Integrating Bioenergetic and Foraging Behavior: The Physiological Ecology of Larval Cod (Gadus morhua)

How do larval cod, Gadus morhua, balance foraging effort against the high cost of swimming in a viscous hydrodynamic regime? A respirometry system was developed to measure the activity metabolism of individual larvae. The cost of swimming was modeled as a power-performance relationship (energy expen...

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Bibliographic Details
Main Author: Ruzicka, James J.
Other Authors: OFFICE OF NAVAL RESEARCH ARLINGTON VA
Format: Text
Language:English
Published: 2004
Subjects:
Ecology
Stress Physiology
Non-electrical Energy Conversion
*STRESS(PHYSIOLOGY)
*ESTIMATES
*ENERGY CONSUMPTION
*LARVAE
*FISHES
*ECOLOGY
VELOCITY
POSITION(LOCATION)
STRATEGY
HIGH COSTS
TURBULENCE
METABOLISM
COST MODELS
TRAVEL
DRAG
VISCOSITY
ENERGY CONSERVATION
HYDRODYNAMICS
ADULTS
SWIMMING
*BIOENERGETICS
*GADUS MORHUA
RESPIORMETRY SYSTEM
Gadus morhua
Online Access:http://www.dtic.mil/docs/citations/ADA425457
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA425457
Description
Summary:How do larval cod, Gadus morhua, balance foraging effort against the high cost of swimming in a viscous hydrodynamic regime? A respirometry system was developed to measure the activity metabolism of individual larvae. The cost of swimming was modeled as a power-performance relationship (energy expenditure as a function of swimming speed) and as the cost of transport (the cost to travel a given distance). The cost of transport was high relative to juvenile and adult fish, but larvae swam more efficiently as they grew and became better able to overcome viscous drag. A large-volume observation system was developed to record foraging behavior in three dimensions. There are two phases of the saltatory search cycle used by larval cod: the burst which serves to position larvae within a new search volume and the pause when larvae search for prey. Burst characteristics did not change under different prey treatments, but pause duration increased while foraging capacity and swimming activity decreased when prey were absent. Longer pause durations could reflect greater effort to visually process each search volume when prey were difficult to find. Reduced swimming activity could also be an energy conservation strategy under unfavorable foraging conditions. By applying the cost of swimming model to the observed swimming intensity of freely foraging larvae, foraging activity was estimated to account for up to 80% of routine metabolism. A trophodynamic model was developed incorporating observed foraging behavior and swimming costs to estimate the prey density required to cover all metabolic demands. Small larvae (5mm) can survive on typical mean Georges Bank prey densities in mildly turbulent conditions. Larger larbae (>6mm) can survive even at high turbulence levels.

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