1. Introduction

Sulfur dioxide (SO₂), as one of the most serious atmospheric pollutants, can enter the living organisms through the respiratory system and then can be turned into sulfite (SO₃²⁻)/bisulfate (HSO₃) in aqueous [1,2,3]. Although these endogenous derivatives in organisms have some functions for relaxing the vascular smooth muscle and resisting oxidation [4,5,6], SO₂ could cause diseases in the respiratory system, the nervous system and the cardiovascular system, such as strokes, asthmatic attacks, migraine headaches, allergic reactions and ischemic heart diseases [7,8,9,10]. Considering the relationship between SO₂ and the above-mentioned potential health problems, many countries have enforced strict regulations of the concentrations of SO₃²⁻/HSO₃⁻ in food, beverages and medicine. Therefore, effective analytical methods were developed to test the SO₃²⁻/HSO₃⁻ concentrations in vitro and in vivo, which is essential for the accurate determination of the biological activity of SO₂ derivatives [11,12].

Compared with traditional detection methods like titration [13], electrochemistry [14,15] and capillary electrophoresis [16,17], fluorescent probes have strengths in operation, sensitivity and selectivity, and can be applied in real-time bioimaging in vivo. Fluorescent probes based on the (E)-1,1,3-trimethyl-2-styryl-1H-benzo[e]indol-3-ium platform are popular because of their strong fluorescence, good water solubility and relatively large Stokes shift. For example, based on the skeleton (E)-1,1,3-trimethyl-2-styryl-1H-benzo[e]indol-3-ium with acetyl substitution, a probe reported by Zhou et al. can usefully test carboxylesterase [18]. Nowadays, there are some fluorescent probes based on different reaction mechanisms to detect SO₃²⁻/HSO₃⁻, such as 1,4-Michael addition [19,20,21,22], nucleophilic 1,2-addition [11,23] and deprotection of levulinate [24]. However, most fluorescent probes were based on limitedly single fluorescence changes, which will be influenced due to fluctuations in the system and the probe’s concentration. For example, a probe reported by Yu et al. can usefully test SO₃²⁻/HSO₃⁻, but a single fluorescence change was used, which limited its use [25]. While the ratiometric fluorescent probes can gain more accurate results for its capacity to detect fluorescence emission/excitation intensities at two different wavelengths [26,27]. Therefore, compared with the single fluorescent probes, it is evitable for the ratiometric fluorescent probes to be influenced by the environmental changes [28]. Based on the ratiometric fluorescent probes, a probe with CF₃ substitution reported by Sun et al. can usefully test SO₃²⁻/HSO₃⁻, but the probe also reacted with CN⁻, which was a low selectivity for its practical applications [19]. In order to develop new fluorescent probes for SO₃²⁻/HSO₃⁻ detection [29], we paid more attention to developing a ratiometric probe that could satisfy the practical applications.

On account of the ideas above, we first developed a novel ratiometric fluorescent probe EB (E)-3-ethyl-2-(4-hydroxystyryl)-1,1-dimethyl-1H-benzo[e]indol-3-ium iodide for sensing SO₃²⁻/HSO₃⁻ (Scheme 1), which is based on the nucleophilic reaction between SO₃²⁻/HSO₃⁻ and the C=C bond. The 3-ethyl-1,1,2-trimethyl-1H-benzo[e]indol-3-ium iodide (the hemicyanine part) and 4-hydroxybenzaldehyde were used to synthesize the probe as the intramolecular charge transfer (ICT) donor and the acceptor respectively [30,31]. The hemicyanine was proved to be the effective fluorophores in designing fluorescent chemosensors, which had a blue fluorescence with high quantum efficiency and the chemical stability [20,32,33,34]. After the specific 1,4-addition reaction of SO₃^2–/HSO₃^– with the vinyl group of probe EB (Scheme 1), the structure of probe EB was destroyed by SO₂ derivatives. Therefore, because of the obvious emission between probe EB and the hemicyanine derivative, we could detect two well-resolved emission bands before and after addition of SO₃^2–/HSO₃^–. Thus, we could observe significant changes in the UV-Vis absorption spectra and fluorescence spectra and make the colorimetric and fluorogenic detection of SO₃⁻/HSO₃²⁻ possible. Scheme 2 showed the synthesis route of probe EB and the structure of probe EB was confirmed by ¹H-NMR, ¹³C-NMR and MS (Figures S1–S3). What’s more, the probe showed excellent characteristics including the large hypsochromic shift, the ultrafast response time (within 60 s), high sensitivity (a detection limit of 28 nM), low cytotoxicity and excellent selectivity of SO₂ derivatives over other anions and biothiols. Additionally, it could effectively monitor SO₂ derivatives and successfully applied in real samples and living cells.

