A comparative study of the biomass-based and individual-based models of blue mussels
Authored by Daisuke Kitazawa, Shigeru Tabeta, Takayoshi Kato, Piet Ruardij
Date Published: 2008
DOI: 10.1016/j.ecolmodel.2008.02.014
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Abstract
The performance of a biomass-based model is compared with that of an
individual-based model for a blue mussel Mytilus galloprovincialis. The
mathematical models are developed to predict the environmental impacts
of blue mussels, which adhere to the surface of coastal artificial
structures and vary the surrounding material cycle with their feeding
and respiratory activities. The existing biomass-based model is based on
Scope for Growth (SFG) concept and allometric relations between body
size and physiological rates. One problem of this approach is that it
does not discriminate between fed and starved mussels in the mussel bed.
However, mussels are usually attached to each other in several layers, with subsequent competition for food among them. Hence, some of the
mussels are shoved to the inner layer of the mussel bed and must be
starved due to their unfavorable position. They continue living by
consuming the reserved materials little by little by means of standard
respiration, therefore they does not contribute much to food ingestion
and oxygen consumption rates of the mussel bed. in the present study, an
individual-based model is developed to describe the dynamics of mussels
as controlled by Competition for Space and Food (CSF) availability. The
model consists of a physiological growth submodel based on Dynamic
Energy Budget (DEB) concept and a competition submodel. Both the
biomass-based and individual-based models are applied to the mussels
growing on the artificial substrata suspended from the top of a pontoon
type floating platform anchored in the head of Tokyo Bay in Japan. Then
the observed results of growth and oxygen consumption rate of mussels
are compared with the predicted results by means of both models.
Consequently, the performance of the biomass-based model is sufficient
when the mussel bed forms mono layer, however the performance of the
individual-based model is better in the case when the mussel bed has
several layers. (C) 2008 Elsevier B.V. All rights reserved.
Tags
Water
growth
Temperature
Nw spain
Mytilus-edulis l
Cultured mussel
Galloprovincialis
Sediments
Seston
Filtration