Determining day‐to‐day human variation in indirect calorimetry using Bayesian decision theory

New Findings What is the central question of this study? We sought to understand the day‐to‐day variability of human indirect calorimetry during rest and exercise. Previous work has been unable to separate human day‐to‐day variability from measurement error and within‐trial human variability. We dev...

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Published in	Experimental physiology Vol. 103; no. 12; pp. 1579 - 1585
Main Authors	Tenan, Matthew S., Bohannon, Addison W., Macfarlane, Duncan J., Crouter, Scott E.
Format	Journal Article
Language	English
Published	England John Wiley & Sons, Inc 01.12.2018
Subjects	Bayes Theorem Bayesian Bayesian analysis Biological Variation, Individual Calorimetry Calorimetry, Indirect - methods Carbon dioxide Circadian Rhythm Decision Theory Exercise Gas exchange Humans individual differences Lung - physiology Mathematical models Models, Biological Precision medicine Predictive Value of Tests probability Pulmonary Gas Exchange Reproducibility of Results Rest Time Factors ventilation probability Bayesian ventilation individual differences
Online Access	Get full text
ISSN	0958-0670 1469-445X 1469-445X
DOI	10.1113/EP087115

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Abstract	New Findings What is the central question of this study? We sought to understand the day‐to‐day variability of human indirect calorimetry during rest and exercise. Previous work has been unable to separate human day‐to‐day variability from measurement error and within‐trial human variability. We developed models accounting for different levels of human‐ and machine‐level variance and compared the probability density functions using total variation distance. What is the main finding and its importance? After accounting for multiple levels of variance, the average human day‐to‐day variability of minute ventilation, CO2 output and O2 uptake is 4.0, 1.8 and 2.0%, respectively. This is a new method to understand human variability and directly enhances our understanding of human variance during indirect calorimetry. One of the challenges of precision medicine is understanding when serial measurements taken across days are quantifiably different from each other. Previous work examining gas exchange measured by indirect calorimetry has been unable to separate differential measurement error, within‐trial human variance and day‐to‐day human variance effectively in order to ascertain how variable humans are across testing sessions. We used previously published reliability data to construct models of indirect calorimetry variance and compare these models with methods arising from Bayesian decision theory. These models are conditional on the data upon which they are derived and assume that errors conform to a truncated normal distribution. A serial analysis of modelled probability density functions demonstrated that the average human day‐to‐day variance in minute ventilation (V̇E), carbon dioxide output (V̇CO2) and oxygen uptake (V̇O2) was 4.0, 1.8 and 2.0%, respectively. However, the average day‐to‐day variability masked a wide range of non‐linear variance across flow rates, particularly for V̇E. This is the first report isolating day‐to‐day human variability in indirect calorimetry gas exchange from other sources of variability. This method can be extended to other physiological tools, and an extension of this work facilitates a statistical tool to examine within‐trial V̇O2 differences, available in a graphical user interface.
