Long-term telemetry of heart rates and energy metabolic rate during the diurnal cycle in normothermic and torpid African blue-naped mousebirds ( Urocoliusmacrourus)

Colies are one of the phylogenetically oldest groups among the modern birds; the earliest finds are from about 35 million years ago. In states of energy deficiency they can undergo torpor during the night when metabolic rate and body temperature are decreased drastically to save energy (up to 90%)....

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Bibliographic Details
Published in:Comparative biochemistry and physiology. Part A, Molecular & integrative physiology Molecular & integrative physiology, 1999-12, Vol.124 (4), p.439-445
Main Authors: Schaub, Ralph, Prinzinger, Roland
Format: Article
Language:English
Subjects:
Adaptation, Physiological - physiology
Africa
Animals
Basal Metabolism - physiology
Birds - physiology
Body Temperature - physiology
Cardiac work
Circadian Rhythm - physiology
Coliiformes
Feeding Behavior - physiology
Food Deprivation - physiology
Heart rate
Heart Rate - physiology
Metabolic rate
Phylogeny
Rest - physiology
Sleep - physiology
Stroke Volume - physiology
Telemetry
Telemetry - instrumentation
Telemetry - methods
Torpor
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Summary:Colies are one of the phylogenetically oldest groups among the modern birds; the earliest finds are from about 35 million years ago. In states of energy deficiency they can undergo torpor during the night when metabolic rate and body temperature are decreased drastically to save energy (up to 90%). Here, we report the first measurements of heart rate (HR) by long-term telemetry, in seven individuals of blue-naped mousebirds ( Urocolius macrourus); simultaneously and continuously metabolic rate (MR) was determined. HR at night was about 20% below the range of expected values (246/310 bpm). Mean oxygen pulse (O 2 output/stroke) in normothermic birds was in a range of 0.019–0.020 ml O 2/stroke; during torpor nights this value decreased significantly to 0.0086. Mean cardiac output ranged from 724 to 1214 ml blood/kg per min; in torpid birds this value fell to 400 ml blood/kg per min. Cardiac regulation of metabolic demand within an activity phase (day or night) is mainly achieved by chronotropy. Inotropy contributes at most 25% to the differences in MR between day and night (ca. 40%). Entry into torpor is brought about mainly by changes in HR (decrease from 240 to 90 bpm); after torpor levels have been reached, there is an increase in HR (to 200 bpm) and a sharp decrease (−53%) in stroke volume. This regulation by inotropy is also characteristic of arousal from torpor.
ISSN:1095-6433
1531-4332
DOI:10.1016/S1095-6433(99)00136-1