Mink PJ, Alexander DD, Barraj LM, Kelsh MA, Tsuji JS. Low-level arsenic exposure in drinking water and bladder cancer: A review and meta-analysis. Regul Toxicol Pharmacol 2008, in press. Epub ahead of print: http://dx.doi.org/10.1016/j.yrtph.2008.08.010.
Tsuji JS, Yost LJ, Barraj LM, Scrafford CG, Mink PJ. Use of background inorganic arsenic exposures to provide perspective on risk assessment results. Regul Toxicol Pharmacol 2007; 48:59–68.
Barraj LM, Tsuji JS, Scrafford CG. The SHEDS-Wood Model: Incorporation of observational data to estimate exposure to arsenic for children playing on CCA-treated wood structures. Environ Health Perspect 2007; 115(5):781–786.
Barraj LM, Tsuji JS. Letter to the editor. Risk Anal 2007; 27(1):1-3.
Tsuji JS, Maynard AD, Howard PC, James JT, Lam C-W, Warheit DB, Santamaria AB. Research strategies for safety evaluation of nanomaterials. Part IV: Risk assessment of nanoparticles. Toxicol Sci 2006; 89(1):42-50.
Tsuji JS, Van Kerkhove MD, Kaetzel RS, Scrafford CG, Mink PJ, Barraj LM, Crecelius EA, Goodman M. Evaluation of exposure to arsenic in residential soil. Environ Health Perspect 2005; 113(12):1736-1740.
Tsuji JS, Benson R, Schoof RA, Hook GC. Response to additional support for derivation of an acute/subchronic reference level for arsenic. Regul Toxicol Pharmacol 2004; 40:372.
Tsuji JS, Benson R, Schoof RA, Hook GC. Health effect levels for risk assessment of childhood exposure to arsenic. Regul Toxicol Pharmacol 2004; 39:99-110.
Schoof RA, Tsuji JS, Benson R, Hook GC. Response to Byrd et al. (2004) comment on health effect levels for risk assessment of childhood exposure to arsenic. Regul Toxicol Pharmacol 2004; 40:374-375.
Yost LJ, Tao S-H, Egan SK, Barraj LM, Smith KM, Tsuji JS, Lowney YW, Schoof RA, Rachman NJ. Estimation of dietary intake of inorganic arsenic in U.S. children. Hum Ecol Risk Assess 2004; 10:473-483.
Massot M, Huey RB, Tsuji J, van Berkum FH. Genetic, prenatal, and post natal correlates of dispersal in hatchling fence lizards. Behav Ecol 2003; 14:650-655.
Tsuji JS, Williams PRD, Edwards MR, Allamneni KP, Kelsh MA, Paustenbach DJ, Sheehan PJ. Evaluation of mercury in urine as an indicator of exposure to low levels of mercury vapor. Environ Health Perspect 2003; 111(4):623-630.
Tsuji JS, Robinson S. Separating potential source exposure from background exposure in subsistence populations in developing countries. Toxicology 2002; 181-182:467-470.
Tsuji JS, Serl KM. Current uses of the EPA lead model to assess health risk and action levels for soil. Environ Geochem Health 1996; 18(1):25–33.
Kalvig BA, Maggio-Price L, Tsuji JS, Giddens WE. Salmonellosis in laboratory-housed iguanid lizards (Sceloporus spp). J Wildl Dis 1991; 27(4):551–556.
Tsuji JS, Huey RB, van Berkum FH, Garland Jr. T, Shaw RG. Locomotor performance of hatchling fence lizards (Sceloporus occidentalis): Quantitative genetics and morphological correlates. Evolut Ecol 1989; 3:240–252.
van Berkum FH, Huey RB, Tsuji JS, Garland Jr. T. Repeatability of individual differences in locomotor performance and body size during early ontogeny of the lizard Sceloporus occidentalis (Baird & Girard). Funct Ecol 1989; 3:97–105.
Tsuji JS. Seasonal profiles of standard metabolic rate of lizards (Sceloporus occidentalis) in relation to latitude. Physiol Zool 1988; 61:230–240.
Tsuji JS. Thermal acclimation of metabolism in Sceloporus lizards from different latitudes. Physiol Zool 1988; 61:241–253.
van Berkum FH, Tsuji JS. Interfamilial differences in sprint speeds of hatchling Sceloporus occidentalis (Reptilia: Iguanidae). J Zool London 1987; 212:511–519.
Tsuji JS, Kingsolver JG, Watt WB. The in-flight thermal physiological ecology of a butterfly (Colias). Oecologia 1986; 69:161–170.
Stevenson RD, Peterson CR, Tsuji JS. The thermal dependence of locomotion, tongue flicking, digestion and oxygen consumption in the wandering garter snake. Physiol Zool 1985; 58:46–57.
Tracy CR, van Berkum FH, Tsuji JS, Stevenson RD, Nelson J, Barnes B, Huey RB. Errors resulting from linear approximations of heat balance equations in biophysical ecology. J Thermal Biol 1984; 9:261–264.
Feder ME, Gibbs AG, Griffith GA, Tsuji JS. Thermal acclimation in salamanders: Fact or artifact? J Thermal Biol 1984; 9:255–260.
Published Abstracts of Presentations
Tsuji JS, Mowat FS. Health risks of carbon nanotubes: What can we learn from mineral fibers or ultrafine particulates? Toxicologist 2007; 96(1):7.
Mowat FS, Tsuji JS. Assessment of health risks of carbon nanotubes: Where do we go from here? Toxicologist 2007; 96(1):8.
Tsuji JS, Mowat FS, Kaetzel RS. Approaches for risk assessment and risk management of nanomaterials: “Inert” metal oxides. Toxicologist 2006; 90(1), Abstract 2201.
Mink PJ, Alexander DD, Barraj LM, Kelsh MA, Tsuji JS. Meta-analysis of low level arsenic exposure and bladder cancer: Implications for risk assessment in the United States. Toxicologist 2006; 90(1), Abstract 2184.
Yost LJ, Tsuji JS, Scrafford CG.. Implications of changes in the arsenic cancer slope factor for risk communication. Toxicologist 2006; 90(1), Abstract 2180.
Tsuji JS. Emerging issues in risk assessment and risk perception of nanomaterials. Toxicologist 2005; 78(1-S) Abstract 648.
Tsuji JS, Kerkhove MD, Scrafford CS, Kaetzel RS. Biomonitoring of a community for soil arsenic exposure. Toxicologist 2005; 78(1-S), Abstract 693.
Tsuji JS, Williams PR, Edwards MR, Avadhanam KP, Paustenbach DJ. Is mercury in urine indicative of exposure to low levels of mercury vapor? Toxicol Sci 2002; 66(1-S), Abstract 979.
