Development, validation, and evaluation of a continuous, real-time, bivalve biomonitoring system

A biological monitoring tool to assess water quality using bivalve gape behavior was developed and demonstrated. The purpose of this work was to develop methodologies for screening water quality appropriate to the goals of the watershed paradigm. A model of bivalve gape behavior based on prediction of behavior using autoregressive techniques was the foundation of the bivalve biomonitoring system. Current technology was used in developing the system to provide bivalve gape state data in a continuous real-time manner. A laboratory version of the system, including data collection and analysis hardware and software, was developed for use as a toxicological assay for determination of effective concentrations of toxicant(s) or other types of stress on bivalve gape behavior. Corbicula fluminea was monitored and challenged with copper, zinc, and chlorpyrifos using the system. Effective concentrations of 176 ± 23μg/L copper, 768 ± 412μg/L zinc, and 68μg/L chlorpyrifos were observed using a natural water with high dissolved organic carbon concentrations.; A rugged field version of the bivalve biomonitoring system was developed and deployed in two locations. The field systems were fitted with a photovoltaic array, a single board computer, and a CDPD telemetry modem for robust remote operation. Data were telemetered at a time relevant rate of once every ten minutes. One unit was deployed in Lake Lewisville, Denton County, TX in February of 2000. Data were telemetered and archived at a 92% success rate. Bivalve gape data demonstrated significant behavioral deviations on average 5 times per month. A second unit was deployed in Pecan Creek, Denton, TX in June of 2001. Data from this site were telemetered and archived at a 96% success rate. Over the months of June–August 2001, 16 significant behavioral deviations were observed, 63% of which were correlated with changes in physical/chemical parameters.; This work demonstrated the relative sensitivity of bivalve gape as a toxicological endpoint and the feasibility of its use in a continuous, real-time, bivalve biomonitoring system. Technical aspects of collecting, telemetering, and analyzing this type of data in a time-relevant manner were developed resulting in a system appropriate for use as a means of data collection within the watershed paradigm.