2. Results and Discussion

2.1. UV-Vis and Fluorescence Spectra for Sulphite Detection

First, the UV-Vis absorption spectra of the probe were detected in PBS solution (pH = 7.4). As shown in Figure 1a, the UV-Vis absorption of probe EB showed an intense absorption peak at 510 nm, while the absorbance at 510 nm decreased dramatically after it had reacted with 500 µM SO₃²⁻. At the same time, there was a significant color change: the obvious pink color of solution faded to colorless (Figure 1a and Figure 1a inset), which suggested that a naked-eye colorimetric method could be used expediently to detect SO₃²⁻/HSO₃⁻. Next, due to the strong intramolecular charge transfer (ICT), probe EB (10 μM) showed a strong fluorescence peak at 570 nm (excitation at 485 nm), while with the increase of SO₃²⁻(0–500 μM), the fluorescence emission band decreased dramatically at 570 nm (Figure 1b) and a new emission band simultaneously increased at 473 nm (excitation at 380 nm) (Figure 1c). The fluorescent quantum yield (Φ = 0.029) of probe EB at 570 nm and the fluorescent quantum yield (Φ = 0.537) of probe EB after reaction with 500 μM SO₃²⁻ at 473 nm has also been determined, with Rhodamine B as a reference. These changes were attributed to the transformation of the conjugated structure of the probe by reacting with SO₃²⁻/HSO₃⁻. What’s more, there was a linear correlation between the fluorescence intensity ratios (I₄₇₃/₅₇₀) and the concentration of SO₃²⁻ ranging from 0 to 60 µM (Figure 1d). According to the signal to noise ratio (S/N = 3), the limit of detection came out to be 28 nM, suggesting probe EB could be applied to detect traces of SO₃²⁻ under environmental or biological conditions.

2.2. The Selective Response of Probe to Sulfite

The excellent selectivity of the probe played an essential role in practical application. In order to illustrate its anti-interference ability, we detected the fluorescence changes of probe EB (10 μM) with 500 μM other anions after 3 min, which aimed to prove no interference of the most common anions and biological thiols in the environment, including CO₃²⁻, HCO₃⁻, Ac^-, PO₄³⁻, HPO₄²⁻, H₂PO₄⁻, Cl⁻, Br⁻, I⁻, NO₂⁻, S²⁻, SO₄²⁻, Hcy, Cys and GSH. As shown in Figure 2 (black), even 50 equivalents of the other species did not respond to the fluorescence ratio I₄₇₃/₅₇₀, but S²⁻ led to a slight increase of the fluorescence ratio I₄₇₃/₅₇₀, which may be influenced by the nucleophilicity of S²⁻. Meanwhile, in Figure 2 (red), the competition experiments meant that other analytes did not influence on detecting SO₃²⁻ (500 μM). The results showed great selectivity of probe EB towards SO₃²⁻, which indicated the excellent ability in the further application.

