Abstract
ObjectiveA suite of adaptations facilitating endurance running (ER) evolved within the hominin lineage. This may have improved our ability to reach scavenging sites before competitors, or to hunt prey over long distances. Running economy (RE) is a key determinant of endurance running performance, and depends largely on the magnitude of force required to support body mass. However, numerous environmental factors influence body mass, thereby significantly affecting RE. This study tested the hypothesis that alternative metabolic strategies may have emerged to enable ER in individuals with larger body mass and poor RE.MethodsA cohort of male (n = 25) and female (n = 19) ultra-endurance runners completed submaximal and exhaustive treadmill protocols to determine RE, and V̇O2Max.ResultsBody mass was positively associated with sub-maximal oxygen consumption at both LT1 (male r=0.66, p<0.001; female LT1 r=0.23, p=0.177) and LT2 (male r=0.59, p=0.001; female r=0.23, p=0.183) and also with V̇O2Max (male r=0.60, p=0.001; female r=0.41, p=0.046). Additionally, sub-maximal oxygen consumption varied positively with V̇O2Max in both male (LT1 r=0.54, p=0.003; LT2 r=0.77, p<0.001) and female athletes (LT1 r=0.88, p<0.001; LT2 r=0.92, p<0.001).ConclusionsThe results suggest that, while individuals with low mass and good RE can glide economically as they run, larger individuals can compensate for the negative effects their mass has on RE by increasing their capacity to consume oxygen. The elevated energy expenditure of this low-economy high-energy turnover approach to ER may bring costs associated with energy diversion away from other physiological processes, however.
Highlights
Humans as Endurance RunnersHumans are unique amongst primates in being able to run distances of multiple kilometres using aerobic metabolism (Carrier, 1984)
Males were 17.7kg heavier, 14.6cm taller, 1.0 km/h faster at lactate threshold 1 (LT1), 1.2 km/h faster at lactate turn-point 2 (LT2) and had a VO2Max 4.4ml/kg/min larger
Body mass was found to vary negatively with running economy (RE) in both male and female athletes. This was consistent with the existing literature (Anderson, 1996; Pate et al, 1992)
Summary
Humans are unique amongst primates in being able to run distances of multiple kilometres using aerobic metabolism (Carrier, 1984) This ability emerged during evolution of the hominin lineage. Horses can maintain a gallop speed of 8.9 m/s for 10 km (much faster than humans), but are limited to a canter at around 5.8 m/s for distances around 20 km/ day (beatable by well-trained humans) (Lieberman & Bramble, 2007; Minetti, 2003). This capability allows human runners to comfortably cover daily distances in excess of 10 km, which is comparable with the scavenging and hunting of hunting dogs and hyenas (Lieberman et al, 2006)
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