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Article
Photolysis of antibiotics under simulated sunlight irradiation: identification of photoproducts by high resolution mass spectrometry Rosa María Baena-Nogueras, Eduardo Gonzalez-Mazo, and Pablo Antonio Lara-Martín Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.6b03038 • Publication Date (Web): 14 Feb 2017 Downloaded from http://pubs.acs.org on February 20, 2017
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Photolysis of antibiotics under simulated sunlight irradiation: identification of photoproducts by high resolution mass spectrometry
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Rosa María Baena-Noguerasa, Eduardo González-Mazoa and Pablo A. Lara-Martín*a
6 7
a
Department of Physical Chemistry, Faculty of Marine and Environmental Sciences, CEI·MAR, University of Cadiz, Puerto Real, 11510, Spain
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* Corresponding author: e-mail:
[email protected], phone: +34 956016159, fax: +34 956016040
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Abstract
13
There is a growing concern on the widespread use of antibiotics and their presence in
14
the aqueous environment. Their removal in the water column is mediated by different
15
types of degradation processes for which the mechanisms are still unclear. This research
16
is focused on characterizing the photodegradation kinetics and pathways of two largely
17
employed antibiotics families: sulfonamides (9 SDs) and fluoroquinolones (6 FQs).
18
Degradation percentages and rates were measured in pure water exposed to simulated
19
natural sunlight at a constant irradiance value (500 W m-2) during all the experiments,
20
and the main photoproducts formed were characterized through accurate mass
21
measurement using ultra-performance liquid chromatography – quadrupole-time-of-
22
flight – mass spectrometry (UPLC-QToF-MS). Over 100 different phototransformation
23
products were identified for SDs and FQs, 66% of them, to the best of our knowledge,
24
have not been described before. Their sequential formation and disappearance over the
25
course of the experiments reveal the existence of several pathways for the degradation
26
of target antibiotics. Occurrence of new photoproducts derived from desulfonation
27
and/or denitrification as well as hydroxylation of photo-oxidized heterocyclic rings,
28
have been identified during photodegradation of SDs, whereas a new pathway yielding
29
oxidation of the benzene ring after the cleavage of the piperazine ring (e.g. CIP product
30
with m/z 263) is described for FQs.
31 32
Keywords: sulfonamides, fluoroquinolones, photoproducts, pathway, kinetic, high
33
resolution mass spectrometry
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1. Introduction
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The extensive use of antibiotics in human and veterinary medicine is a matter of
36
growing concern because of their role in the emergence and potential spread of
37
resistance genes. More specifically, anthropogenic activities and the inefficient removal
38
of antibiotics and many other pharmaceuticals in wastewater treatment plants (WWTPs)
39
lead to the continuous discharge of these substances into aquatic environments. Among
40
these compounds, fluoroquinolones (FQs) and sulfonamides (SDs) are largely used in
41
human health care systems and in animal farms (1,2), and their increasing detection in
42
WWTP effluents and streams is foreseen as a potential risk for aquatic organisms (3).
43
As examples, levels reported for sulfamethoxazole in San Francisco Bay and
44
Skateneakeles Lake in New York are in the range of 2.4 to 66.7 ng L-1 (4,5), while
45
sulfamehoxazole and ofloxacin occur at levels of up to 169 and 146 ng L-1, respectively,
46
in Ebro River (6,7).
47
Regarding the environmental fate of many antibiotics, including FQs and SDs,
48
degradation processes involving natural light (photodegradation) have been reported as
49
one of the major mechanisms involved in their removal (8-10). Identification of new
50
transformation products of xenobiotics commonly detected in surface waters is of
51
environmental relevance as these chemicals are often ignored in monitoring programs
52
and their toxicity towards aquatic species is unknown. Adverse environmental effects of
53
other pharmaceutical degradation byproducts have been recently highlighted, for
54
example carbamazepine, for which one of the major photoproducts, acridine, is a toxic,
55
mutagenic, and carcinogenic chemical, and therefore, its environmental impact is much
56
higher than that of the parent substrate (11). The photodegradation pathways of most
57
antibiotics, however, are still not fully understood. Several mechanisms have been
58
recently reported to occur during the transformation of specific SDs, such as
59
desulfonation and photohydrolysis for sulfadiazine and sulfapyridine (10,12). Other
60
proposed transformation pathways are the rearrangement of the isoxazole ring and its
61
hydroxylation for sulfamethoxazole (13), as well as the oxidation/reduction of N atoms
62
for sulfadiazine and sulfamethazine (12, 14). Regarding FQs, direct defluorination,
63
hydroxylation of the heterocyclic ring, oxidative degradation of the piperazine moiety,
64
and cyclopropane cleavage at acid pH have been described for ciprofloxacin and
65
enrofloxacin (8,15,16,17,18).
