Sorption and Mobility of Charged Organic Compounds: How to Confront and Overcome Limitations in Their Assessment

Gabriel Sigmund; Hans Peter H. Arp; Benedikt M. Aumeier; Thomas D. Bucheli; Benny Chefetz; Wei Chen; Steven T.J. Droge; Satoshi Endo; Beate I. Escher; Sarah E. Hale; Thilo Hofmann; Joseph Pignatello; Thorsten Reemtsma; Torsten C. Schmidt; Carina D. Schönsee; Martin Scheringer

doi:https://doi.org/10.1021/acs.est.2c00570

Sorption and Mobility of Charged Organic Compounds: How to Confront and Overcome Limitations in Their Assessment

Gabriel Sigmund, Hans Peter H. Arp, Benedikt M. Aumeier, Thomas D. Bucheli, Benny Chefetz, Wei Chen, Steven T.J. Droge, Satoshi Endo, Beate I. Escher, Sarah E. Hale, Thilo Hofmann, Joseph Pignatello, Thorsten Reemtsma, Torsten C. Schmidt, Carina D. Schönsee, Martin Scheringer

Department of Soil and Water Sciences

The Hebrew University of Jerusalem

Research output: Contribution to journal › Article › peer-review

Abstract

Permanently charged and ionizable organic compounds (IOC) are a large and diverse group of compounds belonging to many contaminant classes, including pharmaceuticals, pesticides, industrial chemicals, and natural toxins. Sorption and mobility of IOCs are distinctively different from those of neutral compounds. Due to electrostatic interactions with natural sorbents, existing concepts for describing neutral organic contaminant sorption, and by extension mobility, are inadequate for IOC. Predictive models developed for neutral compounds are based on octanol-water partitioning of compounds (K_ow) and organic-carbon content of soil/sediment, which is used to normalize sorption measurements (K_OC). We revisit those concepts and their translation to IOC (D_owand D_OC) and discuss compound and soil properties determining sorption of IOC under water saturated conditions. Highlighting possible complementary and/or alternative approaches to better assess IOC mobility, we discuss implications on their regulation and risk assessment. The development of better models for IOC mobility needs consistent and reliable sorption measurements at well-defined chemical conditions in natural porewater, better IOC-, as well as sorbent characterization. Such models should be complemented by monitoring data from the natural environment. The state of knowledge presented here may guide urgently needed future investigations in this field for researchers, engineers, and regulators.

Original language	English
Pages (from-to)	4702-4710
Number of pages	9
Journal	Environmental Science and Technology
Volume	56
Issue number	8
DOIs	https://doi.org/10.1021/acs.est.2c00570
State	Published - 19 Apr 2022

Keywords

anion
cation
contaminant fate
environmental risk assessment
ionizable organic compound
sorption model
zwitterion

All Science Journal Classification (ASJC) codes

General Chemistry
Environmental Chemistry

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https://doi.org/10.1021/acs.est.2c00570

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Sigmund, G., Arp, H. P. H., Aumeier, B. M., Bucheli, T. D., Chefetz, B., Chen, W., Droge, S. T. J., Endo, S., Escher, B. I., Hale, S. E., Hofmann, T., Pignatello, J., Reemtsma, T., Schmidt, T. C., Schönsee, C. D., & Scheringer, M. (2022). Sorption and Mobility of Charged Organic Compounds: How to Confront and Overcome Limitations in Their Assessment. Environmental Science and Technology, 56(8), 4702-4710. https://doi.org/10.1021/acs.est.2c00570

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title = "Sorption and Mobility of Charged Organic Compounds: How to Confront and Overcome Limitations in Their Assessment",

abstract = "Permanently charged and ionizable organic compounds (IOC) are a large and diverse group of compounds belonging to many contaminant classes, including pharmaceuticals, pesticides, industrial chemicals, and natural toxins. Sorption and mobility of IOCs are distinctively different from those of neutral compounds. Due to electrostatic interactions with natural sorbents, existing concepts for describing neutral organic contaminant sorption, and by extension mobility, are inadequate for IOC. Predictive models developed for neutral compounds are based on octanol-water partitioning of compounds (Kow) and organic-carbon content of soil/sediment, which is used to normalize sorption measurements (KOC). We revisit those concepts and their translation to IOC (Dowand DOC) and discuss compound and soil properties determining sorption of IOC under water saturated conditions. Highlighting possible complementary and/or alternative approaches to better assess IOC mobility, we discuss implications on their regulation and risk assessment. The development of better models for IOC mobility needs consistent and reliable sorption measurements at well-defined chemical conditions in natural porewater, better IOC-, as well as sorbent characterization. Such models should be complemented by monitoring data from the natural environment. The state of knowledge presented here may guide urgently needed future investigations in this field for researchers, engineers, and regulators.",

keywords = "anion, cation, contaminant fate, environmental risk assessment, ionizable organic compound, sorption model, zwitterion",

author = "Gabriel Sigmund and Arp, {Hans Peter H.} and Aumeier, {Benedikt M.} and Bucheli, {Thomas D.} and Benny Chefetz and Wei Chen and Droge, {Steven T.J.} and Satoshi Endo and Escher, {Beate I.} and Hale, {Sarah E.} and Thilo Hofmann and Joseph Pignatello and Thorsten Reemtsma and Schmidt, {Torsten C.} and Sch{\"o}nsee, {Carina D.} and Martin Scheringer",

