Modeling the oxygen uptake kinetics during exercise testing of patients with chronic obstructive pulmonary diseases using nonlinear mixed models

Florent Baty; Christian Ritz; Arnoldus van Gestel; Martin Brutsche; Daniel Gerhard

doi:10.1186/s12874-016-0173-8

Modeling the oxygen uptake kinetics during exercise testing of patients with chronic obstructive pulmonary diseases using nonlinear mixed models

Florent Baty, Christian Ritz, Arnoldus van Gestel, Martin Brutsche, Daniel Gerhard

Lifecourse Nutrition & Health

7 Citations (Scopus)

104 Downloads (Pure)

Abstract

Background: The six-minute walk test (6MWT) is commonly used to quantify exercise capacity in patients with several cardio-pulmonary diseases. Oxygen uptake (V ? $\dot {\mathrm {V}}$ O₂) kinetics during 6MWT typically follow 3 distinct phases (rest, exercise, recovery) that can be modeled by nonlinear regression. Simultaneous modeling of multiple kinetics requires nonlinear mixed models methodology. To the best of our knowledge, no such curve-fitting approach has been used to analyze multiple V ? $\dot {\mathrm {V}}$ O₂ kinetics in both research and clinical practice so far. Methods: In the present study, we describe functionality of the R package medrc that extends the framework of the commonly used packages drc and nlme and allows fitting nonlinear mixed effects models for automated nonlinear regression modeling. The methodology was applied to a data set including 6MWT V ?$\dot {\mathrm {V}}$ O₂ kinetics from 61 patients with chronic obstructive pulmonary disease (disease severity stage II to IV). The mixed effects approach was compared to a traditional curve-by-curve approach. Results: A six-parameter nonlinear regression model was jointly fitted to the set of V ? $\dot {\mathrm {V}}$ O₂ kinetics. Significant differences between disease stages were found regarding steady state V ? $\dot {\mathrm {V}}$ O₂ during exercise, V ? $\dot {\mathrm {V}}$ O₂ level after recovery and V ? $\dot {\mathrm {V}}$ O₂ inflection point in the recovery phase. Estimates obtained by the mixed effects approach showed standard errors that were consistently lower as compared to the curve-by-curve approach. Conclusions: Hereby we demonstrate the novelty and usefulness of this methodology in the context of physiological exercise testing.

Original language	English
Article number	66
Journal	B M C Medical Research Methodology
Volume	16
Issue number	1
Number of pages	9
ISSN	1471-2288
DOIs	https://doi.org/10.1186/s12874-016-0173-8
Publication status	Published - 1 Jun 2016

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title = "Modeling the oxygen uptake kinetics during exercise testing of patients with chronic obstructive pulmonary diseases using nonlinear mixed models",

abstract = "Background: The six-minute walk test (6MWT) is commonly used to quantify exercise capacity in patients with several cardio-pulmonary diseases. Oxygen uptake (V ? $\dot {\mathrm {V}}$ O2) kinetics during 6MWT typically follow 3 distinct phases (rest, exercise, recovery) that can be modeled by nonlinear regression. Simultaneous modeling of multiple kinetics requires nonlinear mixed models methodology. To the best of our knowledge, no such curve-fitting approach has been used to analyze multiple V ? $\dot {\mathrm {V}}$ O2 kinetics in both research and clinical practice so far. Methods: In the present study, we describe functionality of the R package medrc that extends the framework of the commonly used packages drc and nlme and allows fitting nonlinear mixed effects models for automated nonlinear regression modeling. The methodology was applied to a data set including 6MWT V ?$\dot {\mathrm {V}}$ O2 kinetics from 61 patients with chronic obstructive pulmonary disease (disease severity stage II to IV). The mixed effects approach was compared to a traditional curve-by-curve approach. Results: A six-parameter nonlinear regression model was jointly fitted to the set of V ? $\dot {\mathrm {V}}$ O2 kinetics. Significant differences between disease stages were found regarding steady state V ? $\dot {\mathrm {V}}$ O2 during exercise, V ? $\dot {\mathrm {V}}$ O2 level after recovery and V ? $\dot {\mathrm {V}}$ O2 inflection point in the recovery phase. Estimates obtained by the mixed effects approach showed standard errors that were consistently lower as compared to the curve-by-curve approach. Conclusions: Hereby we demonstrate the novelty and usefulness of this methodology in the context of physiological exercise testing.",

author = "Florent Baty and Christian Ritz and {van Gestel}, Arnoldus and Martin Brutsche and Daniel Gerhard",