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So far, most studies have relied on the use of liquid chromatography coupled to
67
triple quadrupole mass spectrometry analyzers (LC-MS/MS) for monitoring the
68
photodegradation of the parent compound and for achieving the identification of
69
possible photodegradation products. This last task is mainly performed through
70
fragmentation of their quasimolecular ions and interpretation of the resulting mass
71
spectra (8,18,19). New generation high resolution mass spectrometers (HRMS) open a
72
new range of possibilities as they allow accurate mass measurement of the
73
quasimolecular ions of possible photoproducts and their specific fragments, enabling
74
unequivocal confirmation of the molecular structures. Therefore, application of
75
advanced HRMS, including a detailed interpretation of the resulting fragmentation
76
pathways at different collision energies, is a powerful tool for relatively rapid and
77
certain structure identification of transformation products, including those from
78
biological reactions (20). New intermediates recently discovered using this approach are
79
desulfonated
80
ciprofloxacin (PT 330) (14,21).
sulfamethazine
(PT
215),
and
defluorinated
and
hydroxylated
81
The aim of this study was to provide a better knowledge on the photodegradation of
82
a selected number of widely used SDs (9) and FQs (6), for many of which there is no
83
available information, in pure water under simulated sunlight irradiation. First,
84
photodegradation kinetics were measured by LC-MS/MS to confirm the disappearance
85
of parent compounds in a short period of time and, later, selected samples were
86
analyzed by ultra-performance liquid chromatography – quadrupole-time-of-flight –
87
mass spectrometry (UPLC-QToF-MS) to elucidate the molecular structure of the new
88
resulting products as well as to confirm the previous proposed photoproducts from
89
studies carried out without using these techniques. Finally, several photodegradation
90
pathways were proposed taking into consideration different photoreaction mechanisms
91
and the sequential appearance/disappearance of several photoproducts over the course
92
of the degradation experiments.
93 94
2. Experimental section
95
2.1. Photolysis experiments
96
Target compounds are listed in Table S1. Photolysis experiments were carried out
97
following the OECD guidelines No. 316 for phototransformation of chemicals in water
98
by direct photolysis. Irradiation was provided by a Suntest CPS+ simulator (Madrid, 3 ACS Paragon Plus Environment
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Spain) equipped with a xenon lamp which simulates natural sunlight in a wavelength
100
range of 300-800 nm and equipped with coated quartz glass filter. Irradiance was
101
maintained constant at 500 W m-2 during all the experiments and the temperature was
102
monitored, fluctuating between 25 and 35ºC. The solution employed in the first series of
103
experiments consisted of 250 mL of HPLC grade water spiked to 100 ng mL-1 of target
104
compounds. Aliquots of this solution were introduced into 20 quartz tubes of 15 mL
105
each that were placed inside the photo-reactor. Ten of these tubes were covered with
106
aluminum foil and were used as dark controls to account for additional losses from
107
other processes (e.g., hydrolysis and adsorption). Nineteen sampling times were
108
established over a total exposure time of 24 hours, taking two 1 mL aliquots at each
109
sampling time. Once measured, the decreasing concentrations of target compounds
110
versus time were adjusted to the pseudo first-order kinetic.
111
Once photodegradation kinetics were known, a second series of experiments were
112
carried out to identify possible degradation products. These experiments were similar to
113
those aforementioned, but the quartz tubes were filled with individual test solutions of
114
each analyte at 10 µg mL-1. The duration of these experiments was 5 hours, enough to
115
achieve the photodegradation of a significant amount of the parent compounds (from 50
116
to more than 99%), and 13 sampling times were selected. Additionally, pH was
117
monitored in the two series of experiments and remained constant (pH = 6.7) over the
118
course of both assays.
