Stable isotope turnover and half-life in animal tissues: a literature synthesis

Stable isotopes of carbon, nitrogen, and sulfur are used as ecological tracers for a variety of applications, such as studies of animal migrations, energy sources, and food web pathways. Yet uncertainty relating to the time period integrated by isotopic measurement of animal tissues can confound the...

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Veröffentlicht in:	PloS one 2015-01, Vol.10 (1), p.e0116182
Hauptverfasser:	Vander Zanden, M Jake, Clayton, Murray K, Moody, Eric K, Solomon, Christopher T, Weidel, Brian C
Format:	Artikel
Sprache:	eng
Schlagworte:	Analysis Animal migration Animal tissues Animals Approximation Aquatic sciences Birds Body mass Body size Carbon Carbon Isotopes - metabolism Carbon Isotopes - pharmacokinetics Diet Ecological monitoring Endothermic reactions Energy sources Fisheries Food chains Food sources Food webs Fundulus heteroclitus Half life Isotopes Laboratories Limnology Marine ecology Marine mammals Mathematical models Muscles Nitrogen Nitrogen Isotopes - metabolism Nitrogen Isotopes - pharmacokinetics Organs Paralichthys dentatus Pomatoschistus minutus Slopes Species Specificity Stable isotopes Studies Sulfur Sulfur compounds Sulfur Isotopes - metabolism Sulfur Isotopes - pharmacokinetics Taxa Tissue Distribution Tracers Turnover rate
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description	Stable isotopes of carbon, nitrogen, and sulfur are used as ecological tracers for a variety of applications, such as studies of animal migrations, energy sources, and food web pathways. Yet uncertainty relating to the time period integrated by isotopic measurement of animal tissues can confound the interpretation of isotopic data. There have been a large number of experimental isotopic diet shift studies aimed at quantifying animal tissue isotopic turnover rate λ (%·day(-1), often expressed as isotopic half-life, ln(2)/λ, days). Yet no studies have evaluated or summarized the many individual half-life estimates in an effort to both seek broad-scale patterns and characterize the degree of variability. Here, we collect previously published half-life estimates, examine how half-life is related to body size, and test for tissue- and taxa-varying allometric relationships. Half-life generally increases with animal body mass, and is longer in muscle and blood compared to plasma and internal organs. Half-life was longest in ecotherms, followed by mammals, and finally birds. For ectotherms, different taxa-tissue combinations had similar allometric slopes that generally matched predictions of metabolic theory. Half-life for ectotherms can be approximated as: ln (half-life) = 0.22*ln (body mass) + group-specific intercept; n = 261, p
doi_str_mv	10.1371/journal.pone.0116182
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subjects	Analysis Animal migration Animal tissues Animals Approximation Aquatic sciences Birds Body mass Body size Carbon Carbon Isotopes - metabolism Carbon Isotopes - pharmacokinetics Diet Ecological monitoring Endothermic reactions Energy sources Fisheries Food chains Food sources Food webs Fundulus heteroclitus Half life Isotopes Laboratories Limnology Marine ecology Marine mammals Mathematical models Muscles Nitrogen Nitrogen Isotopes - metabolism Nitrogen Isotopes - pharmacokinetics Organs Paralichthys dentatus Pomatoschistus minutus Slopes Species Specificity Stable isotopes Studies Sulfur Sulfur compounds Sulfur Isotopes - metabolism Sulfur Isotopes - pharmacokinetics Taxa Tissue Distribution Tracers Turnover rate
title	Stable isotope turnover and half-life in animal tissues: a literature synthesis
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