Sage Journals: Discover world-class research

Abstract

Background:

Improvements in cardiorespiratory fitness attenuate the risk for metabolic syndrome (MetS). However, the determinants of cardiorespiratory fitness measurements such as oxygen consumption (VO₂) peak and anaerobic threshold (AT) have not been investigated in persons with MetS. Therefore, the main aim of this study was to compare VO₂ peak and AT between subjects with and without MetS and to investigate determinants of cardiorespiratory fitness and its effects on the odds for MetS and its individual components.

Methods:

Thirty-one males with MetS and 24 healthy male participants each performed a VO₂ peak and a blood lactate transition threshold test. Waist circumference, body mass index (BMI), blood pressure, fasting plasma triglyceride, total cholesterol, high-density lipoprotein cholesterol, glucose, and insulin levels were measured. Separate multivariable linear regression models were developed in which VO₂ peak, AT, and the components of MetS were used as the dependent variables, while a multivariable logistic regression model was used for MetS.

Results:

The VO₂ peak [median (interquartile range)] was lower in subjects with MetS compared with controls [27.9 (23.0–31.0) vs. 35.0 (32.0–45.0) mL·min⁻¹·kg⁻¹; P < 0.0001]. Multivariable regression analysis demonstrated that there was a bidirectional association between MetS and VO₂ peak that was mediated by waist circumference and blood pressure. The VO₂ peak was a strong negative determinant of waist circumference (β = −0.36, P < 0.0001), but not of BMI (β = −0.13, P = 0.21).

Conclusions:

A higher VO₂ peak is associated with a lower odds ratio for MetS, which is related to greater cardiorespiratory fitness in a cyclical relationship that is mediated by blood pressure and waist circumference. A higher VO₂ peak is specifically associated with lower waist circumference, and vice versa, possibly by effects on visceral fat.

Get full access to this article

View all access options for this article.

References

Carroll

, Cooke

, Butterly

. Metabolic clustering, physical activity and fitness in non-smoking middle-aged men. Med Sci Sports Exerc, 2000; 32:2079–2086.

Irwin

, Ainsworth

, Mayer-Davis

. Physical activity and the metabolic syndrome in a tri-ethnic sample of women. Obes Res, 2002; 10:1030–1037.

Kullo

, Hensrud

, Allison

. Relation of low cardiorespiratory fitness to the metabolic syndrome in middle-aged men. Am J Cardiol, 2002; 90:795–797.

Lakka

, Laaksonen

, Lakka

H-M

, et al. Sedentary life-style, poor cardiorespiratory fitness and the metabolic syndrome. Med Sci Sports Exerc, 2003; 35:1279–1286.

LaMonte

, Barlow

, Jurca

, et al. Cardiorespiratory fitness is inversely associated with the incidence of metabolic syndrome. A prospective study of men and women. Circulation, 2005; 112:505–512.

Whaley

, Kampert

, Kohl

. Physical fitness and clustering of risk factors associated with the metabolic syndrome. Med Sci Sports Exerc, 1999; 31:287–293.

Katzmarzyk

, Church

, Blair

. Cardiorespiratory fitness attenuates the effects of metabolic syndrome on all-cause and cardiovascular disease mortality in men. Arch Intern Med, 2004; 164:1092–1097.

Knaeps

, Bourgois

, Charlier

, et al. Ten-year change in sedentary behaviour, moderate-to-vigorous physical activity, cardiorespiratory fitness and cardiometabolic risk: Independent associations and mediation analysis. Br J Sports Med, 2018; 52:1063–1068.

Earnest

, Artero

, Sui

, et al. Maximal estimated cardiorespiratory fitness, cardiometabolic risk factors, and metabolic syndrome in the aerobics center longitudinal study. Mayo Clin Proc, 2013; 88:259–270.

10.

Myers

, Kokkinos

, Nyelin

. Physical activity, cardiorespiratory fitness, and the metabolic syndrome. Nutrients, 2019; 11:1652.

11.

Alberti

, Eckel

, Grundy

, et al. Harmonizing the metabolic syndrome. Circulation, 2009; 120:1640–1645.

12.

Matthews

, Hosker

, Rudenski

, et al. Homeostasis model assessment: Insulin resistance and beta-cell function from fasting plasma glucose and insulin concentrations in man. Diabetologia, 1985; 28:412–419.

13.

Torres

, Crowther

, Rogers

. Reproducibility and levels of blood lactate transition thresholds in persons with metabolic syndrome. Metab Syndr Relat Disord, 2013; 11:121–127.

14.