AbstractList	New Findings What is the central question of this study? We sought to understand the day‐to‐day variability of human indirect calorimetry during rest and exercise. Previous work has been unable to separate human day‐to‐day variability from measurement error and within‐trial human variability. We developed models accounting for different levels of human‐ and machine‐level variance and compared the probability density functions using total variation distance. What is the main finding and its importance? After accounting for multiple levels of variance, the average human day‐to‐day variability of minute ventilation, CO2 output and O2 uptake is 4.0, 1.8 and 2.0%, respectively. This is a new method to understand human variability and directly enhances our understanding of human variance during indirect calorimetry. One of the challenges of precision medicine is understanding when serial measurements taken across days are quantifiably different from each other. Previous work examining gas exchange measured by indirect calorimetry has been unable to separate differential measurement error, within‐trial human variance and day‐to‐day human variance effectively in order to ascertain how variable humans are across testing sessions. We used previously published reliability data to construct models of indirect calorimetry variance and compare these models with methods arising from Bayesian decision theory. These models are conditional on the data upon which they are derived and assume that errors conform to a truncated normal distribution. A serial analysis of modelled probability density functions demonstrated that the average human day‐to‐day variance in minute ventilation (V̇E), carbon dioxide output (V̇CO2) and oxygen uptake (V̇O2) was 4.0, 1.8 and 2.0%, respectively. However, the average day‐to‐day variability masked a wide range of non‐linear variance across flow rates, particularly for V̇E. This is the first report isolating day‐to‐day human variability in indirect calorimetry gas exchange from other sources of variability. This method can be extended to other physiological tools, and an extension of this work facilitates a statistical tool to examine within‐trial V̇O2 differences, available in a graphical user interface. What is the central question of this study? We sought to understand the day-to-day variability of human indirect calorimetry during rest and exercise. Previous work has been unable to separate human day-to-day variability from measurement error and within-trial human variability. We developed models accounting for different levels of human- and machine-level variance and compared the probability density functions using total variation distance. What is the main finding and its importance? After accounting for multiple levels of variance, the average human day-to-day variability of minute ventilation, CO2 output and O2 uptake is 4.0, 1.8 and 2.0%, respectively. This is a new method to understand human variability and directly enhances our understanding of human variance during indirect calorimetry.NEW FINDINGSWhat is the central question of this study? We sought to understand the day-to-day variability of human indirect calorimetry during rest and exercise. Previous work has been unable to separate human day-to-day variability from measurement error and within-trial human variability. We developed models accounting for different levels of human- and machine-level variance and compared the probability density functions using total variation distance. What is the main finding and its importance? After accounting for multiple levels of variance, the average human day-to-day variability of minute ventilation, CO2 output and O2 uptake is 4.0, 1.8 and 2.0%, respectively. This is a new method to understand human variability and directly enhances our understanding of human variance during indirect calorimetry.One of the challenges of precision medicine is understanding when serial measurements taken across days are quantifiably different from each other. Previous work examining gas exchange measured by indirect calorimetry has been unable to separate differential measurement error, within-trial human variance and day-to-day human variance effectively in order to ascertain how variable humans are across testing sessions. We used previously published reliability data to construct models of indirect calorimetry variance and compare these models with methods arising from Bayesian decision theory. These models are conditional on the data upon which they are derived and assume that errors conform to a truncated normal distribution. A serial analysis of modelled probability density functions demonstrated that the average human day-to-day variance in minute ventilation ( V ̇ E ), carbon dioxide output ( V ̇ C O 2 ) and oxygen uptake ( V ̇ O 2 ) was 4.0, 1.8 and 2.0%, respectively. However, the average day-to-day variability masked a wide range of non-linear variance across flow rates, particularly for V ̇ E . This is the first report isolating day-to-day human variability in indirect calorimetry gas exchange from other sources of variability. This method can be extended to other physiological tools, and an extension of this work facilitates a statistical tool to examine within-trial V ̇ O 2 differences, available in a graphical user interface.ABSTRACTOne of the challenges of precision medicine is understanding when serial measurements taken across days are quantifiably different from each other. Previous work examining gas exchange measured by indirect calorimetry has been unable to separate differential measurement error, within-trial human variance and day-to-day human variance effectively in order to ascertain how variable humans are across testing sessions. We used previously published reliability data to construct models of indirect calorimetry variance and compare these models with methods arising from Bayesian decision theory. These models are conditional on the data upon which they are derived and assume that errors conform to a truncated normal distribution. A serial analysis of modelled probability