2.3. Time-Dependence and pH-Dependence in the Detection Process of Sulfite

Time and pH are the pivotal factors, which could affect the application of the probe. Thus, with 500 μM SO₃²⁻, we detected the fluorescent ratio (I₄₇₃/₅₇₀) changes of probe EB (10 μM) in different times (1–10 min) (Figure 3a). It showed that the fluorescent ratio (I₄₇₃/₅₇₀) of the probe tends to be stable in 1 min with the reaction of SO₃^2- (Figure 3a), implying the probe could act as a “fast response” fluorescent probe for SO₃²⁻ detection and may be used to timely sense SO₃²⁻ in living cells. Furthermore, the effect of pH on the fluorescent ratio (I₄₇₃/₅₇₀) of the probe to SO₃²⁻ was investigated ranging from pH 3 to 10. The fluorescent ratio (I₄₇₃/₅₇₀) of the probe was 0 without SO₃²⁻ when the pH ranged from 3 to 10 (Figure 3b), suggesting the probe kept stable within a broad pH range. By adding SO₃²⁻, the fluorescent ratio (I₄₇₃/₅₇₀) of the probe increased rapidly to the peak at pH 8 and then dropped modestly, which indicated that in the normal physiological ranges (pH = 7.4), the probe could reliably detect SO₃²⁻/HSO₃⁻.

As described above, the probe displayed excellent analytical property comparing with some other fluorescent probes of recent reports for the detection of SO₃²⁻/HSO₃⁻. The comparison data are listed in Table S1, indicating that the probe is promising for practical analysis.

2.4. Reaction Mechanism

In order to monitor the reaction mechanism, ESI-MS was used to inspect the reaction between probe EB and SO₃²⁻. In the ESI-MS spectrum (Figure 4), the main peak at m/z = 342.34 was assigned to probe EB (calculated: [C₂₀H₂₄NO]⁺, 342.18). When Na₂SO₃ (10.0 equiv.) was added, the peak corresponds to probe-SO₃^2- appeared at m/z = 446.16 (calculated: [C₂₄H₂₄NNaO₄S + H]⁺, 446.13). On the basis of the above experiment results, the reaction mechanism of probe EB with SO₃²⁻ was proposed and illustrated in Scheme 1, and it follows a 1,4-nucleophilic addition reaction of SO₃²⁻ to the vinyl group of probe EB.

2.5. Sulfite Detection in Real Samples

In order to verify the practicability of the probe, we firstly investigated the sulfite levels in real samples by using probe EB, including tap water, river water, sugar water and chrysanthemum, which were dissolved and diluted in PBS solution (pH 7.4) into consistency for analysis. For comparison, a traditional titration method was used as validation. Two methods obtained almost consistent results (Table 1), which proved the practicability of probe EB. In addition, based on the above results, a standard addition method was used to detect sulfite in these real food samples. Adding an exact amount of SO₃²⁻ (25, 50 and 100 μM) to the diluted sample, the I₄₇₃/₅₇₀ fluorescent ratio was measured. Excellent recovery ranged from 95.9% to 107.7% was observed in Table 1, suggesting the probe was practical and reliable for detecting sulfite in real samples.

2.6. Fluorescence Imaging in Living Cells

The application of the probe for cell bioimaging was studied based on the results above. Cytotoxicity experiment was firstly incubated in HepG2 cells using Cell Counting Kit-8 (CCK8), and as shown in Figure 5, the survival rate of HepG2 cells was about to reach 90 % after incubating with 100 μM probe EB for 24 h, which suggested that the probe has low cytotoxicity for application in living cells.

To verify the biological applications of the probe, we tried to explore potentialities about detecting SO₃^2– in living cells. Firstly, we incubated the HepG2 with various concentrations of SO₃^2– (0, 10, 20, 50, 100, 200 μM) for 2 h. After that quantitative probe (10 μM) was added into all cell groups waiting for 2 h, and monitoring tests were operated by the confocal laser-scanning microscopy. HepG2 cells showed a clear red profile after the incubation with probe (10 μM) for 2 h (Figure 6a), which suggested that the probe EB could permeate into HepG2 cells. While HepG2 cells were incubated with different concentrations of SO₃^2– (0, 10, 20, 50, 100, 200 μM) for 2 h beforehand and then incubated with the probe EB. After 2 h, the fluorescence in the blue channel enhanced with the concentration of SO₃²⁻ raised, but the fluorescence under the red channel degraded (Figure 6a–f). Finally, the HepG2 cells (Figure 6f) displayed strong blue fluorescence and weak red fluorescence. Therefore, the probe EB could be employed for the SO₃²⁻ fluorescence imaging in living cells.

