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First published online July 26, 2004
Journal of Experimental Biology 207, 2925-2933 (2004)
Published by The Company of Biologists 2004
doi: 10.1242/jeb.01121

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Thermal stability and muscle efficiency in hovering orchid bees (Apidae: Euglossini)

Brendan J. Borrell^*, and Matthew J. Medeiros^*

Section of Integrative Biology, University of Texas, Austin, TX 78712, USA

Author for correspondence at present address (e-mail: bborrell{at}berkeley.edu)

Accepted 2 June 2004

To test whether variation in muscle efficiency contributes to thermal stability during flight in the orchid bee, Euglossa imperialis, we measured CO₂ production, heat loss and flight kinematics at different air temperatures (T_a). We also examined the relationship between wingbeat frequency (WBF) and T_a in five additional species of orchid bees. Mean thoracic temperature (T_th) for Eg. imperialis hovering in a screened insectary and in the field was 39.3±0.77°C (mean ± 95% C.I.), and the slope of T_th on T_a was 0.57. Head and abdominal temperature excess ratios declined with T_a, indicating that Eg. imperialis were not increasing heat dissipation from the thorax at high T_a. Elevation of T_th above T_a was correlated with WBF, but T_th alone was not. Estimates of heat production from both respirometry and heat loss experiments decreased 33% as T_a rose from 24 to 34°C. Mean muscle efficiency over this temperature range was 18% assuming perfect elastic energy storage and 22% assuming zero elastic energy storage. Both efficiency estimates increased significantly as T_a rose from 24 to 34°C. In all six species examined, WBF declined significantly with T_a. These data indicate that hovering orchid bees regulate heat production through changes in wingbeat kinematics and consequent changes in energy conversion by the flight motor. Temperature-dependent variation in elastic energy storage or muscle contraction efficiency or both may contribute to the observed trends.

Key words: flight energetics, thermoregulation, muscle, power, efficiency, bee, Euglossa imperialis, Euglossini

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