119
2.2. Analysis of samples
120
Simultaneous separation, determination and quantification of parent compounds for
121
the first series of photodegradation experiments were carried out by UPLC-MS/MS
122
using a Bruker Advance - EVOQ system (Bruker Corp., Billerica, MA, USA) following
123
the methodology proposed by Baena-Nogueras et al. (2016) (22). Aqueous samples
124
from the second series of experiments were injected in a UPLC-QToF-MS system, more
125
specifically a Waters Acquity - Synapt G2 tandem (Waters Corp., Milford, MA, USA),
126
for the identification of photodegradation products. Two different functions were use
127
simultaneously in the same run: low energy (4 eV) to obtain quasimolecular ions for
128
parent compounds and photodegradation products, and high energy (energy ramp from
129
10 to 40 eV) to obtain fragments. Further details on sample analysis are described in
130
Supporting Information.
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2.3. Structure elucidation
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Due to the relatively high concentrations used in the second series of experiments
134
(10 mg/L), the presence of transformation product peaks could be easily identified by
135
visual inspection against the baseline of the chromatogram. Those having lower
136
abundances were detected through suspect analysis. Identification of these
137
photoproducts was based on the accurate mass measurement (error < 5 ppm) of the
138
detected quasimolecular ions and fragments, as well as the comparison of theoretical
139
and measured isotopic patterns. The MS/MS spectra interpretation was performed using
140
the Mass Fragment tool (MassLynx 4.1 software). Retention times (RTs) of the
141
photoproducts were also considered, being usually lower retention than those for the
142
parent molecules (over 90% of the detected and identified photoproducts had RTs
143
below 3.5 minutes). To clearly communicate the confidence of the proposed
144
transformation products, we assigned confidence levels according to the classification
145
system proposed by Schymanski et al. (2014) (23): identification by exact mass (5),
146
unequivocal molecular formula (4), tentative candidates (3), probable structure (2), and
147
confirmed structure (1). In addition, based on these confidence levels, varying
148
certainties were also attributed to the resulting reactions following the procedure
149
proposed by Gulde et al. (2016) (24): certain, likely, possible and unknown. More
150
detailed information on this can be found in these references and in the columns ‘A’
151
from Tables S2 and S3 (prefix S refers to Supporting Information).
152 153
3. Results and discussion
154
Figures S1 and S2 show the decrease in the concentrations of SDs and FQs over the
155
course of the first series of experiments and their average percentage removals (>98%)
156
at the end of the experiments (24 h), respectively. Table S1 include the kinetic
157
parameters adjusted to the first-order kinetic model which provided a good fit to the
158
experimental data, with coefficients of determination (R2) generally higher than 0.95.
159
Degradation rates (k) and half-lives (t1/2) were in the range of 0.003 to 0.3 min-1 and 2 to
160
227 min, respectively. These two parameters were recalculated (ko and to1/2) considering
161
the effect of other processes (e.g., hydrolysis or sorption onto glass walls) through the
162
analysis of dark controls. This effect was negligible in most cases as differences were
163
below 20% when comparing k and ko (Table S1).
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3.1. Structural elucidation of sulfonamide photoproducts and proposed photodegradation pathways
166
SDs are characterized by the sulfonamide functional group (-RSO2NH2), which
167
consists of a sulfonyl group connected to an amine group. They also have other
168
distinctive features depending on the compound considered, such as heterocyclic ring
169
structures (thiadiazole, isoxazole, and oxazole). Several photodegradation routes have
170
been proposed for the 9 target parent compounds based on the elucidation of the
171
structures of different photoproducts detected by UPLC-Q-ToF-MS, their consecutive
172
formation and elimination, and available information from previous publications. All
173
details on the identification of these photoproducts (n = 102) are shown in Table S2,
174
including retention times, accurate mass measurement, fragments and proposed
175
structures, as well as the mass spectra are displayed in Figure S3. At least 68 out of 102
176
photoproducts identified were described for the first time. More specifically, both direct
177
irradiation and hydrolysis in water led to the degradation of all SDs and the detection of
178
up to 17 degradation products for SMZ, 16 for SMX, 15 for SMP, 13 for SDZ, 10 for
179
STZ, 9 for SGD, SFX and SMT, and 4 for SND. Tentative phototransformation
180
pathways for the 9 SDs under study are presented in Figure 1 and Figures S4 to S11 to
181
illustrate the different mechanisms that take place during the degradation process.