3. Materials and Methods

3.1. Materials and Instrumentation

The chemistry reagents (chemical grade) used in experiments was obtained from Sino Pharm Chemical Reagent Co. Ltd. (Shanghai, China). The real samples river water and tap water were obtained from the Shanghai University of Traditional Chinese Medicine, and sugar was purchased from a local supermarket (Shanghai, China). The chrysanthemum was purchased from Shanghai Kangqiao Chinese Medicine, grown in HangZhou, China. The analytical thin-layer chromatography (TLC) with pre-coated silica gel GF254 plates (Sino Pharm Chemical Reagent Co. Ltd., Shanghai, China) was used to detect any spots at 254 nm under UV light. ¹H-NMR and ¹³C-NMR spectra were measured at 25 °C and referenced to tetramethyl silane (TMS) by a BRUKER AVANCE III spectrometer (Bruker, German). Electron ionization mass spectra (ESI-MS) was recorded on an Agilent 6460 triple quad LC-MS mass spectrometer (Agilent, Santa Clara, CA, USA). UV-Vis spectra and fluorescence spectra were recorded by Agilent 8454 UV-Vis spectrometer (Agilent) and Agilent G9800A fluorescence spectrophotometer (Agilent) respectively. Leica TCS-SP8 multiphoton illustrated the fluorescence images with the confocal microscope having a 63 × oil-immersion objective lens (Leica, Wetzlar, German).

3.2. Preparation of Probe EB

In a two-neck round-bottom flask, compound 1, 3-ethyl-1,1,2-trimethyl-1H-benzo[e]indol-3-ium iodide (200.0 mg, 0.55 mM) and anhydrous ethanol (20 mL) were added. Subsequently, compound 2, 4-hydroxybenzaldehyde (66.9 mg, 0.55 mM) was added to the mixture. This mixture reacted at 80 °C for 12 h. Then, the solution was disposed in a rotary vacuum desiccator and the solid was extracted with CH₂Cl₂/H₂O. The organic layer was collected and dried via anhydrous Na₂SO₄. The crude product was purified with the CH₂Cl₂/MeOH eluent using the silica-gel column, see Supplementary Materials. Yield: 220 mg (87%). ESI/MS m/z: 342.34 [M]⁺; ¹H-NMR (600 MHz, DMSO-d₆) δ 10.86 (s), 8.52 (d, J. = 16.1 Hz), 8.42 (d, J. = 8.5 Hz), 8.30 (d, J. = 8.9 Hz), 8.25 – 8.16 (m), 8.12 (d, J. = 8.9 Hz), 7.81 (t, J. = 7.6 Hz), 7.72 (t, J. = 7.5 Hz), 7.53 (d, J. = 16.2 Hz), 7.00 (d, J. = 8.7 Hz), 4.90 – 4.72 (m), 2.03 (s), 1.50 (t, J. = 7.2 Hz). ¹³C-NMR (150 MHz, DMSO-d₆) δ 196.44, 138.68, 137.51, 133.51, 131.20, 130.21, 128.89, 127.76, 127.73, 123.90, 113.66, 55.94, 43.80, 21.95, 14.10.

3.3. Preparation of Solutions and Spectra Measurements

The probe was dissolved in ethyl alcohol to prepare the 1 mM stock solution. The anion and amino acid solution such as CO₃²⁻, HCO₃⁻, Ac^-, PO₄³⁻, HPO₄²⁻, H₂PO₄⁻, Cl⁻, Br⁻, I⁻, NO₂⁻, S²⁻, SO₄²⁻, Hcy, Cys, GSH and SO₃²⁻ were all prepared by corresponding saline solution in purified water (10 mM). A small amount of stock probe EB (10 μM) and SO₃²⁻ (500 μM) were transferred to a 5 mL volumetric flask, diluted with PBS (pH = 7.4) to volume as the test solution at room temperature, which was prepared to measure fluorescent spectra and UV-Vis absorption. The test solution should be shaken well and detected after 3 min. The same volume of SO₃²⁻ solution could be replaced by various anion solutions mentioned above to detect interference using the same condition of spectra.

