Investigation of Euphrasia rostkoviana Hayne Using GC–MS and LC–MS

Gas and liquid chromatography coupled with mass spectrometry was applied to solve difficulties and reinvestigate the serious matrix problems affecting analysis of the active compounds in Euphrasia rostkoviana Hayne. The main groups of compounds were obtained by extracting the herb stepwise with n-hexane, chloroform, ethyl acetate and methanol. Polyamide column chromatography facilitated further separation. Phenolic/flavonoid- and terpenoid-type molecules were studied by GC–MS, HPLC and LC–MS–MS. The β-sitosterol content of the herb was determined by gas chromatography with flame ionisation detection (GC-FID). Caffeic acid, chlorogenic acid, coumaric acid and flavonoid glycosides of apigenin, luteolin, rhamnetine (hexoside), kaempferol (both hexoside and rutinoside) and quercetin (rutinoside) were identified in the fractions of the methanolic extract.     

LC–MS–MS Determination of Stabilizers and Explosives Residues in Hand-Swabs

The contribution of explosive trace detection in samples from the hands of suspects has been fundamental in several forensic cases involving terrorists. This paper describes a method for the rapid extraction and unequivocal confirmation of some high potential explosives (trinitrotoluene, cyclotrimethylenetrinitramine, pentaerythritol tetranitrate, nitroglycerin) and two stabilizer (diphenylamine and ethylcentralite) residues in hand-swabs using liquid chromatography–tandem mass spectrometry. The extraction procedure of the analytes from the swabs is realized by solvent elution and the extracts are directly analyzed. Recoveries from spiked swabs range from 78 to 96%; the limits of quantification are between 0.04 and 1.8 ng injected and the inter-day method precision is less than 15%. The developed procedure was applied to the detection of explosives traces in samples after handling tests.     

Detection and Confirmation of Ginsenosides in Horse Urine by GC–MS and LC–MS

Ginseng has been used by the Chinese as a traditional herbal medicine for thousands of years. In view of the growing popularity in the use of ginseng preparations as natural remedies and food supplements worldwide, there is an increasing concern for their abuse in both human and animal sports. Ginsenosides are considered the major constituents of ginseng responsible for its pharmacological properties. In this study, a method was developed for the detection and confirmation of a number of ginsenosides in horse urine. The intact ginsenosides were detected and confirmed at 5–100 ng mL^?1 by LC–MS², and two deglycosylation metabolites, namely protopanaxadiol and protopanaxatriol, could both be detected and confirmed at 2 ng mL^?1 by GC–MS² after trimethylsilylation. The above GC–MS and LC–MS methods were then applied to study the in vitro metabolism of ginsenosides Rg1 and Rb1 and the in vivo urinary metabolites after oral administration of Rg1 to horses. Results obtained reveal the very first evidence for the existence of the metabolites, Rg1 and protopanaxatriol, as glucuronides in urine.     

Quantitative determination of cationic modified polysaccharides on hair using LC–MS and LC–MS–MS

Cationic polysaccharides containing N-hydroxypropyl-N,N,N-trimethylammonium substituents are widely used as conditioning agents for hair-care products. A sensitive method has been developed for the quantitation of these polymers. After acidic extraction from hair the polysaccharides are hydrolyzed using trifluoroacetic acid. The cationic monoglycosides are determined using liquid chromatography–tandem mass spectrometry (LC–MS–MS). The developed method is independent of hair treatment. Even hair cut from test persons after customary hair wash can be analyzed. After treatment of natural and bleached hair tresses using a real-life treatment procedure 180 g and 300 g of polymer per gram hair were quantified, respectively. Additionally the fragmentation mechanism of the cationic N-hydroxypropyl-N,N,N-trimethylammonium group during electrospray ionization was investigated. A mass loss of 60 Da in combination with loss of a single charge is observed and associated with cleavage of trimethylamine and a proton. It is assumed that this process is promoted by the anionic counter-ion which might be hydroxide in an aqueous environment.     

