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Article

Ultrasensitive Photoelectrochemical Immunoassay Strategy Based on Bi2S3/Ag2S for the Detection of the Inflammation Marker Procalcitonin

by
Guanhui Zhao
1,
Yingying Wang
2,
Huixin Wang
2,
Guozhen Bai
1,
Nuo Zhang
1,*,
Yaoguang Wang
2,* and
Qin Wei
1
1
Key Laboratory of Interfacial Reaction & Sensing Analysis in Universities of Shandong, School of Chemistry and Chemical Engineering, University of Jinan, Jinan 250022, China
2
Shandong Provincial Key Laboratory of Molecular Engineering, School of Chemistry and Chemical Engineering, Qilu University of Technology (Shandong Academy of Sciences), Jinan 250353, China
*
Authors to whom correspondence should be addressed.
Biosensors 2023, 13(3), 366; https://doi.org/10.3390/bios13030366
Submission received: 28 January 2023 / Revised: 22 February 2023 / Accepted: 8 March 2023 / Published: 10 March 2023
(This article belongs to the Special Issue Application of Nanomaterials for Biosensors)
Browse Figures
Versions Notes

Abstract

:
As an inflammatory marker, procalcitonin (PCT) is more representative than other traditional inflammatory markers. In this work, a highly efficient photoelectrochemical (PEC) immunosensor was constructed based on the photoactive material Bi2S3/Ag2S to realize the sensitive detection of PCT. Bi2S3 was prepared by a hydrothermal method, and Ag2S quantum dots were deposited on the ITO/Bi2S3 surface via in situ reduction. Bi2S3 is a kind of admirable photoelectric semiconductor nanomaterial on account of its moderate bandgap width and low binding rate of photogenerated electron holes, which can effectively convert light energy into electrical energy. Therefore, based on the energy level matching principle of Bi2S3 and Ag2S, a labeled Bi2S3/Ag2S PEC immunosensor was constructed, and the sensitive detection of PCT was successfully established. The linear detection range of the PEC immunosensor was 0.50 pg∙mL−1 to 50 ng∙mL−1, and the minimum detection limit was 0.18 pg∙mL−1. Compared with the traditional PEC strategy, the proposed PEC immunosensor is simple, convenient, and has good anti-interference, sensitivity, and specificity, which could provide a meaningful theoretical basis and reference value for the clinical detection of PCT.

