Measurement of Whole-Body CO2Production in Birds Using Real-Time Laser-Derived Measurements of Hydrogen (δ2H) and Oxygen (δ18O) Isotope Concentrations in Water Vapor from Breath

The doubly labeled water (DLW) method is commonly used to measure energy expenditure in free-living wildlife and humans. However, DLW studies involving animals typically require three blood samples, which can affect behavior and well-being. Moreover, measurement of H (δ2H) and O (δ18O) isotope conce...

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Bibliographic Details
Published in:Physiological and biochemical zoology 2015-11, Vol.88 (6), p.599-606
Main Authors: Mitchell, G. W., Guglielmo, C. G., Hobson, K. A.
Format: Article
Language:eng ; jpn
Subjects:
Air
Blood
Fractionation
Infrared spectrometers
Isotopes
Laser spectrometers
Lasers
Spectrometers
Vaporizers
Vapors
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Summary:The doubly labeled water (DLW) method is commonly used to measure energy expenditure in free-living wildlife and humans. However, DLW studies involving animals typically require three blood samples, which can affect behavior and well-being. Moreover, measurement of H (δ2H) and O (δ18O) isotope concentrations in H2O derived from blood using conventional isotope ratio mass spectrometry is technically demanding, time-consuming, and often expensive. A novel technique that would avoid these constraints is the real-time measurement of δ2H and δ18O in the H2O vapor of exhaled breath using cavity ring-down (CRD) spectrometry, provided that δ2H and δ18O from body H2O and breath were well correlated. Here, we conducted a validation study with CRD spectrometry involving five zebra finches (Taeniopygia guttata), five brown-headed cowbirds (Molothrus ater), and five European starlings (Sturnus vulgaris), where we compared δ2H, δ18O, andrCO2(rate of CO2production) estimates from breath with those from blood. Isotope concentrations from blood were validated by comparing dilution-space estimates with measurements of total body water (TBW) obtained from quantitative magnetic resonance. Isotope dilution-space estimates from δ2H and δ18O values in the blood were similar to and strongly correlated with TBW measurements (R 2= 0.99). The2H and18O (ppm) in breath and blood were also highly correlated (R 2= 0.99 and 0.98, respectively); however, isotope concentrations in breath were always less enriched than those in blood and slightly higher than expected, given assumed fractionation values between blood and breath. Overall,rCO2measurements from breath were strongly correlated with those from the blood (R 2= 0.90). We suggest that this technique will find wide application in studies of animal and human energetics in the field and laboratory. We also provide suggestions for ways this technique could be further improved.
ISSN:1522-2152
1537-5293
DOI:10.1086/683013