Add to ORKGSmall animals use more metabolic energy per unit mass than large animals to run on a level surface. If the cost to lift one gram of mass one vertical meter is constant, small animals should require proportionally smaller increases in metabolic cost to run uphill. To test this hypothesis on very small animals possessing an exceptional capacity for ascending steep gradients, we measured the metabolic cost of locomotion in the cockroach, Periplaneta americana, running at angles of 0, 45 and 90 degrees to the horizontal. Resting oxygen consumption (VO2rest) was not affected by incline angle. Steady-state oxygen consumption (VO2ss) increased linearly with speed at all angles of ascent. The minimum cost of locomotion (the slope of the VO2ss versu...
This series of four papers investigates the link between the energetics and the mechanics of terrest...
Energetically costly behaviours, such as flight, push physiological systems to their limits requirin...
Animals use different amounts of energy to move from place to place depending on their size and mode...
Small animals use more metabolic energy per unit mass than large animals to run on a level surface. ...
It is well established that the metabolic cost of horizontal locomotion decreases as a regular funct...
The mass-specific minimum cost of terrestrial locomotion (Cmu,) decreases with an increase in body m...
The mass-specific minimum cost of terrestrial locomotion (Cmin) decreases with an increase in body m...
The capacity for sustained, terrestrial locomotion in the cockroach. Blaberus discoidalis, was deter...
<p>The grey box shows the proposed operational area of subjects. Walking towards an attractive semio...
Energy costs of locomotion in mammals can be predicted from running speed and body mass, with the mi...
Flying insects achieve the highest mass-specific aerobic metabolic rates of all animals. However, fe...
Altering speed and moving on a gradient can affect an animal’s posture and gait, which in turn can c...
To examine the effects of variation in body form on the mechanics of terrestrial locomotion, we used...
The hemimetabolous migratory locust Locusta migratoria progresses through five instars to the adult,...
Historically, several different approaches have been applied to explain the metabolic cost of uphill...
This series of four papers investigates the link between the energetics and the mechanics of terrest...
Energetically costly behaviours, such as flight, push physiological systems to their limits requirin...
Animals use different amounts of energy to move from place to place depending on their size and mode...
Small animals use more metabolic energy per unit mass than large animals to run on a level surface. ...
It is well established that the metabolic cost of horizontal locomotion decreases as a regular funct...
The mass-specific minimum cost of terrestrial locomotion (Cmu,) decreases with an increase in body m...
The mass-specific minimum cost of terrestrial locomotion (Cmin) decreases with an increase in body m...
The capacity for sustained, terrestrial locomotion in the cockroach. Blaberus discoidalis, was deter...
<p>The grey box shows the proposed operational area of subjects. Walking towards an attractive semio...
Energy costs of locomotion in mammals can be predicted from running speed and body mass, with the mi...
Flying insects achieve the highest mass-specific aerobic metabolic rates of all animals. However, fe...
Altering speed and moving on a gradient can affect an animal’s posture and gait, which in turn can c...
To examine the effects of variation in body form on the mechanics of terrestrial locomotion, we used...
The hemimetabolous migratory locust Locusta migratoria progresses through five instars to the adult,...
Historically, several different approaches have been applied to explain the metabolic cost of uphill...
This series of four papers investigates the link between the energetics and the mechanics of terrest...
Energetically costly behaviours, such as flight, push physiological systems to their limits requirin...
Animals use different amounts of energy to move from place to place depending on their size and mode...