Stress Studies and Identification of Degradation Products of Cephalexin Using LC–PDA and LC–MS/MS

A stability indicating RP-HPLC method for cephalexin has been developed and validated to identify and characterize potential degradation products. Drug was subjected to hydrolytic (acidic, basic, and neutral), oxidative, thermal, and photolytic stresses as per ICH guidelines Q1A (R2) and Q1B. Chromatographic separation was achieved on C8 column with mixture of ammonium acetate buffer pH 4.5 and acetonitrile in gradient mode as a mobile phase with PDA detection. Specificity of the method was established by peak purity studies. Method was validated as per ICH guideline Q2 (R1) for accuracy, precision, linearity, sensitivity, and robustness. Kinetics for each degradation condition was studied with respect to order of reaction and rate constant. Method was found to comply with acceptance criteria of validation parameters with respect to specificity (peak purity greater than 0.999) linearity (r ² greater than 0.99), accuracy (% recovery in the range of 98–102%), and precision (% RSD not more than 2). A total of six degradation products were generated in different stress conditions; these were identified and structures were proposed using LC–MS/MS. Cephalexin undergoes degradation in almost all the conditions. The developed stability indicating method is suitable for analysis of stability samples as it adequately separates all degradation products. Degradation products generated in photolytic and oxidative conditions are reported for the first time.     

Sensitive Determination of Felodipine in Human and Dog Plasma by Use of Liquid–Liquid Extraction and LC–ESI–MS–MS

Summary A sensitive and selective liquid chromatographic method coupled with electrospray ionization tandem mass spectrometry (LC–ESI–MS–MS) has been developed for quantification of felodipine in human and dog plasma. Compounds were separated on a 2.0 mm × 150 mm, 5.0 m particle, C₈ column with 1 m m ammonium acetate–acetonitrile, 20:80, pH 6.0, as mobile phase at a flow rate of 200 L min^–1. Nifedipine was used as internal standard. Plasma samples were extracted with diethyl ether, the centrifuged upper layer was evaporated, the residue was reconstituted with mobile phase, and the reconstituted samples were injected. The analytical column lasted for at least 1000 injections. By use of multiple reaction monitoring (MRM) mode in MS–MS felodipine and nifedipine were detected without severe interference from the human or dog plasma matrix. Felodipine produced a protonated precursor ion ([M + H]⁺) at m/z 384 and a corresponding product ion at m/z 338. And internal standard (nifedipine) produced a protonated precursor ion ([M + H]⁺) at m/z 347 and a corresponding product ion at m/z 315. Detection of felodipine in human and dog plasma was accurate and precise, with a limit of quantification of 0.05 ng mL^–1. The method has been successfully applied to preliminary pharmacokinetic study of felodipine in human and dog plasma.     

LC–MS/MS and NMR characterization of forced degradation products of mirabegron

A rapid, precise, and reliable liquid chromatography tandem mass spectrometry (LC–MS/MS) method has been developed for the characterization of stressed degradation products of mirabegron. It is used in the treatment of overactive bladder and administered to treat urinary symptoms such as urgency or frequency and incontinence. It also works by relaxing the muscles around bladder.

Mirabegron was subjected to hydrolysis (acidic, alkaline, and neutral) and peroxidation, as per ICH-specified conditions. The drug showed degradation under stress conditions. However, it was stable to neutral conditions. A total of seven degradation products were observed and the chromatographic separation of the drug and its degradation products was achieved on X-TerraRP-8 (250 mm × 4.6 mm, i.d., 5 µm) column using 0.01 M ammonium acetate as mobile phase-A and 60:40 ratio of acetonitrile (ACN):water as mobile phase-B. The degradation products were characterized by LC–MS/MS and its fragmentation pathways were proposed. Probable possible structures were drawn based on parent and daughter molecular ions. One peroxide degradant impurity was isolated using preparative LC and characterized using liquid chromatography–mass spectrometry and NMR data.     

Simultaneous Determination of Tamsulosin and Dutasteride in Human Plasma by LC–MS–MS

A sensitive and selective liquid chromatographic tandem mass spectrometric (LC–MS–MS) method was developed for simultaneous identification and quantification of tamsulosin and dutasteride in human plasma, which was well applied to clinical study. The method was based on liquid–liquid extraction, followed by an LC procedure with a Gemini C-18, 50 mm × 2.0 mm (3 μm) column and using methanol:ammonium formate (97:3, v/v) as the mobile phase. Protonated ions formed by a turbo ionspray in positive mode were used to detect analytes and internal standard. MS–MS detection was by monitoring the fragmentation of 409.1 → 228.1 (m/z) for tamsulosin, 529.3 → 461.3 (m/z) for dutasteride and 373.2 → 305.3 (m/z) for finasteride (IS) on a triple quadrupole mass spectrometer. The lower limit of quantification for both tamsulosin and dutasteride was 1 ng mL^?1. The proposed method enables the unambiguous identification and quantification of tamsulosin and dutasteride for clinical drug monitoring.     