182
Among the first reactions occurring, the extrusions of sulfonyl and amine groups,
183
which can also happen simultaneously, were common for all SDs considered in this
184
study. Boreen and colleagues (2004) determined that photodegradation occurs through
185
SO2 extrusion for SDs containing six-membered heterocyclic substituents, while SDs
186
with five-heterocyclic groups experience a cleavage at various positions (25). The
187
desulfonation process has been also reported (10,12) for some specific compounds such
188
sulfadiazine and sulfapyridine using conventional HPLC, and it was confirmed in our
189
experiments for eight additional SDs. García-Galán and co-workers (2012) (14) also
190
used high resolution mass spectrometry to identify the formation of photoproducts after
191
desulfonation and a combination of desulfonation and denitrification for SMZ and
192
sulfapyridine (m/z 173 and 158). Here, we report for the first time the occurrence of
193
several co-desulfonated and denitrificated products for SMZ (m/z 200, 214, 216), SDZ
194
(m/z 188, 186, 172), SMX (m/z 193, 191, 175), and SMP (m/z 202, 216, 218) (Table
195
S2).
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Multiple hydroxylated products were also formed during the photolysis
197
experiments, having one or more hydroxyl groups (-OH) that are often positioned in the
198
sulfonamide group (e.g., PT 267 and 283 for SDZ, see Fig. S6) (12,26). Niu and
199
colleagues (2013) (13) have also reported the –OH attack (hydroxylation) on the
200
phenylamine for SMX (PT 272, Fig. 1), which we have confirmed to occur for all the
201
SDs under study: SND (PT 189, Fig. S4), SGD (PT 231, Fig. S5), , SDZ (PT 267, Fig.
202
S6), STZ (PT 272, Fig. S7), SFX (PT 284, Fig. S8), SMT (PT 287, Fig. S9), SMZ (PT
203
295, Fig. S10) and SMP (PT 297, Fig. S11). The hydroxylamine formed may then
204
experience further reduction (27) (e.g., PT 293 for SMZ or PT 265 for SDZ, see Table
205
S2). Additionally, the photo-oxidation of heterocyclic rings has been proposed by
206
Guerard (2009), Niu (2013) (13,27) and co-workers, and observed for some of the
207
compounds tested in this research, such as for the isoxazole ring of SMX (PT 193, Fig.
208
1). New photoproducts derived from all these hydroxylated compounds were identified
209
in our experiments for SMX (PT 270, 256), SMZ (PT 311, 309), SMT (PT 285), SGD
210
(PT 229), STZ (PT 270) and SDZ (PT 265) as a result of successive oxidation and/or
211
reduction reactions. Formation of some of these compounds was also detected in dark
212
controls (e.g., PT 297 from SMP, Table S4), although their signal intensity was often
213
between one and two order of magnitude lower than in irradiated samples, suggesting
214
that light enhances the hydrolysis of SDs. Enhancement of the production of hydrolysis
215
TPs during irradiation has been reported recently for other contaminants such as dioctyl
216
sulfosuccinate (DOSS) (28).
217
Finally, a third photodegradation mechanism involved the cleavage of the
218
sulfonamide group, yielding two major products containing aniline and sulfanilic acids
219
that were previously detected for specific SDs such as SMX, SFX, SMT and STZ (29).
220
Formation of other intermediates such as sulfanilamide (the simplest sulfonamide),
221
aminopyrimidine, or the oxazole ring has been observed for specific SDs depending on
222
their molecular structures. Some SDs were detected as photoproducts of those having a
223
more complex structure and higher molecular weight. Examples are the transformation
224
of SMT into SGD and of SMP into SDZ (Table S2).
225
Many of the reactions described above led to the presence of several
226
chromatographic peaks corresponding to different mono- and di-hydroxylated products
227
(e.g., mono and di-hydroxylated compounds such as the previously identified PT 272
228
and PT 288, respectively, for SMX). Determining the specific position of the hydroxyl 7 ACS Paragon Plus Environment
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229
moiety in the molecule was the most challenging part of this study and was achieved by
230
analysis of the fragmentation patterns in the QToF-MS high energy function (see Fig.S3
231
for mass spectra of specific SD intermediates). As an example, high energy spectra
232
allowed us to elucidate the molecular structures of two SMZ photoproducts having the
233
same mass (m/z 295) but observed at different retention times (Table S2).