Garry MR, Tsuji JS. Evaluating lead exposure at mining sites with heterogeneous soil types and lead bioavailability. Toxicol Sci 2002; 66(1-S), Abstract 500.
Tsuji JS, Garry MR. Metals exposure from homegrown produce at mining and smelting sites. Toxicol Sci 2001; 60(1–S): Abstract 95.
Garry MR, Lowney YW, Tsuji JS. A critical analysis of assumptions used when evaluating intake of metals from homegrown vegetables. Toxicol Sci 2001; 60(1-5): Abstract 2077.
Goodman M, Tsuji JS. Is sulfate in drinking water a hazard for infants? Toxicol Sci 2000; 54(1-S), Abstract 1174:250.
Schoof RA, Tsuji JS. The role of outdoor dust in exposures to chemicals in soil: Case studies for arsenic. Toxicol Sci 2000; 54(1-S), Abstract 1168:249.
Tsuji JS, Schoof RA, Hook GC. Subchronic health effect levels for childhood exposure to arsenic. Toxicol Sci 2000; 54(1-S), Abstract 346:73.
Tsuji JS, Serl KM. Multipathway exposure and risks to mercury in soil. Toxicol Sci 1998; 42(1-S), Abstract 1139:231.
Tsuji JS, Serl K, Fricke JR. Predicted versus observed blood lead levels for a smelter site. Fund Appl Toxicol 1997; 36(1):Part 2, Abstract 1706:336.
Presentations
Tsuji JS. Environmental health: Nanomaterials: nifty or naughty? Invited panel participant. Society for Environmental Journalists. Stanford University, Stanford, CA, September 7, 2007.
Tsuji JS. Background arsenic exposure from diet and water provide perspective for assessing arsenic exposure from other sources. Invited speaker for session on Risk Characterization and Risk Assessment. Conference on Urban Environmental Contamination and Health Under the Microscope: The Aftermath of Hurricane Katrina. The Society for Environmental Geochemistry and Health, New Orleans, LA, July 22–25, 2007.
Tsuji JS. From slippery slope factor to drinking water standard: How risk assessment affects the arsenic MCL. Invited speaker for session on Natural Poisons and Unnatural Products. American Water Works Association Annual Conference, Toronto, Ontario, June 27, 2007.
Tsuji JS, Mowat FS. Exposure and toxicology of nanomaterials. Invited speaker for Nano Safety and Health Forum. Society for the Advancement of Materials and Process Engineering (SAMPE) Conference, Baltimore, MD, June 6, 2007.
Tsuji JS, Mowat FS. Health risks of carbon nanotubes: What can we learn from mineral fibers or ultrafine particulates? Workshop organizer and chairperson. Annual Meeting of the Society of Toxicology. Charlotte, NC, March 25–29, 2007.
Tsuji J, Mowat F. Assessment of products containing nanomaterials. Symposium entitled, “Regulating nanotechnology: Developing stakeholder consensus for future rulemaking by EPA, FDA and OSHA.” Division of Chemistry and the Law of the 232nd American Chemical Society National Meeting. San Francisco, CA, September 10–14, 2006.
Tsuji JS, Mowat FS. Risk assessment of nanoscale metal particles. Invited presentation at the Environmental Protection Agency (EPA) Region 5 Nanotechnology for Site Remediation Workshop. Chicago, IL, September 6–7, 2006.
Mowat FS, Tsuji J. Nanotechnology and the water market: Applications and health effects. Abstract 747. Presented at 9th Annual NSTI Nanotechnology Conference and Trade Show. Boston, MA, May 7–11, 2006.
Tsuji JS, Mowat FS. Potential benefits and hazards of nanotechnology in water. Session on Natural Poisons and Unnatural Products. American Water Works Association Annual Conference. San Francisco, CA, 2005.
Tsuji JS. Emerging issues in risk assessment and risk perception of nanomaterials. Symposium organizer and chairperson at the Society of Toxicology annual meeting, New Orleans, LA, 2005.
Tsuji JS. Assessing children’s exposure to arsenic treated wood. Society of Toxicology continuing education course on Fundamentals of Risk Assessment and Applications of Recent Methods to Difficult Problems, Salt Lake City, UT, 2003.
Tsuji JS. Childhood lead exposure pathways and risk factors for lead exposure at U.S. mining and smelting sites. Plenary presentation at Local Solutions Smart Future Conference and Celebration, Working and Living with Lead, Port Pirie, South Australia, 2003.
Tsuji JS, Yost L, Barraj L. Background inorganic arsenic exposures in children. Session on CCA Treated Wood—Regulations, Science, and Risk Assessment. The Annual International Conference on Soils Sediments and Water, University of Massachusetts, Amherst, MA, October 22, 2003
Tsuji JS, Williams P. Use of biomonitoring versus risk assessment methods for evaluating human exposures. Platform presentation at the Society of Risk Analysis Annual Meeting, New Orleans, LA, 2002.
Tsuji JS, Benson R, Schoof RA, Hook GC. Childhood Health Effect Levels for Arsenic. Poster presentation at the 5th International Conference on Arsenic Exposure and Health Effects, San Diego, CA, 2002.
Tsuji JS, Robinson S. Separating potential source exposure from background exposure in subsistence populations in developing countries. Invited symposium presentation at the 9th International Congress of Toxicology Conference, Brisbane, Australia, 2001.
Tsuji JS, Schoof RA, Robinson S, Seidel P. Dietary arsenic in subsistence populations from Indonesia. Invited presentation at the 4th International Conference on Arsenic Exposure and Health Effects, San Diego, CA, 2000.
Tsuji JS. Risk Assessment and Cleanup Goals. Presentation within the Continuing Legal Education Course: Real World Applications of Contaminant Source Identification, Age Dating, and Toxicology in Environmental Litigation. University of California San Diego Extension, 2000.
Tsuji JS. Chairman and introductory speaker for a session on community health monitoring and education programs. National Environmental Policy Institute Conference on Lead in Soil and Blood Lead of Children, 1998.
Tsuji JS. The role of risk assessment in water quality. Presentation at the Washington State Bar Association, Continuing Legal Education Committee and Environmental and Lead Use Law Section, “Science and the Law,” Seattle, WA, 1997.
Tsuji JS. Risk assessment/toxicology. Presentation at the Environmental Science for Attorneys Workshop, Utah State Bar Continuing Legal Education, Salt Lake City, UT, 1996.
Tsuji JS. Site specific risk assessment and risk based corrective action: Are these cleanup approaches worth the cost? Presentation at the 13th Annual Hazardous Waste Law and Management Conference, Seattle, WA, and Portland, OR, 1996.
