3.1 Photoinduced degradation of venlafaxine
The absorption spectrum of venlafaxine and the emission spectrum of the UV lamp are given in the supplemental information, cf. Figure S1. The emission band at 254 nm coincides with an absorption band of venlafaxine, indicating the potential for photo-excitation and subsequent direct degradation. Normalized concentration-time curves, i.e. mass area vs. irradiation time, of photoinduced degradation of venlafaxine are presented in Fig. 2. The thus derived rate constants and the corresponding half-lives are collected in Table S1 in the supplemental information. The presence of hydrogen peroxide accelerated the decomposition, whereas the radical scavenger tert-butanol exercised strong deceleration.
While the addition of hydrogen peroxide augments the occurrence of hydroxyl radicals, a too large excess of hydrogen peroxide, as was the case with 30 mg/L, did not significantly increase the degradation velocity since recombination side reactions would occur. This is referred to as supersaturation (Sun and Bolton 1996; Parsons 2004; Homem and Santos 2011; Voigt and Jaeger 2017). The comparison between the degradation in ultra-pure water and the degradation after addition of 5 mg humic acid is interesting. The majority of degradation experiments in various studies was carried out under laboratory conditions in ultra-pure water. The addition of 5 mg humic acid was found to represent the water matrix of surface water (data not shown). Humic acid reduced the degradation velocity. This might be due to the radical scavenging properties or light absorption of humic acid thus reducing in both cases the amount of hydroxyl radicals. Further to diminishing the amount of radiation available for venlafaxine decomposition induction, humic acid itself was found to degrade upon irradiation (Tang et al. 2020). It can therefore be assumed that venlafaxine may degrade more slowly in natural or effluent waters when applying AOPs. Supersaturation also occurred upon addition of tert-butanol. Yet, tert-butanol itself decomposes upon UV irradiation. Hence, hydroxyl radicals were less scavenged and degradation of venlafaxine, albeit to a lesser extent, was observed. Taking the absorption spectrum into account, the degradation could also be due to a contribution of the direct mechanism. As the addition of substances with radical scavenging properties reduced the degradation velocity, the indirect mechanism was nevertheless assumed the dominant mechanism. At this stage, a contribution from the direct mechanism cannot be excluded. To address this issue, identification, structure elucidation and quantitative estimation of the transformation products were employed, since products from the two pathways should be different and may be specific for the two pathways.
3.2 Photoinduced transformation products of venlafaxine
The photo-induced transformation products were investigated using higher-order mass spectrometry after chromatographic separation. The observed and identified transformation products are collected in Table 1.
A total of eight products were identified in ultra-pure water under UV irradiation, two of which have not yet been described in previous studies. Upon addition of 30% tert-butanol, no transformation products were observed above a 1% threshold with respect to the initial substance. This fact was taken indicative that products were formed via the indirect path, and thus the dominance of the hydroxyl radical induced mechanism was evident. Inspecting the proposed structures, it can be recognized that hydroxyl groups were accumulated in the molecule, which is consistent with the indirect mechanism. No products point to the direct absorption pathway.
In the MS/MS spectra, all except product V278 showed the fragment with m/z = 58.0652 ± 0.001. This was interpreted as the dimethylamine fragment of venlafaxine, which remained stable. For V278, a methyl group was substituted by a hydroxyl group prohibiting the observation of the dimethylamine fragment. Another frequently observed fragment was characterized by m/z = 121.0649 ± 0.001. This was assigned to 1-methoxy-4-methylbenzene.
Giannakis et al. proposed different structures for observed ions in their study (Giannakis et al. 2017). These corresponded to isomers of V194, V292 and V310. García-Galán et al. and Osawa et al observed o-desmethylvenlafaxine and further isomers of V274, V278, V292, V294 and V310 (García-Galán et al. 2016; Osawa et al. 2019). In all studies, MS/MS spectra were recorded, such that structure interpretation support the occurrence of different isomers.
The products V294a and V294b had the same m/z ratios and appeared at different retention times. This observation suggested isomers, which can be traced back to different substitution positions of hydroxyl groups leading to different polarities of the products. For more detailed identification, MSn spectra were applied. Yet, identical fragments were observed. It was hence assumed that the hydroxyl group was located at the aromatic ring. The exact position however could not be determined for either isomer.