1. Introduction

Procalcitonin (PCT) is an effective marker of blood infection that can be used to guide antibiotic treatment and disease evaluation in patients with respiratory system infections and blood flow infections [1,2]. The PCT levels increase when the patient has inflammation and infection, since the endocrine cells in the lungs and intestinal tissue synthesize and secrete large amounts of PCT [3,4]. The more serious the infection, the higher the PCT content [5,6]. In addition, the level of PCT concentration also plays a guiding role in the diagnosis of sepsis [7,8]. When the concentration of PCT in human serum exceeds 2 ng mL−1, it indicates that the blood has an infection that manifests as septicemia [9,10]. In summary, accurate detection of PCT content in serum has important significance for the early prevention and further treatment of inflammation [11,12]. To date, many PCT detection strategies have been reported, including colorimetric immunoassay [13,14], chemiluminescence immunoassay [15], electrochemical immunoassay [16], microfluidic immunoassay, and fluorescence immunoassay [17,18]. Here, we studied the application of PEC immunosensor technology to detect PCT.
PEC immunosensors are a kind of sensing technology that combines photoelectric materials and specific recognition of biomolecules [19]. At present, many biomolecules (e.g., disease markers, gene sequences, specific recognition cells, etc.) have been used as detection targets [20]. The development prospects of immunosensor technology are promising because of its advantages, such as sensitive recognition, high selectivity, simple and easy operation process, and low cost. It is widely used in clinical medicine, food detection, and environmental monitoring [21]. PEC immunosensor is a kind of high-efficiency sensor that combines the advantages of photoelectrochemistry and biochemistry [22]. It has the advantages of miniaturization, simple operation, high sensitivity, and high specificity [23]. Although it has shown many advantages in various fields compared with traditional chemical detection methods, there are still many problems to be solved in the process of PEC technology’s development [24]. Firstly, a more stringent testing environment is required. Secondly, its stability and photoelectric conversion efficiency need to be improved [25]. Therefore, PEC immunosensors not only need bioactive materials with high photoelectric conversion efficiency, a large absorption range, and good stability, but also need to increase the diversity of the detection environment and the tolerance of the sensors [26]. In this work, two kinds of semiconductor materials with excellent photoelectric activity were selected to prepare a photoelectric chemical immunosensor that possessed the advantages of high photoelectric conversion efficiency, high stability, and simple determination [27].
Bi2S3 belongs to a family of metal chalcogenides in a class of non-toxic semiconductor materials [28], whose importance in photovoltaic and thermoelectric applications is well recognized [29]. Bi2S3 is an excellent photoelectric material because of its moderate bandgap width and low binding rate of photogenerated electron holes, which can effectively convert light energy into electrical energy [30]. Therefore, Bi2S3 was selected as the base material of the immunosensor in this work. In addition, Bi2S3 was sensitized by in situ deposition of Ag2S quantum dots via an immersion method. The preparation process was simple, universal, green, and excellent. The Bi2S3/Ag2S modified electrode significantly improved the photocurrent signal intensity of the sensor substrate, laying a good foundation for the construction of the PEC immunosensor. In this work, rod-like Bi2S3 was synthesized by a hydrothermal method, and Ag2S quantum dots were deposited in situ via an immersion strategy. Based on this, Bi2S3/Ag2S was used as the base material of the electrode, and anti-PCT, bovine serum albumin (BSA), and PCT were modified layer by layer; thus, a new and high-efficiency PEC immunosensor was constructed to realize the sensitive detection of PCT, and the limit of detection (LOD) was 0.18 pg mL−1. Compared with traditional sensors, the preparation process was simple and had fewer interference factors. The sensitivity, selectivity, and stability were excellent. This work could provide a theoretical basis for the use of semiconductor materials in sensing analysis.

2. Materials and Methods

2.1. Materials

Anti-PCT and PCT were obtained from Lingchao Biotechnology Co., Ltd. (Shanghai, China). The other materials and apparatus used are discussed in the Supplementary Materials.

2.2. Synthesis Procedure of Bi2S3

The Bi2S3 was synthesized via a one-step hydrothermal method as reported in the literature [31]. First, 0.2254 g of thioacetamide and 0.7902 g of anhydrous bismuth nitrate were mixed and dissolved in 40 mL of ethanol, which was stirred to completely dissolve the mixture and then transferred to high-pressure Teflon-lined stainless-steel autoclave for 12 h at 180 °C. The product was washed with ultrapure water and ethanol and dried at 70 °C for 12 h in a vacuum-drying oven to obtain Bi2S3 as a black powder.

2.3. Steps of Synthesis of Bi2S3/Ag2S

On the basis of the previous literature, Ag2S was deposited in situ via an immersion method. First, the ITO modified with Bi2S3 was immersed in 0.1 mol L−1 AgNO3 solution prepared with ethanol for 3 min, and then washed gently with ethanol. After natural drying at room temperature, it was immersed in 0.1 mol L−1 Na2S prepared by blending methanol and ultrapure water (volume ratio 1:1) for 3 min. Then, it was washed with a mixture of methanol and water (volume ratio 1:1). After drying at room temperature, Ag2S was successfully deposited on the surface of the Bi2S3/ITO electrode.