234
Fragmentation of one of these products resulted in the excision of the hydroxylated
235
aniline (m/z 108), hence the binding of an OH group to this part of the molecule is
236
expected, whereas it led to the loss of just aniline in the other product (Figure 2). The
237
same fragmentation pattern was observed for two other detected photoproducts sharing
238
the same m/z 272 but different retention times in the case of SMX degradation. This
239
approach, however, is limited as fragmentation of a few photoproducts (e.g., the di-
240
hydroxylated SMX product with m/z 288, Table S2) was not observed at the energies
241
selected. Identification in these cases could be improved by using data dependent
242
MS/MS acquisition, although their molecular formulas could be tentatively assigned by
243
accurate mass measurement of their molecular ions and several adducts (e.g., [M+Na]+),
244
an alternative strategy proposed by García-Galán and co-workers (2012) (14). There
245
were other cases (e.g., the identified PT 208, see Fig. 1) where, although fragmentation
246
was feasible and several peaks at different retention times were observed, no distinctive
247
fragments could be identified and therefore the position of the hydroxylated moiety
248
could not be defined.
249
Co-elution of several photoproducts occurred but individual extraction of their
250
respective chromatograms enabled us to outline different evolution curves based on the
251
peak areas (Fig. S12), as we can observe in Figure 3a for SND and its identified
252
photoproducts with m/z 109, 110 and 112. During the first 50 min, two different
253
maximum concentrations could be detected for SND hydroxylated products sharing the
254
same molecular ion m/z 189. This can be explained considering two different oxidation
255
processes such as one over the terminal N atom and another over the benzene ring. The
256
decrease in these photoproducts was followed by an increase in the signal intensities of
257
PT 112 and, later, PT 109 and 110, between 120 and 180 min. After that, the intensities
258
of these compounds became also lower but a further increase could be observed towards
259
the end of the experiment for PT 109 and 110. This could indicate the potential
260
reversibility of some reactions such as dehydroxilation, previously reported by Khaleel
261
and co-workers (2013) (19), and the existence of different degradation pathways 8 ACS Paragon Plus Environment
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occurring at different speeds (Figure S4). In most cases, and closely related to the
263
oxidation processes aforementioned, there were also photo-reduction reactions resulting
264
in a double bond (from –OH to =O). Equivalent intermediate oxidation steps have been
265
already reported by other authors (10,14) and they were found for all SDs considered in
266
this research.
267
A more detailed description of the evolution in the concentrations of the different
268
photoproducts over the course of the experiments is presented in Figure S12 for SDs,
269
including those intermediates that were also detected in dark controls. This is also
270
summarized in Table S2 (column ‘C’) by using an approach similar to that proposed by
271
Gulde et al. (2016) (24), including a combination of the terms rising (r), steady (s), and
272
falling (f). This strategy also allows assessing the importance of different reactions in
273
terms of how much of the parent compound was transformed via a specific reaction.
274
This is achieved by selecting the highest peak area of each transformation product and
275
relating it to the degree of photodegradation of the parent SD at that same time to
276
calculate the maximal relative amount (column ‘B’ at Table S2). Most SDs were
277
phototransformed through desulfonation reactions showing maximal relative amount
278
values of 91.7, 46, 33.5 and 3.8% for SMP (PT 217), SDZ (PT 187), SMZ (PT 215) and
279
STZ (PT 168). Oxazole ring cleavage of the desulfonated photoproducts (PT 192) was
280
also relevant (10%) for SMX. Other minor reactions that were common for all SDs were
281
oxidation and/or reduction of the heterocyclic ring (e.g., PT 189 from SND) and
282
nitrogen atoms (e.g., PT 229, PT 201, and PT 285 from SGD, SDZ, and SMT,
283
respectively), showing maxima relative amounts up to 2.4%. The rest of reactions were
284
below 1%, except the photohydrolysis of SGD (PT 60) and SMT (PT 116), and the
285
desnitrification of SFX in parallel to hydroxylation (PT 269).
286 287
3.2.