density functions demonstrated that the average human day-to-day variance in minute ventilation ( V ̇ E ), carbon dioxide output ( V ̇ C O 2 ) and oxygen uptake ( V ̇ O 2 ) was 4.0, 1.8 and 2.0%, respectively. However, the average day-to-day variability masked a wide range of non-linear variance across flow rates, particularly for V ̇ E . This is the first report isolating day-to-day human variability in indirect calorimetry gas exchange from other sources of variability. This method can be extended to other physiological tools, and an extension of this work facilitates a statistical tool to examine within-trial V ̇ O 2 differences, available in a graphical user interface. What is the central question of this study? We sought to understand the day-to-day variability of human indirect calorimetry during rest and exercise. Previous work has been unable to separate human day-to-day variability from measurement error and within-trial human variability. We developed models accounting for different levels of human- and machine-level variance and compared the probability density functions using total variation distance. What is the main finding and its importance? After accounting for multiple levels of variance, the average human day-to-day variability of minute ventilation, CO output and O uptake is 4.0, 1.8 and 2.0%, respectively. This is a new method to understand human variability and directly enhances our understanding of human variance during indirect calorimetry. One of the challenges of precision medicine is understanding when serial measurements taken across days are quantifiably different from each other. Previous work examining gas exchange measured by indirect calorimetry has been unable to separate differential measurement error, within-trial human variance and day-to-day human variance effectively in order to ascertain how variable humans are across testing sessions. We used previously published reliability data to construct models of indirect calorimetry variance and compare these models with methods arising from Bayesian decision theory. These models are conditional on the data upon which they are derived and assume that errors conform to a truncated normal distribution. A serial analysis of modelled probability density functions demonstrated that the average human day-to-day variance in minute ventilation ( ), carbon dioxide output ( ) and oxygen uptake ( ) was 4.0, 1.8 and 2.0%, respectively. However, the average day-to-day variability masked a wide range of non-linear variance across flow rates, particularly for . This is the first report isolating day-to-day human variability in indirect calorimetry gas exchange from other sources of variability. This method can be extended to other physiological tools, and an extension of this work facilitates a statistical tool to examine within-trial differences, available in a graphical user interface. One of the challenges of precision medicine is understanding when serial measurements taken across days are quantifiably different from each other. Previous work examining gas exchange measured by indirect calorimetry has been unable to separate differential measurement error, within‐trial human variance and day‐to‐day human variance effectively in order to ascertain how variable humans are across testing sessions. We used previously published reliability data to construct models of indirect calorimetry variance and compare these models with methods arising from Bayesian decision theory. These models are conditional on the data upon which they are derived and assume that errors conform to a truncated normal distribution. A serial analysis of modelled probability density functions demonstrated that the average human day‐to‐day variance in minute ventilation (V̇E), carbon dioxide output (V̇CO2) and oxygen uptake (V̇O2) was 4.0, 1.8 and 2.0%, respectively. However, the average day‐to‐day variability masked a wide range of non‐linear variance across flow rates, particularly for V̇E. This is the first report isolating day‐to‐day human variability in indirect calorimetry gas exchange from other sources of variability. This method can be extended to other physiological tools, and an extension of this work facilitates a statistical tool to examine within‐trial V̇O2 differences, available in a graphical user interface.
Author	Bohannon, Addison W. Macfarlane, Duncan J. Crouter, Scott E. Tenan, Matthew S.
Author_xml	– sequence: 1 givenname: Matthew S. surname: Tenan fullname: Tenan, Matthew S. email: matthew.s.tenan.civ@mail.mil organization: Research Triangle Park – sequence: 2 givenname: Addison W. surname: Bohannon fullname: Bohannon, Addison W. organization: Aberdeen Proving Ground – sequence: 3 givenname: Duncan J. surname: Macfarlane fullname: Macfarlane, Duncan J. organization: Hong Kong University – sequence: 4 givenname: Scott E. surname: Crouter fullname: Crouter, Scott E. organization: University of Tennessee at Knoxville
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Snippet	New Findings What is the central question of this study? We sought to understand the day‐to‐day variability of human indirect calorimetry during rest and... What is the central question of this study? We sought to understand the day-to-day variability of human indirect calorimetry during rest and exercise. Previous... One of the challenges of precision medicine is understanding when serial measurements taken across days are quantifiably different from each other. Previous...
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SubjectTerms	Bayes Theorem Bayesian Bayesian analysis Biological Variation, Individual Calorimetry Calorimetry, Indirect - methods Carbon dioxide Circadian Rhythm Decision Theory Exercise Gas exchange Humans individual differences Lung - physiology Mathematical models Models, Biological Precision medicine Predictive Value of Tests probability Pulmonary Gas Exchange Reproducibility of Results Rest Time Factors ventilation
Title	Determining day‐to‐day human variation in indirect calorimetry using Bayesian decision theory
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