2.4. The Establishment Process of the Proposed PEC Immunosensor

Firstly, the ITO glass electrode was cut to 2.5 × 1.0 cm2. Then, the ITO was washed ultrasonically with acetone, ethanol, and ultrapure water solution successively for 30 min. Then, the ITO was dried at 70 °C in the vacuum oven for 2 h. Next, we took 6 μL of Bi2S3 suspension solution (concentration = 5 mol L−1), applied it to the surface of the clean ITO electrode, and allowed it to dry naturally at room temperature until slightly wet. Then, the Bi2S3/ITO electrode was immersed in 0.1 mol L−1 AgNO3 solution for 3 min and then gently washed once with ethanol after being taken out with a clip. After it was dried naturally at room temperature, the ITO was immersed in 0.1 mol L−1 Na2S solution for 3 min. Then, it was taken out with a clip and washed twice with a mixture of methanol and ultrapure water (1:1). Thus, the synthetic deposition of Ag2S quantum dots was successful, and the Ag2S/Bi2S3/ITO modified electrode was successfully prepared.
Then, we added 6 μL of 3 mmol L−1 TGA solution onto the prepared Ag2S/Bi2S3/ITO surface, and the carboxyl group in TGA and the amino group in the anti-PCT could undergo a condensation reaction and connect with one another. Subsequently, 6 μL of EDC/NHS (1:1) mixture was dropped onto the ITO to connect the anti-PCT with the base material and dried at 4 °C in a refrigerator until the surface was slightly wet. Then, 6 μL of PBS solution containing 0.1% BSA was dropped to block non-specific binding sites on the surface of the Ag2S/Bi2S3/ITO. Finally, we added different concentrations of PCT and dried them at 4 °C in the refrigerator until the surface was slightly wet. It is worth noting that in each step of the electrode modification process, PBS solution was used once to wash away the excess substances not participating in the reaction when the electrode surface was dried to slightly wet. At this point, we had completed the construction of the PCT/BSA/anti-PCT/EDC/NHS/Ag2S/Bi2S3/ITO immunosensor, and it was then stored at 4 °C for standby. The construction diagram of the sensor is shown in Scheme 1.

2.5. PEC Analysis of PCT

The photocurrent signal of this PEC sensor was measured with a three-electrode system on the photoelectrochemical workstation. The three-electrode system included a saturated calomel electrode (reference electrode), a counter electrode, and a working electrode. The calomel electrode was easily affected by the concentration and temperature of potassium chloride, so it was necessary to ensure that the potassium chloride solution was saturated. The counter electrode used in this workstation was a platinum counter electrode. As the electronic conductor of the other two electrodes, it did not participate in the electrode reaction. The Bi2S3/Ag2S modified ITO glass electrode was used as the working electrode.
We placed the three-electrode system in PBS (pH = 7.4) solution containing 0.14 mol L−1 ascorbic acid (AA), and the light source was an LED lamp. The photocurrent signal of the sensor was detected by chronoamperometry, and the working curve was constructed according to the relationship between the photocurrent signal and the logarithm of the concentration of PCT antigen, so as to achieve the detection of the concentration level of the inflammatory marker PCT.

3. Results and Discussion

3.1. The Characteristics of Bi2S3 and Bi2S3/Ag2S

Field-emission scanning electron microscopy (SEM) was used to observe the nanoscale morphology and structure of Bi2S3 and the Bi2S3/Ag2S composites to determine whether the synthesized materials met the requirements and whether Ag2S was successfully loaded onto the Bi2S3 materials, as shown in Figure 1. Figure 1A,B show the SEM images of Bi2S3 at different magnifications. It can be seen that Bi2S3 was a block composed of nanorods of different lengths and thicknesses crisscrossed together. Figure S1 shows the X-ray diffraction of Bi2S3, where it can be seen that, compared with the standard card, the XRD spectrum covered the most of the characteristic peaks of Bi2S3. Figure 1B shows that Bi2S3 was actually scattered nanorods with a diameter of 17~26 nm. The cylindrical side of the rod-shaped structure could provide a greater specific surface area and more active sites for the loading of Ag2S.
Figure 1C,D show the SEM images of Bi2S3/Ag2S material under two detectors (InLens and BSE, respectively). The BSE detector was mainly used for signal scanning of backscattered electrons. The higher the atomic number, the stronger the signal, and the brighter the image. By comparing the brightness and size in Figure 1C,D, it can be seen that the Ag2S quantum dots were uniformly attached to the surface of the Bi2S3.
At the same time, the elements contained in the material were analyzed with an energy spectrometer, as shown in Figure 1E. It could be seen that the base material contained the elements Bi, S, and Ag, and the Ag was uniformly distributed on the surface of the Bi2S3, further proving that Bi2S3 and Ag2S were successfully modified on the surface of the ITO electrode. In addition, the EDS mapping images of the Bi2S3/Ag2S composites are shown in Figure S2.
In order to further prove that the Ag2S quantum dots were successfully deposited on the Bi2S3 nanorods, the UV–vis absorption spectra of Bi2S3 and Bi2S3/Ag2S were measured, as shown in Figure 1F. It could be observed that when the Ag2S quantum dots were deposited on the Bi2S3, the absorbance of Bi2S3/Ag2S (b curve) increased significantly and showed slight redshifts, indicating that Ag2S has a certain sensitization effect on Bi2S3.
The satisfying photoelectric performance of the substrate material was dependent on its electron transfer mechanism. As shown in Figure 2, Bi2S3 has a bandgap energy of about 1.38 eV. Under the illumination of the light source, the absorbed light energy of electrons in the valence band of Bi2S3 transitioned to the conduction band. Thus, the holes were generated in the valence band and the electrons were increased in the conduction band. The electron holes moved and formed the current circuit, which successfully converted light energy into electric energy. AA, as an electron donor, could provide electrons and neutralize excessive photogenerated holes in the valence band, inhibiting the recombination of electron–hole pairs, enhancing the continuity of the current circuit, and improving the output efficiency of the photocurrent. Thus, the photoelectric activity of Bi2S3 could be improved. In addition, the generation principle of the electron–hole pairs was the same as described above when the light source was irradiated on the Ag2S quantum dots. The electrons in the conduction band of the Ag2S quantum dots were transferred to the conduction band of the Bi2S3 and then transferred to the electrode surface, forming an electron gradient flow. The energy band matching of the Bi2S3 and the Ag2S quantum dots effectively prevented the electron–hole recombination of Ag2S. Therefore, the electrons on the Ag2S could be efficiently transferred to the electrode surface to increase the photocurrent.

