A standard calculation methodology for human doubly labeled water studies

Authors

John R. Speakman, Shenzhen Institute of Advanced Technology
Yosuke Yamada, National Institute of Health and Nutrition
Hiroyuki Sagayama, University of Tsukuba
Elena S.F. Berman, Berman Scientific Consulting
Philip N. Ainslie, Liverpool John Moores University
Lene F. Andersen, Universitetet i Oslo
Liam J. Anderson, Liverpool John Moores University
Lenore Arab, David Geffen School of Medicine at UCLA
Issaad Baddou, Université Ibn Tofail
Kweku Bedu-Addo, Kwame Nkrumah University of Science & Technology
Ellen E. Blaak, Universiteit Maastricht
Stephane Blanc, University of Wisconsin-Madison
Alberto G. Bonomi, Philips Research
Carlijn V.C. Bouten, Technische Universiteit Eindhoven
Pascal Bovet, Institut Universitaire de Médecine Sociale et Préventive Lausanne
Maciej S. Buchowski, Vanderbilt University Medical Center
Nancy F. Butte, USDA ARS Children's Nutrition Research Center
Stefan G.J.A. Camps, Universiteit Maastricht
Graeme L. Close, Liverpool John Moores University
Jamie A. Cooper, University of Wisconsin-Madison
Seth A. Creasy, University of Colorado School of Medicine
Sai Krupa Das, Tufts University
Richard Cooper, Loyola University Chicago
Lara R. Dugas, Loyola University Chicago
Cara B. Ebbeling, Boston Children's Hospital
Ulf Ekelund, Norges Idrettshøgskole
Sonja Entringer, Berliner Institut für Gesundheitsforschung
Terrence Forrester, The University of the West Indies
Barry W. Fudge, University of Glasgow
Annelies H. Goris, Universiteit Maastricht
Michael Gurven, University of California, Santa Barbara
Catherine Hambly, University of Aberdeen
Asmaa El Hamdouchi, Université Ibn Tofail

Document Type

Article

Publication Date

2-16-2021

Abstract

The doubly labeled water (DLW) method measures total energy expenditure (TEE) in free-living subjects. Several equations are used to convert isotopic data into TEE. Using the International Atomic Energy Agency (IAEA) DLW database (5,756 measurements of adults and children), we show considerable variability is introduced by different equations. The estimated rCO2 is sensitive to the dilution space ratio (DSR) of the two isotopes. Based on performance in validation studies, we propose a new equation based on a new estimate of the mean DSR. The DSR is lower at low body masses (<10 >kg). Using data for 1,021 babies and infants, we show that the DSR varies non-linearly with body mass between 0 and 10 kg. Using this relationship to predict DSR from weight provides an equation for rCO2 over this size range that agrees well with indirect calorimetry (average difference 0.64%; SD = 12.2%). We propose adoption of these equations in future studies.

Publication Source (Journal or Book title)

Cell Reports Medicine

Recommended Citation

Speakman, J., Yamada, Y., Sagayama, H., Berman, E., Ainslie, P., Andersen, L., Anderson, L., Arab, L., Baddou, I., Bedu-Addo, K., Blaak, E., Blanc, S., Bonomi, A., Bouten, C., Bovet, P., Buchowski, M., Butte, N., Camps, S., Close, G., Cooper, J., Creasy, S., Das, S., Cooper, R., Dugas, L., Ebbeling, C., Ekelund, U., Entringer, S., Forrester, T., Fudge, B., Goris, A., Gurven, M., Hambly, C., & El Hamdouchi, A. (2021). A standard calculation methodology for human doubly labeled water studies. Cell Reports Medicine, 2 (2) https://doi.org/10.1016/j.xcrm.2021.100203