Summary
Gas exchange was measured in pigeons flying non-stop for at least 60 min in a wind tunnel and using a flow-through respirometry system similar to that of Tucker (1968).
-
1.
O2 consumption (\(\dot V_{O_2 } \)), CO2 release (\(\dot V_{CO_2 } \)), respiratory exchange ratio (R) and metabolic rate (MR) show a characteristic time course independent of age, race, body mass, feeding condition, ambient temperature, flight speed and time of the year.\(\dot V_{O_2 } \) and MR decrease slightly (ca. 10%) within the first 10–15 min of flight before reaching a steady state value.\(\dot V_{CO_2 } \) decreases continuously with flight time reaching a constant level earliest after 45 min, resulting in a decrease of R.
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2.
The absolute values of\(\dot V_{O_2 } \) and MR are dependent on body mass, flight speed, pigeon race and individual differences in flight behaviour, but are independent of ambient temperature in the range between 5–23°C. Mean MR in the optimal speed range between 11–13 m s−1 lies between 30.5–34.2 W or 100.1±5.0 W kg−1.
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3.
R seems to decrease with flight time to the steady state level of R≈0.7 (flight duration was not always long enough to prove this statement), indicating a gradual changeover from a fuel rich in carbohydrate to one consisting nearly exclusively of fat. The initial value of R (ca. 1.1–0.84) as well as the time of decay before reaching the steady state level of R≈0.7 depends on the feeding condition and the time of the year.
The results are interpreted and discussed in comparison to other data available on bird flight.
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Abbreviations
- m b :
-
body mass
- m o :
-
loss in body mass per unit time
- MR :
-
metabolic rate
- MR s :
-
specific metabolic rate (per unit body mass)
- P :
-
power
- R :
-
respiratory exchange ratio
- T a :
-
ambient temperature
- \(\dot V_{CO_2 } \) :
-
CO2 release per unit time
- \(\dot V_{O_2 } \) :
-
oxygen consumption per unit time
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Rothe, H.J., Biesel, W. & Nachtigall, W. Pigeon flight in a wind tunnel. J Comp Physiol B 157, 99–109 (1987). https://doi.org/10.1007/BF00702734
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DOI: https://doi.org/10.1007/BF00702734