Application of CE–ICP–MS and CE–ESI–MS in metalloproteomics: challenges,developments, and limitations

Application of capillary electrophoresis (CE) as a high-resolution separation technique in metalloproteomics research is critically reviewed. The focus is on the requirements and challenges involved in coupling CE to sensitive element and molecule-specific detection techniques such as inductively coupled plasma mass spectrometry (ICP–MS) or electrospray ionisation mass spectrometry (ESI–MS). The complementary application of both detection techniques to the structural and functional characterisation of metal-binding proteins and their structural metal-binding moieties is emphasised. Beneficial aspects and limitations of mass spectrometry hyphenated to CE are discussed, on the basis of the literature published in this field over the last decade. Recent metalloproteomics applications of CE are reviewed to demonstrate its potential and limitations in modern biochemical speciation analysis and to indicate future directions of this technique.     

Multiresidue Analysis of Pesticides in Vegetables and Citrus Fruits by LC–MS–MS

In this work, an analytical multiresidue method using liquid chromatography tandem-mass spectrometry (LC–MS–MS) with triple quadrupole in selected reaction monitoring (SRM) mode for the simultaneous determination of 54 pesticides in vegetables (pepper and tomato) and citrus fruits (orange and lemon) has been developed. The procedure involves initial single phase extraction of sample with acetonitrile by agitation, followed by liquid–liquid partition aided by “salting out” process using NaCl. The average recovery by the LC–MS–MS method obtained for these compounds varied from 65.5 to 114.5% with a relative standard deviation between 2.3 and 8.3%. The method presents good linearity over the range assayed 10–500 μg L^?1 (except famoxadone 50–1,000 μg L^?1) and the detection limits for the pesticides studied varied from 0.03 to 14.9 μg kg^?1. The proposed method was used to determine pesticide levels in vegetables and citrus fruit samples from different experimental orchards and greenhouses from the Region of Murcia.     

Simultaneous Determination of Atenolol and Chlorthalidone by LC–MS–MS in Human Plasma

A simple, sensitive, selective and rapid liquid chromatography–tandem mass spectrometry method was developed and validated for the simultaneous separation and quantitation of atenolol and chlorthalidone in human plasma using metoprolol and hydrochlorothiazide as internal standard. Following solid phase extraction, the analytes were separated by an isocratic mobile phase on a reversed-phase C₁₈ column and analyzed by MS in the multiple reaction-monitoring mode (atenolol in positive and chlorthalidone in the negative ion mode). The limit of quantitation for this method was 10 and 15 ng mL^?1 and the linear dynamic range was generally 10–2,050 ng mL^?1 and 15–3,035 ng mL^?1 for atenolol and chlorthalidone, respectively.     

Determination of Pentachloronitrobenzene and Its Metabolites in Ginseng by Matrix Solid-Phase Dispersion and GC–MS–MS

A rapid method was developed for the determination of pentachloronitrobenzene (PCNB) and its metabolites pentachloroaniline, pentachlorothioanisole residues in ginseng. Extraction and clean-up were carried out in a single step and analysis was accomplished by gas chromatography–mass spectrometry with multiple reaction monitoring. The main parameters affecting extraction yield and selectivity, such as type and amount of dispersant material, clean-up co-sorbent and extraction solvent were evaluated. The best results were obtained using 1 g ginseng, 2 g florisil as dispersant sorbent, 0.5 g neutral alumina as clean-up co-sorbent, and subsequent extraction with 10 mL acetone–n-hexane (5:5, v/v) with assisted sonication and repeated with another 5 mL of the same solvent mixture. The method was validated by analysis of ginseng samples fortified at different concentration levels (0.01–0.10 mg kg^?1). Average recoveries (n = 5) ranged from 85 to 95% with relative standard deviation between 2.5 and 11.2%. Spiked blank samples were used as standards to counteract the matrix effect observed in the chromatographic determination. The detection limits ranged from 0.2 to 0.9 µg kg^?1 in ginseng. The method was applied to the analysis of PCNB and its metabolite residues in commercial ginseng samples.     

