Identification of position isomers by energy‐resolved mass spectrometry

Menacherry, Sunil Paul M.; Laprévôte, Olivier; Nguyen, Thao P.; Aravind, Usha K.; Pramod, G.; Aravindakumar, Charuvila T.

doi:10.1002/jms.3607

Cited by 23 publications

(22 citation statements)

References 27 publications

(77 reference statements)

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“…The absorption bands between 300–350 nm region (335 in the present case) with nearly diffusion controlled rate constants (k 2 =(1.08 ± 0.06) × 10 10 dm 3 mol −1 s −1 in the present case) are widely accepted as the characteristic bands of hydroxycyclohexadienyl – type radicals . Additionally, characterization of ortho, meta and para hydroxylated analogues of DPH during our end‐product studies as well as in our previous report further supports the involvement of a number of unresolved radicals on the transient spectra. Furthermore, minor contributions from a number of other radicals were also expected in this transient spectrum and are i) one more aromatic hydroxylated adduct radical at either one of the equivalent ipso positions ( 1 and 1’ ) of DPH ( b ) and ii) one or more radical species formed as a result of the abstraction of a hydrogen atom from DPH (discussed later).…”

Section: Resultssupporting

confidence: 86%

“…for C 17 H 22 NO 2 272.1645). An energy‐resolved mass spectrometry (ERMS) based characterization of these compounds has been already developed and is discussed in our earlier report . Identification of position isomers of this kind, that are generated due to the non‐position selectivity of • OH during its reaction with aromatic compounds, otherwise requires multi‐stage separation/purification processes and the use of multi‐spectroscopic techniques.…”

Section: Resultsmentioning

confidence: 99%

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Transformation Reactions of Radicals from the Oxidation of Diphenhydramine: Pulse Radiolysis and Mass Spectrometric Studies

Menacherry

Nair

Nair³

et al. 2016

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Mechanistic aspects of diphenhydramine (DPH) oxidation induced by hydroxyl (•OH) and sulfate (SO4•−) radicals have been explored in detail by pulse radiolysis technique and high resolution mass spectrometry (HRMS). The transient absorption spectrum along with HRMS analysis undoubtedly established the non‐position selective hydroxylation of DPH by •OH (a; k2 = (1.08 ± 0.06) × 1010 dm3 mol−1 s−1; λmax: 335 nm) led to various transformation products (i ‐ vii) including isomeric mono (Ia‐d), di (IIa‐c) and tri (VIIa‐e) hydroxylated analogues. On the other hand, SO4•− (specific one electron oxidant) ultimately generates another hydroxylated adduct radical ‘c’ λmax: 330 nm, k2=(5.70 ± 0.03) × 109dm3 mol−1 s−1) which is formed as a result of preferential hydroxylation of initially formed radical cation ‘b’ at ipso position. The mechanism leading to the formation of various transformation products induced by •OH and SO4•− are thoroughly discussed. The mechanistic findings obtained from our studies (especially in the case of less investigated oxidant like SO4•−) are capable to enrich the fundamental understanding on environmentally relevant reactions initiated by •OH and SO4•−.

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Section: Resultssupporting

confidence: 86%

Section: Resultsmentioning

confidence: 99%

Transformation Reactions of Radicals from the Oxidation of Diphenhydramine: Pulse Radiolysis and Mass Spectrometric Studies

Menacherry

Nair

Nair³

et al. 2016

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“…We have mainly utilized time-offlight mass spectrometry for the identification of the intermediate products during various oxidation processes such as UV photolysis (Sunil Paul et al 2014), sonolysis (Nejumal et al 2014) and other oxidation processes (Thomas et al 2014). Recently, various positional isomers, formed during the oxidation reaction, have been differentiated by this technique (Menachery et al 2015;Sreekanth et al 2014). The influence of some micropollutants on the degradation of methylparaben has also been investigated by this high-resolution mass spectrometric technique (Sasi et al 2015).…”

