Chemistry graduate student Ivan Titaley has been immersed in polycyclic aromatic hydrocarbon (PAH) research within SRP Project 5 – Formation of Hazardous PAH Breakdown Products in Complex Environmental Mixtures at Superfund Sites under Dr. Staci Simonich.

Ivan Titaley
Ivan Titaley

Recently, Ivan was selected by Dr. Dayle Smith as a sponsored fellow at the Pacific Northwest National Laboratory (PNNL) to get hands-on training in modeling of polycyclic aromatic hydrocarbons. This program is through the Office of Science and Engineering Education (SEE) at PNNL. The selection is commendable, and will allow Ivan to apply new modeling techniquesl in his own research on OPAHs and OHPAHs transformation processes.

To financially support Ivan on this unique training opportunity, he has been awarded an SRP Trainee Externship Award through the SRP Training Core. This activity provides important synergy between Project 5 and Core C – Biostatistics and Modeling.

Dr. Smith will provide mentoring for Ivan to perform computational chemistry work to predict the formation of oxygenated-PAHs (OPAHs) and hydroxy-PAHs (OHPAHs) from higher molecular weight parent PAHs. More specifically, Ivan will be working using the NWChem 6.5 computational chemistry software. Using thermodynamic data on potential OH-PAH-adduct, he will be able to show which compounds will form based on thermodynamic stability.

Congratulations, Ivan!

 

OSU Press Release:  http://bit.ly/1sjfefn

MEDIA CONTACT:  David Stauth, 541-737-0787

David Williams, 541-737-3277 or david.williams@oregonstate.edu

12/10/2014

CORVALLIS, Ore. – Researchers for the first time have developed a method to track through the human body the movement of polycyclic aromatic hydrocarbons, or PAHs, as extraordinarily tiny amounts of these potential carcinogens are biologically processed and eliminated.

PAHs, which are the product of the incomplete combustion of carbon, have been a part of everyday human life since cave dwellers first roasted meat on an open fire. More sophisticated forms of exposure now range from smoked cheese to automobile air pollution, cigarettes, a ham sandwich and public drinking water. PAHs are part of the food we eat, the air we breathe and the water we drink.

However, these same compounds have gained increasing interest and scientific study in recent years due to their role as carcinogens. PAHs or PAH mixtures have been named as three of the top 10 chemicals of concern by the Agency for Toxic Substances Disease Registry.

With this new technology, scientists have an opportunity to study, in a way never before possible, potential cancer-causing compounds as they move through the human body. The findings were just published by researchers from Oregon State University and other institutions in Chemical Research in Toxicology, in work supported by the National Institute of Environmental Health Sciences (NIEHS)

The pioneering work has been the focus of Ph.D. research by Erin Madeen at Oregon State, whose studies were supported in part by an award from the Superfund Research Program at NIEHS for her work at Lawrence Livermore National Laboratory.

“We’ve proven that this technology will work, and it’s going to change the way we’re able to study carcinogenic PAHs,” said David Williams, director of the Superfund Research Program at OSU, a professor in the College of Agricultural Sciences and principal investigator with the Linus Pauling Institute.

“Almost everything we know so far about PAH toxicity is based on giving animals high doses of the compounds and then seeing what happens,” Williams said. “No one before this has ever been able to study these probable carcinogens at normal dietary levels and then see how they move through the body and are changed by various biological processes.”

The technology allowing this to happen is a new application of accelerator mass spectrometry, which as a biological tracking tool is extraordinarily more sensitive than something like radioactivity measuring. Scientists can measure PAH levels in blood down to infinitesimal ratios – comparable to a single drop of water in 4,000 Olympic swimming pools, or to a one-inch increment on a 3-billion mile measuring tape.

As a result, microdoses of a compound, even less than one might find in a normal diet or environmental exposure, can be traced as they are processed by humans. The implications are profound.

“Knowing how people metabolize PAHs may verify a number of animal and cell studies, as well as provide a better understanding of how PAHs work, identifying their mechanism or mechanisms of action,” said Bill Suk, director of the NIEHS Superfund Research Program.