3.4. Measurements of Sulfite in Real Samples

Four kinds of samples: tap water, river water, sugar and chrysanthemum were prepared to detect sulfite respectively. Sugar and River water were diluted with PBS to a concentration of around 25 % (pH = 7.4) as the diluent solution. And the chrysanthemum sample was extracted with PBS solution (pH = 7.4) as the test solution (0.5 g/100 mL). Then transferred stock probe solution (10 μM) to a 5 mL volumetric flask, diluted with the diluent solution to volume. Incubated for 5 min at room temperature before detection. By the way, the recovery test also needed to add accurate SO₃²⁻ (25, 50 or 100 μM) in water samples. Then, the emission intensities at 473 nm and 570 nm were detailed and the analysis results were also compared with that achieved by the titration method.

3.5. Methods for Fluorescent Quantum Yield

The fluorescent quantum yields of probe EB and probe EB after reaction with SO₃²⁻ were detected using Rhodamine B (Φs = 0.89 in ethanol) as a standard. The Fluorescent quantum yields were determined based on the Equation:

Φ_a = Φ_st × (F_a/F_st) × (A_st/A_a) × (η_a/η_st)²

3.6. Limit of Detection

The detection limit (LOD) was calculated based on the fluorescence titration of the probe (10 μM) in the presence of SO₃²⁻. The fluorescence intensity ratio of the probe was measured and the standard deviation of the blank measurement was achieved. The limit of detection was calculated according to the following formula: LOD = 3σ/k

LOD: detection limit; σ: the standard deviation of the fluorescence intensity ratio (I₄₇₃/I₅₇₀) of the probe scanning for 10 times; k: the slope of the line graph of fluorescence intensity ratio (I₄₇₃/I₅₇₀) and reactant concentration.

3.7. Cell Culture and Fluorescence Imaging

HepG2 cells came from the Chinese Academy of Sciences. The cells were cultured in Dulbecco’s modified Eagle’s medium (DMEM) added with 1% Penicillin-Streptomycin Solution (100×), 10% fetal bovine serum (FBS) at 37 °C under the atmosphere containing 5% CO₂. Then transferred cells to confocal dishes and waited for 24 h to keep adaption.

To inspect the sensitivity of the probe, cells were incubated in 10 μM probe for 2 h at 37 °C with culture medium (90% DMEM, 10% FBS). To detect exogenetic sulfite, cells were pretreated with different concentrations of SO₃²⁻ (0–200 μM) at 37 °C for 2 h and then incubated with the probe (10 μM) for 2 h. Before the detection achieved by the apparatus of Fluorescence Microscope and a 63× oil-immersion objective lens (Leica), cells needed to be washed by PBS for three times. The cells were stimulated by the intensity of wavelengths at 405 nm, 488 nm, and collected emission on 450–490 nm, 550–590 nm.

4. Conclusions

On the basis of the Michael addition reaction, we developed a new ratiometric fluorescent probe EB for SO₃²⁻/HSO₃⁻ detection under physiological pH, which exhibited a colorimetric and ratiometric response to SO₃²⁻/HSO₃⁻. It could demonstrate a quick response, high sensitivity and selectivity to SO₃²⁻/HSO₃^– in aqueous solution and real samples. The sensing mechanism of the interaction between the probe and SO₃²⁻/HSO₃⁻ was verified using ESI-MS. Moreover, it exhibited the excellent application of detecting SO₂ derivatives in living cells with low cytotoxicity. All the results suggested this safe and harmless probe could be used conveniently.

Supplementary Materials

The following are available online. Figure S1. ¹H-NMR spectrum of the probe in DMSO-d₆; Figure S2. ¹³C-NMR spectrum of compound the probe in DMSO-d₆; Figure S3. Mass spectrum of compound the probe. Table S1: Comparison of the probe for the detection of SO₃²⁻/HSO₃⁻.

Author Contributions

Conceived and designed the experiments: Y.D. and J.-S.L. Performed research and analyzed the data: X.-Y.J., Y.-H.Q., T.W., Y.-F.Q., J.-Y.G., A.A., K.-X.S., W.-Y.K. and B.-Y.H.; Wrote the paper: X.-Y.J., T.Z. and Y.-H.Q. All authors read and approved the final manuscript.

