Response characteristics of an aquatic biomonitor used for rapid toxicity detection
Autor: | WH van der Schalie, Tommy R. Shedd, Linda M. Brennan, Mark W. Widder |
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Rok vydání: | 2004 |
Předmět: |
Movement
Biosensing Techniques Biology Toxicology Aquatic toxicology chemistry.chemical_compound Water Supply Toxicity Tests Respiration Animals Humans Water Pollutants Effluent Toxins Biological Behavior Animal Aquatic animal Pesticide Perciformes Pentachlorophenol chemistry Environmental chemistry Toxicity Malathion Biological Assay Environmental Monitoring |
Zdroj: | Journal of Applied Toxicology. 24:387-394 |
ISSN: | 1099-1263 0260-437X |
DOI: | 10.1002/jat.1028 |
Popis: | The response characteristics of an aquatic biomonitor that detects toxicity by monitoring changes in bluegill (Lepomis macrochirus Rafinesque) ventilatory and movement patterns were evaluated in single chemical laboratory studies at concentrations near the 96-h LC(50) concentration and at the EILATox-Oregon Workshop in sequential tests of multiple unknown samples. Baseline data collected prior to exposure allows each fish to serve as its own control. When at least 70% of exposed fish exhibit ventilatory or movement parameters significantly different from baseline observations, a group alarm is declared. In the laboratory studies, the aquatic biomonitor responded to the majority of chemicals at the 96-h lc(50) within an hour or less, although substantially higher response times were found for malathion and pentachlorophenol. Workshop tests of single chemical concentrations presented as blind samples were consistent with the laboratory test results. There were no alarms under control conditions in any test. Although data are limited, the aquatic biomonitor appears to respond more rapidly to chemicals causing membrane irritation, narcosis or polar narcosis than to acetylcholinesterase inhibitors or oxidative phosphorylation uncouplers. All four monitored parameters (ventilatory rate, cough rate, ventilatory depth and movement) contributed to identification of first alarms at acutely toxic levels. Understanding these response patterns can be useful in data interpretation for biomonitor applications such as surface water monitoring for watershed protection, wastewater treatment plant effluent monitoring or source water monitoring for drinking water protection. |
Databáze: | OpenAIRE |
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