U.S. EPA Contaminated Site Cleanup Information (CLU-IN)


U.S. Environmental Protection Agency
U.S. EPA Technology Innovation and Field Services Division

Biogeochemical Interactions Affecting Bioavailability for in Situ Remediation: Session I - Innovative Approaches for Chlorinated Compound Bioremediation in Groundwater

Sponsored by: NIEHS Superfund Research Program

Archived: Monday, April 22, 2019
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This webinar series will feature individual research projects funded by the NIEHS Superfund Research Program (SRP). In 2013, the SRP initiated a targeted research program to better understand how contaminants in the environment are affected by complex biological, geological, and chemical processes. By understanding these complex interactions, we are better equipped to optimize remediation strategies and, therefore, improve science-based decision making for site management, priority-setting, and remedy selection. The individual research project grants support problem-solving research on the mechanisms of biogeochemical interactions that may impact remediation of contaminated soil, sediment, surface water, or groundwater.

In session 1, we will hear about SRP-funded individual research projects at Johns Hopkins University, University of Tennessee, and University of California, Berkeley. The first session will also include a brief introduction to the targeted research program and cohort of awardees.

Researchers led by Edward Bouwer, Ph.D., at Johns Hopkins Whiting School of Engineering are evaluating a novel technology — a flow-through barrier containing granular activated carbon coated with anaerobic and aerobic microorganisms — to see if it can completely break down chlorobenzenes and benzene contaminants, which are known or suspected carcinogens. The researchers seek to understand the environmental processes and conditions that influence interactions among contaminants and the barrier to improve its effectiveness in contaminated groundwater. Laboratory and field tests are being conducted at the Standard Chlorine of Delaware, Inc. Superfund site where dense non-aqueous phase liquid (DNAPL) chlorobenzene contamination is present in wetland sediments and groundwater. For more information, please visit: Dual-Biofilm Reactive Barrier for Treatment of Chlorinated Benzenes at Anaerobic-Aerobic Interfaces in Contaminated Groundwater and Sediments.

At the University of Tennessee, Frank Loeffler, Ph.D., and his research team are investigating the role of the microbial community for supplying specific nutrients called corrinoids, which organohalide-respiring Dehalococcoidia require to dechlorinate and detoxify solvents such as tetrachloroethene (PCE) and trichloroethene (TCE). The team is designing and validating the B12-qChip — an innovative, high-throughput quantitative PCR tool — that can be used to recognize when the bioavailability corrinoids limits dechlorination activity. Using samples from Third Creek, a polluted creek in Knoxville, Tennessee, they are conducting detailed studies that combine cultivation-based approaches, high-throughput sequencing, bioinformatics analyses, and state-of-the art analytical procedures to reveal the best biogeochemical conditions for bioremediation. For more information, please visit: Biogeochemical Controls over Corrinoid Bioavailability to Organohalide-Respiring Chloroflexi.

Assistant Project Scientist Shan Yi, Ph.D., will describe a project at the University of California, Berkeley led by Lisa Alvarez-Cohen, Ph.D., using a combination of molecular, biochemical, and analytical tools to evaluate how microbes used for trichloroethene (TCE) bioremediation interact with co-existing organisms in various geological, chemical, and biological conditions. The researchers are constructing simplified groups of microbes living symbiotically that they will expose to stresses such as changes in salinity as well as the introduction of potential competitive electron acceptors to the system (e.g., sulfate ions) to see how TCE bioremediation is affected. They will also combine intercellular data gained from both microarray and RNA sequencing techniques to develop mechanistic models that describe the effects of geochemical parameters on bioremediation. For more information, please visit: Metabolic Interactions Supporting Effective TCE Bioremediation under Various Biogeochemical Conditions.