Tsuji JS. Toxic tort update emphasizing medical monitoring. Presentation at the 4th Annual Fall Meeting, American Bar Association, Section of Natural Resources, Energy, and Environmental Law, Boston, MA, 1996.
Serl KM, Tsuji JS. Use of a pharmacokinetic model for assessing lead risk in East Helena, Montana. Co-authored Poster at the Society of Toxicology Annual Meeting, Baltimore, MD, 1995.
Tsuji JS. Current uses of the EPA lead model to assess health risks and action levels for soil. Platform presentation at the Rocky Mountain Lead, Arsenic Conference. Society for Environmental Geochemistry and Health, Salt Lake City, UT, 1994.
Tsuji JS. From mice to men: How risk-based cleanup levels are developed. Presentation at The Science Behind Environmental Law Workshop. Washington State Bar Association Continuing Legal Education Committee and Environmental Land Use Section, Seattle, WA, 1994.
Tsuji JS. Guest lecturer on risk assessment and toxicology for course on environmental law. Stanford University School of Law, Palo Alto, CA, 1994.
Tsuji JS. Metals uptake and health risks associated with cattle grazing on mine tailings. Platform presentation at the Society of Environmental Toxicology and Chemistry Annual Meeting, Denver, CO, 1994.
Tsuji JS. Scientific considerations in using aquatic and sediment criterion. Presentation at The Second Annual Clean Water Act Conference. Puget Sound Water Quality Authority, Seattle, WA, 1994.
Tsuji JS. Toxic exposure and risk factors. Presentation at The Science in the Court-room Workshop. Washington State Bar Association Continuing Legal Education Committee, Seattle, WA, 1994.
Tsuji JS. Air toxics and risk management analysis in Arizona. Presentation at the Air Quality Technical Workshop sponsored by the Arizona Association of Industries and Kleinfelder, Inc., Prescott, AZ, 1993.
Tsuji JS. Effects of chemical and physical form on the bioavailability of arsenic in the environment. Poster presentation at the International Conference on Arsenic Exposure and Effects. Society of Environmental Geochemistry and Health, New Orleans, LA, 1993.
Tsuji JS. Risk assessments in Washington State. Invited Speaker for the monthly program of the Association of Women in Environmental Professions, Seattle, WA, 1993.
Tsuji JS. Risk assessment in independent cleanup actions. Lecture for the Continuing Legal Education (CLE) International Conference on the Washington Model Toxics Control Act, Seattle, WA, 1992.
Tsuji JS. Risk assessment of residue disposal and utilization. Presentation at the Meeting of the International Ash Working Group, Rutgers University, 1992.
Tsuji JS. Toxicological basis of absorption factors. Presentation at the Annual Meeting of the Society of Toxicology, Seattle, WA, 1992.
Tsuji JS. Advanced issues: risk assessment methodologies. Presentation at the Eighth Annual Hazardous Waste Law and Management Conference. Sponsors: U.S. Environmental Protection Agency, Region 10, and University of Washington School of Law, 1991.
Blanchet R, Tsuji JS. Evaluation of impacts to terrestrial ecosystems: opportunity for ecotoxicologists. Co-authored poster at the Annual Meeting of the Society of Environmental Chemistry and Toxicology, Seattle, WA, 1991.
Tsuji JS. Risk assessment of hazardous wastes and hazardous materials. Invited speaker for the quarterly meeting of the Academy of Hazardous Materials Management, Pacific Northwest Chapter, Seattle, WA, 1990.
Tsuji JS. Essential components of a human health risk assessment. Invited speaker for the Puget Sound Section of the American Chemical Society, Everett, WA, 1989.
Tsuji JS. Health effects of solid waste incinerator ash. Symposium on Solid Waste Management, National Environmental Health Association, Everett, WA, 1989.
Tsuji JS. Application of toxicology. Participant in a panel discussion for the Annual Meeting of the Pacific Northwest Association of Toxicologists, Moscow, ID, 1988.
Tsuji JS. Principles of toxicology. Invited lecturer for the Hazardous Waste Managers Course. University of California, Los Angeles, CA, 1987.
Product Safety
Conducted state-of-the-science reviews of potential exposure and health effects related to nanometal oxides, and other inorganic and organic nanomaterials proposed for use in several products with widespread consumer uses. Evaluated exposure and health effects literature related to worker or consumer exposure and potential environmental effects. Directed a team of material scientists and toxicologists to assess the potential for exposure to nanoparticles from these products during manufacture and consumer use.
Directed a literature review and assessment of studies of potential exposure and health effects associated with nanometal pigments used in sunscreen formulations. Provided senior review of a survey of toxicology studies on nanoscale silver and silver in general with relevance for use in personal care products.
Evaluated the toxicology of cleaning and sanitizing agents for a Fortune 500 consumer product company negotiating backflow device requirements with health authorities. Communicated the nature of the toxicity of the ingredients and compared exposure during a backflow event with other dietary or cosmetic exposures to these chemicals.
Researched the toxicology of the more than 22 ingredients in carpet glue for a glue manufacturer who was sued along with the carpet manufacturer, carpet installers, and landlord of a retail space in which tenants claimed multiple chemical sensitivity and other long-term health effects from short-term exposure to a newly installed carpet.
Directed an assessment of exposure and health risks for chemicals associated with fragrances used in various consumer products. Evaluated the potential for certain compounds to react with ozone and assessed the toxicity of the reaction by-products. Compiled comprehensive literature summaries and identified data gaps and areas for additional research and investigation.
Provided senior review and direction in commenting on several versions of probabilistic risk assessments developed by the U.S. EPA Office of Pesticide Prevention to assess childhood and residential exposure to treated wood used in playground equipment and residential decks.
Metals
Worked with a team of epidemiologists on a meta-analysis of low levels arsenic exposures and cancer. Eight studies of arsenic exposures and bladder cancer met these criteria (e.g., low level exposure, case-control or cohort study design, nutritionally sufficient populations). The results of the meta-analysis were submitted to the EPA Science Advisory Board (SAB) reviewing the cancer slope factor for arsenic. Also provided technical comments to the SAB regarding arsenic toxicology and nutrition, perspective on background exposure via diet and water, and information from health studies from a number of smelting sites.
As a part of an inter-disciplinary, international team, evaluated the health effects of metals and other constituents in tailings discharged into a river system from a copper mine in Southeast Asia. Served as the senior toxicologist for the human health risk assessment. This risk assessment entailed designing a dietary, human exposure, and biomarker survey of subsistence populations in the area and overseeing the implementation of the survey at the site. The survey information was used in both screening-level and detailed probabilistic assessments of risks to these populations. Trained local scientists in how to conduct risk assessments and presented preliminary results to a government scientific review panel.
