Aberrant water homeostasis detected by stable isotope analysis

While isotopes are frequently used as tracers in investigations of disease physiology (i.e., 14C labeled glucose), few studies have examined the impact that disease, and disease-related alterations in metabolism, may have on stable isotope ratios at natural abundance levels. The isotopic composition...

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Bibliographic Details
Published in:PloS one 2010-07, Vol.5 (7), p.e11699-e11699
Main Authors: O'Grady, Shannon P, Wende, Adam R, Remien, Christopher H, Valenzuela, Luciano O, Enright, Lindsey E, Chesson, Lesley A, Abel, E Dale, Cerling, Thure E, Ehleringer, James R
Format: Article
Language:English
Subjects:
Aberration
Analysis
Animals
Biology
Body water
Body Water - metabolism
Deuterium - metabolism
Diabetes
Diabetes and Endocrinology/Type 1 Diabetes
Diabetes mellitus
Diabetes Mellitus, Experimental - metabolism
Diet
Disease detection
Drinking water
Ecology/Physiological Ecology
Endocrinology
Energy expenditure
Fluctuations
Flux
Food habits
Glucose
Homeostasis
Hydrogen
Hyperglycemia
Insulin
Isotope composition
Isotope ratios
Isotopes
Isotopic composition
Mammals
Mathematical models
Medical research
Metabolism
Mice
Models, Theoretical
Oxygen
Oxygen Isotopes - metabolism
Physiological aspects
Physiology
Prediction models
Rodents
Streptozocin
Tracers
Tracers (Chemistry)
Urine
Water
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Summary:While isotopes are frequently used as tracers in investigations of disease physiology (i.e., 14C labeled glucose), few studies have examined the impact that disease, and disease-related alterations in metabolism, may have on stable isotope ratios at natural abundance levels. The isotopic composition of body water is heavily influenced by water metabolism and dietary patterns and may provide a platform for disease detection. By utilizing a model of streptozotocin (STZ)-induced diabetes as an index case of aberrant water homeostasis, we demonstrate that untreated diabetes mellitus results in distinct combinations, or signatures, of the hydrogen (delta2H) and oxygen (delta18O) isotope ratios in body water. Additionally, we show that the delta2H and delta18O values of body water are correlated with increased water flux, suggesting altered blood osmolality, due to hyperglycemia, as the mechanism behind this correlation. Further, we present a mathematical model describing the impact of water flux on the isotopic composition of body water and compare model predicted values with actual values. These data highlight the importance of factors such as water flux and energy expenditure on predictive models of body water and additionally provide a framework for using naturally occurring stable isotope ratios to monitor diseases that impact water homeostasis.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0011699