Elimination half‐life as a metric for the bioaccumulation potential of chemicals in aquatic and terrestrial food chains

The assessment of chemicals as bioaccumulative in the regulatory process makes use of the bioconcentration factor as a metric. However, this metric does not account for the dietary uptake route and therefore cannot be applied to terrestrial food chains. In recent years, the biomagnification factor (BMF) and the trophic magnification factor (TMF) have been suggested as standard metrics for bioaccumulation. For regulatory purposes, though, the BMF and the TMF also suffer from a number of shortcomings. They are not applicable to assess uptake routes other than the diet (e.g., dermal uptake, as is important for personal care products). When measured in the field, they depend largely on biological and ecological factors and less so on the chemical's properties, and they are difficult to normalize and standardize. In the present study, the authors suggest the elimination half‐life (EL0.5) of a chemical as an alternative metric for bioaccumulation. The EL0.5 is equivalent to the depuration rate constant (k2) that is measured in various bioaccumulation and bioconcentration tests. This metric can be applied to air‐ and water‐breathing animals, and it is valuable for all uptake routes. It has a number of practical advantages over the BMF and the TMF. In combination with a standard uptake scenario, the EL0.5 can also be linked directly to a BMF threshold of unity. Thus, the EL0.5 as a bioaccumulation metric overcomes the shortcomings of the BMF and the TMF while still conserving the advantages of the latter metrics. Environ Toxicol Chem 2013;32:1663–1671. © 2013 SETAC

[1]  D. Mackay,et al.  Dynamics of dietary bioaccumulation and faecal elimination of hydrophobic organic chemicals in fish , 1988 .

[2]  S. Heymsfield,et al.  The five-level model: a new approach to organizing body-composition research. , 1992, The American journal of clinical nutrition.

[3]  J. Hobbie,et al.  Using ratios of stable nitrogen isotopes to estimate bioaccumulation and flux of polychlorinated dibenzo‐p‐dioxins (PCDDs) and dibenzofurans (PCDFs) in two food chains from the Northern Baltic , 1992 .

[4]  Dag Broman,et al.  Dietary uptake in pike (Esox lucius) of some polychlorinated biphenyls, polychlorinated naphthalenes and polybrominated diphenyl ethers administered in natural diet , 1997 .

[5]  D. Mackay,et al.  Controlling persistent organic pollutants-what next? , 1998, Environmental toxicology and pharmacology.

[6]  Aaron T. Fisk,et al.  Dietary accumulation and depuration of hydrophobic organochlorines: Bioaccumulation parameters and their relationship with the octanol/water partition coefficient , 1998 .

[7]  Robert S. Boethling,et al.  Screening for persistent organic pollutants: Techniques to provide a scientific basis for POPs criteria in international negotiations , 1999 .

[8]  M. McLachlan,et al.  The influence of dietary concentration on the absorption and excretion of persistent lipophilic organic pollutants in the human intestinal tract. , 2001, Chemosphere.

[9]  K. Hobson,et al.  Influence of chemical and biological factors on trophic transfer of persistent organic pollutants in the northwater polynya marine food web. , 2001, Environmental science & technology.

[10]  F. Gobas,et al.  Bioaccumulation of persistent organic pollutants in lichen-caribou-wolf food chains of Canada's Central and Western Arctic. , 2001, Environmental science & technology.

[11]  S. Lindstedt,et al.  Use of allometry in predicting anatomical and physiological parameters of mammals , 2002, Laboratory animals.

[12]  Karlheinz Ballschmiter,et al.  Man-made chemicals found in remote areas of the world: The experimental definition for POPs , 2002, Environmental science and pollution research international.

[13]  F. Gobas,et al.  Quantitative Structure Activity Relationships for Predicting the Bioaccumulation of POPs in Terrestrial Food‐Webs , 2003 .

[14]  F. Gobas,et al.  Intestinal absorption and biomagnification of organic contaminants in fish, wildlife, and humans , 2004, Environmental toxicology and chemistry.

[15]  Michael S McLachlan,et al.  Bioaccumulation potential of persistent organic chemicals in humans. , 2004, Environmental science & technology.

[16]  Geoffrey B. West,et al.  The predominance of quarter-power scaling in biology , 2004 .

[17]  G. O. Thomas,et al.  Absorption of decabromodiphenyl ether and other organohalogen chemicals by grey seals (Halichoerus grypus). , 2005, Environmental pollution.