3.2. The Performance Characterization of the Proposed PEC Immunosensor

Figure 3 shows the electrochemical impedance spectroscopy (EIS) characteristics of the immunosensor in PBS (pH = 7.4) solution containing 2.5 mmol L−1 [Fe(CN)6]3−/4− and 5 mmol L−1 KNO3. As shown in Figure 3A, with the layer-by-layer modification of the electrode surface, the semicircle’s diameter changed accordingly. Curve (a) shows the bare ITO glass electrode, and its semicircle diameter is very small, which indicates that its electron transfer resistance was very low. When the Bi2S3 (curve b) nanorod was modified to the electrode surface, it could be seen that it had a certain impedance because Bi2S3 is a nano-semiconductor material. However, the impedance value decreased instead (curve c) when Ag2S was deposited on the Bi2S3/ITO surface. Curves (d) and (e) show the impedance changes after successful modification of the coupling agents TGA and EDC/NHS, respectively. The impedance value decreased after the addition of TGA (curve d), which may have been due to the acidic nature of TGA. This could make the base liquid around the tested electrode present a strong electrolyte solution, resulting in an increase in the action of free electron transfer. After dropping with EDC/NHS (curve e), the diameter of the semicircle increased. We hypothesized that the EDC/NHS activated the carboxyl groups and reduced the acidity of TGA, so the free electron transfer decreased and the impedance value increased. The impedance value increased significantly (curve f) when the antibody, BSA, and PCT were successfully deposited in sequence, because they are biological protein molecules. As shown in Figure 3B, we studied the timing currents of the electrodes at different modification steps. It can be seen from curve (a) that the timing current of the bare ITO electrode was almost zero. The photocurrent signal increased significantly to 16 μA when the electrode surface was modified with Bi2S3 (curve b), because Bi2S3 is an efficient photoelectric semiconductor material. After depositing Ag2S on the surface of Bi2S3 (curve c), the current signal increased significantly to about 130 µA because of the energy band matching principle of Bi2S3 and Ag2S. After the coupling agents TGA (curve d) and EDC/NHS (curve e) were deposited onto the Ag2S/Bi2S3/ITO surface in sequence, the photocurrent change was inversely proportional to the EIS. When the antibody (curve f), BSA (curve g), and PCT were continuously deposited on the Ag2S/Bi2S3/ITO surface, the current signal decreased successively, because all of these substances are biological protein molecules that could block the electronic transmission.

