Abstract
Early detection of environmental disturbances affecting shellfish stock condition is highly desirable for aquaculture activities. In this article, a new biophysical model-based early warning system (EWS) is described, that assesses bivalve stock condition by diagnosing signs of persistent physiological dysfunctioning. The biophysical model represents valve gape dynamics, controlled by active contractions of the adductor muscle countering the passive action of the hinge ligament; the dynamics combine continuous convergence to a steady-state interspersed with discrete closing events. A null simulation was introduced to describe undisturbed conditions. The diagnostic compares valve gape measurements and simulations. Indicators are inferred from the model parameters, and disturbances are assessed when their estimates deviate from their null distribution. Instead of focusing only on discrete events, our EWS exploits the complete observed dynamics within successive time intervals defined by the variation scales. When applied to a valvometry data series, collected in controlled conditions from scallops (Pecten maximus), the EWS indicated that one among four individuals exhibited signs its physiological condition was degrading. This was detected neither during experiments nor during the initial data analysis, suggesting the utility of an approach that quantifies physiological mechanisms underlying functional responses. Practical implementations of biological-EWS at farming sites are then discussed.
Highlights
IntroductionPublisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations
The system that we proposed in this study is, to the best of our knowledge, the first to be built on a biophysical model of the adductor muscle dynamics
This study presented a new approach for biological-early warning system (EWS) based on valvometry measurements and simulations of a biophysical model
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Bivalves are ectothermic organisms that have colonized most aquatic and marine ecosystems. They are mainly sedentary species, live under a wide range of environmental conditions, and exhibit a variety of behaviors manifested by shell movements [1]. Numerous authors have suggested bivalves would be good sentinels of aquatic environment quality (e.g., [2], and references therein) and this, in turn, inspired several long-term contaminant bioaccumulation programs using the shellfish species (e.g., [3])
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