Funding

This work was supported by programs of the National Natural Science Foundation of China [81872981]; National Scientific and Technological Major Special Project of China [2019ZX09201004-002]; Program of Shanghai Academic/Technology Research Leader [18XD1403700]; Youth Talent Sail Plan from the Shanghai Committee of Science and Technology [18YF1423600]; Project of the Shanghai Municipal Commission of Health and Family Planning [2017YQ072 and 201740152]; Projects sponsored by the development fund for Shanghai talents [2018105]; Undergraduate innovation project from Shanghai University of traditional Chinese Medicine [grant number 2019SHUTCM145] and Xinglin Young Talent Program.

Conflicts of Interest

The authors declare no conflict of interest.

Footnotes

Sample Availability: Not available.

Figures, Schemes and Table

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Scheme 1. Probe EB as a new ratiometric fluorescence probe for sensing of sulfite/bisulfite.

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Scheme 2. Synthesis of probe EB.

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Figure 1. (a) UV-Vis absorption spectra changes and (b–c) fluorescence spectra changes of the probe EB (10 µM) in PBS solution (pH 7.4) with increasing amount of SO32− (0–500 µM). For (b) λex = 485 nm slits: 10.0/10.0 nm; for (c) λex = 380 nm slits: 5.0/5.0 nm. (d) Linear correlation between the emission intensity ratio (I473/I570) and the concentration of SO32−.

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Figure 2. Fluorescence intensity of probe EB (10 μM) in PBS solution (pH 7.4) upon addition of various reactive sulphur and other anions (500 μM). 1. CO32−, 2. HCO3−, 3. Ac−, 4. PO43−, 5. HPO42−, 6. H2PO4−, 7. Cl−, 8. Br−, 9. I−, 10. NO2−, 11. S2−, 12. SO42−, 13. Hcy, 14. Cys and 15. GSH, 16. SO32−. For λex = 380 nm, λem = 473 slits: 5.0/5.0 nm; for λex = 485 nm, λem = 570 nm slits: 10.0/10.0 nm.

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Figure 3. (a): Effect of time on the I473/I570 fluorescence intensity ratio of probe EB (10 μM) in PBS solution (pH = 7.4) upon addition of 500 μM SO32−; (b): Effect of pH on the I473/I570 fluorescence intensity ratio of probe EB (10 μM) and probe EB upon addition of 500 μM SO32−.

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Figure 4. Mass spectrum of probe EB and the crude product of the probe with SO32−. (a) Probe EB in MeOH. (b) Probe EB with Na2SO3 in MeOH: H2O (1:1).

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Figure 5. CCK8 assay of HepG2 cells incubated in the probe EB (0–100 μM) at 37 °C for 24 h.

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Figure 6. Imaging of SO32− in HepG2 cells by the probe. The cells were stained with (a) 10 μM probe EB for 2 h; (b) 10 μM SO32− for 2 h, 10 μM probe EB for 2 h; (c) 20 μM SO32− for 2 h, 10 μM probe EB for 2 h; (d) 50 μM SO32− for 2 h, 10 μM probe EB for 2 h; (e) 100 μM SO32− for 2 h, 10 μM probe EB for 2 h; (f) 200 μM SO32− for 2 h, 10 μM probe EB for 2 h; Blue channel: λex = 405 nm; λem = 450–490 nm; Red channel: λex = 488 nm; λem = 550–590 nm.

Determination of SO₃²⁻ in water samples using the probe EB.

^a In the detection solutions, the concentration of sugar was 5.0 g/100 mL (pH 7.4); the River water was diluted 3 times with PBS solution (pH 7.4); the chrysanthemum sample was extracted with PBS solution (pH = 7.4) as the test solution (0.5 g/100 mL).By means of the three measurements(n = 3), we obtained the standard derivations. ^b Analysis for SO₃^2- in water samples determined by the fluorescent probe. ^c Analysis for SO₃²⁻ in water samples determined by a traditional titration method.