Structural
elucidation
288
photodegradation pathways
of
fluoroquinolone
photoproducts
and
proposed
289
The essential structure of all FQs is formed by a piperazine and a two ring core
290
(containing pyridine and benzene with a fluorine atom at C-7 position) which are
291
responsible for the antimicrobial activity. As in the case of SDs, several
292
photodegradation routes have been proposed for the 6 FQs selected based on the
293
elucidation of the structures of different photoproducts detected by HRMS. All details
294
on the identification of these photoproducts (n = 116) are shown in Table S3, including 9 ACS Paragon Plus Environment
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retention times, accurate mass measurement, fragments and proposed structures, as well
296
as the mass spectra are displayed in Figure S13 At least 76 out of the 116 photoproducts
297
are described here for the first time. More in detail, the photolysis of FQs led to the
298
detection of up to 26 degradation products for OFX, 24 for CIP, 19 for NOR, 16 for
299
ENR, and SPAR and 15 for DAN. Tentative phototransformation pathways for the 6
300
FQs under study are presented in Figure 4 and Figures S14 to S18 to illustrate the
301
different mechanisms taking place during the degradation.
302
Figure 4 shows the different intermediates that were identified during the
303
photodegradation of ciprofloxacin (CIP), which is one of the most commonly detected
304
antibiotics in wastewater and surface waters (6,30). Up to 24 different photodegradation
305
products were formed as a consequence of direct irradiation and collateral processes
306
such as hydrolysis. Following their changes in intensity over the course of the
307
experiment and their appearance order (Table S5) we were able to propose five different
308
main degradation pathways. The first pathway consists of the hydroxylation (m/z 348)
309
and fluorine solvolysis (m/z 330) of the parent compound, which can take place
310
separately or simultaneously (yielding the detected photoproduct with m/z 346 in the
311
latter case) (21). Wei and coworkers (2013) (15) proposed an alternative structure for
312
PT 346 based on the oxidation of the pyridine ring. The ion formula obtained by
313
accurate mass measurement (C17H20N3O5) as well as the main fragment ions (m/z 328 and
314
300) of this photoproduct matched, however, with the structure proposed by Haddad
315
and Kümmerer (2014) (21). Closely related to PT 346 and PT 348, we could also
316
observe the production of PT 362_2 and 364, derived from a nucleophilic attack over
317
the fluorine atom and two hydroxylations, respectively, although they were detected at
318
lower intensities. The molecular structure for PT 364 was described before (31), not so
319
for PT 362_2.
320
The second route for CIP photodegradation consisted on a direct defluorination
321
(m/z 314) of the parent compound followed by the oxidation of one of the amino groups
322
of the piperazine ring into an amide (m/z 328). Similar products but with two hydrogen
323
atoms less (m/z 312 and 326) were reported before, which may be formed via side-chain
324
oxidation of the piperazine moiety. That would result in intermediates with a double
325
bond previously described not only for CIP but also for enrofloxacin (ENR) (16,18),
326
and also confirmed for the rest of FQs considered in the present research. Previous
327
studies have reported that OH- addition is the most thermodynamically favorable way to 10 ACS Paragon Plus Environment
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328
promote the defluorination reaction not only for FQs (15) but also for many
329
haloaromatic substances under irradiation (32). The elucidation of the molecular
330
structure of PT 328 was recently achieved by Haddad and Kümmerer (2014) (21) for
331
ciprofloxacin using a combination of Orbitrap and ion-trap mass spectrometers.
332
Comparison of the mass spectrum obtained in that study with that reported here using
333
QToF-MS reveals a strong fragmentation relationship by the formation of the same
334
fragments, with minor differences (m/z 245 and 231 were recorded only in our case and
335
m/z 213 not) attributed to the use of MS3 in the ion trap in order to gain more structural
336
information.
337
The third degradation route continues both first and second routes described above.
338
It consists of the oxidative degradation of the piperazine ring (see detected
339
photoproducts with m/z 306 and 316_1) (Figure 4). The intermediates formed are
340
derived from two major detected photoproducts, PT 348 (from route 1) and PT 328
341
(from route 2), and, after conversion into PT 306 and 316_1, respectively, end up
342
forming PT 288. This last compound is one of the most abundant CIP products
343
observed, next to PT 330, in agreement with previous studies performed under similar
344
conditions (16,17). Wei and coauthors (2013) (15) also reported the predominance of
345
PT 346, but mostly at acidic and basic pH, whereas PT 306 was only detected at pH 2.