Automated SPE and nanoLC–MS analysis of somatostatin

Plasma peptides are widely used in clinical diagnosis and therapy monitoring. Our aim was an efficient system development for the enrichment of small, low abundant peptides from plasma by robotized sample preparation. The automation of SPE yields additional time saving and improves system robustness and repeatability. Automation is based on combining a Waters SPE kit with Oasis HLB sorbent and a multichannel liquid handling workstation with cheap commercially available electronic devices such as a programmable logic controller (PLC) and an AVR controller. Reversed phase nano liquid chromatography coupled with a sensitive quadrupole time of flight mass spectrometer (QTOF MS) was used for the quantitative determination of somatostatin (SST). We quantified SST from mouse plasma, where lower limit of detection (LLOD) and lower limit of quantification (LLOQ) were 2.5 and 8.3 fmol/ml, respectively. We investigated linearity of response, accuracy, precision, recovery, reproducibility and stability of SST during both short-term sample processing and long-term storage. This method allows reliable quantification of plasma peptides. The developed automated sample preparation solid phase extraction method can be easily and conveniently adopted for different volumes and amounts of sample in routine analysis using controlled vacuum. The highest advantage is enhanced reproducibility, which makes it suitable for the investigations of large sample cohorts in clinical studies.     

LC–MS–MS Analysis of Mirtazapine in Plasma, and Determination of Pharmacokinetic Data for Rats

A sensitive LC–MS–MS method with electrospray ionization has been developed for analysis of mirtazapine in rat plasma. After addition of diazepam as internal standard, liquid–liquid extraction was used to produce a protein-free extract. Chromatographic separation was achieved on a 150 × 4.6 mm, 5 μm particle, ODS column with 84:16 (v/v) methanol–water containing 0.1% ammonium acetate and 0.01% glacial acetic acid as mobile phase. LC–MS–MS was performed in selected-ion-monitoring (SIM) mode using target fragment ions m/z 195.09 for mirtazapine and m/z 192.80 for the IS. Calibration plots were linear over the range of 0.516–618.8 ng mL^?1. The lower limit of quantification was 0.516 ng mL^?1. Intra-day and inter-day precision were better than 12.6 and 8.8%, respectively. Mean recovery of mirtazapine from plasma was in the range 87.41–90.06%; average recovery was 88.40% (RSD 3.95%). Significant gender differences between mirtazapine pharmacokinetic data were observed in this study.     

LC–MS and UPLC–Quadrupole Time-of-Flight MS for Identification of Photodegradation Products of Aflatoxin B1

UV irradiation of a solution of aflatoxin B₁ in acetonitrile resulted in three major degradation products which have been identified by LC–MS. Accurate masses and proposed molecular formulas of the degradation products—315.0868 (C₁₇H₁₅O₆), 285.0758 (C₁₆H₁₃O₅), and 275.0553 (C₁₄H₁₁O₆)—were obtained with low mass error and high matching property by ultra-performance liquid chromatography–quadrupole time-of-flight mass spectrometry (UPLC–Q-TOF MS). Structural formulas of the photodegradation products, and the degradation pathways leading to the compounds, are proposed on the basis of the molecular formulas and MS–MS spectra. UPLC–Q-TOF MS has been recognized as a powerful analytical tool for qualitative analysis of trace materials and degradation products.     

