Predicting VO2max Using Lung Function and Three-Dimensional (3D) Allometry Provides New Insights into the Allometric Cascade (M0.75)

IF 9.3 1区医学 Q1 SPORT SCIENCES

Sports Medicine Pub Date : 2025-04-13 DOI:10.1007/s40279-025-02208-3

Alan M. Nevill, Matthew Wyon, Jonathan Myers, Matthew P. Harber, Ross Arena, Tony D. Myers, Leonard A. Kaminsky

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引用次数: 0

Abstract

Background

Using directly measured cardiorespiratory fitness (i.e. VO_2max) in epidemiological/population studies is rare due to practicality issues. As such, predicting VO_2max is an attractive alternative. Most equations that predict VO_2max adopt additive rather than multiplicative models despite evidence that the latter provides superior fits and more biologically interpretable models. Furthermore, incorporating some but not all confounding variables may lead to inflated mass exponents (∝ M^0.75) as in the allometric cascade.

Objective

Hence, the purpose of the current study was to develop multiplicative, allometric models to predict VO_2max incorporating most well-known, but some less well-known confounding variables (FVC, forced vital capacity; FEV₁, forced expiratory volume in 1 s) that might provide a more dimensionally valid model (∝ M^2/3) originally proposed by Astrand and Rodahl.

Methods

We adopted the following three-dimensional multiplicative allometric model for VO_2max (l⋅min⁻¹) = M^k1·HT^k2·WC^k3·exp(a + b·age + c·age² + d·%fat)·ε, (M, body mass; HT, height; WC, waist circumference; %fat, percentage body fat). Model comparisons (goodness-of-fit) between the allometric and equivalent additive models was assessed using the Akaike information criterion plus residual diagnostics. Note that the intercept term ‘a’ was allowed to vary for categorical fixed factors such as sex and physical inactivity.

Results

Analyses revealed that significant predictors of VO_2max were physical inactivity, M, WC, age², %fat, plus FVC, FEV₁. The body-mass exponent was k₁ = 0.695 (M^0.695), approximately∝M^2/3. However, the calculated effect-sizes identified age² and physical inactivity, not mass, as the strongest predictors of VO_2max. The quality-of-fit of the allometric models were superior to equivalent additive models.

Conclusions

Results provide compelling evidence that multiplicative allometric models incorporating FVC and FEV₁ are dimensionally and theoretically superior at predicting VO_2max(l⋅min⁻¹) compared with additive models. If FVC and FEV₁ are unavailable, a satisfactory model was obtained simply by using HT as a surrogate.

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来源期刊

Sports Medicine 医学-运动科学

CiteScore

18.40

自引率

5.10%

发文量

165

审稿时长

6-12 weeks

期刊介绍： Sports Medicine focuses on providing definitive and comprehensive review articles that interpret and evaluate current literature, aiming to offer insights into research findings in the sports medicine and exercise field. The journal covers major topics such as sports medicine and sports science, medical syndromes associated with sport and exercise, clinical medicine's role in injury prevention and treatment, exercise for rehabilitation and health, and the application of physiological and biomechanical principles to specific sports. Types of Articles: Review Articles: Definitive and comprehensive reviews that interpret and evaluate current literature to provide rationale for and application of research findings. Leading/Current Opinion Articles: Overviews of contentious or emerging issues in the field. Original Research Articles: High-quality research articles. Enhanced Features: Additional features like slide sets, videos, and animations aimed at increasing the visibility, readership, and educational value of the journal's content. Plain Language Summaries: Summaries accompanying articles to assist readers in understanding important medical advances. Peer Review Process: All manuscripts undergo peer review by international experts to ensure quality and rigor. The journal also welcomes Letters to the Editor, which will be considered for publication.