The compounds of Fig. 3 exhibited a prolonged formation in ultra-pure water in the presence of tert-butanol. They reached a maximum of 0.5% of the initial compound concentration after 10 minutes of UV irradiation. Figure 3 shows the corresponding normalized concentration-time graphs in the presence of 10% tert-butanol.
The product formation proceeded approximately linear in analogy to the degradation of venlafaxine, cf. Figure 2. The course was interpreted as tert-butanol decomposing and hydroxyl radical concentration increasing after 10 min of irradiation. Hence, the concentration of the indirectly formed products increased slowly.
As preliminary conclusion, photoinduced degradation of venlafaxine occurred exclusively via the indirect mechanism. There were no indications for the direct degradation mechanism. Thus, the formation of hydroxyl radicals in water will have a great influence on degradation and product formation. The application of EAOP and the mechanistic comparison will be discussed in the following.
3.3 Electrochemical oxidation
The electrochemical oxidation of venlafaxine under various conditions was monitored using HPLC-HRMS. The resulting exposure time-dependent mass-areas were normalized and plotted as normalized concentration-time curves. They are displayed in Fig. 4.
All concentration-time curves obtained were best described according to first-order kinetics in agreement with previous studies (Pipi et al. 2014; Turabik et al. 2014; Jum’H et al. 2018). Compared to the photoinduced degradation experiments, total degradation was achieved after about six hours, while photoinduced degradation was nearly completed after 10 min. The degradation was accelerated on addition of sulfate and chloride ions well as hydrogen peroxide. The addition of humic acid also showed an accelerating effect. Quantitative comparison was achieved via the rate constants and their corresponding half-lives as given in Table 2.
Table 2
Conductivity of the venlafaxine matrix solution, rate-constants k and corresponding half-lives t0.5 of venlafaxine for electrochemical oxidation.
pH-Value
|
pH adjusting adjusted by:
|
tert-butanol /%
|
H2O2
/ mg L− 1
|
k /min− 1
|
t0.5 /min
|
conductivity /µS cm− 1 @20°C
|
3
|
formic acid
|
0
|
0
|
1.12E-02
|
62.00
|
218
|
6
|
-
|
0
|
0
|
8.84E-03
|
78.39
|
7.1
|
9
|
ammonia
|
0
|
0
|
1.43E-02
|
48.44
|
55.6
|
3
|
sulfuric acid
|
0
|
0
|
1.88E-02
|
36.89
|
752
|
3
|
hydrochloric acid
|
0
|
0
|
2.75E-02
|
25.18
|
303
|
3
|
Humic acid and formic acid
|
0
|
0
|
2.52E-02
|
27.55
|
370
|
3
|
formic acid
|
10
|
0
|
9.11E-03
|
76.09
|
170
|
3
|
formic acid
|
30
|
0
|
8.21E-03
|
84.43
|
194
|
3
|
formic acid
|
0
|
10
|
2.30E-02
|
30.20
|
226
|
3
|
formic acid
|
0
|
30
|
2.61E-02
|
26.56
|
234
|
Stability tests were performed to exclude degradation over time without electrochemical oxidation. Venlafaxine is stable at all three pH values.
The rate constants at different pH values showed that degradation was slowest at pH 6. This was due to the low conductivity. Degradation was faster at pH 3 and fastest at pH 9, despite of the conductivity of the solution. Ammonia accelerated degradation, which was explained in previous studies as due to oxidation at the BDD-electrode generating amino-radicals (Michels et al. 2010; Kumari and Kumar 2023). In the presence of oxygen, the aminoradicals give rise to aminoperoxyl radicals, which react further to form different nitroxides as oxidants.
Ions, such as sulfate and chloride, led to acceleration, too, where chloride proved the better oxidant, compensating for the lower conductivity. Since structure elucidation did not reveal any chlorine or nitro substituted transformation products, the indirect chloride mechanism, i.e. hydroxyl radical mediated, appeared the predominant one. The analogue should apply for solutions containing ammonia.
