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DOI: 10.1055/s-2003-45237
Body Size and V·O2peak: A New Perspective?
Publikationsverlauf
Accepted after revision: May 20, 2003
Publikationsdatum:
29. Januar 2004 (online)
Abstract
The purpose of this paper was to show how dimensional analysis and biological similarity theory can be used to define and derive extensive (size-dependent) and intensive (size-independent) variables. The method was then used to analyze the peak rate of oxygen consumption (V·O2 peak) data of children, adolescents, and adults to determine if size-independent increases in V·O2 peak occur during growth and development. The results indicated growth and development is accompanied by a substantial increase in size-independent V·O2 peak, which was associated with improvements in size-independent peak heart rate (HR peak). When differences in fat free mass (FFM) were considered, size-independent HR peak was similar in boys and girls within each age-group, but was greater in men than in women. In contrast, when differences in FFM were accounted for, size-independent peak oxygen pulse (O2P peak) was independent of age, although males tended to have greater values than females at all ages. Because O2P peak is proportional to the product of stroke volume (SV) and arterial mixed-venous oxygen difference (a-vO2 peak), when differences in FFM were considered, the size-independent nature of O2P peak indicated the combined effects changes in SV peak and (a-vO 2peak) played a secondary role in improving aerobic capacity. In conclusion, during normal growth and development improvement in HR peak, not stroke volume and arterial mixed-venous oxygen difference, appears to increase aerobic capacity.
Key words
Biological similarity - body size - dimensional analysis
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1 Quantities and variables are denoted by italic type, and dimensions by bold sans-serif as prescribed in the National Institute of Standards and Technology Special Publication 811: Guide for the use of the International System of Units (SI), 1995 Edition, published by the United States Department of Commerce Technology Administration.
D. J. McCann, Ph. D.
Department of Exercise Science · Gonzaga University
Spokane · WA 99258-0004 · USA ·
Telefon: +1 (509) 323-3487
Fax: +1 (509) 323-5869
eMail: mccann@gonzaga.edu