Provided senior direction for development of a framework to assess arsenic and chromium exposure and toxicity to children from chromated copper arsenic (CCA)-treated wood used for play equipment and residential decks. This project involved analysis of the available scientific data and identification of critical uncertainties for exposure parameters that would benefit most from additional research. Presented the analysis to the Agency for Toxic Substances and Disease Registry and EPA. Commented on EPA’s deterministic risk assessment of CCA-treated wood and on the agency’s probabilistic exposure model for assessing exposures to wood treatment chemicals. Testified at EPA’s FIFRA Science Advisory Panel meetings and before the Consumer Product Safety Commission regarding background exposures to inorganic arsenic via diet and water in comparison to CCA exposures.
Commented on inaccuracies in a British Broadcasting Corporation interview and commentary on dock worker health effects from exposure to an arsenical wood-treating solution that leaked from shipping containers at an African port. Separated symptoms associated with arsenic poisoning from those more likely due to hemorrhagic fevers or other local health problems.
Served as the senior toxicologist for a probabilistic risk assessment of arsenic in soil in a community in Arizona that received historical flooding from a tailings impoundment. Provided arsenic toxicology expertise and scientific input on distributions of values for arsenic bioavailability and other inputs to the Monte Carlo risk assessment.
Participated in an EPA working group involving the Agency for Toxic Substances and Disease Registry, state and local health agencies, interested parties, and concerned residents of a Superfund and Environmental Justice site in Denver with elevated levels of arsenic and lead over a large residential area. A primary source of the elevated arsenic levels was found to be historic use of an herbicide for lawns. Attended monthly meetings over a 2.5 year period and provided comments on data collection, bioavailability of metals, biomonitoring, risk assessment, and the toxicology of arsenic and lead. Participated in focused technical meetings on the short-term toxicology of arsenic in children and pica soil ingestion by children.
Served as senior toxicologist on a case involving lead-containing brass in water meter parts for a water department of a large municipality in California. The water department was seeking cost recovery from a supplier that provided water meters and valves containing more lead than specified in the order. The water department also had concerns for public exposures. Our work involved evaluation of the leach test information and conducting various exposure simulations of the potential effect on blood lead levels of children.
Directed human health and ecological efforts to evaluate risks before and after reclamation of an abandoned mine site in a wildlife refuge in Northern California. These assessments were performed for the State Department of Fish and Wildlife. Features of the site included an acidic pit lake, tailings and waste rock piles, and mine drainage and mineralization of groundwater and a nearby creek.
Directed a health risk assessment of tetraethyl lead in sediments at an overseas offshore loading facility. The assessment evaluated the current literature on organic lead toxicity and included design of site-specific data collection and analysis to quantify exposure. Assessed health risks via fish ingestion probabilistically using Monte Carlo techniques. Developed a survey of local practices related to fishing and designed experiments to quantify cooking loss of tetraethyl lead. Educated scientific experts of the foreign court on health risk assessment and presented the risk assessment findings. The acceptance of this risk assessment allowed approval of the site closure strategy.
Appointed as an expert to advise a U.S. district court on health risks related to lead, arsenic, and other inorganic and organic chemicals for an 11-mile2 area of the city of Dallas, Texas. The study area included a former secondary lead smelter, several battery and metals reclamation facilities, numerous other industries, a large public housing project, single and multi-family private residents, and schools.
Conducted risk assessments and health risk reviews and worked with federal and state regulators to evaluate various health issues in areas near a large open pit copper mine and smelter in Utah. The areas included residential and recreational area soils affected by past air emissions or by deposition of metals in tailings during flooding from a stream channel. Evaluated the results of an environmental exposure and biomonitoring program for lead and arsenic in children for use in assessing health risks and cleanup levels. Also assessed drinking water exposure to sulfate and other inorganic constituents in groundwater. Provided a scientific review of the toxicity of sulfate to humans that U.S. EPA Region 8 relied on to set a site-specific action level for sulfate in groundwater used for drinking water.
Directed the human health and ecological risk assessments for tailings and naturally mineralized soil at a former mill site in New Mexico. The primary site constituents were manganese and zinc in groundwater and lead, manganese, and arsenic in soil. Lead in soil was evaluated using EPA’s adult and child lead models with site-specific assumptions when justified. Detailed site geochemistry studies and simulated gastrointestinal leaching tests indicated very low bioavailability of lead in soil. This work was conducted as a part of a voluntary removal action. Worked with the state regulatory agency to permit closure of the site.
Evaluated claims by a couple in New Mexico that past weekend exposures to elevated levels of metals and fluoride in their drinking water put them at risk of future disease.
Retained as an expert in two separate legal suits at a mining site in Washington. One suit involved releases of acrylamide in drilling muds to groundwater; the other, cyanide and metals concentrations in surface water and groundwater near the gold mine. Assessed the potential health risks of chemical concentrations to populations in the vicinity. Testified before a jury in the latter case.
Provided toxicology and exposure assessment support for a litigation case involving a competitive shooter who alleged his health effects and elevated blood lead level were caused by the conditions of an indoor firing range. Assessed lead data from range samples and designed an exposure study at an outdoor range to assess whether the plaintiff’s lead exposure was associated more with his equipment and style of rapid firing than with the ventilation conditions in the range. Also evaluated whether the plaintiff’s health effects were related to his chelation therapy and whether this treatment was applied appropriately.
Retained by a county in Oregon to direct a risk assessment of elemental mercury and cinnabar ore in soil at the site of a former small-scale refining operation. The RI/FS was conducted under the state voluntary cleanup program and involved close coordination with state toxicologists. The risk assessment evaluated direct exposures to soil as well as mercury vapor emissions and potential effects on groundwater and migration to nearby rivers. This study justified health-based cleanup levels that resulted in limited hot-spot removal.
Conducted risk assessments for a former copper smelter in Tacoma, Washington. Risks were assessed for arsenic and lead in soil and slag in nearby residential areas and for more than eight metals, PAHs, PCBs, and aniline compounds in soil, slag, demolition debris, groundwater, and surface water on the smelter site. Risks of the site to aquatic life and fishermen were also considered. Participated in discussions of health issues with EPA; in risk communication at public meetings and with citizen groups; and in a technical work group with EPA, the state, NOAA, and other trustees to design and implement toxicity testing and assessment of sediment impacts.