Yet structure elucidation, cf. Table 3, did not reveal any chlorine or amino substituted transformation products, hence either the indirect chloride mechanism, i.e. hydroxyl radical mediated, or the direct electrochemical oxidation would be predominant. The fastest venlafaxine disintegration was observed in the presence of chloride, 30 mg/L hydrogen peroxide, and 5 mg/L humic acid. Analogously to the photoinduced degradation, the electrochemical oxidation process was slowed down by adding tert-butanol, again suggesting that hydroxyl radicals may play a major role as oxidants. While supersaturation was observed again, the addition of hydrogen peroxide exercised a much stronger effect than was the case during irradiation.
In general, it may be concluded that the conductivity of a solution accounted only for a small contribution to the efficiency of the electrochemical oxidation. The application of oxidants or hydrogen peroxide promoted the acceleration of the degradation. With respect to utilization as advanced purification stage in wastewater treatment plants, it is interesting that the presence of humic acid rendered degradation faster in contrast to prolonging photoinduced degradation.
Structural inspection of the transformation products will shed light on the mechanistic details. The identified products are shown in Table 3.
A total of four transformation products with m/z = 276.1953, m/z = 264.1956, m/z = 196.1334 and m/z = 194.1177 were identified. None of them has previously been reported with electrochemical oxidation using a BDD electrode. The two products V276 and n-desmethylvenlafaxine were observed exclusively at pH 9. V194 was detected in all electrochemical oxidation experiments except at pH 9 containing ammonia. V196 and V194 were most likely formed through hydroxyl radicals, since the cyclohexanol moiety was substituted by a hydroxyl group. In contrast, V276 and n-desmethylvenlafaxine underwent reduction and demethylation, which may be traced back to the direct electrochemical oxidation mechanism. It is interesting to note that o-desmethylvenlafaxine was formed during photoinduced degradation but n-desmethylvenlafaxine during electrochemical oxidation. Both were observed at the same mass-charge ratio, but had different retention times. Distinction succeeded via MSn fragmentation. As opposed to photoinduced degradation of venlafaxine, indices for both the direct electrochemical oxidation and the hydroxyl radical mediated indirect mechanism were found.
All observed products emerged in low concentrations during electrochemical oxidation. Yet, a concentration-time profiles in relation to venlafaxine could be derived for the product V194 under various matrix conditions. The data could be best described following a subsequent follow-up reaction according to Eq. 4 in the supplemental information, see Fig. 5.
On hydrogen peroxide addition, V194 was formed and degraded faster, presumably due to increased hydroxyl radical concentrations. Deceleration was observed on addition of radical scavengers, where the transformation product was formed after an extended period of electrochemical oxidation. Degradation despite of the presence of tert-butanol may be explained in terms of tert-butanol degradation. A higher concentration of hydrogen peroxide or tert-butanol resulted in a lower amount of the product. The presence of chloride, sulfate and humic acid was found to have an accelerating effect on both formation and degradation of V194. Again, chloride ions resulted in the fastest decay of the transformation product V194 as was found for venlafaxine. Compared to photoinduced degradation, significantly fewer products were observed. In both processes, a maximum of 8% product formation was observed.
3.4 QSAR Analysis of photoinduced and electrochemical degradation products
To compare the potential ecotoxicological hazard arising from the application of both AOPs, in silico QSAR analysis based on the identified structures was performed. Among the different transformation products, the single identical product was Ven194. All ecotoxicological values predicted using ECOSAR are listed in Table S2 of the Supplemental Information. When no unequivocal identification could be achieved, the hydroxyl group was assumed at different positions. This was taken into account in the QSAR analysis. Details are described in Supplemental Information. Based on the predicted ecotoxicity values, structures were ranked from higher to lower values as illustrated in Fig. 6.
Except for n-desmethylvenlafaxine, the ECOSAR class Aliphatic Amines (1.0) was applied. With an increasing number of hydroxyl group substituents, the ecotoxicity of the transformation products decreased. A similar finding has been reported for imidacloprid in previous studies (Voigt et al. 2022b). As a consequence, the indirect mechanism, which leads to hydroxyl radical addition or substitution, may be considered the preferential mechanism in terms of ecotoxicity if the conditions might be adjusted in ecological or technical installations. An encouraging finding with respect to environmental hazard was that all products resulting from photoirradiation and electrochemical treatment were predicted less toxic than venlafaxine itself. The most ecotoxic transformation product was V276 resulting from electrochemical generation, followed by V274 and V278 from photoirradiation.