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Presenters:

Edward Bouwer, Ph.D.Edward Bouwer, Ph.D., Johns Hopkins Whiting School of Engineering (bouwer@jhu.edu or 410-516-7437)
Edward Bouwer Ph.D., is the Abel Wolman Professor of Environmental Engineering at the Johns Hopkins Whiting School of Engineering. He has extensive experience with drinking water and wastewater treatment processes, microbial process engineering, and contaminant transport and fate. He is the principal investigator for the Dual-Biofilm Reactive Barrier for Treatment of Chlorinated Benzenes at Anaerobic-Aerobic Interfaces in Contaminated Groundwater and Sediments SRP R01 grant. Bouwer's research provides guidance on defining and managing environmental risks and how to interpret human and ecological health risk data. He directs the Center for Contaminant Transport, Fate, and Remediation, established to study the effects of contamination in Maryland's urban environments and make these findings known and understood by public officials, groups, and the media. He has a BSCE in Civil Engineering from Arizona State University, and an M.S. and Ph.D. in Environmental Engineering and Science from Stanford University.


Frank Loeffler, Ph.D.Frank Loeffler, Ph.D., University of Tennessee (frank.loeffler@utk.edu or 865-974-4933)
Frank Loeffler, Ph.D., is the Governor's Chair Professor in the department of microbiology and department of civil and environmental engineering at the University of Tennessee. He is the principal investigator for the Biogeochemical Controls over Corrinoid Bioavailability to Organohalide-Respiring Chloroflexi SRP R01 grant. His lab focuses on discovering microorganisms and processes to clean the environment, counter damage done to ecosystems by human activity, and improve environmental health. He studies how naturally occurring bacteria break down pollutants like chlorinated solvents, radioactive wastes, and greenhouse gases. He has a B.S. in agricultural sciences and biology and an M.S. in microbiology from the University of Hohenheim in Germany, a Ph.D. in technical biochemistry and microbiology from the Technical University Hamburg, University of Hohenheim, and completed a postdoc in microbial ecology at Michigan State University.


Shan Yi, Ph.D.Shan Yi, Ph.D., University of California, Berkeley (shan_yi@berkeley.edu or 510-965-5488)
Shan Yi, Ph.D., is an assistant project scientist in the Department of Civil and Environmental Engineering at the University of California, Berkeley. Her research focuses on investigating microbial metabolism and syntrophic interactions and their impact on the performance of bioprocesses in environmental engineering, such as bioremediation of chlorinated solvents. Shan obtained her Ph.D. in Environmental Engineering from Nanyang Technological University in Singapore and her baccalaureate in Biochemical Engineering from Tianjin University in China.


Moderators:

Heather Henry, Ph.D.Heather Henry, Ph.D., Superfund Research Program, National Institute of Environmental Health Sciences (henryh@niehs.nih.gov or 984-287-3268)
Since 2006, Heather Henry, Ph.D., has been a program administrator for the NIEHS SRP in Research Triangle Park, North Carolina. Her responsibilities include administration of the SRP Multi-Project Center Grants (P42), the SRP Individual Research Project Grants (R01), and the Small Business / Technology Transfer Grants (R41/42; R43/44). She earned a B.S. in Biological Sciences (Ecology and Evolution) at the University of Rochester, Rochester, NY; a Ph.D. in Biological Sciences at the University of Cincinnati, Cincinnati, OH; and completed a Fulbright Fellowship (post-doctoral) at the University of Melbourne and the University of Adelaide in Australia.


Jean BalentJean Balent, U.S. EPA Technology Innovation and Field Services Division (balent.jean@epa.gov or 703-603-9924)
Ms Balent is on the staff of the EPA's Technology Innovation and Field Services Division where she has worked to collect and disseminate hazardous waste remediation and characterization information since 2003. Ms Balent manages the Clean Up Information Network website and actively supports online communication and collaboration resources available to EPA. She formerly worked with the US Army Corps of Engineers Environmental Engineering Division in the Buffalo District. Ms Balent was also a member of the SUNY-Buffalo Groundwater Research Group where she constructed and tested large scale models of groundwater flow. Ms Balent has also conducted research relating to the Great Lakes, environmental remediation, and brownfields re-development. She holds a Bachelor's degree in environmental engineering from SUNY-Buffalo and a Master's degree in Information Technology from AIU.


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If you have a suggested topic or idea for a future CLU-IN internet seminar, please contact:

Jean Balent
Technology Integration and Information Branch

PH: (703) 603-9924 | Email: balent.jean@epa.gov
Michael Adam
Technology Integration and Information Branch

PH: (703) 603-9915 | Email: adam.michael@epa.gov