One PAH compound studied in this research, dibenzo (def,p)-chrysene, is fairly potent and defined as a probable human carcinogen. It was administered to volunteers in the study in a capsule equivalent to the level of PAH found in a 5-ounce serving of smoked meat, which provided about 28 percent of the average daily dietary PAH intake. There was a fairly rapid takeup of the compound, reaching a peak metabolic level within about two hours, and then rapid elimination. The researchers were able to study not only the parent compound but also individual metabolites as it was changed.

“Part of what’s so interesting is that we’re able to administer possible carcinogens to people in scientific research and then study the results,” Williams said. “By conventional scientific ethics, that simply would not be allowed. But from a different perspective, we’re not giving these people toxins, we’re giving them dinner. That’s how much PAHs are a part of our everyday lives, and for once we’re able to study these compounds at normal levels of human exposure.”

What a scientist might see as a carcinogen, in other words, is what most of us would see as a nice grilled steak. There are many unexpected forms of PAH exposure. The compounds are found in polluted air, cigarettes, and smoked food, of course, but also in cereal grains, potatoes and at surprisingly high levels in leafy green vegetables.

“It’s clear from our research that PAHs can be toxic, but it’s also clear that there’s more to the equation than just the source of the PAH,” Williams said. “We get most of the more toxic PAHs from our food, rather than inhalation. And some fairly high doses can come from foods like leafy vegetables that we know to be healthy. That’s why we need a better understanding of what’s going on in the human body as these compounds are processed.”

The Williams-led OSU laboratory is recruiting volunteers for a follow-up study that will also employ smoked salmon as a source of a PAH mixture and relate results to an individual’s genetic makeup.

Some of the early findings from the study actually back up previous research fairly well, Williams said, which was done with high-dose studies in laboratory animals. It’s possible, he said, that exposure to dietary PAHs over a lifetime may turn out to be less of a health risk that previously believed at normal levels of exposure, but more work will need to be done with this technology before such conclusions could be reached.

Collaborators on the study were from the Pacific Northwest National Laboratory, Lawrence Livermore National Laboratory, and the OSU Environmental Health Sciences Center.

“Further development and application of this technology could have a major impact in the arena of human environmental health,” the researchers wrote in their conclusion.

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Blair with clam
Blair Paulik out in the field with the butter clams.

The Samish Indian Nation invited Blair Paulik (OSU SRP Project 4 Trainee) and Diana Rohlman (OSU SRP CEC Coordinator) to the 3rd annual Fidalgo Bay Science Conference on October 23, 2014.

Our SRP presented a poster highlighting the recent butter clam sampling performed with the Samish and Swinomish tribal communities. In addition, governmental agencies, university researchers, citizen scientists and Tribal scientists presented on restoration projects (Custom Plywood Mill), the surf smelt spawning study (Salish Sea Stewards) and the Samish Natural Resources Program projects (Current Projects).

Two Samish Tribal members opened the Fidalgo Bay Science Conference floor with song and traditional stories to explain the importance of a healthy environment.

Tribal events such as this give our SRP Trainees valuable professional development experiences, exposing them to the history and culture of our Tribal partners and ways to work successfully with them.

 

Poster Presentation:

Paulik LB, Rohlman D, Donatuto J, Woodward C, Kile M, Anderson KA, Harding A. Improving techniques for estimating butter clam (Saxidomus gigantean) contamination in the Salish Sea. Poster presented at: Fidalgo Bay Science Conference, hosted by the Samish Indian Nation; 2014 October 23; Anacortes, WA.

Butter Clam Sampling Process
Butter Clam Sampling Process

See the story “Tribes partner with OSU to study clam contamination” on the Northwest Indian Fisheries Commission web site.

Dr. David Williams was recently awarded the PANWAT Achievement Award at the 2014 Pacific Northwest Association of Toxicologist Meeting in Bothell, Washington on September 19.Screen Shot 2014-10-09 at 4.11.13 PM

Dr. Williams joined the faculty of the College of Agricultural Sciences in 1987 as an Assistant Professor, originally in Food Science and Technology, then transferring to the Department of environmental and Molecular Toxicology.

