Determining the Temperature Dependency of Biodegradation Kinetics for 34 Hydrocarbons while Avoiding Chemical and Microbial Confounding Factors

Karina Knudsmark Sjøholm*, Heidi Birch, Rikke Hammershøj, David M. V. Saunders, Arnaud Dechesne, Andreas P. Loibner, Philipp Mayer

*Corresponding author for this work

    Research output: Contribution to journalJournal articleResearchpeer-review

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    Abstract

    Biodegradation kinetics data are keystone for evaluating the environmental persistence and risk of chemicals. Biodegradation kinetics depend highly on the prevailing temperature, which influences microbial community structures, metabolic rates, and chemical availability. There is a lack of high-quality comparative biodegradation kinetics data that are determined at different test temperatures but with the same microbial inoculum and chemical availability. The present study was designed to determine the effect of test temperature on the biodegradation kinetics of hydrocarbons while avoiding confounding factors. We used inocula from a Northern river (2.7 °C) and a Central European river (12.5 °C). Aqueous stock solutions containing 45 individual hydrocarbons were generated by passive dosing and added to river water containing the native microorganisms. Compound-specific biodegradation kinetics were then determined at 2.7, 12, and 20 °C based on substrate depletion. Main findings comprise the following: (1) Degradation half-times (DegT50) of 34 test chemicals were determined at different test temperatures and were largely consistent with the Arrhenius equation (activation energy, 65.4 kJ/mol). (2) Differences in biodegradation kinetics between tested isomers were rather limited. (3) The recent lowering of standard test temperature from 20 to 12 °C results typically in a doubling of DegT50 values and can lead to a stricter persistency assessment.
    Original languageEnglish
    JournalEnvironmental Science and Technology
    Volume55
    Issue number16
    Pages (from-to)11091-11101
    ISSN0013-936X
    DOIs
    Publication statusPublished - 2021

    Bibliographical note

    ACS AuthorChoice Open Access after 12 months

    Keywords

    • Arrhenius equation
    • Danube
    • Isomer-specific degradation
    • OECD 309
    • Simulation biodegradation test

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