Bourdon

Blood lactate transition thresholds: Concepts and controversies. In: Gore

(ed). Physiological Tests for Elite Athletes. Champaign, IL: Human Kinetics; 2000: 50–65.

15.

Cheng

, Kuipers

, Snyder

. A new approach for the determination of ventilatory and lactate thresholds. Int J Sports Med, 1992; 13:518–522.

16.

Greenland

. Modeling and variable selection in epidemiologic analysis. Am J Public Health, 1989; 79:340–349.

17.

Laaksonen

, Lakka

H-M

, Salonen

. Low levels of leisure-time physical activity and cardiorespiratory fitness predict development of the metabolic syndrome. Diabetes Care, 2002; 25:1612–1618.

18.

Eisenmann

, Wickel

, Welk

, et al. Relationship between adolescent fitness and fatness and cardiovascular disease risk factors in adulthood: The Aerobics Center Longitudinal Study (ACLS). Am Heart J, 2005; 149:46–53.

19.

Jago

, Drews

, McMurray

, et al. Fatness, fitness, and cardiometabolic risk factors among sixth-grade youth. Med Sci Sports Exerc, 2010; 42:1502–1510.

20.

Pouliot

, Despres

, Lemieux

, et al. Waist circumference and abdominal sagittal diameter: Best simple anthropometric indexes of abdominal visceral adipose tissue accumulation and related cardiovascular risk in men and women. Am J Cardiol, 1994; 73:460–468.

21.

Ross

, Aru

, Freeman

, et al. Abdominal adiposity and insulin resistance in obese men. Am J Physiol Endocrinol Metab, 2002; 282:E657–E663.

22.

Gruzdeva

, Borodkina

, Uchasova

, et al. Localization of fat depots and cardiovascular risk. Lipids Health Dis, 2018; 17:218.

23.

Shioya-Yamada

, Shimada

, Nishitani-Yokoyama

, et al. Association between visceral fat accumulation and exercise tolerance in non-obese subjects without diabetes. J Clin Med Res, 2018; 10:630–635.

24.

Kantartzis

, Thamer

, Peter

, et al. High cardiorespiratory fitness is an independent predictor of the reduction in liver fat during a lifestyle intervention in non-alcoholic fatty liver disease. Gut, 2009; 58:1281–1288.

25.

Park

, Kim

, et al. Visceral adipose tissue area is an independent risk factor for hepatic steatosis. J Gastroenterol Hepatol, 2008; 23:900–907.

26.

Adams

, Anstee

, Tilg

, et al. Non-alcoholic fatty liver disease and its relationship with cardiovascular disease and other extrahepatic diseases. Gut, 2017; 66:1138–1153.

27.

Church

. The low-fitness phenotype as a risk factor: More than just being sedentary?. Obesity, 2009; 17:S39–S42.

28.

Aunola

, Merniemi

, Alanen

, et al. Muscle metabolic profile and oxygen transport capacity as determinants of aerobic and anaerobic thresholds. Eur J Appl Physiol, 1988; 57:726–734.

29.

Stringer

, Hansen

, Wasserman

. Cardiac output estimated noninvasively from oxygen uptake during exercise. J Appl Physiol, 1997; 82:908–912.

30.

Mazic

, Suzic Lazic

, Dekleva

, et al. The impact of elevated blood pressure on exercise capacity in elite athletes. Int J Cardiol, 2015; 80:171–177.

31.

Whelton

, Chin

, Xin

, et al. Effect of aerobic exercise on blood pressure: A meta-analysis of randomized, controlled trials. Ann Intern Med, 2002; 136:493–503.

32.

Merlotti

, Ceriani

, Morabito

, et al. Subcutaneous fat loss is greater than visceral fat loss with diet and exercise, weight-loss promoting drugs and bariatric surgery: A critical review and meta-analysis. Int J Obes, 2017; 41:672–682.

33.

Barlow

, LaMonte

, Fitzgerald

, et al. Cardiorespiratory fitness is an independent predictor of hypertension incidence among initially normotensive healthy women. Am J Epidemiol, 2006; 163:142–150.

34.

Wahl

, Scalzo

, Regensteiner

, et al. Mechanisms of aerobic exercise impairment in diabetes: A narrative review. Front Endocrinol, 2018; 9:181.

35.

Chehade

, Gladysz

, Mooradian

. Dyslipidemia in type 2 diabetes: Prevalence, pathophysiology, and management. Drugs, 2013; 73:327–339.

36.

Cohen

. Statistical Power Analysis for the Behavioral Sciences, 2nd ed. Hillsdale, NJ: Lawrence Earlbaum Associates; 1988.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.03 MB