Bivalve condition index as an indicator of aquaculture intensity: A meta-analysis
Authored by R Filgueira, L A Comeau, T Landry, J Grant, T Guyondet, A Mallet
Date Published: 2013
DOI: 10.1016/j.ecolind.2012.10.001
Sponsors:
Fisheries and Oceans Canada (DFO)
Prince Edward Island Aquaculture Alliance (PEIAA)
Platforms:
R
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
http://cran.r-project.org/web/packages/mgcv/index.html
Abstract
Shellfish aquaculture implies the placement of artificial structures in
the coastal environment and the alteration of natural bivalve
populations, which calls for the establishment of legislative regulatory
frameworks based on an ecosystem approach. One of the challenges for
policy makers is the need to monitor the effectiveness of management
actions. In this study, a meta-analysis across different bays, covering
a large spatial scale in Atlantic Canada, was performed to test the
response of two potential indicators of aquaculture intensity: (1) the
bivalve growth using both Dynamic Energy Budget (DEB) and Scope For
Growth (SFG) approaches, and (2) the bivalve condition index (CI = (meat
weight/shell weight) x 100). Our underlying premise was that
overstocking of bivalves leads to increased competition for food
resources, which might ultimately have a significant effect on bivalve
growth performance and the Cl. Bivalve growth performance for cohorts of
Mytilus edulis and Crassostrea virginica were simulated by combining
satellite remote sensing (temperature and chlorophyll) with individual
based models using both DEB and SFG approaches. These models were
calibrated for each cohort, by adjusting the half-saturation coefficient
of the food ingestion function term (X-K), which is a common parameter
related to feeding behavior in both approaches. A significant
correlation between X-K and lease coverage (lease area/bay area, dimensionless) was found for M. edulis. However, because of unrealistic
X-K values in some M. edulis cohorts and the lack of consistent
simulations for C. virginica precluded using X-K as a reliable indicator
of aquaculture intensity. By contrast, according to the observed results
CI emerged as a good indicator of aquaculture intensity for both
species. A General Additive Model (GAM) for C. virginica provided a
regression that included the initial dry meat weight as a linear term
and the lease area as a non-linear term, explaining a total deviance of
59.9\% in describing final CI values. The GAM for M. Mulls included only
non-linear terms, lease coverage, and lease area, explaining a total
deviance of 61.0\%. Since the CI theoretically integrates the effects of
changing trophic conditions over time, the good relationship between the
CI and lease/bay characteristics provides a scientific framework for its
use as a reliable ecological indicator of aquaculture intensity. From an
applied perspective, this finding is of relevance because the CI is easy
to measure and is widely available in government and industry datasets.
(c) 2012 Elsevier Ltd. All rights reserved.
Tags
New-zealand
Oyster crassostrea-gigas
Mussels mytilus-edulis
Prince-edward-island
Pacific oyster
Environmental parameters
Sustainable
management
Reproductive condition
Phytoplankton biomass
Perna-canaliculus