSV), avian reovirus (ARV) and the avian influenza virus H9 subtype (AIV H9) were collected and stored in our laboratory prior to use.
Synthesis of MWCNTs-Chi
MWCNTs-Chi was prepared by following the method described above. First, 0.5 g of Chi was added to 100 mL of 1.0% (v/v) acetic acid solution, and the mixture was magnetically stirred at room temperature for 0.5 h. A 0.5 wt% Chi solution was obtained. Second, 100 mg of MWCNTs was added to 100 mL of Chi solution obtained by the above preparation, ultrasonicated for 0.5 h, and continuously magnetically stirred for 48 h at room temperature. A stable MWCNTs-Chi (1 mg/mL) suspension was subsequently obtained.
Synthesis of MWCNTs-Chi-Pt/AgNPs-FAdV/PAb
MWCNTs-Chi-Pt/AgNPs-FAdV/PAb were prepared by following the method described above. First, 1 mL of AgNO3 (10 mmol/L) and 1 mL of K2PtCl4 (10 mmol/L) were added to the above-prepared MWCNTs-Chi (30 mL) suspension, and the mixture was continuously magnetically stirred for 5 h at room temperature. Second, the mixture was heated in a water bath to 90 °C and kept for 0.5 h for further reaction (Pb2+ and Ag+ were reduced to Pt/AgNPs by Chi here); then, MWCNTs-Chi-Pt/AgNPs were obtained. Different proportions of MWCNTs-Chi-Pt/AgNPs were prepared by adding different volumes of AgNO3 (10 mmol/L) and K2PtCl4 (10 mmol/L) to 30 mL of the MWCNTs-Chi (1 mg/mL) suspension by the method mentioned above.
Third, the as-prepared MWCNTs-Chi-Pt/AgNPs (10 mL) were mixed with 1 mL of 1 μg/mL FAdV-I/PAb, and the mixture was vibrated in a shaker at 4 °C for 12 h. The product was subsequently washed with PBS (pH 7.4) containing 1 wt% BSA and centrifuged at 10,000 rpm for 5 min, after which the supernatant was discarded to remove the unbound FAdV-I/PAb. Finally, the obtained MWCNTs-Chi-Pt/AgNPs-FAdV/PAb were redispersed into 10 mL of PBS (pH 7.4) containing 1 wt% BSA.
Fabrication of an electrochemical immunosensor
First, a glass carbon electrode (GCE, Ø = 3 mm) was polished to a mirror surface with 0.05 μm Al2O3 polishing powder, washed with ddH2O and cleaned via ultrasonication in ddH2O, CH3CH2OH and ddH2O for 5 min each.
Second, a 0.5 mol L−1 H2SO4 solution was injected with N2 for 5 min to remove oxygen, after which the GCE was scanned via cyclic voltammetry (CV) in H2SO4 solution at a scanning speed of 50 mV/s and a voltage range of − 0.3 ~ + 1.5 V until the CV current was stable. Afterward, the GCE was washed with ddH2O three times and dried with N2 for further modification.
Third, 10 μL of 1 mg/mL MWCNTs-Chi was dropped on the surface of the GCE and dried at 37 °C. Next, 10 μL of 10 μg/mL FAdV-I/MAb was deposited onto the electrode, incubated at 4 °C for 8 h, and then washed with PBS (pH 7.4) three times to remove the unbound FAdV-I/MAb.
Fourth, 10 μL of 1 wt% BSA, which was used as a nonspecific binding blocker, was deposited onto the electrode and incubated for 1 h at 37 °C to eliminate nonspecific binding, after which the modified electrode was washed with PBS (pH 7.4) three times to remove the excess BSA. The obtained immunosensor (GCE-MWCNTs-Chi-FAdV-I/MAb-BSA) was stored at 4 °C until use.
Detection of the electrochemical immunosensor
The procedure for the electrochemical immunosensor preparation is shown in Fig. 6. First, 10 μL of solution containing different concentrations of FAdV-I was incubated with the developed immunosensor for 30 min to ensure specific binding of FAdV-I to FAdV-I/MAb, after which the mixture was washed with PBS (pH 7.4) three times to remove unbound FAdV-I and other interfering substances. Second, 10 μL of the developed immunosensor was incubated with MWCNTs-Chi-Pt/AgNPs-FAdV/PAb at 37 °C for 40 min and then washed with PBS (pH 7.4) three additional times to remove the excess MWCNTs-Chi-Pt/AgNPs-FAdV/PAb. Finally, amperometric i–t measurements were performed, and the voltage was set to − 0.1 V based on minimized interfering components and background current (supplementary material Fig. S1). After the signal stabilized (approximately 50 s later), H2O2 (5 mmol/L) was added to PBS (10 mL, pH 7.4) under continuous stirring, and the current change was recorded. The mechanism of signal production by catalytic H2O2 was as follows41: H2O2 + e− → OHad + OH−; OHad + e− → OH−; 2H+ + 2OH− → 2H2O. In the H2O2 reduction process, the key step is OHad formation, which helps to amplify the signal for sensitive detection of FAdV-I, and MWCNTs-Chi-Pt/AgNPs can provide abundant catalytic active centers for OHad adsorption42. Electrochemical impedance spectroscopy (EIS) was performed in a [Fe(CN)6]3−/4− (2.5 mM) and 0.1 M KCl mixed solution with an amplitude of 10 mV at 0.2 V (open circuit potential) and frequencies ranging from 0.01 Hz to 100 kHz.
Ethics statement
All the authors confirm that the use of animals in this work was strictly in accordance with the ARRIVE guidelines. This work was approved, conducted and supervised by the Animal Ethics Committee of the Guangxi Veterinary Research Institute. Oral and cloacal swab samples, which were gently collected from chickens in small poultry flocks in Guangxi, China and were suspected to be infected with adenoviruses, were used as clinical samples. The chickens were not anesthetized before sampling, and they were returned to the cages and observed for 0.5 h after sampling. All the authors confirm that all the methods were performed in accordance with the relevant guidelines and regulations.
Data availability
All the data generated or analyzed during this study are included in this article and the supplementary material.
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Acknowledgements
This research project was funded by the Guangxi Youth Natural Science Foundation (2020GXNSFBA297104), the Guangxi Science and Technology Major Program (AA23062050), the Guangxi Science Base and Talents Special Program (AD17195083) and the Guangxi BaGui Scholars Program Foundation (2019A50).
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J.L.H. and Z.X.X. designed and conceived the experiments. J.L.H., S.S.L. and M.L. performed the experiments. J.L.H., L.J.X., Q.F., T.T.Z., Y.F.Z., M.X.Z., Z.Q.X., S.W., D.L., Y.W., X.F.L., L.J.W., and H.Y.R. analyzed the data and contributed reagents, materials, and analytical tools. All the authors reviewed the manuscript.
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Huang, J., Xie, Z., Luo, S. et al. A sandwich amperometric immunosensor for the detection of fowl adenovirus group I based on bimetallic Pt/Ag nanoparticle-functionalized multiwalled carbon nanotubes. Sci Rep 14, 261 (2024). https://doi.org/10.1038/s41598-023-50821-x
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DOI: https://doi.org/10.1038/s41598-023-50821-x