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doi = "https://doi.org/10.1021/acs.est.2c00570",

language = "الإنجليزيّة",

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Sigmund, G, Arp, HPH, Aumeier, BM, Bucheli, TD, Chefetz, B, Chen, W, Droge, STJ, Endo, S, Escher, BI, Hale, SE, Hofmann, T, Pignatello, J, Reemtsma, T, Schmidt, TC, Schönsee, CD & Scheringer, M 2022, 'Sorption and Mobility of Charged Organic Compounds: How to Confront and Overcome Limitations in Their Assessment', Environmental Science and Technology, vol. 56, no. 8, pp. 4702-4710. https://doi.org/10.1021/acs.est.2c00570

TY - JOUR

T1 - Sorption and Mobility of Charged Organic Compounds

T2 - How to Confront and Overcome Limitations in Their Assessment

AU - Sigmund, Gabriel

AU - Arp, Hans Peter H.

AU - Aumeier, Benedikt M.

AU - Bucheli, Thomas D.

AU - Chefetz, Benny

AU - Chen, Wei

AU - Droge, Steven T.J.

AU - Endo, Satoshi

AU - Escher, Beate I.

AU - Hale, Sarah E.

AU - Hofmann, Thilo

AU - Pignatello, Joseph

AU - Reemtsma, Thorsten

AU - Schmidt, Torsten C.

AU - Schönsee, Carina D.

AU - Scheringer, Martin

PY - 2022/4/19

Y1 - 2022/4/19

N2 - Permanently charged and ionizable organic compounds (IOC) are a large and diverse group of compounds belonging to many contaminant classes, including pharmaceuticals, pesticides, industrial chemicals, and natural toxins. Sorption and mobility of IOCs are distinctively different from those of neutral compounds. Due to electrostatic interactions with natural sorbents, existing concepts for describing neutral organic contaminant sorption, and by extension mobility, are inadequate for IOC. Predictive models developed for neutral compounds are based on octanol-water partitioning of compounds (Kow) and organic-carbon content of soil/sediment, which is used to normalize sorption measurements (KOC). We revisit those concepts and their translation to IOC (Dowand DOC) and discuss compound and soil properties determining sorption of IOC under water saturated conditions. Highlighting possible complementary and/or alternative approaches to better assess IOC mobility, we discuss implications on their regulation and risk assessment. The development of better models for IOC mobility needs consistent and reliable sorption measurements at well-defined chemical conditions in natural porewater, better IOC-, as well as sorbent characterization. Such models should be complemented by monitoring data from the natural environment. The state of knowledge presented here may guide urgently needed future investigations in this field for researchers, engineers, and regulators.

AB - Permanently charged and ionizable organic compounds (IOC) are a large and diverse group of compounds belonging to many contaminant classes, including pharmaceuticals, pesticides, industrial chemicals, and natural toxins. Sorption and mobility of IOCs are distinctively different from those of neutral compounds. Due to electrostatic interactions with natural sorbents, existing concepts for describing neutral organic contaminant sorption, and by extension mobility, are inadequate for IOC. Predictive models developed for neutral compounds are based on octanol-water partitioning of compounds (Kow) and organic-carbon content of soil/sediment, which is used to normalize sorption measurements (KOC). We revisit those concepts and their translation to IOC (Dowand DOC) and discuss compound and soil properties determining sorption of IOC under water saturated conditions. Highlighting possible complementary and/or alternative approaches to better assess IOC mobility, we discuss implications on their regulation and risk assessment. The development of better models for IOC mobility needs consistent and reliable sorption measurements at well-defined chemical conditions in natural porewater, better IOC-, as well as sorbent characterization. Such models should be complemented by monitoring data from the natural environment. The state of knowledge presented here may guide urgently needed future investigations in this field for researchers, engineers, and regulators.

KW - anion

KW - cation

KW - contaminant fate

KW - environmental risk assessment

KW - ionizable organic compound

KW - sorption model

KW - zwitterion

UR - http://www.scopus.com/inward/record.url?scp=85127956487&partnerID=8YFLogxK

U2 - https://doi.org/10.1021/acs.est.2c00570

DO - https://doi.org/10.1021/acs.est.2c00570

M3 - مقالة

C2 - 35353522

SN - 0013-936X

VL - 56

SP - 4702

EP - 4710

JO - Environmental Science and Technology

JF - Environmental Science and Technology

IS - 8

ER -

Sorption and Mobility of Charged Organic Compounds: How to Confront and Overcome Limitations in Their Assessment

Abstract

Keywords

All Science Journal Classification (ASJC) codes

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