Estimation of metabolic rate from activity measured by recorders deployed on Japanese sea bass Lateolabrax japonicus

Understanding the energy expenditure of top predators is important because a collapse in them could trigger trophic cascades through ecosystems. One such top predator, Japanese sea bass Lateolabrax japonicus , helps to balance the structure of the coastal marine ecosystem through predation. In this...

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Veröffentlicht in:	Fisheries science 2015-09, Vol.81 (5), p.871-882
Hauptverfasser:	Mori, Tomohiko, Miyata, Naoyuki, Aoyama, Jun, Niizuma, Yasuaki, Sato, Katsufumi
Format:	Artikel
Sprache:	eng
Schlagworte:	Accelerometers Analysis Bass Biomedical and Life Sciences Coastal ecosystems Costs Dicentrarchus labrax Ecosystems Energy Fish Fish & Wildlife Biology & Management Fishery sciences Food Science Freshwater & Marine Ecology Kinematics Lateolabrax japonicus Life Sciences Marine Marine ecosystems Metabolism Original Article Oxygen consumption Physiology Predation Predators Sardinops Seawater Studies Swimming
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container_issue	5
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container_title	Fisheries science
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creator	Mori, Tomohiko Miyata, Naoyuki Aoyama, Jun Niizuma, Yasuaki Sato, Katsufumi
description	Understanding the energy expenditure of top predators is important because a collapse in them could trigger trophic cascades through ecosystems. One such top predator, Japanese sea bass Lateolabrax japonicus , helps to balance the structure of the coastal marine ecosystem through predation. In this study, accelerometry was applied to the Japanese sea bass to estimate its energy expenditure under natural conditions. We attached accelerometers to five wild fish and measured metabolic rates such as the oxygen consumption rate ( V ˙ O 2 , mg O 2 kg −1 min −1 ) using a swim tunnel. Body beat frequency (BBF) was measured using the accelerometer. The BBF was correlated with the tail beat frequency (TBF) by analyzing video recordings. V ˙ O 2 was related to swimming speed ( U ), TBF, and BBF. We estimated the standard (45.9 kJ kg −1 day −1 ) and active (124.0 kJ kg −1 day −1 ) metabolic rates when fish were not swimming and when they were swimming at the optimum swimming speed, respectively. The energy required to compensate for the above metabolic rates are between 83.3 and 275.6 kJ kg −1 day −1 using an assimilation efficiency of 0.7 and assuming that the growth rate is zero. These costs were comparable to consuming one or two prey fish per day (e.g., Japanese sardine: mean total length 155 ± SD 6 mm).
doi_str_mv	10.1007/s12562-015-0910-7
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One such top predator, Japanese sea bass Lateolabrax japonicus , helps to balance the structure of the coastal marine ecosystem through predation. In this study, accelerometry was applied to the Japanese sea bass to estimate its energy expenditure under natural conditions. We attached accelerometers to five wild fish and measured metabolic rates such as the oxygen consumption rate ( V ˙ O 2 , mg O 2 kg −1 min −1 ) using a swim tunnel. Body beat frequency (BBF) was measured using the accelerometer. The BBF was correlated with the tail beat frequency (TBF) by analyzing video recordings. V ˙ O 2 was related to swimming speed ( U ), TBF, and BBF. We estimated the standard (45.9 kJ kg −1 day −1 ) and active (124.0 kJ kg −1 day −1 ) metabolic rates when fish were not swimming and when they were swimming at the optimum swimming speed, respectively. The energy required to compensate for the above metabolic rates are between 83.3 and 275.6 kJ kg −1 day −1 using an assimilation efficiency of 0.7 and assuming that the growth rate is zero. These costs were comparable to consuming one or two prey fish per day (e.g., Japanese sardine: mean total length 155 ± SD 6 mm).</abstract><cop>Tokyo</cop><pub>Springer Japan</pub><doi>10.1007/s12562-015-0910-7</doi><tpages>12</tpages></addata></record>
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subjects	Accelerometers Analysis Bass Biomedical and Life Sciences Coastal ecosystems Costs Dicentrarchus labrax Ecosystems Energy Fish Fish & Wildlife Biology & Management Fishery sciences Food Science Freshwater & Marine Ecology Kinematics Lateolabrax japonicus Life Sciences Marine Marine ecosystems Metabolism Original Article Oxygen consumption Physiology Predation Predators Sardinops Seawater Studies Swimming
title	Estimation of metabolic rate from activity measured by recorders deployed on Japanese sea bass Lateolabrax japonicus
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