Bioavailability and biotransformation of sulforaphane and erucin metabolites in different biological matrices determined by LC–MS–MS

The food-related isothiocyanate sulforaphane (SFN), a hydrolysis product of the secondary plant metabolite glucoraphanin, has been revealed to have cancer-preventive activity in experimental animals. However, these studies have often provided inconsistent results with regard to bioavailability, bioaccessibility, and outcome. This might be because the endogenous biotransformation of SFN metabolites to the structurally related erucin (ERN) metabolites has often not been taken into account. In this work, a fully validated liquid chromatography tandem mass spectrometry (LC–MS–MS) method was developed for the simultaneous determination of SFN and ERN metabolites in a variety of biological matrices. To reveal the importance of the biotransformation pathway, matrices including plasma, urine, liver, and kidney samples from mice and cell lysates derived from colon-cancer cell lines were included in this study. The LC–MS–MS method provides limits of detection from 1 nmol L^?1 to 25 nmol L^?1 and a mean recovery of 99 %. The intra and interday imprecision values are in the range 1–10 % and 2–13 %, respectively. Using LC–MS–MS, SFN and ERN metabolites were quantified in different matrices. The assay was successfully used to determine the biotransformation in all biological samples mentioned above. For a comprehensive analysis and evaluation of the potential health effects of SFN, it is necessary to consider all metabolites, including those formed by biotransformation of SFN to ERN and vice versa. Therefore, a sensitive and robust LC–MS–MS method was validated for the simultaneous quantification of mercapturic-acid-pathway metabolites of SFN and ERN.

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Graphical Abstract Biotransformation of sulforaphane and erucin metabolites in mice and cell culture

     

LC–MS–MS Assay for Simultaneous Quantification of Fexofenadine and Pseudoephedrine in Human Plasma

A rapid, sensitive, and simple HPLC–MS–MS method, with electro-spray ionization and cetirizine as internal standard (IS), has been developed and validated for simultaneous quantification of fexofenadine and pseudoephedrine in human plasma. The analytes were isolated from plasma by solid-phase extraction (SPE) on Oasis HLB cartridges. The compounds were chromatographed on an RP 18 column with a mixture of ammonium acetate (10 mm, pH 6.4) and methanol as mobile phase. Quantification of the analytes was based on multiple reaction monitoring (MRM) of precursor-to-product ion pairs m/z 502 → 466 for fexofenadine, m/z 166 → 148 for pseudoephedrine, and m/z 389 → 201 for cetirizine. The linear calibration range for both analytes was 2–1,700 ng mL⁻¹ (r = 0.995), based on analysis of 0.1 mL plasma. Extraction recovery was 91.5 and 80.88% for fexofenadine and pseudoephedrine, respectively. The method was suitable for analysis of human plasma samples obtained 72 h after administration of a drug containing both fexofenadine and pseudoephedrine.     

LC–MS–MS Determination of Rotenone, Deguelin, and Rotenolone in Human Serum

For the first time we report a rapid and sensitive LC–MS–MS method for quantification of rotenone, deguelin, and rotenolone in human serum. The analytical procedure involves extraction with ethyl acetate without further clean-up. The active ingredients were separated on a C₈ reversed-phase column by isocratic elution. Eleven simultaneous transitions of precursor ions were monitored. Excellent selectivity and sensitivity enables quantification and identification of low levels of rotenoids (LOD 2 ng mL^?1, LOQ 5 ng mL^?1) in human serum.     

Analysis of Para Red and Sudan Dyes in Egg Yolk by UPLC–MS–MS

Matrix solid-phase dispersion (MSPD) with alumina N as adsorbent has been used for extraction of para red, Sudan 1, Sudan 2, Sudan 3, and Sudan 4 dyes from egg yolk. The extracts were analyzed by ultra-performance liquid chromatography–tandem mass spectrometry (UPLC–MS–MS). Mean recovery for the five dyes ranged from 63.2 to 98.6%, with CV 0.55–10.00%. One sample was confirmed to contain 0.3 mg kg^?1 Sudan 4.     

Comparison of GC–MS and LC–MS methods for the analysis of antioxidant phenolic acids in herbs

Two methods were developed for the quantitative analysis of phenolic acids in herb extracts. The methods were based on liquid chromatography–time-of-flight mass spectrometry (LC–TOFMS) and gas chromatography–mass spectrometry (GC–MS). The methods were compared in terms of their linearity, repeatability, selectivity, sensitivity and the speed of the analysis. The sensitivity was good for both methods, with limits of detection of <80 ng/ml for most of the compounds. The relative standard deviations (RSD) of the peak areas were on average 7.2% for the LC–TOFMS method and 1.4% for the GC–MS method. Both methods were found to be suitable for the determination of the target analytes, although GC–MS was better suited to the quantitative determination of compounds present at low concentrations.