346
In our case, PT 346, together with PT 306 and PT 316_1, were detected over the course
347
of the experiment despite conducting it at neutral pH. Additionally, PT 316_1 yielded
348
PT 344 through a reduction reaction (21).
349
The fourth photodegradation mechanism includes the attack of the piperazine
350
moiety, leading to the occurrence of PT 360, formed by the addition of carbonyl group
351
to the parent compound. This reaction has been previously proposed but the PT 360
352
precursor (PT 362_1) is reported here for the first time (21,31). Both intermediates
353
could also be considered as hydrolysis products as their presence was also detected at
354
trace levels in dark controls (see Figure S19) for the evolution in the concentrations of
355
the different photoproducts over the course of these and other experiments with FQs).
356
CIP can be also photodegraded by cleavage of the piperazine ring, which yields two
357
different fragments (m/z 263, m/z 87). Although this reaction has been observed to take
358
place in darkness, hydrolysis was strongly enhanced by light during the irradiation
359
experiments, as it was previously discussed for SDs, too. Furthermore, PT 263 could
360
undergo oxidation (m/z 279), denitrification coupled to hydroxylation (m/z 280), 11 ACS Paragon Plus Environment
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Environmental Science & Technology
361
fluorine subtraction (m/z 245), and/or reductive dehalogenation (m/z 261) followed by a
362
subsequent nucleophilic substitution of the amino group by a hydroxyl radical (m/z
363
262). The final products (m/z 210 and 194) that were identified have only one ring as
364
the benzene has been totally oxidized. This is the first time that this photodegradation
365
route is described for FQs. Other authors have found different intermediates, such as an
366
ethyl derivative from PT 263, formed by UV radiation (18). There are also some
367
discrepancies between the results reported here and those from previous experiments
368
performed using low resolution mass spectrometry. For instance, the molecular
369
structures reported for PT 210 and PT 194 reported by Babic et al. (2013) (8) were
370
different to those observed here. In that sense, Batchu and collaborators (2014) (9)
371
recently revised the CIP phototransformation pathways and, using HRMS as well,
372
proposed alternative structures for PT 288 and PT 245 consisting of the opening of the
373
pyridine instead of the piperazine ring. Accurate mass measurement of these
374
photoproducts and their main fragment ions (m/z 270 and 227) in our experiments,
375
however, provides a better match with the molecular structures described by Wei et al.
376
(2013) (15). This is also in agreement with the degradation of the piperazine moiety into
377
PT 306 and PT 263, identified before as one of the major routes for the photolysis of
378
H4CIP3+ at pH 2. It seems that in our case, where pH is neutral and zwitterion is the
379
expected dominant form in water, the same mechanism also applies. Additionally, the
380
structure proposed here for PT 263 has been already described during the
381
photodegradation of other FQs such as ENR or DAN (8,,33,34).
382
The fifth alternative route for the degradation of CIP includes its transformation
383
into norfloxacin (NOR) (m/z 320), another FQ, through the cyclopropane cleavage. This
384
type of mechanism has been previously observed for other FQs as they share very
385
similar structures (8), such as the transformation of enrofloxacin (ENR) into CIP
386
(Figure S14). More specifically, photolysis experiments carried out with ENR resulted
387
in the identification of 16 irradiation products plus those derived from CIP (Figure 4).
388
The occurrence of CIP during ENR degradation, however, could not be detected during
389
tests performed at acidic pH (8). In our case, ENR followed several degradation
390
pathways that were very similar to those described for CIP, with some new reactions
391
such as the hydrogen abstraction by hydroxyl radical (35) from which PT 376 is
392
transformed into PT 374_2. The photolysis of enrofloxacin has been recently
393
investigated by other groups yielding similar results (18,34) to those presented here, 12 ACS Paragon Plus Environment
Environmental Science & Technology
394
although some of the photoproducts were different depending on the pH. Examples are
395
the cyclopropane cleavage reported at pH 4 and the oxidative photodegradation at pH 8
396
(8,36). To the best of our knowledge, at least seven of the intermediates described in
397
Figure S11 (PT 378, 374_1, 362, 360, 350, 348, and 344) were not reported previously.
398
More details on the photodegradation of ENR are shown in Figure 3b, describing the
399
evolution in the relative abundance of some of the main products over the course of the
400
experiment and representative chromatograms. Hydroxylated compounds, such as those
401
where fluorine atom was replaced by –OH, have lower retention times (
