Monday, September 21, 2015
Delayed effects of Oil Spill Compromise Long-Term Fish Survival
This is important new information and it describes effective chemical retardation. This problem has been observed in humans as well but rarely linked to specific chemical exposure. It is obviously far more deleterious than ever imagined.
I am calling the biolgical problem chemical retardation because the symptons are physical retardation even when there is no clear way to measure effects on the nervous system.
The retardation remains real and compares to physical symptoms observed in known retardation such as from alcohol toxicity during pregnant. Often the physical symptoms are the only obvious clue.
Delayed effects of oil spill compromise long-term fish survival
Low-level oil exposure leads to later heart defects, weaker swimming and reduced survival
NOAA Fisheries West Coast Region
IMAGE: This image shows transient embryonic exposures to crude oil cause lasting reductions in the swimming speed of salmon and herring, months after additional juvenile growth in clean seawater.
Credit: NOAA Fisheries/NWFSC
For 25 years, methodical research by scientists has investigated the effects of the Exxon Valdez oil spill in 1989 on Alaskan communities and ecosystems. A new study released today into the effects of the 1989 Exxon Valdez oil spill in Alaska shows that embryonic salmon and herring exposed to very low levels of crude oil can develop hidden heart defects that compromise their later survival, indicating that the spill may have had much greater impacts on spawning fish than previously recognized.
The herring population crashed four years after the spill in Prince William Sound and pink salmon stocks also declined, but the link to the oil spill has remained controversial. The new findings published in the online journal Scientific Reports suggest that the delayed effects of the spill may have been important contributors to the declines.
"These juvenile fish on the outside look completely normal, but their hearts are not functioning properly and that translates directly into reduced swimming ability and reduced survival," said John Incardona, a research toxicologist at NOAA Fisheries' Northwest Fisheries Science Center in Seattle. "In terms of impacts to shore-spawning fish, the oil spill likely had a much bigger footprint than anyone realized."
The research builds on earlier work by the Auke Bay Laboratories, part of NOAA Fisheries' Alaska Fisheries Science Center, which found much reduced survival of pink salmon exposed as embryos to polycyclic aromatic hydrocarbons (PAH) from crude oil.
"Our findings are changing the picture in terms of assessing the risk and the potential impacts of oil spills," said Nat Scholz, leader of the NWFSC's ecotoxicology program and a coauthor of the new study. "We now know the developing fish heart is exquisitely sensitive to crude oil toxicity, and that subtle changes in heart formation can have delayed but important consequences for first-year survival, which in turn determines the long-term abundance of wild fish populations."
Scientists from the Northwest Fisheries Science Center and Alaska Fisheries Science Center temporarily exposed embryonic salmon and herring to low levels of crude oil from the North Slope of Alaska and found that both absorbed chemicals at similar concentrations in their tissues. The embryos were then transferred to clean seawater and raised as juvenile fish for seven to eight months.
Few of the exposed embryos or larvae were outwardly abnormal in any way. However, closer examination of the fish revealed subtle defects that could reduce their long-term survival:
Juvenile salmon exposed to oil grew more slowly, with those exposed to the highest concentrations growing the slowest. For salmon, early survival in the ocean is strongly influenced by juvenile growth, with smaller fish suffering higher loss to predators.
Scientists used swimming speed as a measure of cardiorespiratory performance and found that fish exposed to the highest concentrations of oil swam the slowest. Slower swimming is an indication of reduced aerobic capacity and cardiac output, and likely makes fish easier targets for predators.
Exposure to oil as embryos altered the structural development of the hearts of juvenile fish, potentially reducing their fitness and swimming ability. Poor swimming and cardiac fitness is also a factor in disease resistance.
"With this very early impact on the heart, you end up with an animal that just can't pump blood through its body as well, which means it can't swim as well to capture food, form schools, or migrate," said Mark Carls, toxicologist at the Alaska Fisheries Science Center. "Crude oil is changing basic physiology, or what makes a fish a fish."
Scientists reviewed data on measured oil concentrations in surface water samples collected in Prince William Sound after the oil spill and during the 1989 herring spawning season. Most of the 233 samples contained less oil than was believed to be toxic to herring at the time, based on gross developmental abnormalities. However, nearly all of the samples contained oil at or above concentrations shown in the new study to alter heart development.
If the Exxon Valdez spill impacted heart development among a large majority of fish that were spawned in proximity to oiled shorelines, the subsequent losses of juveniles to delayed mortality would have left fewer adults to join the population. Although not direct proof, this provides a plausible explanation for the collapse of the Prince William Sound herring stock four years later, when fish spawned during the oil spill would have matured.
The study concludes that the impacts of the Exxon Valdez spill on nearshore spawning populations of fish are likely to have been considerably underestimated in terms of both the geographic extent of affected habitat and the lingering toxicity of low levels of oil. The findings will likely contribute to more accurate assessments of the impacts of future oil spills, Incardona said. "Now we have a much better idea of what we should be looking for," he said.
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