INVITED EDITORIALRun more, perform better—old truth revisitedHeikki KainulainenHeikki KainulainenPublished Online:01 May 2009https://doi.org/10.1152/japplphysiol.00200.2009This is the final version - click for previous versionMoreSectionsPDF (47 KB)Download PDF ToolsExport citationAdd to favoritesGet permissionsTrack citations ShareShare onFacebookTwitterLinkedInEmailWeChat ten years ago Claude Bouchard et al. (1) reported in the HERITAGE Family Study that aerobic exercise training programs result in large heterogeneity in V̇o2max response. The mean V̇o2max response ranged from 293 ml/min in mothers to 486 ml/min in sons, with highest responses up to 1 l/min. However, there were low responders, nonresponders, and even those who responded negatively. HERITAGE Study has shown that in addition to V̇o2max, this variability in response to regular exercise is present in almost any measured parameter including heart rate during submaximal exercise, systolic blood pressure during steady-state exercise, and HDL cholesterol (2). There are also a handful of older and more recent smaller studies showing no or even negative correlations between changes in aerobic performance and V̇o2max (e.g., 4–6).Exercise physiologists often consider V̇o2max as a measure of aerobic performance. The variability in responses to exercise training is seen more or less as a “statistical nuisance” that dilutes the mean increases seen after exercise programs. Because, in addition to increase athletic performance, exercise training is regarded and used as a tool to prevent and mend metabolic and various other diseases, the reasons of individual response differences should be carefully considered and studied. It is quite astonishing that this large variability in responses has not really caught the attention of researchers. What is the link between the improvement of oxygen transport system and the improvement of aerobic performance? This question was presented in a study by Vollaard et al. (8) in the Journal of Applied Physiology, especially considering how muscle metabolic control is related to training-induced improvements in V̇o2max and aerobic performance.And how did Vollaard et al. (8) study these relations? They simply trained young healthy men at 70% V̇o2max for 6 wk in a laboratory setting and determined among other parameters training-induced changes in V̇o2max and aerobic performance. Furthermore, they took muscle biopsy samples to quantify substrates and enzyme activities of energy metabolism. Biopsy sampling was performed just before and directly after a 10-min submaximal cycling test before and after the training period. As one may expect, exercise training improved the mean values of various physiological parameters (including V̇o2max) and aerobic performance. However, individual adaptations varied from negative values to substantial increases. Most importantly, low responders to one variable were not consistent low responders to other variables, suggesting that also the balance of adaptive mechanisms vary from one person to another. V̇o2max and aerobic performance correlated strongly at baseline and after training but the change in V̇o2max and the change in performance were not related at all (r2 = 0.05). Furthermore, Vollaard et al. (8), by combining maximal and submaximal physiological and biochemical parameters, demonstrate that changes in muscle metabolism may explain changes in performance but not in V̇o2max.What are the implications of these results? As Vollaard et al. (8) state, standardizing training intensity to a certain percentage of V̇o2max in training studies will yield large interindividual variation in performance and in metabolic responses. Therefore, V̇o2max should not be considered a universal standardization parameter in aerobic exercise training research. More importantly, the individual variation in responses may have considerable ramifications to the use of exercise as a tool in health care. It is conceivable that general exercise advice, e.g., in the prevention of obesity, the metabolic syndrome, or Type 2 diabetes, does not yield the best possible results. For instance, the new 2008 Physical Activity Guidelines for Americans (7) recommend for adults up to 5 h a week of moderate intensity or 2 h 30 min a week of vigorous-intensity physical activity, or an equivalent combination of both. This and even a smaller amount of work will purportedly yield health benefits but individuality in exercise responses very possibly requires individually fitted training programs for the best possible results. Individual exercise procedures become even more important when exercise is used to treat diseases so that the patients would gain more with less effort. Perhaps it is time to start considering and studying the most practical methods how to determine individual exercise programs with best individual gain.What are then the mechanisms and regulatory processes that participate and lead to the diversity in adaptations? Vollaard et al. (6) propose that calcium-mediated signaling could do the trick in aerobic performance, and HIF1α or VEGF signaling by promoting vascular remodeling might be central for improving oxygen related processes. Obviously this is a very complicated entirety that will be difficult to unravel only by exploiting human exercise studies. Such studies can provide only limited amounts of required tissue samples. One solution to avoid this problem is to develop a suitable experimental model. A project to create rat genetic models for the wide variation that exists for the adaptational component of aerobic capacity is presently going on at the University of Michigan (3). The idea is to produce rats with high response to training and rats with low response to training. Finally, the selectively bred strains are expected to develop contrasting phenotypes and gene networks that determine exercise responsiveness to training. If true, these animal models, in addition to human experiments, could be used to resolve the mechanistic basis for the gene by environment interaction for exercise training response.REFERENCES1 Bouchard C, An P, Rice T, Skinner JS, Wilmore JH, Cagnon J, Perusse L, Leon AS, Rao DC. Familial aggregation of V̇o2max response to exercise training: results from the HERITAGE Family Study. J Appl Physiol 87: 1003–1008, 1999.Link | ISI | Google Scholar2 Bouchard C, Rankinen T. Individual differences in response to regular physical activity. Med Sci Sports Exerc 33: S446–S451, 2001.Crossref | PubMed | ISI | Google Scholar3 Koch LG, Wisloff U, Britton SL. Rat genetic models of response to aerobic exercise. FASEB J 21:735.2, 2007 (Abstract).Google Scholar4 Lortie G, Simoneau JA, Hamel P, Boulay MR, Landry F, Bouchard C. Responses of maximal aerobic power and capacity to aerobic training. Int J Sports Med 5: 232–236, 1984.Crossref | PubMed | ISI | Google Scholar5 Paavolainen L, Häkkinen K, Hämäläinen I, Nummela A, Rusko H. Explosive-strength training improves 5-km running time by improving running economy and muscle power. J Appl Physiol 86: 1527–1533, 1999.Link | ISI | Google Scholar6 Smith TP, Coombes JS, Geraghty DP. Optimising high-intensity treadmill training using the running speed at maximal O2 uptake and the time for which this can be maintained. Eur J Appl Physiol 89: 337–343, 2003.Crossref | ISI | Google Scholar7 The 2008 Physical Activity Guidelines for Americans. http://www.health.gov/PAGuidelines/guidelines/default.aspx.Google Scholar8 Vollaard NBJ, Constantin-Teodosiu D, Fredriksson K, Rooyackers O, Jansson E, Greenhaff PL, Timmons JA, Sundberg CJ. Systematic analysis of adaptations in aerobic capacity and submaximal energy metabolism provides a unique insight into determinants of human aerobic performance. J Appl Physiol (February 5, 2009). doi:10.1152/japplphysiol.91453.2008.Link | ISI | Google ScholarAUTHOR NOTESAddress for reprint requests and other correspondence: H. Kainulainen, Dept. of Biology of Physical Activity, Univ. of Jyväskylä, Jyväskylä, Finland (e-mail: [email protected]) Download PDF Back to Top Next FiguresReferencesRelatedInformationCited ByIndividual Responses to Combined Endurance and Strength Training in Older AdultsMedicine & Science in Sports & Exercise, Vol. 43, No. 3 More from this issue > Volume 106Issue 5May 2009Pages 1477-1478 Copyright & PermissionsCopyright © 2009 the American Physiological Societyhttps://doi.org/10.1152/japplphysiol.00200.2009PubMed19246659History Published online 1 May 2009 Published in print 1 May 2009 Metrics