TY - JOUR
T1 - Biotransformation of 17α- and 17β-estradiol in aerobic soils
AU - Mashtare, Michael L.
AU - Green, Dara A.
AU - Lee, Linda S.
N1 - Funding Information:
This work was funded in part by a U.S.D.A. AFRI Water and Watersheds Award No. 104117 and by a Purdue University College of Agriculture Undergraduate Research Grant . We also wish to acknowledge Stephen Sassman for his analytical chemistry support, Marianne Bischoff for her help with the GC, and Dr. Steven J. Landry for his statistical support.
PY - 2013/1
Y1 - 2013/1
N2 - Considerable research has focused on the fate of 17β-estradiol (17β-E2) given its high estrogenic potency and frequent detection in the environment; however, little is known about the fate behavior of 17α-estradiol (17α-E2) although it often dominates in some animal feces, and recently has been shown to have similar impacts as the β-isomer. In this study, the aerobic biotransformation rates of 17α-E2 and 17β-E2 applied at 50μgkg-1 soil and metabolite trends were quantified in batch microcosms at ∼21°C and 70-85% field capacity using two soils with different taxonomic properties. Soils were extracted at designated times over a 3-week period and analyzed over time using negative electrospray ionization tandem mass spectrometry. For a given soil type, the two isomers degraded at the same rate with half lives across soils ranging between 4 and 12h. Estrone (E1) was the only metabolite detected and in all cases subsequent dissipation patterns of E1 are statistically different between isomers. Autoclaved-sterilized controls support that E2 dissipation is dominated by microbial processes. A first order exponential decay model that assumed sorption did not limit bioavailability was not able to accurately predict hormone residuals at later times, which indicates caution is required when trying to model fate and transport of hormones in the environment.
AB - Considerable research has focused on the fate of 17β-estradiol (17β-E2) given its high estrogenic potency and frequent detection in the environment; however, little is known about the fate behavior of 17α-estradiol (17α-E2) although it often dominates in some animal feces, and recently has been shown to have similar impacts as the β-isomer. In this study, the aerobic biotransformation rates of 17α-E2 and 17β-E2 applied at 50μgkg-1 soil and metabolite trends were quantified in batch microcosms at ∼21°C and 70-85% field capacity using two soils with different taxonomic properties. Soils were extracted at designated times over a 3-week period and analyzed over time using negative electrospray ionization tandem mass spectrometry. For a given soil type, the two isomers degraded at the same rate with half lives across soils ranging between 4 and 12h. Estrone (E1) was the only metabolite detected and in all cases subsequent dissipation patterns of E1 are statistically different between isomers. Autoclaved-sterilized controls support that E2 dissipation is dominated by microbial processes. A first order exponential decay model that assumed sorption did not limit bioavailability was not able to accurately predict hormone residuals at later times, which indicates caution is required when trying to model fate and transport of hormones in the environment.
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U2 - 10.1016/j.chemosphere.2012.09.032
DO - 10.1016/j.chemosphere.2012.09.032
M3 - Article
C2 - 23084590
AN - SCOPUS:84869874435
SN - 0045-6535
VL - 90
SP - 647
EP - 652
JO - Chemosphere
JF - Chemosphere
IS - 2
ER -