[18]  D. Bureau,et al.  Growth and whole body composition of lake trout (Salvelinus namaycush), brook trout (Salvelinus fontinalis) and their hybrid, F1 splake (Salvelinus namaycush × Salvelinus fontinalis), from first–feeding to 16 weeks post first-feeding , 2005 .

[19]  Craig R. White,et al.  Allometric scaling of mammalian metabolism , 2005, Journal of Experimental Biology.

[20]  I. Schultz,et al.  In vitro-in vivo extrapolation of quantitative hepatic biotransformation data for fish. I. A review of methods, and strategies for incorporating intrinsic clearance estimates into chemical kinetic models. , 2006, Aquatic toxicology.

[21]  Frank A. P. C. Gobas,et al.  A review of bioconcentration factor (BCF) and bioaccumulation factor (BAF) assessments for organic chemicals in aquatic organisms , 2006 .

[22]  F. Gobas,et al.  A terrestrial food-chain bioaccumulation model for POPs. , 2007, Environmental science & technology.

[23]  T. Springer,et al.  Assessment of an approach to estimating aquatic bioconcentration factors using reduced sampling , 2008, Environmental toxicology and chemistry.

[24]  W. Hayton,et al.  Allometric scaling of xenobiotic clearance: Uncertainty versus universality , 2008, AAPS PharmSci.

[25]  Jon A Arnot,et al.  Estimating metabolic biotransformation rates in fish from laboratory data , 2008, Environmental toxicology and chemistry.

[26]  Suzanne Schubbert Genotyping and drug response: Use of single nucleotide polymorphisms (SNPs) versus haplotypes to predict albuterol efficacy , 2001, AAPS PharmSci.

[27]  Thomas F Parkerton,et al.  Guidance for Evaluating In Vivo Fish Bioaccumulation Data , 2008, Integrated environmental assessment and management.

[28]  D Mackay,et al.  The physicochemical basis of QSARs for baseline toxicity , 2009, SAR and QSAR in environmental research.

[29]  Helmut Segner,et al.  The state of in vitro science for use in bioaccumulation assessments for fish , 2009, Environmental toxicology and chemistry.

[30]  P. Gaskell,et al.  Importance of prey and predator feeding behaviors for trophic transfer and secondary poisoning. , 2009, Environmental science & technology.

[31]  Frank A. P. C. Gobas,et al.  Revisiting Bioaccumulation Criteria for POPs and PBT Assessments , 2009, Integrated environmental assessment and management.

[32]  Beate I Escher,et al.  Capacities of membrane lipids to accumulate neutral organic chemicals. , 2011, Environmental science & technology.

[33]  K. Hungerbühler,et al.  Intrinsic Human Elimination Half-Lives of Polychlorinated Biphenyls Derived from the Temporal Evolution of Cross-Sectional Biomonitoring Data from the United Kingdom , 2010, Environmental health perspectives.

[34]  A. Weisbrod,et al.  Explaining differences between bioaccumulation measurements in laboratory and field data through use of a probabilistic modeling approach , 2012, Integrated environmental assessment and management.

[35]  L. Burkhard,et al.  Comparing laboratory‐ and field‐measured biota–sediment accumulation factors , 2012, Integrated environmental assessment and management.

[36]  Thomas F Parkerton,et al.  Comparing laboratory and field measured bioaccumulation endpoints , 2012, Integrated environmental assessment and management.

[37]  Jon A Arnot,et al.  Iterative fragment selection: a group contribution approach to predicting fish biotransformation half-lives. , 2012, Environmental science & technology.

[38]  Katrine Borgå,et al.  Use of trophic magnification factors and related measures to characterize bioaccumulation potential of chemicals , 2012, Integrated environmental assessment and management.

[39]  Michael S McLachlan,et al.  Internal benchmarking improves precision and reduces animal requirements for determination of fish bioconcentration factors. , 2012, Environmental science & technology.

[40]  M. Adolfsson-Erici,et al.  In-vivo passive sampling to measure elimination kinetics in bioaccumulation tests. , 2012, Chemosphere.

[41]  Katrine Borgå,et al.  Trophic magnification factors: Considerations of ecology, ecosystems, and study design , 2012, Integrated environmental assessment and management.

[42]  G. Ankley,et al.  First in a special series: Analysis of the impact of papers published in Environmental Toxicology and Chemistry over the past 30 years—an overview and coming attractions , 2013, Environmental toxicology and chemistry.

[43]  Jon A Arnot,et al.  Development and evaluation of a mechanistic bioconcentration model for ionogenic organic chemicals in fish , 2013, Environmental toxicology and chemistry.