Directed a risk assessment of metal concentrations under baseline and post-mine-development conditions as a part of the permitting process for a gold mine in Montana. Because the mine site is located near the confluence of two rivers, fish consumption was a major pathway of exposure in addition to potential effects on groundwater. Assisted in risk communication.
Directed health risk assessments of lead smelter sites in Montana, Utah, and Washington. Reviewed and commented on the health risks of smelter sites in Kansas City, Idaho, Illinois, and Texas. Chemicals of concern included lead, arsenic, and cadmium. Evaluated blood lead and urinary arsenic concentrations of residents and environmental sampling data. Assessed impacts from air, water, soil, and dust using EPA’s integrated exposure/uptake biokinetic (IEUBK) lead model for the Montana site. Commended by EPA, clients, and the public for developing risk-based solutions that facilitated consensus on a remedial approach and expedited site closure.
Conducted a health risk assessment of a lead smelter site on the Missouri River in Omaha, Nebraska, that was proposed for brownfield redevelopment as a park. Assessed health risks during demolition and construction as well as afterwards to visitors and maintenance workers of the park. Also considered the potential impacts resulting from flooding of the site. Discussed health risk issues with the state regulators, and participated in public meetings. This work facilitated the cleanup and redevelopment of the site by addressing health risk concerns.
Served as project manager under a contract with EPA for conducting a risk assessment of a reservoir in Montana filled with sediments from upstream mining and smelting activities. The site covers hundreds of acres involving potential impacts to aquatic life, wetlands, bird life, and local drinking water wells. The risk assessment involved coordination among various agencies (EPA, the State of Montana, the U.S. Fish and Wildlife Service, the Montana State Department of Fish and Game), the public, and the principal responsible party.
Calculated health-based soil remediation goals in support of risk-based closure and redevelopment of a zinc plant site in Oklahoma. Lead, arsenic, and cadmium in soil and smelter debris used as fill material were the primary health concerns. Successfully obtained state approval of health-based remediation goals for nearby residential areas and for the plant site, assuming commercial redevelopment.
Provided technical review and comments on the engineering evaluation/cost assessment for a zinc plant site in southern Illinois. Evaluated site-specific uses of EPA’s IEUBK lead model for estimating lead risk for residential soil with isolated areas of lead-containing smelter debris for both sites. Also calculated lead risks to workers using an adult lead model.
At another zinc plant site in Oklahoma, directed screening-level assessments of exposure and risk and made recommendations for communicating the necessity of closing private wells because of potential risks associated with cadmium in groundwater.
Conducted focused health evaluations for zinc plants in Texas and Tasmania. Presented findings for the Texas site to the regulators and in a brief televised news interview.
Assessed the toxicity of mine tailings to cattle and food chain transfer of metals in tailings to humans consuming beef or beef liver. This study was a part of a successful project in Arizona to use cattle to revegetate and stabilize mine tailings slopes.
Reviewed the scoring of arsenic by the Canadian Government’s Substance Selection Committee, which implemented the Ontario Ministry of the Environment Scoring System for Assessing Environmental Contaminants. Provided technical comments on the environmental fate and persistence, aquatic toxicity, and carcinogenicity of different forms of arsenic. Reviewed a draft Environment Canada report on the long-range transport of metals in the environment with specific focus on the sources and migration of mercury.
Provided health risk and toxicology expertise for an active cadmium refinery in Denver, Colorado. Reviewed risk assessments, evaluated air emissions, interpreted health data of residents, discussed technical issues with the state agencies, and communicated risk to the public. This site required environmental cleanup for cadmium, lead, and arsenic.
As an expert for the Environmental Protection Authority of Victoria, conducted a focused risk assessment of lead in soil from a past battery recycling plant in Melbourne, Australia. Residential development had already commenced at the site without prior remediation. This assessment was instrumental in justifying that health protective actions were necessary.
Provided comments on EPA’s assessment of health risks and potential cleanup levels associated with arsenic and other metals in soil from a mining site near Salmon, Idaho. The site is in a remote area, contains an inn and primitive campgrounds, and is located near two creeks. Stream-side tailings deposited downstream of the site were also a concern. Site-specific issues included the bioavailability of the ore and the amount of exposure associated with recreational or livestock use of the area. Worked with EPA scientists in developing appropriate risk assessment assumptions and cleanup levels.
Reviewed the NPL ranking of a mine waste site in Idaho that received one of the highest scores. Comments primarily focused on the lack of consideration of the bioavailability of arsenic and lead in the mine waste. Provided senior toxicology input to the assessment of both human health and ecological impacts, wetland areas, and a nearby river. Worked on behalf of the responsible parties to help ensure that up-to-date scientific methods and site-specific assumptions were considered. Provided oversight on bioavailability and geochemical studies of the soils and waste rock.
Retained as the senior toxicologist for a risk evaluation of mine tailings in Coeur d’Alene River and Lake in Idaho. Provided technical input and risk communication regarding the likelihood of adverse effects associated with exposure to metals in surface water, fish, and beach sediments resulting from tailings releases from upstream mining. Communicated the findings of the risk evaluation at a press conference. Later retained as an expert on human health issues in the natural resource damage assessment suit. Evaluated the available data relating various sources of environmental lead in the Coeur d’Alene basin to blood lead levels of children.
Served as a senior advisor for human health investigations of environmental and dietary exposures associated with a zinc mine, haul road, and concentrate loading facility in northern Alaska. Native American concerns included deposition or uptake of metals into berries, caribou muscle and organs, and fish. Reviewed data collection work plans and risk evaluations of environmental data.
Assessed the bioavailability and adverse health effects of arsenic-containing ore and mercury contamination of an old gold mining site in Alaska that was turned into a children’s playground. Negotiated a site-specific approach for setting cleanup levels with the Alaska Department of Environmental Conservation. This study developed a cleanup level for arsenic based on a health risk assessment that incorporated the low bioavailability of the ore form of arsenic.
Provided senior direction and review of an evaluation of thallium levels in cement kiln dust and exposures to workers at a cement plant in Florida. Recommendations were made for reducing thallium levels to protect the health of workers.
Assessed exposure to lead and arsenic in soil from historic sandblasting and repainting of water tanks in residential neighborhoods in Seattle, Washington.
Medical/Biological Monitoring Designed and directed an arsenic exposure investigation and biomonitoring study of more than 400 residents living near a pesticide manufacturing plant. The study included a detailed census of the community, public communications, administration of a survey of individual characteristics affecting exposure, and collection and reporting of biological samples (urine and toenails) and environmental samples (house dust, soil, vegetables) for arsenic analysis. The data collected were used in a cross-sectional statistical evaluation of soil arsenic exposure in the community.