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T1 - Modeling the oxygen uptake kinetics during exercise testing of patients with chronic obstructive pulmonary diseases using nonlinear mixed models

AU - Baty, Florent

AU - Ritz, Christian

AU - van Gestel, Arnoldus

AU - Brutsche, Martin

AU - Gerhard, Daniel

N1 - CURIS 2016 NEXS 160

PY - 2016/6/1

Y1 - 2016/6/1

N2 - Background: The six-minute walk test (6MWT) is commonly used to quantify exercise capacity in patients with several cardio-pulmonary diseases. Oxygen uptake (V ? $\dot {\mathrm {V}}$ O2) kinetics during 6MWT typically follow 3 distinct phases (rest, exercise, recovery) that can be modeled by nonlinear regression. Simultaneous modeling of multiple kinetics requires nonlinear mixed models methodology. To the best of our knowledge, no such curve-fitting approach has been used to analyze multiple V ? $\dot {\mathrm {V}}$ O2 kinetics in both research and clinical practice so far. Methods: In the present study, we describe functionality of the R package medrc that extends the framework of the commonly used packages drc and nlme and allows fitting nonlinear mixed effects models for automated nonlinear regression modeling. The methodology was applied to a data set including 6MWT V ?$\dot {\mathrm {V}}$ O2 kinetics from 61 patients with chronic obstructive pulmonary disease (disease severity stage II to IV). The mixed effects approach was compared to a traditional curve-by-curve approach. Results: A six-parameter nonlinear regression model was jointly fitted to the set of V ? $\dot {\mathrm {V}}$ O2 kinetics. Significant differences between disease stages were found regarding steady state V ? $\dot {\mathrm {V}}$ O2 during exercise, V ? $\dot {\mathrm {V}}$ O2 level after recovery and V ? $\dot {\mathrm {V}}$ O2 inflection point in the recovery phase. Estimates obtained by the mixed effects approach showed standard errors that were consistently lower as compared to the curve-by-curve approach. Conclusions: Hereby we demonstrate the novelty and usefulness of this methodology in the context of physiological exercise testing.

AB - Background: The six-minute walk test (6MWT) is commonly used to quantify exercise capacity in patients with several cardio-pulmonary diseases. Oxygen uptake (V ? $\dot {\mathrm {V}}$ O2) kinetics during 6MWT typically follow 3 distinct phases (rest, exercise, recovery) that can be modeled by nonlinear regression. Simultaneous modeling of multiple kinetics requires nonlinear mixed models methodology. To the best of our knowledge, no such curve-fitting approach has been used to analyze multiple V ? $\dot {\mathrm {V}}$ O2 kinetics in both research and clinical practice so far. Methods: In the present study, we describe functionality of the R package medrc that extends the framework of the commonly used packages drc and nlme and allows fitting nonlinear mixed effects models for automated nonlinear regression modeling. The methodology was applied to a data set including 6MWT V ?$\dot {\mathrm {V}}$ O2 kinetics from 61 patients with chronic obstructive pulmonary disease (disease severity stage II to IV). The mixed effects approach was compared to a traditional curve-by-curve approach. Results: A six-parameter nonlinear regression model was jointly fitted to the set of V ? $\dot {\mathrm {V}}$ O2 kinetics. Significant differences between disease stages were found regarding steady state V ? $\dot {\mathrm {V}}$ O2 during exercise, V ? $\dot {\mathrm {V}}$ O2 level after recovery and V ? $\dot {\mathrm {V}}$ O2 inflection point in the recovery phase. Estimates obtained by the mixed effects approach showed standard errors that were consistently lower as compared to the curve-by-curve approach. Conclusions: Hereby we demonstrate the novelty and usefulness of this methodology in the context of physiological exercise testing.

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DO - 10.1186/s12874-016-0173-8

M3 - Journal article

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SN - 1471-2288

VL - 16

JO - B M C Medical Research Methodology

JF - B M C Medical Research Methodology

IS - 1

M1 - 66

ER -

Modeling the oxygen uptake kinetics during exercise testing of patients with chronic obstructive pulmonary diseases using nonlinear mixed models

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