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Mercury in Hawaiian bigeye, yellowfin tuna rising

Mercury concentrations in Hawaiian-caught bigeye and yellowfin tuna are steadily rising and mirror increases in North Pacific waters that have been linked to atmospheric mercury emissions from Asia.

Researchers compiled and re-analyzed data from previously published reports on yellowfin and bigeye tuna caught near Hawaii over the past four decades, then used a mathematical model to look for trends.

They found that mercury concentrations in yellowfin tuna increased about 5.5 percent per year between 1998 and 2008. Levels in bigeye tuna increased about 3.9 percent per year from 2002 to 2008. Mercury concentrations tended to be greater in bigeye tuna than in yellowfin tuna.

The work was reported in a study scheduled for online publication March 6 in the journal Environmental Toxicology and Chemistry. The first author is Paul Drevnick, a former University of Michigan researcher who now works for the Alberta provincial government in Calgary. The other author is Barbara Brooks of the Hawaii Department of Health.

Most of the work was done while Drevnick was at U-M, and the research was funded in part by the university. The new study updates yellowfin findings that Drevnick reported two years ago and expands the effort to include bigeye tuna.

“This paper confirms our previous work showing that mercury concentrations in yellowfin tuna caught near Hawaii are increasing, and it demonstrates that the same phenomenon is happening in bigeye tuna,” Drevnick said.

Both yellowfin and bigeye tuna are marketed as ahi and are widely used in raw fish dishes—especially sashimi—or for grilling. In January, the U.S. Food and Drug Administration and the U.S. Environmental Protection Agency added bigeye tuna to its list of fish to be avoided by pregnant women, women who might become pregnant, breastfeeding women and young children due to mercury concerns.

Mercury is a toxic trace metal that can accumulate to high concentrations in fish, posing a health risk to people who eat large, predatory marine fish such as swordfish and tuna. In the open ocean, the principal source of mercury is atmospheric deposition from human activities, especially emissions from coal-fired power plants and artisanal gold mines.

In North Atlantic waters, mercury concentrations peaked in the 1980s and ’90s and are now declining in response to environmental regulations in North America and Europe.

But in the North Pacific, mercury concentrations in waters shallower than 1,000 meters increased about 3 percent per year between 1995 and 2006 and are expected to double by 2050 if current mercury deposition rates are maintained, according to Drevnick.

“The temporal trend in mercury concentrations in these waters is mirrored by the changes in mercury concentrations in yellowfin and bigeye tuna caught near Hawaii,” Drevnick said. “For that reason, future monitoring efforts should include these species from this location.

“At the same time, more stringent policies are needed—especially in Asia—to reduce releases of mercury into the atmosphere, which eventually make their way into the oceans and into the fish we eat.”

The researchers also looked at blue marlin in their latest study. But the data for that fish did not allow for a fair comparison among years.

The work involved reviewing previous studies that reported data for individual fish, including approximate location and year of capture, mass and total mercury concentration in white muscle, measured in parts per million in wet tissue. For yellowfin tuna, fish from 49 to 168 pounds were used. For bigeye tuna, fish from 35 to 168 pounds were used.

For both bigeye and yellowfin tuna, Drevnick and Brooks found that mercury concentrations in fish tissue rarely exceeded the U.S. Food and Drug Administration’s “action level” of 1 part per million of methylmercury—the toxic organic form of the element—in an edible portion.

“The FDA action level is defined as ‘a limit at or above which FDA will take legal actions to remove products from the market,’ and according to the limit and the data here, no action should be taken,” they wrote.

The U.S. Environmental Protection Agency has a “fish tissue residue criterion” for methylmercury that applies to freshwater and estuarine fish and shellfish—but not to marine fish such as tuna. Even so, the authors note that the average mercury concentrations for both yellowfin and bigeye now exceed the EPA criterion and that “consumers of yellowfin tuna and bigeye tuna caught in the North Pacific are not protected from adverse effects of mercury.”

The latest study confirms and expands on work Drevnick and his colleagues reported in 2015 for Pacific yellowfin tuna. That paper, also published in Environmental Toxicology and Chemistry, reported that mercury concentrations in yellowfin tuna caught near Hawaii increased by at least 3.8 percent per year from 1998 to 2008.

At U-M, Drevnick was an assistant research scientist in the School of Natural Resources and Environment and at the U-M Biological Station. Though he now lives and works in Canada, he has retained visiting faculty status at the Biological Station.




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