3.3. Optimal Conditions for Analysis

The different concentrations of Bi2S3 suspensions were prepared to drop onto the electrode. The photocurrent detection results are shown in Figure 4A. It can be seen that excessive concentrations of Bi2S3 suspension would make the resistance greater than the conductivity. Therefore, 5 mg mL−1 of Bi2S3 suspension was selected. As shown in Figure 4B, the thick material layer formed by the surplus Ag2S nanoparticles could reduce the conductivity and electron transfer rate and increase the photogenerated electron–hole binding rate. Therefore, 0.1 mol L−1 of AgNO3 solution was finally selected as the best concentration. Figure 4C shows that the photocurrent value reached its maximum when the pH was 7.4. Thus, PBS buffer with pH 7.4 was selected in this experiment. It can be seen from Figure 4D that the photocurrent response was the strongest when the concentration of AA was 0.14 mol L−1. The decrease in the photocurrent signal at higher concentrations of AA could be because of the quenching absorption of the electrolyte solution, which reduced the formation efficiency and light intensity of the excited electron–hole center. As shown in Figure 4E, the photocurrent signal intensity reached about 127 µA and then remained essentially unchanged when the working current was 3.0 A. In order to avoid the impact of strong light on photoelectric materials and biomolecules, 3.0 A was selected as the best working current.

3.4. PCT Detection

Under the optimal experimental conditions, the photocurrent response curves were as shown in Figure 5A. Because PCT and PCT-antibody are not conductive, they could hinder the transfer of electrons between the electrode surface and the substrate solution. Thus, the response current continued to decrease with the increase in the PCT concentration and presented a good linear relationship, as shown in Figure 5B. The linear equation was I (μA) = 35.7555–12.6381 log c; linear correlation coefficient R2 = 0.9952. The linear detection range of PCT for this proposed immunosensor was 0.5 pg mL−1~50 ng mL−1, and the detection limit was as low as 0.18 pg mL−1. (S/N = 3). In order to verify the accuracy of the constructed PEC immunosensor, four samples with known PCT concentrations were mixed and dropped onto the constructed immunosensor. In Figure 5C, curve (a) shows the photocurrent curve of the mixture of two known PCT concentrations (0.1 ng mL−1 and 0.5 ng mL−1). According to the linear fitting formula, the theoretical photocurrent intensity was 42.0 μA. The actual photocurrent intensity was 44.65 μA. Curve (b) shows the photocurrent curve of the mixture of two known PCT concentrations (0.01 ng mL−1 and 0.005 ng mL−1). According to the linear fitting formula, the theoretical photocurrent intensity was 62.0 μA. The actual photocurrent intensity was 63.75 μA, and the relative deviation was 2.8% and 5.9%, respectively, showing that the accuracy of this PEC immunosensor was high and met the experimental needs. Comparing this sensor with other sensors (Table S1), it can be concluded that this PEC sensor has a wide linear range and a low detection limit, indicating that it has relatively excellent performance in detecting PCT, so this work is valuable.

3.5. Specificity, Stability, and Application of the PEC Immunosensor

In order to study the specificity of the PEC immunosensor, we selected the interfering substance B-type natriuretic peptide (BNP). In Figure 5D, curve (a) shows the photoelectric signal response of the blank sample. Curve (b) shows the photoelectric signal response of a mixture of BNP (100 ng mL−1) and blank. Curve (c) shows the photoelectric signal response of the PCT sample (0.50 ng mL−1). Curve (d) shows the photoelectric signal response of the sample containing PCT (0.50 ng mL−1) and BNP (100 ng mL−1). The prepared sensor was determined according to the experimental method. Adding BNP had no obvious effect on the current signal of the PEC immunosensor, indicating that it had good specificity. To test the stability of the PEC immunosensor, the light was repeatedly switched on and off 18 times in 400 s to detect the photocurrent. The experimental results are shown in Figure 5E. The relative standard deviation (RSD) was 0.047, and the coefficient of variation (CV) was 4.7% relative to the stability experiment. The difference between the timing current after 18 on/off cycles and the initial timing current was very small, indicating that the PEC immunosensor has good operational stability. In addition, seven sensors were stored in a refrigerator at 4 °C for five days, and the results showed that the current value of the immunosensor changed by less than 4%, indicating that the sensor has good storage stability. To study the potential application significance of the proposed PEC immunosensor for PCT determination, the standard addition recovery tests were implemented. Before that, we conducted pre-treatment for serum samples, including low-speed centrifugation at 4 °C, removing sediments, and using the supernatant for testing. As shown in Table S2, the recoveries were in the range of 86~101%, and the RSD was in the range of 3.1~4.1%, indicating great reference significance for clinical PCT detection.

