HPLC-ESI-HRMS2 Determination of N-(2-Hydroxyethyl)-l-valyl-l-leucine in Human Urine: Method Validation.

Biomonitoring of human exposure to reactive electrophilic chemicals such as ethylene oxide (EO) has been commonly based on the determination of adducts with N-terminal valine in blood protein globin, but a systematic search has also been undertaken to find surrogate markers enabling non-invasive sampling. Recently, N-(2-hydroxyethyl)-L-valyl-L-leucine (HEVL) has been identified as an ultimate cleavage product of EO-adducted globin in the urine of occupationally exposed workers. Herein, full validation of the analytical procedure consisting of solid-phase extraction of HEVL from urine samples (2 mL) followed by high-performance liquid chromatography-electrospray ionization-high-resolution mass spectrometry determination using deuterium-labeled HEVL as an internal standard (IS) is described. Method limit of quantitation is 0.25 ng/mL, and its selectivity is excellent as demonstrated by the invariable ratio of the qualifier and quantifier ion intensities across diverse urine samples and synthetic standard. The linear calibration model was applicable over the whole concentration range tested (0.25-10 ng/mL). The method accuracy assessed as a recovery of HEVL using a spiking experiment was 98-100%. Within-day precision of the method ranged from 1.8% to 3.0%, while the results from consecutive analytical runs conducted within 1 week or within 10-150 weeks differed in the range of 2.2-9.7%. The stability study on urine samples (-20°C up to 3 years, freeze-and-thaw up to 10 cycles) as well as on aqueous solutions (5°C up to 4 months) indicated no relevant changes in HEVL concentration (≤4%) over the time tested. Analytical responses of both HEVL and IS correlated with urinary creatinine as an index of matrix composition, but this matrix effect was mostly eliminated using the HEVL/IS peak area ratio, attaining the IS-normalized relative matrix effect <3%. In conclusion, the method complied successfully with the bioanalytical method validation criteria, making it a reliable tool for HEVL determination in human biomonitoring.

Determination of N-(2-hydroxyethyl)valine in globin of ethylene oxide-exposed workers using total acidic hydrolysis and HPLC-ESI-MS2.

Ethylene oxide (EO), an industrial intermediate and gaseous sterilant for medical devices, is carcinogenic to humans, which warrants minimization of exposure in the workplaces. The principal analytical strategy currently used in biomonitoring of exposure to EO consists in the conversion of N-(2-hydroxyethyl) adduct at the N-terminal valine (HEV) in globin to a specific thiohydantoin derivative accessible to GC-MS analysis (modified Edman degradation, MED). Though highly sensitive, the method is laborious and, at least in our hands, not sufficiently robust. Here we developed an alternative strategy of HEV determination based on acidic hydrolysis (AH) of globin followed directly by HPLC-ESI-MS2 analysis. Limit of quantitation is ca. 25 pmol HEV/g globin. Comparative analyses of globin samples from EO-exposed workers by both the AH-based and MED-based methods provided results that correlated well with each other (R2 > 0.95) but those obtained with AH were significantly more accurate (according to external quality control programme G-EQUAS) and repeatible (5% and 6% for intra-day and between-day analyses, respectively). In conclusion, the new AH-based method surpassed MED being similarly sensitive, much less laborious and more reliable, thus applicable as an effective tool for biomonitoring of EO in exposure control and risk assessment.

Biological fate of styrene oxide adducts with globin: Elimination of cleavage products in the rat urine.

The in vivo fate of globin adducts with styrene 7,8-oxide (SO), an electrophilic metabolic intermediate of styrene, was studied in male Wistar rats dosed intraperitoneally with racemic SO, 100mg/kg b.w. Regioisomeric hydroxy(phenyl)ethyl (HPE) adducts at Cys, N-terminal Val, Lys and His in globin were determined and their elimination from blood was followed during 60days, corresponding to life span of rat erythrocytes. In the rat urine, Nα-acetylated products of hydrolytic cleavage of the HPE adducts with Cys, Lys and His were determined. On the first day post-exposure, abundant Nα-acetyl-HPE-Cys adducts (mercapturic acids) formed via direct conjugation of SO with hepatic glutathione were excreted rapidly, but then a much slower phase of elimination reflecting formation of Nα-acetyl-HPE-Cys via cleavage of the adducted globin was observed. A two-phase elimination occurred also in urinary Nα-acetyl-HPE adducts with His and Lys. While a decline by 75-85% during the first 7days post-exposure most likely reflected elimination of adducted albumin, the subsequent slow decline until day 60 corresponded to elimination kinetics of the adducted globin. Thus, the study not only provided original data on the fate of SO-globin adducts but also allowed to reveal general toxicokinetics properties of the urinary cleavage products as a novel type of chemical exposure biomarkers.