Section: Sonoelectrochemical Methodsmentioning

confidence: 98%

“…There have been several techniques, especially mass spectrometric technique for the identification of the oxidation products. The most common method applied for the identification of degraded products is liquid chromatography-based techniques such as liquid chromatography mass spectrometry (Hisaindee et al 2013), time-of-flight mass spectrometry and hybrid quadrupole time of flight, in combination with ultrahigh-performance liquid chromatography (Menachery et al 2015;Sasi et al 2015). Since most of the species are in the aqueous phase and contains polar groups, therefore gas chromatography-based technique is applied very rarely (Hisaindee et al 2013).…”

Section: Sonoelectrochemical Methodsmentioning

confidence: 99%

“…It causes a more violent cavitational collapse of the bubbles to release the reactive species. The increased power also leads to the vibration of the pollutants in the liquid medium, which causes the faster movement of the pollutant toward the interface region (Mason et al 1990). However, when the number of bubbles in the medium is increased, it could scatter the sound wave and return back to the surface of the transducer.…”

Section: Sonochemical Degradation Of Pharmaceutically Active Compoundsmentioning

confidence: 98%

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Degradation of pharmaceuticals by ultrasound-based advanced oxidation process

2016

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Water pollution by pharmaceutically active compounds is an emerging issue. Toxicological studies reveal that pharmaceuticals are indeed toxic for living organisms. The lack of suitable treatment technology for the complete removal of pharmaceuticals is therefore a major challenge. Advanced oxidation processes are emerging removal techniques that have many advantages versus conventional technologies. Many studies indicate that advanced oxidation processes, either in single or in combination with other degradation techniques, can enhance the degradation of pharmaceuticals in aqueous solutions. Here, we review the degradation of pharmaceuticals by sonolysis, an oxidation processes using ultrasound. In this technique, hydroxyl radicals are generated by pyrolytic cleavage of water molecules. We review the influence of operational parameters, additives and hybrid techniques on the degradation of pharmaceuticals. The maximum degradation of organic compounds was observed in the frequency range of 100-1000 kHz, which is in the high-frequency medium-power ultrasound. Even though almost all the experiments presented more than 90 % removal and good biodegradability of the target compound, good mineralization and the toxicity removal were hardly achieved. The efficiency of the degradation varies with water matrixes and varying pH. Major pathways of degradation are hydroxylation, dehalogenation, demethylation, decarboxylation, deamination, etc. More hybrid techniques have to be developed to scale up the application of ultrasound.

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Quantitative Ligand Affinity Scales for Metal Triflate Salts: Application to Isomer Differentiation

et al. 2017

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Owing to the importance of metal triflates in catalysis, the affinity of the cationic center for a selection of organic ligands was explored for InIII and ZnII triflates. The organic Lewis bases include a variety of carbonyls (amides, unsaturated ketones, a lactone) and cyclic 1,2‐diols. The relative affinity of the ligands for the cationic center in triflates was quantitatively determined on the basis of relative ion concentrations determined by electrospray‐ionization mass spectrometry. The affinity scales were discussed with reference to gas‐phase proton basicity and Lewis basicity scales. Structural isomers and stereoisomers display significant affinity differences in several cases. In the case of isomer mixtures, a model describing the relative peak intensities in the mass spectra was developed. On this basis, an isomer titration method was set up. Remarkably, this MS‐based method overcame the blindness of mass spectrometry to isomers without the need for isotope labeling or MS/MS experiments. This model may prove to have applications in analytical chemistry and catalysis.

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Identification of position isomers by energy‐resolved mass spectrometry

Cited by 23 publications

References 27 publications

Transformation Reactions of Radicals from the Oxidation of Diphenhydramine: Pulse Radiolysis and Mass Spectrometric Studies

Transformation Reactions of Radicals from the Oxidation of Diphenhydramine: Pulse Radiolysis and Mass Spectrometric Studies

Degradation of pharmaceuticals by ultrasound-based advanced oxidation process

Quantitative Ligand Affinity Scales for Metal Triflate Salts: Application to Isomer Differentiation

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