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13. A specific and sensitive GC–MS-MS method for the quantitative determination of 2-phenoxyethanol and selected metabolites in human blood and urine.

Author

Jäger, Thomas, Eckert, Elisabeth, Leibold, Edgar, and Bader, Michael

Subjects
URINE, TANDEM mass spectrometry, HYDRAULIC fluids, PHENOXYACETIC acid, OCCUPATIONAL exposure, METABOLITES, LIQUID-liquid extraction
Abstract

2-Phenoxyethanol (PhE) is widely used as a preservative in consumer products such as cosmetics as well as at the workplace as a component of metal-working fluids and hydraulic fluids. Therefore, both industry workers and consumers may potentially be exposed to PhE. An analytical method for the quantification of PhE and three selected metabolites, namely phenoxyacetic acid (PhAA), 4-hydroxyphenoxyacetic acid (4-OH-PhAA), and 4-hydroxyphenoxyethanol (4-OH-PhE), in human urine and blood was developed and validated. The sample preparation includes enzymatic hydrolysis of urine samples or protein precipitation of blood samples, followed by liquid – liquid extraction and silylation of the target analytes. Analyses of the extracts were carried out by gas chromatography with tandem mass spectrometry (GC – MS-MS). 3,4-Hydroxyphenoxyethanol, a probably minor PhE metabolite, could not be reliably analyzed due to its instability. The limits of quantification (LOQ) of the analytes ranged between 0.5 and 6.1 μg/L and 2.0 and 3.9 μg/L in urine and blood, respectively. The method was successfully applied to spot urine samples of 50 individuals without occupational exposure to PhE and additionally to blood samples from seven volunteers. In urine, PhAA and 4-OH-PhAA could be quantified in all analyzed samples, whereas 4-OH-PhE and unchanged PhE were found in 36% and 32% of the samples, respectively. In blood, PhAA was also found in every sample in levels above the LOQ, whereas PhE itself was detected in three of seven samples only. Neither 4-OH-PhAA nor 4-OH-PhE was found in any of the analyzed blood samples. The developed method promises to be a valuable tool for PhE monitoring of urine and blood samples and may also enable an advanced investigation of PhE biotransformation pathways in humans. [ABSTRACT FROM AUTHOR]

Published
2024
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24. Sensory irritation as a basis for setting occupational exposure limits

Author

Brüning, Thomas, Bartsch, Rüdiger, Bolt, Hermann Maximillian, Desel, Herbert, Drexler, Hans, Gundert-Remy, Ursula, Hartwig, Andrea, Jäckh, Rudolf, Leibold, Edgar, Pallapies, Dirk, Rettenmeier, Albert W., Schlüter, Gerhard, Stropp, Gisela, Sucker, Kirsten, Triebig, Gerhard, Westphal, Götz, and van Thriel, Christoph

Published
2014
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29. Vinyl Esters

Author

Bienewald, Frank, primary, Leibold, Edgar, additional, Tužina, Pavel, additional, and Roscher, Günter, additional

Published
2019
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31. Oligomers of styrene are not endocrine disruptors

Author

Gelbke, Heinz-Peter, primary, Banton, Marcy, additional, Block, Christian, additional, Dawkins, Gordon, additional, Leibold, Edgar, additional, Pemberton, Mark, additional, Sakoda, Atsunobu, additional, and Yasukawa, Atsushi, additional

Published
2018
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33. The Use of Metabolomics In Vivo for the Development of Agrochemical Products

Author

Kamp, Hennicke G., primary, Ahlbory‐Dieker, Doerthe, additional, Fabian, Eric, additional, Herold, Michael, additional, Krennrich, Gerhard, additional, Leibold, Edgar, additional, Looser, Ralf, additional, Mellert, Werner, additional, Prokoudine, Alexandre, additional, Strauss, Volker, additional, Walk, Tilmann, additional, Wiemer, Jan, additional, and van Ravenzwaay, Bennard, additional

Published
2012
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35. Metabolite profiling—A new tool for the identification of toxicological effects of chemicals

Author

Kamp, Hennicke, primary, Buesen, Roland, additional, Cunha, Georgia Coelho-Palermo, additional, Fabian, Eric, additional, Fischer, Wolfgang, additional, Herold, Michael, additional, Leibold, Edgar, additional, Looser, Ralf, additional, Krennrich, Gerhard, additional, Mellert, Werner, additional, Nishino, Tsuyuki, additional, Prokoudine, Alexandre, additional, Strauss, Volker, additional, Walk, Tilmann, additional, Wiemer, Jan, additional, and van Ravenzwaay, Bennard, additional

Published
2009
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36. Human Metabolism and Urinary Elimination Kinetics of the Fragrance Geraniol after Oral Dosage

