Hepatic and extra-hepatic metabolism of propylene glycol ethers in the context of central nervous system toxicity
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Autor:in (Körperschaft)
Publikationsdatum
03.2025
Typ der Arbeit
Studiengang
Typ
01A - Beitrag in wissenschaftlicher Zeitschrift
Herausgeber:innen
Herausgeber:in (Körperschaft)
Betreuer:in
Übergeordnetes Werk
Toxicology
Themenheft
DOI der Originalpublikation
Link
Reihe / Serie
Reihennummer
Jahrgang / Band
512
Ausgabe / Nummer
Seiten / Dauer
154081
Patentnummer
Verlag / Herausgebende Institution
Elsevier
Verlagsort / Veranstaltungsort
Auflage
Version
Programmiersprache
Abtretungsempfänger:in
Praxispartner:in/Auftraggeber:in
Zusammenfassung
Propylene glycol ethers (PGEs) are mixtures of an α-isomer and a β-isomer (β-PGE) that is oxidized via alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH) to potentially neurotoxic alkoxy propionic acids (β-metabolites). While the liver is the primary organ for ADH- and ALDH-mediated metabolism, the contribution to the metabolism of β-PGEs by the blood-brain barrier (BBB) and the brain remains unknown. Here, we aimed to assess the neurotoxic potential of PGEs after systemic exposure by (1) comparing 3D HepaRG and human liver subcellular fraction (S9) for the in vitro determination of the kinetics of hepatic metabolism for β-PGEs, (2) evaluating the BBB-permeability of PGEs and β-metabolites, (3) determining the presence of ADH1 and ALDH2 and the extent of metabolization of β-PGEs in the BBB and brain. The results show that 3D HepaRG and S9 served as competent systems to estimate the enzymatic kinetic (clearance) for β-metabolite formation. We observed that PGEs and the β-metabolites could cross the BBB, based on their permeance across a cellular barrier consisting of the hCMEC/D3 cell line. Metabolic enzymes were not exclusive to the liver, as expression of ADH1 and ALDH2 was demonstrated using RT-qPCR, Western blot, and immunostainings in the BBB in vitro models and in BrainSpheres. Furthermore, LC-MS/MS quantification of the β-metabolites in all in vitro models revealed that 3D HepaRG had a similar metabolic capacity to primary human hepatocytes and that the amount of β-metabolite formed per protein in the BBB was approximately 10–30 % of that in the liver. We also demonstrated active metabolism in the BrainSpheres. In conclusion, the hepatic in vitro models provided data that will help to refine toxicokinetic models and predict internal exposures, thereby supporting the risk assessment of PGEs. In addition, the high permeance of the PGEs and the β-metabolites across the BBB increases the plausibility of neurotoxicity upon systemic exposure. This is further supported by the presence of active ADH1 and ALDH2 enzymes in the BBB in vitro systems and in BrainSpheres, suggesting metabolite formation in the central nervous system. Hence, we suggest that BBB-permeance and extra-hepatic metabolism of the β-PGEs may contribute to the neurotoxicity of PGEs.
Schlagwörter
Neurotoxicity, Glycol ether, Hepatic metabolism, Extra-hepatic metabolism, blood-brain barrier, In silico, Alcohol- and aldehyde dehydrogenase
Fachgebiet (DDC)
Veranstaltung
Startdatum der Ausstellung
Enddatum der Ausstellung
Startdatum der Konferenz
Enddatum der Konferenz
Datum der letzten Prüfung
ISBN
ISSN
0300-483X
Sprache
Englisch
Während FHNW Zugehörigkeit erstellt
Ja
Zukunftsfelder FHNW
Future Health
Publikationsstatus
Veröffentlicht
Begutachtung
Peer-Review der ganzen Publikation
Open Access-Status
Hybrid
Lizenz
Zitation
Werner, S., Pamies, D., Zurich, M.-G., & Suter-Dick, L. (2025). Hepatic and extra-hepatic metabolism of propylene glycol ethers in the context of central nervous system toxicity. Toxicology, 512, 154081. https://doi.org/10.1016/j.tox.2025.154081