4. Conclusions

In this work, since the complex of Bi2S3/Ag2S has excellent photoelectric performance, it was used as the base material to construct the PEC immunosensor. In addition, anti-PCT, BSA, and PCT were successively deposited on the Bi2S3/Ag2S/ITO surface. The novel unmarked PEC immunosensor was constructed successfully and achieved the highly sensitive detection of PCT in human serum. Under the optimal experimental conditions, the linear range of the PEC immunosensor for PCT detection was 0.5 pg mL−1~50.0 ng mL−1, and the detection limit was as low as 0.18 pg mL−1. Moreover, the PEC immunosensor showed admirable stability, selectivity, and reproducibility. This could provide a theoretical basis and reference value for the clinical application of semiconductor materials in the field of disease marker detection.

Supplementary Materials

The following supporting information [8,32,33,34,35,36] can be downloaded at https://www.mdpi.com/article/10.3390/bios13030366/s1: Materials; Apparatus; Figure S1: The XRD of Bi2S3; Figure S2: The EDS mapping images of Bi2S3/Ag2S composites; Table S1: Comparison of the performance of the proposed and reference methods for PCT detection; Table S2: The results of the PCT determination in human serum samples.

Author Contributions

Conceptualization, G.Z., N.Z. and Y.W. (Yaoguang Wang); methodology, G.Z., Y.W. (Yingying Wang) and H.W.; software, G.Z.; validation, Y.W. (Yaoguang Wang) and N.Z.; formal analysis, G.Z. and G.B.; investigation, G.Z.; resources, Y.W. (Yaoguang Wang); data curation, G.Z.; writing—original draft preparation, G.Z.; writing—review and editing, G.Z., N.Z. and Y.W. (Yaoguang Wang); visualization, G.Z.; supervision, Y.W. (Yaoguang Wang), N.Z. and Q.W.; project administration, Y.W. (Yaoguang Wang) and N.Z.; funding acquisition, Y.W. (Yaoguang Wang) and N.Z. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Natural Science Foundation of China (Nos. 22006080, 22274062), the Shandong Provincial Natural Science Foundation (Nos. ZR2021YQ07, ZR2020QB094, ZR2020QB097), and the Program for Scientific Research Innovation Team in Colleges and Universities of Shandong Province.

Data Availability Statement

The data presented in this study are available upon request from the corresponding authors.

Conflicts of Interest

The authors declare no conflict of interest.