Author

Jäger, Thomas, Koch, Holger M., Leibold, Edgar, and Bader, Michael

Abstract

Geraniol is a fragrance with a characteristic rose-like smell, naturally occurring in terpene oil and also chemically synthesized on a large scale. Geraniol is widely used in consumer products such as cosmetics, personal care products, and household cleaners and as an additive in foods. An experimental study in human volunteers was carried out to investigate the metabolism and elimination kinetics of geraniol. Three subjects were orally exposed to geraniol in two different dosages (25 or 250 mg). In each case, one pre-exposure urine sample and all urine voids for 72 h after exposure were collected separately. The geraniol metabolites Hildebrandt acid, geranic acid, 3-hydroxycitronellic acid, and 8-carboxygeraniol were analyzed in every sample after enzymatic hydrolysis and liquid–liquid extraction using liquid chromatography-tandem mass spectrometry (LC-MS/MS). Maximum urinary concentrations of the metabolites were measured between 1 and 5 h after oral dosing, and elimination half-lives were determined to be about 2–4 h. The predominant metabolite found in urine was Hildebrandt acid with 34.4 ± 5.6% of the ingested dose, followed by geranic acid (12.7 ± 5.6%), 3-hydroxycitronellic acid (2.2 ± 0.4%), and 8-carboxygeraniol (0.19 ± 0.09%). In total, the four metabolites determined represent 41.7–55.5% of the ingested dose. Only 8-carboxygeraniol is, however, a specific metabolite, while the other three target analytes are also formed from other terpenes like citral. Within this study, conversion factors were calculated, which allow for a rough estimate of the total geraniol uptake by back-calculation from metabolite concentrations of spot urine samples. Taking the conversion factor for all four metabolites into account, a mean daily uptake of geraniol of 1.43 mg was estimated from 41 urine samples of occupationally nonexposed adults. The metabolites Hildebrandt acid, geranic acid, 3-hydroxycitronellic acid, and 8-carboxygeraniol in urine are suitable biomarkers of exposure for geraniol and can be used for human biomonitoring studies.

Published
2023
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37. Hexamoll ® DINCH: Lack of in vivo evidence for obesogenic properties.

Author

Langsch A, David RM, Schneider S, Sperber S, Haake V, Kamp H, Leibold E, Ravenzwaay BV, and Otter R

Subjects
Adipose Tissue metabolism, Adiposity drug effects, Animals, Body Weight drug effects, Cyclohexanecarboxylic Acids pharmacokinetics, Dicarboxylic Acids pharmacokinetics, Diethylhexyl Phthalate metabolism, Diethylhexyl Phthalate toxicity, Dose-Response Relationship, Drug, Female, Half-Life, Liver drug effects, Male, Metabolome drug effects, Organ Size drug effects, Plasticizers pharmacokinetics, Pregnancy, Prenatal Exposure Delayed Effects, Rats, Rats, Wistar, Cyclohexanecarboxylic Acids toxicity, Dicarboxylic Acids toxicity, Obesity chemically induced, Plasticizers toxicity
Abstract

Hexamoll ® DINCH is an important alternative to phthalate plasticizers. Although regulatory reviews have not identified any potential hazards even in sensitive populations, an in vitro study by Campioli et al. (2015) suggested Hexamoll ® DINCH might alter fat storage in adipocytes resulting in obesity. To evaluate this hypothesis, data from studies with Hexamoll ® DINCH were reviewed for evidence of deposition in fat, changes in body weight, or changes in serum chemistry reflecting altered metabolic status. Body weights of F1 and F2 pups in a two-generation study did not differ from controls even at 1000 mg Hexamoll ® DINCH/kg body weight. Mean relative liver weights from the 1000 and 300 mg/kg bw groups were increased, but without histopathologic changes. Triglyceride and cholesterol levels in serum were not affected. In addition, subchronic and chronic studies in rats did not give evidence of an obesogenic effect. Radioactivity from 20 or 1000 mg/kg bw 14 C-labelled Hexamoll ® DINCH dosed orally remained 2-3 times longer in adipose tissue than in well-perfused tissues; however, levels were 20-500% below other tissues at 1 and 8 h post dosing. Radioactivity concentrations in organs and tissues excluding the GI tract declined rapidly and continuously, and decreased in parallel to the concentration in plasma during the following 20 h. Both, initial and terminal half-lives of radioactivity concentration do not indicate a potential for accumulation. Furthermore, a metabolomic comparison of Hexamoll ® DINCH with DEHP and other phthalates shows complete separation of the metabolomic profile of these two chemical classes, meaning that their effects on the body and the body's reaction to the substance are different. Hence, comprehensive in vivo data do not show any evidence of Hexamoll ® DINCH altering fat metabolism or having obesogenic properties., (Copyright © 2018 Elsevier B.V. All rights reserved.)

Published
2018
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