Evaluated potential for health effects and provided technical consulting pro bono to a homeowner who drank well water with elevated arsenic levels, including review of well water data, medical records and biomonitoring results.
Served as the senior toxicologist of a team that designed and conducted an environmental and dietary exposure study to assess potential metals exposure of highland, lowland, and estuarine populations living along a river that carried tailings from a mine and mill in Southeast Asia. This study also included biomonitoring of inorganic substances in blood, urine, and hair to correlate with other measures of exposure.
Developed work plans for community protection measure programs to address residual risks to lead and arsenic in residential soil at a former smelting area in Utah and for several communities in the tri-state mining district in Oklahoma. The programs involved health education, blood lead and urinary arsenic monitoring, health intervention, and environmental abatement, if warranted. These programs were developed cooperatively with federal, state, and local health agencies. Worked with EPA and state and local health departments in interpreting blood lead and environmental lead data for risk management decisions at the Leadville, Colorado, mining and smelting site.
Served as a toxicology expert in legal cases involving children in Oklahoma. The families alleged that their children’s prior blood lead levels resulted from wind-blown dust from mine waste piles and had caused behavioral and academic problems in school. Evaluated sources of exposure for each child and the potential effects associated with their blood lead levels.
For two residential areas in the Midwest involving releases of elemental mercury from gas meter regulators in homes, provided information on the toxicity of elemental mercury, biomonitoring of individuals for exposure, and background sources of elemental mercury. Provided risk communication and technical support in developing strategy for working with EPA Region 5 on what levels might constitute a concern in homes. Conducted a meta-analysis of studies examining the relationship between mercury levels in air and in urine. Based on this analysis, recommended limits to the usefulness of biomonitoring for mercury vapor.
Directed an evaluation of beryllium exposure in workers manufacturing aluminum alloy products. Reviewed air and wipe sample data and provided a review of the available scientific and medical information regarding the likelihood of disease and strengths and limitations of medical monitoring tests.
Retained as an expert on the toxicology and health risk of metals associated with contamination of private wells by acid mine drainage in Arizona. Served as the senior lead of the human health risk assessment team and worked with county and state health officials to assess and communicate to residents the potential health effects indicated by well water sampling results. Manganese was the primary chemical of concern. As a part of a settlement for a class action lawsuit, proposed an approach to exposure screening and medical monitoring and worked with plaintiffs’ expert from a local university to develop a reasonable medical monitoring program for residents.
Provided testimony in a class action lawsuit in Washington State regarding the alleged need for medical monitoring for all residents in the vicinity of a smelter living on soil with arsenic and lead levels above background levels. Key issues included the lack of sensitivity of tests at these low exposure levels and the low risk of adverse effects.
Risk Communication Evaluated residual lead levels in dust and cleanup efforts for a former printing facility building in Colorado that was converted for use as a charter school. Explained lead exposure and health issues at two town hall meetings for parents, teachers, and students.
Provided toxicological expertise and risk communication for a school district dealing with the issue of lead in drinking water of schools. Assessed the sampling data, recommended further testing and controls, and discussed the nature of the risks and solutions with school officials. Contributed to press releases and communication to parents.
Met with a daycare owner and concerned parents in a residential area near a former smelter to discuss their potential health concerns associated with soil sampling results for arsenic and lead on the property.
Selected as an external expert to engage in a brainstorming session to assess the relative importance of environmentally related human health problems in the State of Washington. This work was a part of EPA’s Pilot Comparative Risk Project, Region 10, 1997.
Participated in public meetings and news conferences as a health risk expert. Explained health issues to concerned parents at a daycare facility near a Superfund site. Evaluated and communicated potential health risks of a nearby hazardous waste site cleanup to the cast and crew of a television studio in California.
Air Toxics
Conducted a state-of-the-science review of the toxicological basis for short-term and long-term air quality criteria for methylene chloride. Evaluate air guidelines developed by agencies in the United States, Canada, Europe, Israel and by the World Health Organization. This project was followed by a review of the scientific basis supporting short-term and long-term exposure limits for airborne levels of 12 other chemicals.
Retained as the senior toxicologist on odor and health issues for a pulp mill in Camas, Washington, that had a release of hydrogen sulfide and mercaptans that reached a school. The strong odors at the school resulted in children feeling acutely ill with some being sent to the local hospital. Discussed the nature of the risk and latest scientific information with state and local health agencies to promote better risk communication and attended a public meeting at the site.
Provided senior review of a health evaluation of workers exposed to hydrogen sulfide, mercaptans, and other sulfur compounds in air at a geothermal energy plant. Issues of concern also included potential toxic interactions among these compounds.
As an expert for a city, evaluated the potential health effects of odorous chemicals (primarily hydrogen sulfide and mercaptans) associated with emissions from a wastewater treatment plant. A critical issue was the distinction of odor levels that are a public nuisance, possibly resulting in subjective effects in some individuals, but that do not cause clinically defined adverse health effects.
Retained by the U.S. Department of Justice as a toxicology expert to help assess cases involving enforcement actions by EPA for two sites with potential public exposures: one with chromium in groundwater, the other with accidental releases of hydrogen sulfide from a plant into a community. Testified on findings at an administrative hearing for the hydrogen sulfide case.
Evaluated the inhalation toxicology and health risks of criteria pollutants, metals, and silica for an application submitted to the Texas Air Board for permitting of modernized equipment at a copper smelter. The permit was approved.
Directed multipathway risk assessments of hazardous and municipal waste incinerators. Researched the health effects of incineration ash. Incineration sites included New Jersey, Kentucky, some midwestern states, and Seattle, Washington. Chemicals of primary concern for potential risks were metals, dioxins, and furans.
Served as senior reviewer of risk assessments and scientific reviews of the health risks associated with cement kilns burning hazardous waste. Participated in an investigation of occupational exposures and health and safety issues for cement kiln dust.
Assessed the nature of health risks associated with chemicals emitted by semiconductor industries (projects for four different companies) in Arizona. Chemicals emitted by operations were primarily acute toxicants, such as acids or bases and some solvents, rather than chemicals with potential long-term cumulative effects. Communicated risks to regulators and concerned citizens at a public hearing and assisted in preparing a corporate environmental report and other information for the public. The projects involved emissions from proposed facilities that were subsequently permitted; from operating facilities; and from a circuit-board manufacturing plant that had a fire.
Served as a toxicology and risk assessment expert in commenting on proposed hazardous air pollutant (HAP) rules for non-federal HAPs in the State of Arizona. Participated in a series of public hearings and communicated the latest scientific information to the Arizona Association of Industries (AAI), public interest groups, and the Arizona Department of Environmental Quality (ADEQ). Commended by ADEQ, AAI, and public representatives for scientific contributions to the process and facilitation of consensus.
Subsequently, commented on the revised HAPs program proposed by the State of Arizona. In addition to comments on the overall process, specific comments were submitted on the health-based methodology and use of the toxicological literature in developing short-term and long-term air criteria for individual chemicals.
Served as the senior toxicologist as a part of a team of industrial hygiene and air quality specialists investigating possible causes and remedies for various health complaints suffered by staff working in the neonatal intensive care unit of a hospital in Nevada. Possible causes investigated included re-entrainment of boiler exhaust, other problems with the ventilation system, or indoor sources of chemicals.
Selected by a major cancer research facility and the local fire department to help settle a dispute regarding the acute inhalation toxicity of formalin and its classification according to the Uniform Fire Code. Strict interpretation would have required the facility to shut down because only a small amount of formalin would have been allowed per building. Provided the scientific interpretation on the toxicity of formalin versus formaldehyde that resolved the conflicting conclusions provided by experts for each of the parties, thereby allowing the facility to operate and the fire department to be confident that health would be protected in the event of a fire.
Provided an independent scientific review of a risk assessment of benzene in air of a daycare facility located on petroleum-contaminated soil.
On behalf of the surviving family, provided a summary of opinion as a toxicology expert in a case involving the death of a refrigerator repairman by carbon dioxide poisoning from dry ice used in a broken freezer. The key issues considered were the physiological and toxicological effects of elevated carbon dioxide levels and whether the repairman would have been able to rescue himself from the situation.
Pesticides and Herbicides
Conducted detailed toxicology evaluations of ethylene dibromide, dibromochloropropane, 1,3-dichloropropene, 1,2-dichloropropane, 1,2,3-trichloropropane, and epichlorohydrin for cases involving alleged exposures to fumigants from drift off of fields and from groundwater contamination. Specifically evaluated the scientific evidence related to whether exposure to these chemicals would cause the alleged health effects.
Evaluated health risks associated with residential exposure to pesticides and herbicide releases as a result of a fire at a nearby grain silo and a warehouse in Oregon containing more than 100 agricultural chemicals. Emergency response action levels were developed to guide remediation of residential soil contaminated by surface runoff of water used in fighting the fire.
Retained specifically to resolve risk assessment and cleanup levels issues with the state regulatory agency for persistent pesticides and herbicides in soil at an agricultural chemical site in Oregon.
Provided senior oversight on an evaluation of health and environmental effects of pesticides and herbicides used by Northwest utilities on vegetation and on utility poles.
In support of a settlement for a major retailer, evaluated the toxicity of their waste stream (mostly cardboard, although damaged packages of pesticides, herbicides, or fertilizers were also alleged to have been contributed) relative to other wastes that were historically sent to a landfill in Washington that had accepted municipal, medical, and hazardous waste.
Conducted a risk assessment of residual levels of chlorinated organic pesticides in “clean” fill used for remediating a residential area in California. Evaluated direct exposure via ingestion of soil and indirect exposure from eating home vegetable gardens.
Supervised expert toxicology work regarding a potential poisoning caused by an organophosphate pesticide and the use of pesticides on school buses and likely effects on children.
Volatile Organic Compounds (see also Air Toxics) Served as an expert witness for a case involving a perchloroethylene (PCE) plume in groundwater attributed to a former laundry and dry cleaning facility in Wyoming. Testified in court regarding the toxicology of PCE, health risks (via drinking water and volatilization in indoor air) to residents living over the plume, and effects on aquatic biota as a result of groundwater reaching a river. The court’s decision regarding the lack of an imminent and substantial endangerment reflected this testimony.
Directed and peer-reviewed assessments of health and environmental impacts of chemicals in groundwater as a part of landfill closures and corrective actions at multiple landfill sites in California, Montana, Washington, and Arizona. The evaluations included potential effects on drinking water wells and irrigation water, soil vapor exposure, and migration of volatile organic chemicals (e.g., trichloroethylene (TCE), PCE, vinyl chloride, chloroform) in groundwater to surface water bodies with exposure to aquatic organisms and fishermen. Detailed analysis of the human toxicology of these chemicals was also conducted to assess the limitations of the regulatory criteria, which are largely based on animal data.
Assessed sources and likely exposures to TCE and its breakdown products, 1,2-dichloroethene and vinyl chloride, in groundwater, soil gas, and indoor air samples at an industrial plant and for nearby residential properties in western Washington. Soil gas and air samples also included other volatile chemicals. Conducted a screening of health risks for the site and provided comments on a health consultation by the state department of health.
Retained as a toxicology expert by a county in Arizona for pending litigation concerning a landfill. The landfill had received multiple waste streams over time, including both hazardous, municipal, and construction debris. Evaluated the site environmental data and exposures at nearby retail stores, a restaurant, and motel that had elevated levels of volatile organic compounds in their well water.
Evaluated concentrations of volatile organic chemicals in air within a commercial building in southern California to assess whether volatile chemicals in groundwater were migrating into the building at concentrations of health concern for workers. Exposures were found to be less than California worker health criteria.
Evaluated the potential health risks of groundwater containing volatile organic chemicals in support of a legal settlement for a property owner adjacent to a major Superfund site in Washington.
Provided senior review for a facility in which workers received historical exposure to TCE in drinking water. This project included an evaluation of the scientific literature and current debates on the health risks of TCE and other volatile chlorinated compounds.
Worked with a team of epidemiology and toxicology experts to provide written comments on EPA’s risk assessment of TCE.
Developed risk-based cleanup levels for acetone, methyl ethyl ketone, methylene chloride, and toluene in soil at an industrial facility in North Carolina. Modeled exposure by soil ingestion, dermal contact, and inhalation of volatile emissions.
PCBs Assessed the adverse effects of PCBs and priority pollutants in uplands soils and river sediments on the environment (including aquatic organisms and associated terrestrial wildlife) and on public health at a former utility substation on the Willamette River in Oregon that was to be redeveloped into a museum. Designed a tissue residue study of local fish and used the results to derive more realistic bioaccumulation rates for PCBs in sediment. Presented the risk assessment to the Oregon Department of Environmental Quality (ODEQ). The cleanup based on this risk assessment was approved by ODEQ.
Assessed possible changes in cleanup levels for PCBs in sediments of an urban waterway in Commencement Bay, Washington. Evaluated the recent toxicological literature, sediment concentrations, fish consumption rate studies, and changes in regulatory guidance.
Provided senior review for a remedial investigation and ecological and health risk assessment of marine sediments in an urban harbor in southern California. Project efforts included sampling of sediment chemistry and biota, as well as implementation of aquatic and sediment bioassays. The primary chemicals of concern were PAHs from petroleum solvents, metals, PCBs, and persistent pesticides.
Assessed the relative hazards posed by PCBs compared with those posed by PAHs at a coal gasification and metal recycling NPL site in Washington. The study supported a de minimis settlement by the utility companies that had contributed transformers with residual PCB oil.
Dioxins/Furans, Pentachlorophenol On behalf of a city in Washington State, commented on the proposed changes in the state cleanup level regulations for dioxins and furans in soil. Provided scientific input on the toxicological basis of such criteria. Also on behalf of the city, provided comments on a remedial investigation report of a local pulp mill site with dioxins and furans in soil.
Investigated potential exposures and health risks of dioxins and furans emitted by a cement plant in Arizona. Supervised modeling and risk communication efforts.
Provided risk assessment input for a remedial investigation of a pole yard and wood products facility in Montana. Helped design sampling to collect the necessary data for a risk assessment and provided technical input on the need for interim remedial actions. The primary concern regarded pentachlorophenol and dioxins/furans released to soil and groundwater from former dip tanks for wood treatment. Groundwater releases threatened a sole-source aquifer. Reviewed and commented on the state’s risk assessment work plan and risk assessment drafts. Addressed issues of particular concern to the community such as the toxicity of dioxins/furans.
Conducted a RCRA evaluation of human health and ecological risks for a wood-treating facility bordering wetlands, a wildlife refuge, and a major tributary of the Columbia River. Primary issues of concern were transport of copper, chromium, arsenic, pentachlorophenol, and PAHs to the wetlands via contaminated groundwater. Soil sampling revealed these chemicals as well as petroleum hydrocarbons and dioxins. The potential toxicity of sediment samples was also assessed.
Served as an expert for EPA in evaluating effects to human health and aquatic organisms resulting from organic chemicals (pentachlorophenol, creosote, PAHs) and metals (copper, chromium, arsenic) in soil, groundwater, marine sediments, and surface water from a Pacific Northwest wood-treating facility. Dioxins and furans were also elevated in soil as a result of a retort fire.
Retained as an expert witness in support of litigation regarding the potential health effects and cleanup levels at an industrial site in northern California involving various activities, including lumber storage, wood treatment, wood products manufacturing, and railroad engine construction. Testified at two court hearings.
Provided senior oversight for risk assessment and risk communication about dioxins and PCBs in onsite and offsite residential soil at a pulp mill in Washington State.
Petroleum Sites Conducted an evaluation of health and environmental effects of a former Pacific Northwest boat repair and cannery site that was redeveloped into a resort. Issues of primary concern included petroleum hydrocarbons in soil and the aquatic toxicity of tributyltin in marine sediments and in groundwater that discharges to the surface water in the harbor. Evaluated the toxicity of tributyltin in sediments, focusing on mussels and oysters as sensitive indicator species. PAHs and lead were also elevated in subsurface soils and in groundwater. Potential human exposures included those of children playing on the beach and people eating seafood collected at the site. This assessment guided a cost-effective, risk-based remediation of the site for development as a resort.
Retained as a toxicology expert for property owners and tenants potentially affected by a groundwater plume of heating oil from a utility site in Spokane, Washington. Provided technical comments on site investigation plans and a risk assessment and assisted the citizens in understanding the health risks and state RI/FS process.
Reviewed and directed multiple risk assessments of petroleum hydrocarbons in soil and groundwater in Washington, Oregon, California, and Arizona. Most of these assessments were risk-based closures of UST sites in support of voluntary actions of two major oil companies or the U.S. Department of Defense. Also provided senior review of a risk-based remediation at a petroleum terminal site in Oregon.
Directed a risk assessment of petroleum compounds in soil and groundwater at a state Superfund site in Washington. Risks were considered for commercial use of the site as well as for potential exposure to nearby users of private wells. The assessment included a detailed toxicity evaluation of volatile and semivolatile chemicals in gasoline and diesel. Site-specific cleanup action levels were recommended depending on various engineering controls.
Assessed risks associated with PAHs and petroleum hydrocarbons in soil from underground storage tanks at an industrial site in Massachusetts. This risk assessment provided the state regulatory agency with sufficient scientific justification to approve a limited cleanup for the protection of workers.
For the City of Seattle, directed a review and assessment of risks to public health and aquatic life due to urban storm water discharges in the Seattle area. Lead and petroleum hydrocarbon compounds such as PAHs were the main concerns.
Provided senior direction and review of a contingency plan for incineration of oil-soaked waste and debris associated with oil spill cleanup in Alaska. This work was performed for a major petroleum consortium in response to regulatory requirements.
Multiple Chemical Sites/Issues
Project manager for a contract with Oak Ridge National Laboratory to write toxicity review documents for chemicals in support of U.S. EPA Integrated Risk Information System database of toxicity criteria for risk assessment.
Directed a health risk assessment for the Queensland government in Queensland, Australia (of a high-profile site known as Australia’s Love Canal), involving a residential area built over an area with previous mining and industrial and municipal disposal activities. The most visible source of concern was the appearance of acid oil sludge at the surface of yards built over mining pits filled with refinery wastes. Chemicals of concern included lead, PAHs, PCBs, cyanide, and chlorinated benzenes in groundwater, surface water, soil, and air.
Examined the nature and extent of underground contamination at an abandoned naval shipyard in northern California converted for residential use. Evaluated the potential for adverse health effects to future residents from long-term exposure to petroleum hydrocarbons, lead, and other metals. Developed and implemented surface flux chamber sampling to measure volatile chemical emissions from soil. Derived cost-effective, risk-based cleanup levels, which were approved by the California Department of Health Services.
Served as an expert for the State of New Jersey regarding health risks associated with a major urban park. Evaluated health risks associated with residual levels of chromium from chromite ore processing, petroleum-related chemicals, lead and other metals, PCBs, and pesticides. Effectively demonstrated the lack of a scientific basis for the opposing expert’s report.
Directed human health and ecological risk assessment of lead, PAHs, and explosive chemicals at a former industrial munitions facility. The site encompassed a large woodland area, including small lakes and a salmon stream, and bordered a wildlife refuge and river delta. Ecological concerns included both potential aquatic effects and risks to burrowing animals in the upland areas.
Retained as an environmental toxicology expert by Whatcom County, Washington, in a legal action filed by the county to cease storage of hazardous and solid waste on a property located within a primary watershed. Evaluated the potential chemical hazards at the property that might threaten the watershed.
Directed projects for EPA’s Technical Enforcement Support program. Responsibilities included direction of risk assessments for EPA and oversight of potentially responsible parties conducting risk assessments.