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Scheme 1. Schematic diagram of the PEC sensor’s construction.
Scheme 1. Schematic diagram of the PEC sensor’s construction.
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Figure 1. SEM images (A,B) of Bi2S3 with different magnification; SEM diagrams (C,D) of Bi2S3/Ag2S under InLens and BSE detectors, respectively; Energy spectrum analysis (EDS) diagram (E) of Bi2S3/Ag2S; Ultraviolet–visible (UV–vis) near-infrared absorption spectra (F) of Bi2S3 (a) and Ag2S (b).
Figure 1. SEM images (A,B) of Bi2S3 with different magnification; SEM diagrams (C,D) of Bi2S3/Ag2S under InLens and BSE detectors, respectively; Energy spectrum analysis (EDS) diagram (E) of Bi2S3/Ag2S; Ultraviolet–visible (UV–vis) near-infrared absorption spectra (F) of Bi2S3 (a) and Ag2S (b).
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Figure 2. The electron transfer mechanism of the PEC immunosensor.
Figure 2. The electron transfer mechanism of the PEC immunosensor.
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Figure 3. The electrochemical impedance spectroscopy (EIS) (A) and the chronoamperogram (B) of the photoelectrochemical immunosensor: (a) ITO; (b) Bi2S3/ITO; (c) Ag2S/Bi2S3/ITO; (d) TGA/Ag2S/Bi2S3/ITO; (e) EDC/NHS/TGA/Ag2S/Bi2S3/ITO; (f) anti-PCT/EDC/NHS/TGA/Ag2S/Bi2S3/ITO; (g) BSA/anti-PCT/EDC/NHS/TGA/Ag2S/Bi2S3/ITO; (h) PCT/BSA/anti-PCT/EDC/NHS/TGA/Ag2S/Bi2S3/ITO.
Figure 3. The electrochemical impedance spectroscopy (EIS) (A) and the chronoamperogram (B) of the photoelectrochemical immunosensor: (a) ITO; (b) Bi2S3/ITO; (c) Ag2S/Bi2S3/ITO; (d) TGA/Ag2S/Bi2S3/ITO; (e) EDC/NHS/TGA/Ag2S/Bi2S3/ITO; (f) anti-PCT/EDC/NHS/TGA/Ag2S/Bi2S3/ITO; (g) BSA/anti-PCT/EDC/NHS/TGA/Ag2S/Bi2S3/ITO; (h) PCT/BSA/anti-PCT/EDC/NHS/TGA/Ag2S/Bi2S3/ITO.
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Figure 4. Optimal concentrations of Bi2S3 (A), AgNO3 (B), and AA (D); pH (C); photocurrent intensity (E). Error bar = SD (n = 5).
Figure 4. Optimal concentrations of Bi2S3 (A), AgNO3 (B), and AA (D); pH (C); photocurrent intensity (E). Error bar = SD (n = 5).
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Figure 5. Photocurrent response curves (A) and the linearity correction curve (B) of the PEC immunosensor at different PCT concentrations: (a) 0.0005, (b) 0.001, (c) 0.005, (d) 0.01, (e) 0.1, (f) 0.5, (g) 1.0, (h) 10, (i) 30, (j) 50 ng mL−1. Photocurrent curve of unknown PCT concentration (C): the mixture of PCT with concentrations of (a) 0.1 ng mL−1 and 0.5 ng mL−1, (b) 0.01 ng mL−1 and 0.005 ng mL−1. The specificity of the constructed immunosensor (D): (a) blank, (b) blank + 100 ng mL−1 BNP, (c) 0.50 ng mL−1 PCT, (d) 0.50 ng mL−1 + 100 ng mL−1 BNP. Stability evaluation of the photoelectric chemical immunosensor under multiple on/off irradiation cycles for 400 s (E). Error bars = SD (n = 5).
Figure 5. Photocurrent response curves (A) and the linearity correction curve (B) of the PEC immunosensor at different PCT concentrations: (a) 0.0005, (b) 0.001, (c) 0.005, (d) 0.01, (e) 0.1, (f) 0.5, (g) 1.0, (h) 10, (i) 30, (j) 50 ng mL−1. Photocurrent curve of unknown PCT concentration (C): the mixture of PCT with concentrations of (a) 0.1 ng mL−1 and 0.5 ng mL−1, (b) 0.01 ng mL−1 and 0.005 ng mL−1. The specificity of the constructed immunosensor (D): (a) blank, (b) blank + 100 ng mL−1 BNP, (c) 0.50 ng mL−1 PCT, (d) 0.50 ng mL−1 + 100 ng mL−1 BNP. Stability evaluation of the photoelectric chemical immunosensor under multiple on/off irradiation cycles for 400 s (E). Error bars = SD (n = 5).
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MDPI and ACS Style

Zhao, G.; Wang, Y.; Wang, H.; Bai, G.; Zhang, N.; Wang, Y.; Wei, Q. Ultrasensitive Photoelectrochemical Immunoassay Strategy Based on Bi2S3/Ag2S for the Detection of the Inflammation Marker Procalcitonin. Biosensors 2023, 13, 366. https://doi.org/10.3390/bios13030366

AMA Style

Zhao G, Wang Y, Wang H, Bai G, Zhang N, Wang Y, Wei Q. Ultrasensitive Photoelectrochemical Immunoassay Strategy Based on Bi2S3/Ag2S for the Detection of the Inflammation Marker Procalcitonin. Biosensors. 2023; 13(3):366. https://doi.org/10.3390/bios13030366

Chicago/Turabian Style

Zhao, Guanhui, Yingying Wang, Huixin Wang, Guozhen Bai, Nuo Zhang, Yaoguang Wang, and Qin Wei. 2023. "Ultrasensitive Photoelectrochemical Immunoassay Strategy Based on Bi2S3/Ag2S for the Detection of the Inflammation Marker Procalcitonin" Biosensors 13, no. 3: 366. https://doi.org/10.3390/bios13030366

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