Chris G. Ingersoll

Intra‐ and interlaboratory variability in acute toxicity tests with glochidia and juveniles of freshwater mussels (unionidae)

The present study evaluated the performance and variability in acute toxicity tests with glochidia and newly transformed juvenile mussels using the standard methods outlined in American Society for Testing and Materials (ASTM). Multiple 48-h toxicity tests with glochidia and 96-h tests with juvenile mussels were conducted within a single laboratory and among five laboratories. All tests met the test acceptability requirements (e.g., >or=90% control survival). Intralaboratory tests were conducted over two consecutive mussel-spawning seasons with mucket (Actinonaias ligamentina) or fatmucket (Lampsilis siliquoidea) using copper, ammonia, or chlorine as a toxicant. For the glochidia of both species, the variability of intralaboratory median effective concentrations (EC50s) for the three toxicants, expressed as the coefficient of variation (CV), ranged from 14 to 27% in 24-h exposures and from 13 to 36% in 48-h exposures. The intralaboratory CV of copper EC50s for juvenile fatmucket was 24% in 48-h exposures and 13% in 96-h exposures. Interlaboratory tests were conducted with fatmucket glochidia and juveniles by five laboratories using copper as a toxicant. The interlaboratory CV of copper EC50s for glochidia was 13% in 24-h exposures and 24% in 48-h exposures, and the interlaboratory CV for juveniles was 22% in 48-h exposures and 42% in 96-h exposures. The high completion success and the overall low variability in test results indicate that the test methods have acceptable precision and can be performed routinely.

Chronic toxicity of azoxystrobin to freshwater amphipods, midges, cladocerans, and mussels in water‐only exposures

Understanding the effects of fungicides on nontarget organisms at realistic concentrations and exposure durations is vital for determining potential impacts on aquatic ecosystems. Environmental concentrations of the fungicide azoxystrobin have been reported up to 4.6u2009μg/L in the United States and 30u2009μg/L in Europe. The objective of the present study was to evaluate the chronic toxicity of azoxystrobin in water-only exposures with an amphipod (Hyalella azteca; 42-d exposure), a midge (Chironomus dilutus; 50-d exposure), a cladoceran (Ceriodaphnia dubia; 7-d exposure), and a unionid mussel (Lampsilis siliquoidea; 28-d exposure) at environmentally relevant concentrations. The potential photo-enhanced toxicity of azoxystrobin accumulated by C. dubia and L. siliquoidea following chronic exposures to azoxystrobin was also evaluated. The 20% effect concentrations (EC20s) based on the most sensitive endpoint were 4.2u2009μg/L for H. azteca reproduction, 12u2009μg/L for C. dubia reproduction and C. dilutus emergence, and >28u2009μg/L for L. siliquoidea. Hyalella azteca was more sensitive to azoxystrobin compared with the other 3 species in the chronic exposures. No photo-enhanced toxicity was observed for either C. dubia or L. siliquoidea exposed to ultraviolet light in control water following azoxystrobin tests. The results of the present study indicate chronic effects of azoxystrobin on 3 of 4 invertebrates tested at environmentally relevant concentrations. The changes noted in biomass and reproduction have the potential to alter the rate of ecological processes driven by aquatic invertebrates. Environ Toxicol Chem 2017;36:2308-2315. Published 2017 Wiley Periodicals Inc. on behalf of SETAC. This article is a US government work and, as such, is in the public domain in the United States of America.

Influence of Sediment Type and Exposure Time on Likeness of Colonization Tray and Background Macroinvertebrate Assemblages

ABSTRACT Colonization trays containing three sediment types (formulated, Florissant, and pond) were field deployed in a pond and a stream to assess the influence of sediment type, colonization time, and habitat type on benthic macroinvertebrate colonization. Benthos colonizing the trays was compared to ambient fauna to determine similarity. The pond was chosen as the optimal habitat type. By week 12, organisms colonizing trays in each of the three sediment types placed in the pond were not statistically different from Ekman grab samples in regard to both total abundance and abundance of each dominant taxa. The Florissant-filled colonization trays were the most similar to Ekman grab samples. Percent composition of dominant taxa was most similar (89% based on an affinity index) to Ekman grab samples and had the least variation in composition from the Ekman grab samples. The majority of invertebrates in the stream colonized a superficial layer of debris rather than in the sediments originally placed in the trays.