Over his 27 years on the faculty in the College of Agricultural Sciences, Dave emerged as an outstanding scholar, instructor and leader. He has been instrumental in developing new research programs or initiatives, most recently by leading the development of the OSU Superfund Research Program (SRP) Center application. Dave has also played a major role in identifying new faculty candidates, directing recruitment and especially mentoring new faculty who have joined EMT.

David is a nationally and internationally recognized leader in the fields of toxicology and carcinogenesis as evidenced by his role as peer reviewer for scientific manuscripts for many journals, especially through his leadership role as an Associate Editor of Toxicology and Applied Pharmacology for 10 years (arguably the top ranked toxicology journal in the world), and for which he has managed over 220 manuscripts to date.

He has also served as an interim Department Head of EMT, Center Director of two NIEHS-funded centers (Director of both the Superfund Research Program and Marine and Freshwater Biomedical Sciences Center at OSU). In addition, Dr. Williams has an outstanding record of leadership in the national scientific community, through his continuous participation as an invited reviewer by NIH in the peer review of research grant applications.

Two other faculty members of OSU Environmental and Molecular Toxicology have recently received this award ‐ Dr. Robyn Tanguay in 2012 and Dr. Nancy Kerkvliet in 2011.

Assessing Contaminants in Subsistence-Harvested Shellfish
with the Swinomish and Samish Indian Tribes

By Blair Paulik (Project 4 Trainee) and Diana Rohlman (CEC Program Coordinator)

On August 20, 2014, Researchers from the Oregon State University (OSU) Superfund Research Program (SRP) have collaborated with two northwestern Tribes, the Swinomish and the Samish, to analyze environmental samples for contaminants. The team worked with Dr. Jamie Donatuto, the Environmental Health Analyst for the Swinomish Tribe, and Christine Woodward, the Director of the Department of Natural Resources for the Samish Tribe, to identify Tribal concerns regarding pollution of butter clams (Saxidomus gigantean).

Shellfish beds in Fidalgo Bay are underused, given concerns regarding contamination from the two nearby oil refineries. The last sampling event in 2002 identified increased levels of toxics in butter clams at sites within Fidalgo Bay.

(August 10-12, 2014) OSU SRP researchers meet with Bill Bailey (far left) and Rosie James (second from left, front) of the Samish Indian Tribe to collect butter clams and place passive pore-water samplers.
(August 10-12, 2014) OSU SRP researchers meet with Bill Bailey (far left) and Rosie James (second from left, front) of the Samish Indian Tribe to collect butter clams and place passive pore-water samplers.

To continue this research, SRP visited four sites on Swinomish and Samish beaches within the Fidalgo and Similk Bay areas, collecting butter clams and deploying passive pore-water samplers in the sediment.

In addition to identifying what contaminants may be present in the butter clams, the research team also aims to identify a new testing method to reduce the amount of resident shellfish that are collected when environmental sampling is needed. The goal is to predict clam contamination using passive pore-water samplers.

If successful, this would enable researchers to determine shellfish contamination by putting out passive samplers instead of collecting clams. Using passive samplers is cheaper, faster, and less harmful to the local ecosystem than collecting resident organisms.

This work aims to provide important information regarding risk from consumption of butter clams, new methods for monitoring baselines trends of contaminants, and may inform novel sampling methods useful to Tribes and Superfund researchers around the country.

 

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(Above) A butter clam (Saxidomus gigantea) collected by the research team. At each site researchers collected five clams.

Where each clam was found, a passive pore-water sampler was placed (below).

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After four weeks, the samplers will be retrieved and analyzed. The chemical profile from the butter clam will be compared to the chemical profile of the passive sampler.

This work was conducted under Material and Data Sharing Agreements with both the Swinomish and Samish Tribes. All data generated from this study belongs to the Tribes. The Tribes must approve any use of the data or samples.

For more information: