Personal exposure meets risk assessment: a comparison of measured and modeled exposures and risks in an urban community.Human exposure research has consistently shown that, for most volatile organic compounds volatile organic compound Environment Any toxic cabon-based (organic) substance that easily become vapors or gases–eg, solvents–paint thinners, lacquer thinner, degreasers, dry cleaning fluids (VOCs), personal exposures are vastly different from outdoor air concentrations. Therefore, risk estimates based on ambient Surrounding. For example, ambient temperature and humidity are atmospheric conditions that exist at the moment. See ambient lighting. measurements may over- or underestimate risk, leading to ineffective or inefficient management strategies. In the present study we examine the extent of exposure misclassification and its impact on risk for exposure estimated by the U.S. Environmental Protection Agency Environmental Protection Agency (EPA), independent agency of the U.S. government, with headquarters in Washington, D.C. It was established in 1970 to reduce and control air and water pollution, noise pollution, and radiation and to ensure the safe handling and (U.S. EPA EPA eicosapentaenoic acid. EPA abbr. eicosapentaenoic acid EPA, n.pr See acid, eicosapentaenoic. EPA, n. ) Assessment System for Population Exposure Nationwide (ASPEN) model relative to monitoring results from a community-based exposure assessment conducted in Baltimore, Maryland "Baltimore" redirects here. For the surrounding county, see Baltimore County, Maryland. For other uses, see Baltimore (disambiguation). Baltimore is an independent city located in the state of Maryland in the United States. (USA). This study is the first direct comparison of the ASPEN model (as used by the U.S. EPA for the Cumulative Exposure Project and subsequently the National-Scale Air Toxics Assessment) and human exposure data to estimate health risks. A random sampling strategy was used to recruit 33 nonsmoking non·smok·ing adj. 1. Not engaging in the smoking of tobacco: nonsmoking passengers. 2. Designated or reserved for nonsmokers: the nonsmoking section of a restaurant. adult community residents. Passive air sampling badges were used to assess 3-day time-weighted-average personal exposure as well as outdoor and indoor residential concentrations of VOCs for each study participant. In general, personal exposures were greater than indoor VOC (Vertical Online Community) See vertical portal. concentrations, which were greater than outdoor VOC concentrations. Public health risks due to actual personal exposures were estimated. In comparing measured personal exposures and indoor and outdoor VOC concentrations with ASPEN model estimates for ambient concentrations, our data suggest that ASPEN was reasonably accurate as a surrogate surrogate n. 1) a person acting on behalf of another or a substitute, including a woman who gives birth to a baby of a mother who is unable to carry the child. 2) a judge in some states (notably New York) responsible only for probates, estates, and adoptions. for personal exposures (measured exposures of community residents) for VOCs emitted primarily from mobile sources or VOCs that occur as global "background" source pollutant pol·lut·ant n. Something that pollutes, especially a waste material that contaminates air, soil, or water. with no indoor source contributions. Otherwise, the ASPEN model estimates were generally lower than measured personal exposures and the estimated health risks. ASPEN's lower exposures resulted in proportional underestimation of cumulative cancer risk when pollutant exposures were combined to estimate cumulative risk. Median cumulative lifetime cancer risk based on personal exposures was 3-fold greater than estimates based on ASPEN-modeled concentrations. These findings demonstrate the significance of indoor exposure sources and the importance of indoor and/or personal monitoring for accurate assessment of risk. Environmental health policies may not be sufficient in reducing exposures and risks if they are based solely on modeled ambient VOC concentrations. Results from our study underscore The underscore character (_) is often used to make file, field and variable names more readable when blank spaces are not allowed. For example, NOVEL_1A.DOC, FIRST_NAME and Start_Routine. (character) underscore - _, ASCII 95. the need for a coordinated multimedia approach to exposure assessment for setting public health policy. Key words: hazardous air pollutants pollutants see environmental pollution. , personal exposure monitoring, risk assessment, urban communities. Environ en·vi·ron tr.v. en·vi·roned, en·vi·ron·ing, en·vi·rons To encircle; surround. See Synonyms at surround. [Middle English envirounen, from Old French environner Health Perspect 112:589-598 (2004). dot: 10.1289/ehp.6496 available via http://dx.doi.org/[Online 22 December 2003] ********** The absence of human exposure information constitutes a critical source of uncertainty for risk-based regulatory decision making. Risk assessments are used by the U.S. Environmental Protection Agency (U.S. EPA) to estimate the likelihood that exposure to a given pollutant will produce an adverse health effect and to determine what regulatory actions are necessary to protect public health. In the absence of human exposure data, policy makers, risk assessors, regulators, researchers, and public health officials often must rely on estimates or surrogates of human exposure levels, such as proximity to a hazardous waste Hazardous waste Any solid, liquid, or gaseous waste materials that, if improperly managed or disposed of, may pose substantial hazards to human health and the environment. Every industrial country in the world has had problems with managing hazardous wastes. site or regional ambient air quality data. Such estimates may be derived from models that predict levels of environmental contamination in the air. These approaches are limited in identifying health risks because they rely on assumptions about actual exposures experienced by people, thus introducing uncertainty in their risk estimates and ensuing en·sue intr.v. en·sued, en·su·ing, en·sues 1. To follow as a consequence or result. See Synonyms at follow. 2. To take place subsequently. policies. Although monitoring is generally recognized as providing a more reliable estimate of exposure, it carries its own limitations, such as cost for implementing on a large population scale over long periods of time to estimate long-term exposures. In 1995, the U.S. EPA released the results of its Cumulative Exposure Project (CEP CEP congenital erythropoietic porphyria. CEP abbr. congenital erythropoietic porphyria ). Under the CEP, the U.S. EPA used an air dispersion dispersion, in chemistry dispersion, in chemistry, mixture in which fine particles of one substance are scattered throughout another substance. A dispersion is classed as a suspension, colloid, or solution. model, the Assessment System for Population Exposure Nationwide (ASPEN) model, and 1990 emissions inventory data to characterize the magnitude, extent, and significance of airborne outdoor concentrations for 148 hazardous air pollutants (HAPs) listed under the 1990 Clean Air Act Amendments (CAAA CAAA Clean Air Act Amendments of 1990 CAAA California Applicants' Attorneys Association CAAA Crane Army Ammunition Activity CAAA California Agricultural Aircraft Association CAAA Clean Air Act Authority CAAA Commuter Airline Association of America 1990) for each of the 60,803 census tracts A census tract, census area, or census district is a particular community defined for the purpose of taking a census. Usually these coincide with the limits of cities, towns or other administrative areas and several tracts commonly exist within a county. in the contiguous Adjacent or touching. Contrast with fragmentation. See contiguous file. United States United States, officially United States of America, republic (2005 est. pop. 295,734,000), 3,539,227 sq mi (9,166,598 sq km), North America. The United States is the world's third largest country in population and the fourth largest country in area. (Woodruff et al. 1998). Although the model estimated exposures to HAPs of ambient origin, by default they were assumed to represent total human exposure forming the basis for human health risk estimation estimation In mathematics, use of a function or formula to derive a solution or make a prediction. Unlike approximation, it has precise connotations. In statistics, for example, it connotes the careful selection and testing of a function called an estimator. . Therefore, not only the validity of the ASPEN estimate relative to ambient measurements of interest but also the magnitude of the difference relative to personal and indoor exposure and the significance of this difference in risk estimation are important to understand. Results from the CEP suggested that HAP HAP. An old word which signifies to catch; as, "to hap the rent," to hap the deed poll." Techn. Dict. h.t. exposures were prevalent nationwide and that, in some locations, concentrations were significantly higher than concentrations associated with the one-in-one million excess cancer risk, levels considered by U.S. EPA researchers as a benchmark for acceptable "de minimus" risk (Caldwell et al. 1998; Woodruffet at. 1998). U.S. EPA researchers also concluded that HAP concentrations estimated by the model may pose a significant public health problem, especially in urban census tracts and census tracts of predominantly pre·dom·i·nant adj. 1. Having greatest ascendancy, importance, influence, authority, or force. See Synonyms at dominant. 2. low-income and minority populations (Morello-Frosch 1997; Morello-Frosch et al. 2000). The main sources of the HAPs were found to be mobile (e.g., automobiles and tracks) and area sources (e.g., dry cleaners and gas stations). The CEP has provided critical information about possible population exposures to HAPs and their relationship with population demographics The attributes of people in a particular geographic area. Used for marketing purposes, population, ethnic origins, religion, spoken language, income and age range are examples of demographic data. (race, ethnicity ethnicity Vox populi Racial status–ie, African American, Asian, Caucasian, Hispanic , and income) never before revealed on a national scale. In addition, the CEP has served as a prototype for the National-Scale Air Toxics Assessment (NATA NATA National Athletic Trainers' Association NATA National Association of Testing Authorities (Australia) NATA National Air Transportation Association (Alexandria, VA, USA) ). The U.S. EPA released the NATA modeling and risk assessment results in two phases: first, in September 2000, the ASPEN modeling data only; and then later in May 2002, results from a human exposure module [Hazardous Air Pollutant Exposure Model 4 (HAPEM HAPEM Hazardous Air Pollutant Exposure Model 4)] added to ASPEN and related risk estimates using 1996 air toxics emissions data as input for the ASPEN model. Given the paucity pau·ci·ty n. 1. Smallness of number; fewness. 2. Scarcity; dearth: a paucity of natural resources. of comprehensive ambient air monitoring data for HAPs and even fewer human exposure data, national air toxics modeling as carried out by the U.S. EPA will play a significant role in identifying effective control strategies to reduce public health risks from exposure to HAPs as required by 1990 CAAA, and in shaping national policies to reduce air pollution emissions. Many volatile organic compounds (VOCs) are listed by the U.S. EPA as HAPs (e.g., benzene benzene (bĕn`zēn, bĕnzēn`), colorless, flammable, toxic liquid with a pleasant aromatic odor. It boils at 80.1°C; and solidifies at 5.5°C;. Benzene is a hydrocarbon, with formula C6H6. , carbon tetrachloride carbon tetrachloride (tĕ'trəklôr`īd) or tetrachloromethane (tĕ'trəklôr'əmĕth`ān), CCl4, colorless, poisonous, liquid organic compound that boils at 76. , and chloroform chloroform (klôr`əfôrm) or trichloromethane (trī'klôrōmĕth`ān), CHCl3 ) and were included in the CEP. Beginning in the 1980s with the U.S. EPA's Total Exposure Assessment Methodology (TEAM) studies of VOCs, it has been demonstrated repeatedly that personal exposures typically exceed outdoor air concentrations and that levels of human exposure to VOCs depend on people's locations, especially indoors, where people spend up to 90% of their time (Akland et al. 1997; Buckley et al. 1997; Clayton et al. 1999; Cohen cohen or kohen (Hebrew: “priest”) Jewish priest descended from Zadok (a descendant of Aaron), priest at the First Temple of Jerusalem. The biblical priesthood was hereditary and male. et al. 1989; Kinney et al. 2002; Leung and Harrison 1998; Lioy 1990; Otson et al. 1994; Ott 1990; Pellizzari et al. 1999; Seifert et al. 1989; U.S. EPA 1987; Wallace 1993; Wallace et al. 1985; Weisel 2002). Therefore, assessment of potential public health impacts from HAPs is limited by the uncertainty in exposure estimates based on fixed-site ambient monitoring or models that use ambient concentrations to estimate exposure. Environmental policies that focus solely on reducing HAP emissions from stationary or point sources may not be effective in reducing human exposures and risks when the indoor environment is a significant contributor to exposures. At the same time that the U.S. EPA released results from the CEP, a community-based VOC exposure study, conducted in partnership with South Baltimore, Maryland, community leaders, was in the planning phases In amphibious operations, the phase normally denoted by the period extending from the issuance of the order initiating the amphibious operation up to the embarkation phase. The planning phase may occur during movement or at any other time upon receipt of a new mission or change in the . As a result, an opportunity arose to examine a) whether ambient concentrations of VOCs based on the U.S. EPA's ASPEN model were adequate estimates of ambient air toxic concentrations in South Baltimore and b) the magnitude of the differences between ambient estimates and the more health relevant indoor and personal exposures and the differences between their associated health risks. In this article we present the results of this investigation. Materials and Methods Study area, The South Baltimore communities of Brooklyn, Brooklyn Park Brooklyn Park, city (1990 pop. 56,381), Hennepin co., SE Minn., a suburb of Minneapolis; chartered as a city 1969. Manufacturing includes machinery, wood and metal products, tools, feeders, and medical and pharmaceutical supplies. , and Curtis Bay are located in the southeastern quadrant quadrant, in analytic geometry quadrant. 1 In analytic geometry, one of the four regions of the plane determined by two lines, the x-axis and the y-axis. of the City of Baltimore and adjacent counties. According to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. the 2000 U.S. Census, approximately 24,000 people live in South Baltimore: 80% white, 15% African American African American Multiculture A person having origins in any of the black racial groups of Africa. See Race. , 2% Asian, 2% Latino, and 1% of other ethnic backgrounds (U.S. Census Bureau Noun 1. Census Bureau - the bureau of the Commerce Department responsible for taking the census; provides demographic information and analyses about the population of the United States Bureau of the Census 2003). Most (60%) of these residents have a high school education, and the median family income in 2000 was about $37,000 per year (U.S. Census Bureau 2003). South Baltimore (Figure 1) presents a unique exposure scenario because of the intensity of large chemical industries in close proximity to residential areas. According to the U.S. EPA, there are approximately 189 permitted or registered stationary air (Physiol.) the air which under ordinary circumstances does not leave the lungs in respiration. See also: Stationary pollution sources [including Toxic Release Inventory (TRI TRI Toxics Release Inventory (US EPA) TRI Touch Research Institute TRI Taux de Rentabilité Interne (French: internal rate of return) TRI Taux de Rentabilité Interne TRI Tile Roofing Institute ) reporting facilities and smaller facilities] located in South Baltimore (U.S. EPA 2000b). South Baltimore (as defined by ZIP codes zip code System of postal-zone codes (zip stands for “zone improvement plan”) introduced in the U.S. in 1963 to improve mail delivery and exploit electronic reading and sorting capabilities. 21226 and 21225) is ranked 12th in the top 100 ZIP codes for total pollutant releases into the environment, with 360,479,759 lb released to air, land, and water bodies annually (Environmental Defense 2001). The communities' industrial air toxics pollutant burden is compounded by intense mobile-source emissions from nearby interstate highways Primary interstates are the major interstate highways of the United States and are assigned a one or two-digit route number. Even route numbers are assigned to east/west routes, with the lower numbered routes being further south (I-10) and higher numbered routes in the and local truck traffic servicing industry. [FIGURE 1 OMITTED] Participant recruitment and data collection. A population-based random sampling strategy was used to recruit 37 adult residents from the study area for personal exposure monitoring during January 2000 through June 2001. Nonsmoking residents were recruited into the study to limit the influence of active tobacco smoking on personal exposure measurements, because the constituents of tobacco smoke include a number of our target VOCs (Miller et al. 1998). Passive air sampling badges (#3500 organic vapor monitor; 3M Co., St. Paul St. Paul as a missionary he fearlessly confronts the “perils of waters, of robbers, in the city, in the wilderness.” [N.T.: II Cor. 11:26] See : Bravery , MN) were used to assess 3-day time-weighted-average (TWA TWA Time-weighted average, see there ) personal inhalation inhalation /in·ha·la·tion/ (in?hah-la´shun) 1. the drawing of air or other substances into the lungs.inhala´tional 2. the drawing of an aerosolized drug into the lungs with the breath. 3. exposures as well as outdoor and indoor residential air concentrations of 11 VOCs (Table 1) for each study participant. Study participants were asked to wear the sampling badges on a shirt lapel or collar near their breathing zone whenever possible. Indoor residential sampling badges were placed in the room where the participant usually spent his or her most time when not sleeping. Residential outdoor sampling badges were placed in a protected but unobstructed location just outside the home. Questionnaires were used to collect participant demographic information, including age, race, occupation, and household income, as well as exposure determinants--for example, use of air fresheners air freshener n → ambientador m air freshener air n → désodorisant m air freshener air n → , dry cleaning dry cleaning, process of cleaning fabrics without water. Special solvents and soaps are used so as not to harm fabrics and dyes that will not withstand the effects of ordinary soap and water. Dry cleaning began in France about the middle of the 19th cent. , and mode of transportation. Each subject was asked to maintain a daily time-activity diary to determine the time spent indoors and outdoors and to identify VOC sources, such as environmental tobacco smoke environmental tobacco smoke (ETS/passive smoke), n the gaseous by-product of burning tobacco products, including but not limited to commercially manufactured cigarettes and cigars; contains toxic elements harmful to the health of adults and children , occupational exposures, or car refueling during the 3-day monitoring period. Informed consent was obtained from all study participants following procedures established by the Johns Hopkins University Johns Hopkins University, mainly at Baltimore, Md. Johns Hopkins in 1867 had a group of his associates incorporated as the trustees of a university and a hospital, endowing each with $3.5 million. Daniel C. Bloomberg School of Public Health Human Subjects Review Board. VOC Sample analysis. At the conclusion of the 3-day sampling period, the sampling badges were collected, sealed with plastic covers and transported to the lab and stored at -20[degrees]C. Analysis was conducted using gas chromatography/mass spectrometry spectrometry /spec·trom·e·try/ (spek-trom´e-tre) determination of the wavelengths or frequencies of the lines in a spectrum. spec·trom·e·try n. (5890/5971 series II; Hewlett Packard, Palo Alto Palo Alto, city, California Palo Alto (păl`ō ăl`tō), city (1990 pop. 55,900), Santa Clara co., W Calif.; inc. 1894. Although primarily residential, Palo Alto has aerospace, electronics, and advanced research industries. , CA) following a standard method outlined by Chung et al. (1999). After adding an internal standard, the adsorbed VOCs were extracted from the sampling badges using a 2:1 solution of acetone acetone (ăs`ĭtōn), dimethyl ketone (dīmĕth`əl kē`tōn), or 2-propanone (prō`pənōn), CH3COCH3 :carbon disulfide carbon disulfide, CS2, liquid organic compound; it is colorless, foul-smelling, flammable, and poisonous. It can be prepared by direct reaction of carbon, e.g., as charcoal, with sulfur. It is a widely used solvent, e.g. containing the surrogate 4-bromofluorobenzene. The method detection limit (MDL MDL - (Originally "Muddle"). C. Reeve, Carl Hewitt and Gerald Sussman, Dynamic Modeling Group, MIT ca. 1971. Intended as a successor to Lisp, and a possible base for Planner-70. Basically LISP 1.5 with data types and arrays. ) was determined from field blanks as the value corresponding to the 99% confidence interval confidence interval, n a statistical device used to determine the range within which an acceptable datum would fall. Confidence intervals are usually expressed in percentages, typically 95% or 99%. . VOC sample concentrations below the MDL were set to one-half the MDL. Further details on the sample analysis methods are discussed elsewhere (Buckley et al. 2003). Descriptive statistics descriptive statistics see statistics. including central tendency and variability were generated to characterize personal exposures and indoor and outdoor concentrations for each of the 11 VOCs. Modeled ambient VOC data. The most recent (1996) ambient modeling results from the U.S. EPA's ASPEN model for the 11 target VOCs were obtained from the U.S. EPA Office of Air Quality Planning and Standards (U.S. EPA 2000c). For each pollutant, ASPEN provides modeled ambient annual average concentrations in units of micrograms per cubic meter Noun 1. cubic meter - a metric unit of volume or capacity equal to 1000 liters cubic metre, kiloliter, kilolitre metric capacity unit - a capacity unit defined in metric terms for three source categories (area, mobile, and point sources) and the total modeled ambient concentrations (U.S. EPA 2000c). These values were abstracted from the database for the eight census tracts that define the study communities. Pollutant concentrations from the ASPEN model were weighted by the number of participants monitored in each census tract and summarized by measures of central tendency and distribution percentiles. Comparison of model with measured exposure concentrations. Although our measured exposure results and the ASPEN model could not be statistically compared because information was lacking on the uncertainty associated with ASPEN model estimates, we could describe the magnitude and direction of differences. For each VOC, ratios were calculated for each individual measurement (indoor, outdoor, and personal) to the ASPEN model estimates corresponding to the individual's home census tract. The ASPEN model estimates were judged reasonable surrogates for personal, indoor, and/or outdoor exposures if they were within a factor of 2 (median ratios of exposure to ASPEN concentrations, ranging from 0.5 to 2.0). The U.S. EPA generally applies this criterion for model-to-monitor comparison when comparing modeled ambient concentrations with data from air monitoring stations (U.S. EPA 2001). The accuracy of the ASPEN estimates across the census tracts was assessed by plotting median VOC concentration obtained from the personal, indoor, and outdoor monitoring against the median concentration from ASPEN and determining the Pearson correlation coefficients Correlation Coefficient A measure that determines the degree to which two variable's movements are associated. The correlation coefficient is calculated as: . Cumulative risk analysis. U.S. EPA cancer classification and the critical end points considered in the risk assessment for each of the target VOCs are presented in Table 1. For carcinogenic carcinogenic having a capacity for carcinogenesis. hazard, both the unit risk estimate (URE; risk per microgram microgram /mi·cro·gram/ (µg) (mi´kro-gram) one millionth (10-6) of a gram. mi·cro·gram n. Abbr. per cubic meter) and the equivalent concentrations (micrograms per cubic meter) representing generally the upper bound of a one-in-one million excess risk or probability of contracting cancer over a lifetime of exposure are also presented in Table 1 (Caldwell et al. 1998). These concentrations posing a one-in-one million cancer risk are presented as a benchmark value for cancer effects, consistent with sections 112(f) and 112(c)(9) in the CAAA (1990) allowing exemption from regulation of source categories when posing less than a one-in-one million lifetime risk to the most exposed individual (Caldwell et al. 1998). Specifically, under the CAAA, a cancer risk of one-in-one million is considered negligible  This article or section is written like a personal reflection or and may require .Please [ improve this article] by rewriting this article or section in an . risk. The non-cancer "health benchmarks" were defined by the inhalation reference concentrations (RfCs). An inhalation RfC is defined as an estimate (with uncertainty spanning perhaps one order of magnitude A change in quantity or volume as measured by the decimal point. For example, from tens to hundreds is one order of magnitude. Tens to thousands is two orders of magnitude; tens to millions is three orders of magnitude, etc. ) of a continuous inhalation exposure to the human population (including sensitive subgroups) that is likely to be without appreciable ap·pre·cia·ble adj. Possible to estimate, measure, or perceive: appreciable changes in temperature. See Synonyms at perceptible. risk of deleterious deleterious adj. harmful. noncancer health effects during a lifetime (U.S. EPA 1994). These toxicity toxicity /tox·ic·i·ty/ (tok-sis´i-te) the quality of being poisonous, especially the degree of virulence of a toxic microbe or of a poison. data were obtained from various sources, including a) the CEP, b) the U.S. EPA's Integrated Risk Information System (IRIS), and c) the California Environmental Protection Agency The California Environmental Protection Agency (Cal/EPA) was created in 1991 by Governor Pete Wilson, through an executive order.[1] The agency combined six board, departments, and offices into one cabinet-level office:[2] Its main offices are in Lyon, France. weight of evidence indicating a potential for carcinogenicity carcinogenicity /car·ci·no·ge·nic·i·ty/ (kahr?si-no-je-nis´i-te) the ability or tendency to produce cancer. carcinogenicity the ability or tendency to produce cancer. or clear evidence of carcinogenicity in animals in a National Toxicology Program National Toxicology Program Environment A program that conducts toxicologic tests on substances frequently found at the EPA's National Priorities List sites, which have the greatest potential for human exposure study, a default potency potency /po·ten·cy/ (po´ten-se) 1. the ability of the male to perform coitus. 2. the relationship between the therapeutic effect of a drug and the dose necessary to achieve that effect. 3. value equal to that of methylene methylene /meth·y·lene/ (meth?i-len) the bivalent hydrocarbon radical —CH2— or CH2dbond. meth·yl·ene n. chloride--the lowest of the 82 available carcinogenic U.S. EPA--derived potency values for individual HAPs--was assigned per the approach used for the U.S. EPA's CEP (Caldwell et al. 1998). Cancer and noncancer risks were assessed using conventional approaches (U.S. EPA 1986, 1999, 2003) applied to the exposure estimates based on our measured exposures and the ASPEN model estimates for comparison purposes. The common approach to estimating inhalation cancer risk is to multiply mul·ti·ply v. 1. To increase the amount, number, or degree of. 2. To breed or propagate. the estimated annual average pollutant concentration by its URE, the inhalation cancer potency estimate based on the slope of the dose-response curve dose-response curve A graphic representation of the effects that varous doses of an agent–eg, ionizing radiation or a chemotherapeutic agent, have on a given parameter–eg, cell viability, mutation frequency, DNA damage, tumor growth or metastasis or . In the absence of information to the contrary, a nonthreshold, linear model is assumed for cancer when extrapolating from high dose to low dose and/or from animals to humans (U.S. EPA 1986, 1999, 2003). The URE represents the excess cancer risk over background associated with continuous lifetime exposure to a pollutant and is typically expressed as risk or probability of cancer for a 70-yr exposure per 1 [micro]g pollutant/[m.sup.3] air (U.S. EPA 1986). UREs are derived either from occupational studies in humans, typically adult males, when available, or from toxicologic studies in animals (Woodruff et al. 2000). A URE based on human data is typically defined as the maximum likelihood estimate representing a "best estimate" of the dose response in the occupational study population and are somewhat less conservative than upper bound estimates. (Woodruff et al. 2000). For example, inhalation potency estimates for two of the pollutants in this present analysis, benzene and chloroform, axe based on human data. UREs based on animal data are the upper 95% confidence bound of the estimated cancer potency, The use of upper bounds is generally considered a health-protective approach for covering the risk to susceptible individuals In epidemiology a susceptible individual (sometimes known simply as a susceptible) is a member of a population who is at risk of becoming infected by a disease, if he or she is exposed to the infectious agent. (U.S. EPA 2003). Cancer risk for each VOC and each study participant was calculated using Equation 1: [1] [E.sub.ij] x UR[E.sub.j] = [R.sub.ij], where [R.sub.ij] is the estimated risk from pollutant j for study participant i, [E.sub.ij]. is the measured exposure (indoor, outdoor, or personal) or ASPEN-modeled estimated exposure concentration (micrograms per cubic meter) for pollutant j for study participant i, and UR[E.sub.j] is the inhalation URE for pollutant j from Table 1. Summary statistics (e.g., mean, median, percentiles) of the cancer risk estimates for each pollutant were calculated across study participants. To derive estimates of lifetime population excess cancer incidence or number of cancer cases expected over a lifetime, we applied Equation 2: [2] [R.sub.ij] x P = C[C.sub.ij], where [R.sub.ij] is the risk associated with each VOC pollutant j and each study participant i from Equation 1, P is the total population size of the study communities (estimated to be 24,000 based on 2000 Census; U.S. Census Bureau 2003), and C[C.sub.ij] is the estimated number of excess cancer cases expected over a lifetime for pollutant j based on exposure for study participant i. C[C.sub.ij] estimates were summarized (e.g., mean, median, percentiles) across study participants for each pollutant to calculate population-level estimates of lifetime excess cancer cases. We compared the mean number of estimated cancer cases because the mean has public health relevance for exposure and risk, because it takes into account the full distribution of values including extreme values, whereas the median and geometric mean (mathematics) geometric mean - The Nth root of the product of N numbers. If each number in a list of numbers was replaced with their geometric mean, then multiplying them all together would still give the same result. lack physical meaning and would underestimate the true risk (Ott 1994). To evaluate cumulative cancer risks associated with exposures to the target VOCs, compound-specific cancer risk estimates for all of the known, possible, and probable carcinogenic VOCs (all but two of the target VOCs) for each study participant were summed as defined below in Equation 3, assuming cumulative cancer risks are additive additive In foods, any of various chemical substances added to produce desirable effects. Additives include such substances as artificial or natural colourings and flavourings; stabilizers, emulsifiers, and thickeners; preservatives and humectants (moisture-retainers); and per U.S. EPA guidelines guidelines, n.pl a set of standards, criteria, or specifications to be used or followed in the performance of certain tasks. (Caldwell et al. 1998): [3] [summation summation n. the final argument of an attorney at the close of a trial in which he/she attempts to convince the judge and/or jury of the virtues of the client's case. (See: closing argument) over (j)] [R.sub.ij] = C[R.sub.i] where [R.sub.ij] is the estimated risk from pollutant j for study participant i and C[R.sub.i] is cumulative cancer risk for participant i. Summary statistics (e.g., mean, median, percentiles) of the cumulative cancer risk estimates C[R.sub.i] were calculated across study participants to estimate population-level cumulative cancer risk estimates. The lifetime excess cancer cases associated with cumulative exposure to the target VOCs were estimated using Equation 4: [4] C[R.sub.i] x P = CC[C.sub.i,] where C[R.sub.i] is cumulative cancer risk for participant i from Equation 3, P is the total population size of the study communities, and CC[C.sub.i] is the estimated excess cumulative cancer cases based on cumulative exposure for study participant i. Summary statistics (e.g., mean, median, percentiles) of the number of cumulative cancer cases CC[C.sub.i] were calculated across study participants to estimate population-level lifetime cumulative cancer cases. Mean number of cumulative cancer cases has more public health relevance and is preferred to compare the mean based on our measured exposures and the ASPEN estimates. For noncancer effects, the default assumption is that the dose-response model has a threshold below which no adverse health effects are expected to occur. Noncancer risks in this stud), were measured by a direct comparison of the exposure with a chemical-specific RfC. Each study participant's exposure was divided by the pollutant's RfC, the noncancer "health benchmark" to calculate a hazard quotient quotient - The number obtained by dividing one number (the "numerator") by another (the "denominator"). If both numbers are rational then the result will also be rational. (HQ): [5] [E.sub.ij]/Rf[C.sub.j] = H[Q.sub.ij] where [E.sub.ij] is the measured exposure (indoor, outdoor, or personal) or ASPEN-modeled estimated exposure concentration (in [micro]g/[m.sup.3]) for pollutant j for study participant i, Rf[C.sub.j] is the noncancer RfC for pollutant j (micrograms per cubic meter), and H[Q.sub.ij] is the HQ for participant i for pollutant j. H[Q.sub.s] > 1 indicated that the VOC concentration exceeded the benchmark concentration and could be of public health concern. If the HQ was " 1, no harm was expected because the exposure was below the threshold (the RfC) for an adverse effect. Cumulative noncancer risks were assessed by aggregating the HQs across the VOCs that affected the same target organ target organ n. A tissue or organ that is affected by a specific hormone. target organ, n the organ or body part whose activity levels demonstrate change in the course of biofeedback. using Equation 6: [6] [MATHEMATICAL EXPRESSION A group of characters or symbols representing a quantity or an operation. See arithmetic expression. NOT REPRODUCIBLE IN ASCII ASCII or American Standard Code for Information Interchange, a set of codes used to represent letters, numbers, a few symbols, and control characters. Originally designed for teletype operations, it has found wide application in computers. ] where H[Q.sub.ij] is the HQ for participant i for pollutant j for a specific health end point (e.g., cardiovascular system cardiovascular system: see circulatory system. cardiovascular system System of vessels that convey blood to and from tissues throughout the body, bringing nutrients and oxygen and removing wastes and carbon dioxide. , central nervous system), where TOSH[I.sub.i] is defined as the target-organ-specific hazard index and is the sum of HQs for individual VOCs that affected the same organ or organ systems for participant i (U.S. EPA 2001). Summary statistics (e.g., mean, median, percentiles) for TOSH[I.sub.i] were calculated across study participants to estimate population-level cumulative noncancer risks. Results Summary of exposure measurements. Most participants were women (70%) and white (84%). Median household income The median household income is commonly used to provide data about geographic areas and divides households into two equal segments with the first half of households earning less than the median household income and the other half earning more. was in the $30,000-,0,000 rage. Median age of the participants was 53 years. Thirty-two percent of study participants had not completed high school, 35% completed high school only, and 22% had attended some college or technical school. The income and racial demographics of our study participants were comparable with the 2000 Census data for South Baltimore; however, our sample was slightly more educated, older, and mostly women compared with the 2000 Census. More than half (54%) of the participants were not working during the exposure monitoring. The automobile was the most common mode of transportation among the participants. Housing stock tended to be older homes (73% of participants lived in homes built in 1950 or earlier) without an attached garage. On average, participants reported that they spent 80% of their time indoors. Based on questionnaire responses, four of the 37 study participants were found to be smokers. Of nonsmoking participants (n = 33), 42% reported environmental tobacco smoke exposure at some time during the monitoring period. Analysis of exposure measurements (personal, indoor, and outdoor) and subsequent comparison with ASPEN and the risk analysis were restricted to the exposure measurements of the nonsmoking adult participants (n = 33). The frequency of VOC detection was greatest for personal, followed by indoor, and then outdoor measurements. The most frequently detected VOCs (e.g., > 80% of samples were above the MDL) in personal air were benzene, carbon tetrachloride, chloroform, ethylbenzene Ethylbenzene is an organic chemical compound which is an aromatic hydrocarbon. Its major use is in the petrochemical industry as an intermediate compound for the production of styrene, which in turn is used for making polystyrene, a commonly used plastic material. , methylene chloride Noun 1. methylene chloride - a nonflammable liquid used as a solvent and paint remover and refrigerant dichloromethane chloride - any compound containing a chlorine atom , methyl methyl (mĕth`əl), CH3, organic free radical or alkyl group derived from methane by the removal of one hydrogen atom. tort-butyl ether ether, in chemistry ether, any of a number of organic compounds whose molecules contain two hydrocarbon groups joined by single bonds to an oxygen atom. (MTBE MTBE Methyl-tert-butyl-ether Surgery An aliphatic ether that rapidly dissolves cholesterol stones in vivo, introduced under local anesthesia via a percutaneous transhepatic cholecystectomy catheter, as a non-invasive method for treating gallstones; after injection, ), styrene sty·rene n. A colorless oily liquid from which polystyrenes, plastics, and synthetic rubber are produced. Also called vinylbenzene. , tetrachloroethylene tetrachloroethylene /tet·ra·chlo·ro·eth·y·lene/ (tet?rah-klor?o-eth´i-len) a moderately toxic chlorinated hydrocarbon used as a dry-cleaning solvent and for other industrial uses. (perc), toluene toluene (tōl`y  ēn') or methylbenzene (mĕth'əlbĕn`zēn), C7H8 , and the xylenes. Similar
frequencies were found with the indoor samples except for styrene, where
only 65% of indoor samples were above MDL. VOCs with > 80% of outdoor
samples detected above the MDL were carbon tetrachloride, MTBE, and the
xylenes.Figure 2 presents a summary of the personal exposure and indoor and outdoor monitoring for each of the target VOCs. The box plots indicate the 10th, 25th, 50th, 75th, and 90th percentiles for the 3-day TWA exposures for each VOC. For most of the VOCs, exposure concentrations spanned several orders of magnitude; however, the range from the 25th to the 75th percentile percentile, n the number in a frequency distribution below which a certain percentage of fees will fall. E.g., the ninetieth percentile is the number that divides the distribution of fees into the lower 90% and the upper 10%, or that fee level was generally no more than one order of magnitude. Trichloroethylene trichloroethylene /tri·chlo·ro·eth·y·lene/ (-eth´i-len) a clear, mobile liquid used as an industrial solvent; formerly used as an inhalant anesthetic. tri·chlo·ro·eth·yl·ene n. (TCE TCE trichloroethylene. TCE Environment A volatile chlorinated hydrocarbon that boils at 88ºC and is highly soluble–1000 ppm in water, with various industrial uses Toxicity Peripheral neuropathy, carcinogenic. ) tended to be the lowest in absolute concentration for all three sample types. MTBE, benzene, toluene, and ethylbenzene tended to he found in the highest absolute concentrations for all sample types. MTBE and toluene had the highest maximum personal (248.4 pg/m3 and 195.6 [micro]/[m.sup.3], respectively), indoor (81.7 [micro]g/[m.sup.3] and 114.80 [micro]g/[m.sup.3], respectively), and outdoor (10.44 [micro]g/[m.sup.3] and 8.61 [micro]g]/[m.sup.3], respectively) exposure measurements. On average, MTBE, toluene, and the xylenes contributed the most to total personal VOC exposures (28, 30, and 19% respectively) as proportion of average total VOC personal exposures. [FIGURE 2 OMITTED] As expected for most of the VOCs, personal exposures were greater than indoor concentrations, which were greater than outdoor concentrations. For example the median personal exposure was 14.6 [micro[g/[m.sup.3] for toluene, compared with median indoor and outdoor toluene concentrations of 12.1 and 3.88 [micro]g/[m.sup.3], respectively. In contrast, carbon tetrachloride and TCE were stable across the three locations as shown in Figure 2. Comparison with the ASPEN model Table 2 presents the summary statistics from the ASPEN model across the eight census tracts in South Baltimore, along with results from the community monitoring. Figure 3 summarizes the observed ambient-to-modal predicted concentration ratios for all 11 VOCs. The distribution of the ratios was positively skewed skewed curve of a usually unimodal distribution with one tail drawn out more than the other and the median will lie above or below the mean. skewed Epidemiology adjective Referring to an asymmetrical distribution of a population or of data . For two of the VOCs, benzene and methylene chloride, ASPEN estimated concentrations were higher than our outdoor measurements, whereas the ASPEN estimates for chloroform, MTBE, and styrene were lower than our measurements. For carbon tetrachloride, ethylbenzene, perc, TCE, and xylenes, the ASPEN mode[ provided reasonable central estimates of measured ambient concentrations. A comparison of the median outdoor monitored concentrations versus the median ASPEN model predicted concentrations for each VOC resulted in a Pearson correlation coefficient of 0.97, demonstrating that ASPEN was capable of distinguishing the relative magnitude of ambient concentrations among the different VOCs, as reported by Rosenbaum et al. (1999). For most VOCs, the median ratios were within a factor of 2 (Figure 3), showing good agreement between ambient measurements and model predictions across South Baltimore. [FIGURE 3 OMITTED] ASPEN estimated ambient concentrations were generally lower than personal and indoor air measurements. However, for benzene, carbon tetrachloride, methylene chloride, MTBE, perc, and TCE, central estimates from the ASPEN model and indoor concentrations were comparable, with median ratios of observed indoor-to-model predicted concentrations within a factor of 2. Interestingly, for these same compounds, comparisons of measured indoor and outdoor concentrations revealed consistent VOC concentrations, indicating that ambient air infiltrated indoors and was an important driver for indoor concentrations posing the potential for influencing personal exposures. The ASPEN model and the personal exposure results for benzene, carbon tetrachloride, methylene chloride, and TCE were also similar, with median ratios of personal exposure to ASPEN model estimates in the factor of 2 range (0.5-2.0), as shown in Figure 4. For other VOCs, ASPEN model estimates were lower than personal exposure, especially for chloroform, toluene, and styrene (Figure 5). [FIGURES 4-5 OMITTED] Health risk estimates, Summary statistics of the estimated lifetime excess cancer risks based on exposure monitoring results from our adult participants and exposure estimates from the ASPEN model are presented by exposure category in Table 3. Cancer risks are all expressed as excess risk per one million population. Chloroform, benzene, and carbon tetrachloride presented the highest median cancer risks at 53, 23, and 12 per one million population, respectively, based on personal exposures, and were similar for risk estimates based on indoor concentrations. Cancer risk estimates based on measured outdoor VOCs concentration were generally lower than personal exposures and indoor concentrations, except for carbon tetrachloride. Cancer risk estimates for carbon tetrachloride were similar across all three exposure monitoring categories. Cancer risk estimates at the 90th percentile for chloroform were higher for personal and indoor exposures than for outdoor exposures, at 181 and 183 versus 20 per one million, respectively. Maximum cancer risk estimates based on personal exposures for benzene, chloroform, and perc were high. For example, the maximum estimated cancer risk based on personal exposures was 133, 801, and 135 per one million for benzene, chloroform, and perc and are in the range that the U.S. EPA would consider warranting action to reduce exposures. Cancer risks based on results of the ASPEN model are also presented in Table 3. Again, chloroform, benzene, carbon tetrachloride, and perc presented the highest median cancer risks. Although the median cancer risks based on the ASPEN model estimates for benzene and carbon tetrachloride were comparable with the risks based on personal exposures, median cancer risk estimates for the other VOCs were lower, especially for chloroform. The differences between risks based on ASPEN and exposure measurements were even greater at the 90th percentile and maximum risk estimates, corresponding to the earlier comparison between exposure estimates. Table 4 shows estimated cumulative cancer risk and estimated number of cancer cases based on measured exposures and the ASPEN model. Assuming risks are additive, the median cumulative cancer risk based on personal exposures was 120 per one million, The average cumulative cancer risk based on personal exposures was 183 per one million, indicating that the distribution was skewed. The difference in the cumulative cancer risk between personal and indoor exposure at the 90th percentile may be the result of individual activities magnifying the variability in personal exposure concentrations. In applying Equation 4, we estimated on average the number of predicted cancer cases based on the distribution of cumulative exposures and risks to be four cancer cases over a lifetime (70 years) within the South Baltimore population. Cumulative risk and cancer incidence estimates were similar for personal and indoor VOC concentration. In contrast, the ASPEN model and measured residential outdoor concentrations resulted in much lower cumulative risk estimates. Based on ASPEN, median cumulative cancer risk was 42 per 1 million, and the expected mean lifetime cancer incidence is estimated as one cancer case within the South Baltimore population. Community exposure monitoring results and ASPEN model results were also evaluated for potential noncancer health risks. Here there was good agreement: Neither the ASPEN results nor the average exposure measurements (personal, indoor, or outdoor) exceeded the RfCs for any of the VOCs (results not shown). The HQs were all < 1, with average HQs ranging from 8.12 x [10.sub.-4] for MTBE based on the ASPEN model estimates to 0.14 for chloroform based on personal exposures. The maximum hazard index (HI) was 0.98 for personal exposure to chloroform. For cumulative noncancer effects, the median TOSHIs were all < 1, across all pollutants and exposure estimators. Discussion Accurate exposure assessment is critical to a credible and scientifically sound assessment of risk (National Research Council 1983; Sexton sex·ton n. An employee or officer of a church who is responsible for the care and upkeep of church property and sometimes for ringing bells and digging graves. et al. 1995). For the CEP, the U.S. EPA adopted the ASPEN model to estimate exposure and risk associated with census tract-level ambient air pollution levels. Because previous studies have shown that, for most VOCs, indoor and other microenvironmental concentrations (e.g., inside automobiles) are primary determinants of exposure and risk (Ott 1995; U.S. EPA 1987; Wallace 1990), the present study was conducted to explore the differences in measured exposure (indoor, outdoor, and personal) with ASPEN model ambient exposure estimates. This is the first direct comparison of the ASPEN model (as used by the U.S. EPA for the CEP and subsequently for the first phase of NATA) with human exposure data to estimate health risks. The relative concentrations of VOCs measured indoors, outdoors, and on persons is a function of relative indoor and outdoor source contribution and time-activity patterns. This was initially identified by the TEAM studies where the indoor source contribution greatly exceeded that from outdoors (U.S. EPA 1987). Many VOCs are emitted from both outdoor sources (e.g., industrial facilities, power plants, dry cleaners, and mobile sources) and indoor sources (e.g., environmental tobacco smoke, paint, pesticides, varnishes, and household cleaners). In comparing our measured personal exposures with measured indoor and outdoor VOC concentrations, certain patterns emerged consistent with previous human exposure studies. For chloroform, toluene, methylene chloride, and styrene, indoor concentrations dominated personal exposures. Ratios of personal to indoor concentrations for these VOCs were close to 1, whereas both indoor and personal exposures were six to seven times higher than measured outdoor concentrations. On the other hand, similar indoor and outdoor concentrations were observed for VOCs usually associated with motor vehicle emission, including benzene and MTBE. In those instances, ambient air may be an important driver for personal exposures, as documented by Kinney et al. (2002). In addition, similar VOC concentrations were observed across indoor, outdoor, and personal measurements for carbon tetrachloride and TCE. On the basis of the observed pattern of measured personal, indoor, and outdoor exposures, we could anticipate the outcome of the comparisons with the ASPEN model. Consistent with what it was designed to estimate, the best agreement between ASPEN and our measurements was observed for outdoor measured VOCs, where all but two of the median ratios (measured to modeled concentrations) were within a factor of 2. The agreement of the modeled estimates to measured ambient concentrations was also indicated by the similarity in their relative ranking of VOCs. The favorable fa·vor·a·ble adj. 1. Advantageous; helpful: favorable winds. 2. Encouraging; propitious: a favorable diagnosis. 3. agreement between ASPEN and ambient VOC concentrations suggests that the VOC emission inventories An emission inventory is an accounting of the amount of air pollutants discharged into the atmosphere. It is generally characterized by the following factors:
tr.v. character·ized, character·iz·ing, character·iz·es 1. To describe the qualities or peculiarities of: characterized the warden as ruthless. 2. for the study area. Styrene and chloroform, however, were the exceptions, with median ratios > 2, indicating that the ASPEN model underpredicted the measured ambient concentrations. The reason for the poor prediction is unclear; however, it may be due to source changes for styrene and chloroform from 1996 (date of the emissions inventories) to 2001 (time period of our community monitoring). These findings are consistent with those in Rosenbaum et al. (1999), who reported that despite a tendency of the model to underpredict, the frequency of agreement in ranking between predicted concentrations and the observed concentrations obtained from stationary monitoring programs across the United States suggest reasonable good performance by ASPEN for most of the primary hazards air pollutants. Rosenbaum et al. (1999) reported an [R.sup.2] statistic statistic, n a value or number that describes a series of quantitative observations or measures; a value calculated from a sample. statistic a numerical value calculated from a number of observations in order to summarize them. of 0.59 for model predicted versus observed HAP concentrations for monitors in the northeastern states. Pratt et al. (2000), in a comparison of ASPEN model estimates with ambient monitoring data for Minnesota, also concluded that the model tended to underestimate the monitored values. As with the present study, the monitor-to-model ratios were within a factor of 2 for most of the pollutants measured. Overall results from the Minnesota study suggest that the monitor and model results were in good agreement (Pratt et al. 2000). A similar ASPEN underestimation was observed in a study conducted by the U.S. EPA (2000a). Both the relative and absolute comparisons we conducted between model and monitored concentrations are important. For instance, if the U.S. EPA is interested in relative risk, then the relative ranking may be especially important. If the goal, on the other hand, is to assess whether risk exceeds some threshold, then the accuracy of the estimate as reflected by the median ratios is critical. Even though ASPEN is designed to estimate exposure to air toxins of ambient origin, its comparison with measured indoor VOC concentrations is of interest for evaluating the magnitude of the difference. Median indoor-to-ASPEN ratios for chloroform, ethylbenzene, toluene, styrene, and xylenes were 24.7, 2.24, 2.03, 6.30, and 2.25, respectively. However, favorable agreement between measured and modeled ambient concentrations was observed for VOCs, with indoor:outdoor ratios close to 1. Six of the 11 VOCs fell into this category: benzene, carbon tetrachloride, methylene chloride, MTBE, perc, and TCE. Similar to what was observed for the outdoor measurements, median indoor-to-ASPEN ratios across all six VOCs did not depart from unity by more than a factor of 2. For benzene and methylene chloride, the good agreement between indoor measurements and ASPEN is probably a result of ASPEN's higher estimation of ambient levels (median ratios of outdoor concentrations to ASPEN were 0.43 and 0.63 for methylene chloride and benzene, respectively). The utility of the ambient concentration estimates given by ASPEN to predict exposure is most directly and comprehensively assessed by its comparison with personal monitoring. This comparison suggests that for VOCs with indoor:outdoor ratios near unity (e.g., benzene, carbon tetrachloride, and TCE), ASPEN provided reasonable central estimates for human exposure. This follows the pattern of agreement between indoor and outdoor measurements and ASPEN estimates discussed above. Although ASPEN provided a reasonable estimate of personal exposure to methylene chloride, median indoor concentrations were three times higher than outdoor concentrations. It was expected for carbon tetrachloride that ASPEN and personal exposures would be somewhat comparable because the main source of exposure to carbon tetrachloride is ambient "background" levels from past emissions (Rosenbaum et al. 1999; U.S. EPA 2000a). Ratios of the VOC concentrations for indoor-to-personal, personal-to-outdoor, and indoor-to-outdoor measurements of carbon tetrachloride were close to 1, suggesting that outdoor air was the only source for indoor and personal exposures. For TCE, the data suggest that there were no significant indoor sources that would affect personal exposures and thus ambient levels were adequate surrogates for exposure. As with the indoor comparison, the suitability of ASPEN for estimating personal exposures for benzene and methylene chloride is probably an artifact A distortion in an image or sound caused by a limitation or malfunction in the hardware or software. Artifacts may or may not be easily detectable. Under intense inspection, one might find artifacts all the time, but a few pixels out of balance or a few milliseconds of abnormal sound of ASPEN's minor overestimation o·ver·es·ti·mate tr.v. o·ver·es·ti·mat·ed, o·ver·es·ti·mat·ing, o·ver·es·ti·mates 1. To estimate too highly. 2. To esteem too greatly. of ambient concentrations for these pollutants, which is consistent with a comparison of the ASPEN model with monitor data (stationary monitors in this case) for northeastern states (including Maryland) conducted by Rosenbaum et al. (1999), based on 1990 emission inventory. For all the other measured VOCs, including chloroform, ethylbenzene, MTBE, pert, toluene, styrene, and xylenes, ASPEN estimated concentrations were less than personal exposures by a factor of 3 (median of the ratio of ASPEN to personal measurements across these pollutants). For some VOCs, (e.g., MTBE and xylenes), personal exposures exceeded both indoor and outdoor concentrations, suggesting exposure in an unmonitored microenvironment microenvironment /mi·cro·en·vi·ron·ment/ (-en-vi´ron-ment) the environment at the microscopic or cellular level. such as work or the automobile. Gasoline gasoline or petrol, light, volatile mixture of hydrocarbons for use in the internal-combustion engine and as an organic solvent, obtained primarily by fractional distillation and "cracking" of petroleum, but also obtained from natural gas, by or refueling is an unlikely source because other mobile source characteristic VOCs (e.g., benzene, toluene, and ethylbenzene) were not similarly elevated. Therefore, as expected, the agreement between the ambient VOC estimates provided by ASPEN and measured personal exposure varied by source: there was better agreement for VOCs with global background source (e.g., carbon tetrachloride) than for VOCs primarily emitted from mobile sources (e.g., benzene) than for VOCs from indoor sources (e.g., chloroform). An additional important distinction between the ASPEN model estimates and the actual measurements (outdoor, indoor, and personal) is the spatial resolution (Data West Research Agency definition: see GIS glossary.) A measure of the accuracy or detail of a graphic display, expressed as dots per inch, pixels per line, lines per millimeter, etc. It is a measure of how fine an image is, usually expressed in dots per inch (dpi). of their assessment. ASPEN provides resolution to the census tract level, whereas monitoring provides within-tract spatial resolution at the level of the individual and residence, thereby including interindividual variability. Therefore, the utility of approach will depend on the variability of interest. Because ASPEN was developed and has been used to assess risk and support policy development, the consequence of exposure misclassification on risk is of primary importance. Our results indicate that South Baltimore residents are routinely exposed to a number of VOCs that are considered toxic air pollutants by the U.S. EPA and at levels above public health benchmarks (approaching 1 in [10.sup.4] excess cancer risk). Cancer risk estimates based on outdoor VOC monitoring are similar to risk estimates based on ASPEN model results, as expected. By comparing risks based on the ASPEN model with risks based on personal and indoor exposures, we demonstrated that the model underestimates exposures and therefore risks. This underestimation is especially pronounced for chloroform, ethylbenzene, MTBE, styrene, and pete, whereas estimates were comparable for benzene, carbon tetrachloride, methylene chloride, and TCE. The present study shows that a modest underestimation of exposure by the ASPEN model on an individual pollutant basis resulted in a proportional underestimation of cumulative cancer risk. Although the numbers of estimated excess lifetime cancer cases due to cumulative exposure are not large in and of themselves, the 4-fold difference between the ASPEN estimate and that derived from measured exposure could have a large impact on risk management or policy decisions. Risk based on the model also underestimated projected cancer incidence for individuals at the upper end of the exposure distribution. Identifying high-exposure groups is important because this population subgroup sub·group n. 1. A distinct group within a group; a subdivision of a group. 2. A subordinate group. 3. Mathematics A group that is a subset of a group. tr.v. is at greatest risk, and it is for this group that intervention strategies will be most effective. Cancer risks based on ASPEN model concentrations did not adequately characterize risk of South Baltimore populations at the extreme end of exposure distributions. Underestimation of exposure and risk may also lead to different prioritization of pollutants for environmental regulatory action to reduce risks and protect public health. Among the 11 VOCs measured in this study, benzene, carbon tetrachloride, chloroform, and perc were identified by both ASPEN and the exposure measurements as major risk drivers. However, their relative contribution to cumulative risk differed greatly. Compared with personal exposures, ASPEN overestimated risk contributions of benzene and carbon tetrachloride by more than 2-fold (52 vs. 17%) and 4-fold (32 vs. 8%), respectively. In contrast, ASPEN's estimate of chloroform's cumulative risk was 6%, whereas personal exposures indicated 61% contribution to cumulative risk. Perc's relative contribution to cumulative cancer risk was similar, with 6% estimated from ASPEN and 9% based on personal exposure. If ASPEN-based estimates of exposure formed the basis for policies to reduce cancer risk from air toxics, the focus would be primarily on benzene, whereas the personal exposure measurements indicate that chloroform contributes more to cumulative cancer risk. Chloroform represents a unique but important indoor air exposure. Indoor chloroform is generally not the result of industrial emissions or consumer products. Rather, it is formed as a byproduct by·prod·uct or by-prod·uct n. 1. Something produced in the making of something else. 2. A secondary result; a side effect. Noun 1. of drinking water drinking water supply of water available to animals for drinking supplied via nipples, in troughs, dams, ponds and larger natural water sources; an insufficient supply leads to dehydration; it can be the source of infection, e.g. leptospirosis, salmonellosis, or of poisoning, e.g. chlorination chlorination Public health Addition of chlorinated compounds to drinking water as disinfectants. Cf Ozonation. and is subject to regulation under the Safe Drinking Water Act The Safe Drinking Water Act (SDWA) is a United States federal law passed by the U.S. Congress on December 16, 1974. It is the main federal law that ensures safe drinking water for Americans. (Safe Drinking Water Act Amendments 1996). National efforts have substantially reduced chloroform levels in drinking water; however, its ubiquitous presence in indoor air underscores the need for a coordinated multimedia approach to regulation. Nonetheless, this is not to suggest that the contribution of benzene to personal exposures, particularly from mobile sources, should be disregarded dis·re·gard tr.v. dis·re·gard·ed, dis·re·gard·ing, dis·re·gards 1. To pay no attention or heed to; ignore. 2. To treat without proper respect or attentiveness. n. . Benzene was identified as the second largest cancer risk contributor in South Baltimore and is highly correlated cor·re·late v. cor·re·lat·ed, cor·re·lat·ing, cor·re·lates v.tr. 1. To put or bring into causal, complementary, parallel, or reciprocal relation. 2. with VOCs typically found in auto and truck exhaust. The toxic effects of benzene are more certain [Group A, known human carcinogen carcinogen: see cancer. carcinogen Agent that can cause cancer. Exposure to one or more carcinogens, including certain chemicals, radiation, and certain viruses, can initiate cancer under conditions not completely understood. (U.S. EPA 2000d)], and benzene is ubiquitous in ambient air. The results of this study suggest that the U.S. EPA should continue to focus on benzene as an air pollutant of concern, but should also consider policies to reduce risk from toxic air pollutants in the indoor environment. These policies could require more extensive disclosure of cancer risks from chemicals in building materials Building materials used in the construction industry to create . These categories of materials and products are used by and construction project managers to specify the materials and methods used for . and household consumer and cleaning products used indoors. This comparison of measured and modeled exposure and risk is limited with respect to two dimensions of time. First, the ASPEN estimates are based on annual averages, whereas the measured values are based on 3-day integrated samples. This limitation is partially offset by the fact that sampling was conducted over one year, thereby encompassing both seasonal and individual variability. The second temporal Having to do with time. Contrast with "spatial," which deals with space. limitation is that ASPEN's 1996 estimates are being related to measurements conducted in 2000-2001. Therefore, results from the present study need to be interpreted with caution, recognizing that true differences between modeled and measured estimates are potentially confounded by differences in averaging time and period. Additional research can address these limitations with a) concurrent measurement and model estimates and b) a repeated measure design providing a better estimate of long-term exposure (Wallace et al. 1994). Although there are limits to this study with respect to the temporal associations forming the basis of comparison, these results provide the basis for an important evaluation of the differences between population-measured exposures and risks and the model estimates. Over the next 2 years, the Years, The the seven decades of Eleanor Pargiter’s life. [Br. Lit.: Benét, 1109] See : Time U.S. EPA is scheduled to reassess reassess Verb to reconsider the value or importance of reassessment n Verb 1. reassess - revise or renew one's assessment reevaluate the cancer and noncancer effects for carbon tetrachloride, chloroform, methylene chloride, and TCE. The impact of this reassessment Reassessment The process of re-determining the value of property or land for tax purposes. Notes: Property is usually reassessed on an annual basis. You may request a "reassessment" if you disagree with your assessment. is particularly important for chloroform because new data being considered under IRIS review suggest that chloroform's carcinogenicity occurs with a threshold and only at relatively high concentrations (U.S. EPA 2000d). Accordingly, the U.S. EPA is working to revise the URE assessment for inhalation exposure for chloroform. Conclusion and Recommendations The U.S. EPA relied upon ASPEN for its CEP to estimate air toxic exposure and risk for the U.S. population. Therefore, the reliability of the ASPEN exposure estimates has implications for risk management and public health policy. The present study provides an evaluation of ASPEN based on measurements of air toxic levels indoors, outdoors, and on individuals. Study results suggest that for pollutants primarily of ambient origin--benzene, carbon tetrachloride, methylene chloride, and TCE--ASPEN provides a reasonable (within a factor of 2) central estimate for personal exposures. However, for the remaining seven VOCs with significant indoor sources, ASPEN estimates are substantially lower than personal exposures. The CEP approach of estimating exposure of ambient origin understates cumulative risks due primarily to the exclusion of indoor exposures. The present analysis suggests that regulation solely focused on exposure and risk from VOCs of ambient origin will address only a small portion of the actual exposure and risk, as has been previously stated by Wallace (1989, 1990, 1991, 1993). Given the resources and time necessary for exposure monitoring of large populations, models to estimate exposures provide a necessary practical alternative. Exposure models are intended to complement results from direct exposure monitoring studies and to extend and extrapolate extrapolate - extrapolation these finding to other locales and other situations. In recognition of the limitations of using ASPEN to estimate risk and the need to account for the time that people spend indoors and outdoors, the U.S. EPA recently developed an exposure module, HAPEM4, and included it in the second phase of NATA. The HAPEM4 model was designed to predict the "apparent" inhalation exposure for specified population groups and air toxics. The HAPEM4 exposure model calculates the concentration in specific microenvironments (e.g., in a home or in a car) based on the ambient air concentration predicted by ASPEN (U.S. EPA 2002). Through a series of calculation routines, the HAPEM4 uses census data, human activity patterns, ambient air quality levels, climate data, and indoor/outdoor concentration relationships to estimate an expected range of "apparent" inhalation exposure concentrations of primarily ambient sources for groups of individuals (U.S. EPA 2002). It also predicts nationwide census-tract-level annual average human exposures and is to be used in a screening-level inhalation risk assessment. As the U.S. EPA continues to apply the ASPEN and HAPEM4 models to identify air toxics of greatest public health concern, and assess progress in reducing exposures across the United States, comparison of exposure measurements with modeling estimates provides the basis for continued model development and refinement. Although the second-phase NATA data were not available at the time of our study, a review of the HAPEM4 data versus ASPEN estimate shows that, for a number of our target VOCs, the HAPEM4 estimates are lower than those from ASPEN. This difference would mean that, compared with our measured personal exposures, risks based on HAPEM4 would be underestimated. We plan to conduct a detailed comparison of HAPEM4 with our measured exposures in a future analysis. Overall validation studies for exposure models would be useful for varying environmental scenarios (e.g., rural community vs. suburban), in different regions of the country, for specific subpopulations (elderly, children, and ethnic minorities), and for an expanded number and more varied types of hazardous pollutants (assuming sample collection instruments and analytical methods are readily available). An existing human exposure monitoring framework such as the U.S. EPA's National Human Exposure Assessment Survey, the Centers for Disease Control and Prevention Centers for Disease Control and Prevention (CDC), agency of the U.S. Public Health Service since 1973, with headquarters in Atlanta; it was established in 1946 as the Communicable Disease Center. (CDC See Control Data, century date change and Back Orifice. CDC - Control Data Corporation ) National Health and Nutrition Examination Survey, and the CDC's Second National Report on Human Exposure might provide excellent opportunities for exposure model validations. Results from these comparisons would help refine the models. Although indoor air is an important contributor to human exposure to VOCs, we do not suggest that ambient VOC concentrations be ignored. Reducing outdoor VOC concentrations results in public health benefits. First, outdoor air has been shown to infiltrate infiltrate /in·fil·trate/ (in-fil´trat) 1. to penetrate the interstices of a tissue or substance. 2. the material or solution so deposited. in·fil·trate v. 1. indoors, adding to the indoor pollutant concentration (Lewis 1991). It is reasonable to assume that ambient concentrations represent minimum exposure for a number of toxic air pollutants. In this study, measured indoor and outdoor concentrations for carbon tetrachloride, ethylbenzene, MTBE, styrene, perc, TCE, and xylenes were significantly positively correlated. Therefore, lowering outdoor concentrations would reduce indoor and personal VOC levels. In addition, controlling outdoor VOCs prevents the formation of secondary air pollutants such as ozone. Exposure is the link between the release of a toxic agent into the environment and subsequent disease in humans. Accurate exposure estimates are critical inputs to risk assessment in evaluating the severity and probability of health impact. Measured and/or modeled ambient pollutant concentrations are appropriately used as surrogates of human exposure in risk assessment. Researchers need to be cognizant cog·ni·zant adj. Fully informed; conscious. See Synonyms at aware. [From cognizance.] Adj. 1. of the limitations of this approach, however, and work diligently dil·i·gent adj. Marked by persevering, painstaking effort. See Synonyms at busy. [Middle English, from Old French, from Latin d to improve the accuracy of these exposure surrogates to best inform policy. The marriage of personal exposure monitoring and risk assessment, even on a limited scale, would help identify the weaknesses of models and surrogates of exposure in estimating cumulative risk, suggest improvements in these models, and possibly reduce some of the current uncertainty associated with risk estimates.
Table 1. Target VOCs and associated toxicity values
Cancer health effects
Unit risk
Weight of estimate
VOC pollutant evidence (a) (per [micro]g/[m.sup.3])
Benzene A 7.8 x [10.sup.-6]
Carbon tetrachloride B2 1.5 x [10.sup.-5]
Chloroform B2 2.3 x [10.sup.-5]
Ethylbenzene Positive in NTP 5.0 x [10.sup.-1]
study but
not classified
Methylene chloride B2 4.7 x [10.sup.-7]
MTBE - 2.6 x [10.sup.-1]
Styrene C 5.0 x [10.sup.-7]
Perc B2, C 5.6 x [10.sup.-6]
Toluene D -
Trichloroethylene B2, C 2.0 x [10.sup.-6]
Xylenes D -
Cancer health effects
One per million cancer
risk equivalent
VOC pollutant concentration Source
([micro]g/[m.sup.3]
Benzene 0.13 IRIS (b)
Carbon tetrachloride 0.067 IRIS (b)
Chloroform 0.043 IRIS (b)
Ethylbenzene 2.0 CEP (d)
Methylene chloride 2.10 IRIS (b)
MTBE 3.84 Cal EPA (c)
Styrene 2.00 CEP (d)
Perc 0.18 Cal EPA (c)
Toluene - IRIS (b)
Trichloroethylene 0.59 Cal EPA (c)
Xylenes - IRIS (b)
Noncancer health effects
Target organ Target organs
for critical for other critical
VOC pollutant chronic effects chronic effects
Benzene Blood; nervous Reproductive/
system; immune developmental
systems
Carbon tetrachloride Liver Kidney,
reproductive/ effects
developmental;
nervous system
Chloroform Liver Kidney,
reproductive/
developmental
Ethylbenzene Reproductive/ Liver and kidney
developmental
Methylene chloride Cardiovascular Central nervous
system system
MTBE Liver/kidney
Styrene Nervous system Liver
Perc Nervous system Liver and kidney
Toluene Nervous system Liver; reproductive/
developmental
Trichloroethylene Nervous system Respiratory, liver
Xylenes Nervous system Respiratory
Noncancer health effects
RfC
VOC pollutant ([micro]g/[m.sup.3] Source
Benzene 60 Cal EPA (c)
Carbon tetrachloride 40 Cal EPA (c)
Chloroform 35 CEP (d)
Ethylbenzene 1,000 IRIS (b)
Methylene chloride 400 Cal EPA (c)
MTBE 3,000 IRIS (b)
Styrene 900 Cal EPA (c)
Perc 35 CEP (d)
Toluene 400 IRIS (b)
Trichloroethylene 600 Cal EPA (c)
Xylenes 300 CEP (d)
MTBE, methyl tert-butyl ether; perc, tetrachloroethylene;-, no data
because the compounds were not classifiable as to cancer risk.
(a) Group A, known carcinogen; group B1, probable carcinogen; group B2,
probable carcinogen; group C, possible carcinogen; group D, not
classifiable; group E, evidence of noncarcinogencity. (b) U.S. EPA's
Integrated Risk Information System (www.epa.gov/iris/index.html;
U.S. EPA 2000d). (c) California Environmental Protection Agency,
Office of Environmental Health Hazards Assessment (http://oehha.ca.gov/
Cal EPA 2002). (d) U.S. EPA's Cumulative Exposure Project
(Caldwell et al. 1998).
Table 2. Comparison of ASPEN (1996) estimated VOC concentrations and
measured (2000-2001) exposure ([micro]g/[m.sup.3]).
ASPEN (Outdoor monitoring (n= 33)
model (a)
VOC pollutant Mean Median Mean Median 10th (b) 90th (b)
Benzene 2.81 2.69 1.84 1.79 0.57 3.14
Carbon tetrachloride 0.88 0.88 0.94 0.90 0.60 1.48
Chloroform 0.10 0.09 0.44 0.22 0.07 0.89
Ethylbenzene 1.02 0.84 1.26 1.00 0.55 2.00
Methylene chloride 0.80 0.68 0.35 0.35 0.06 0.60
MTBE 2.86 2.64 4.41 4.30 0.99 8.70
Styrene 0.12 0.12 0.50 0.25 0.05 1.68
Perc 0.42 0.35 0.47 0.28 0.10 1.09
Toluene 6.05 4.94 4.10 3.88 1.66 6.43
TCE 0.20 0.18 0.19 0.17 0.08 0.24
Xylenes 3.92 3.44 4.68 3.97 2.36 7.09
Indoor monitoring (n=33)
VOC pollutant Mean Median 10th (b) 90th (b)
Benzene 3.70 2.45 1.03 8.34
Carbon tetrachloride 0.98 0.85 0.51 1.66
Chloroform 4.36 2.30 0.61 7.89
Ethylbenzene 3.22 1.95 0.90 7.33
Methylene chloride 2.86 0.95 0.08 7.73
MTBE 10.80 4.25 1.06 21.99
Styrene 2.72 0.43 0.16 8.96
Perc 2.55 0.50 0.10 5.68
Toluene 21.90 12.12 5.79 50.13
TCE 0.36 0.18 0.08 0.56
Xylenes 12.36 7.60 3.57 23.01
Personal monitoring (n=31)
VOC pollutant Mean Median 10th (b) 90th (b)
Benzene 4.06 2.94 1.44 7.30
Carbon tetrachloride 0.94 0.82 0.60 1.70
Chloroform 4.79 2.29 0.70 7.80
Ethylbenzene 4.42 2.53 1.18 9.45
Methylene chloride 2.07 0.93 0.08 5.58
MTBE 24.74 8.80 2.66 66.57
Styrene 2.51 1.30 0.20 7.40
Perc 3.00 0.91 0.19 8.23
Toluene 26.81 14.65 7.75 41.33
TCE 0.41 0.20 0.09 0.83
Xylenes 17.75 9.50 4.61 30.85
(a) Weighted by the number of exposure monitoring samples taken per
census tract. (b) Percentiles.
Table 3. Comparison of estimated individual pollutant cancer risk by
exposure category in South Baltimore : all units in excess cancer
risk per 1 million
VOC ASPEN model (a)
pollutant Mean Min Median 90th (b) Max
Benzene 24.5 3.8 18.4 46.0 51.3
Carbon 15.1 2.9 17.5 24.1 29.4
tetrachloride
Chloroform 2.64 0.49 2.77 4.55 5.48
Ethylbenzene 0.55 0.09 0.42 1.07 1.29
Methylene 0.44 0.08 0.38 0.82 0.98
chloride
MTBE 0.51 0.08 0.39 0.93 1.15
Styrene 0.07 0.01 0.05 0.15 0.19
Perc 2.73 0.43 2.24 4.99 6.03
TCE 0.35 0.06 0.30 0.73 0.82
VOC Outdoor concentration
pollutant Mean Min Median 90th (b) Max
Benzene 14.1 4.21 13.8 24.2 36.9
Carbon 14.1 1.49 13.4 22.1 26.9
tetrachloride
Chloroform 16.9 1.55 5.12 19.9 79.1
Ethylbenzene 0.63 0.07 0.50 1.00 1.85
Methylene 0.17 0.03 0.16 0.29 0.81
chloride
MTBE 0.73 0.05 0.72 1.45 1.74
Styrene 0.25 0.03 0.13 0.84 1.35
Perc 2.61 0.46 1.55 6.04 11.7
TCE 0.33 0.10 0.28 0.41 1.74
VOC Indoor concentration
pollutant Mean Min Median 90th (b) Max
Benzene 28.5 4.42 18.85 64.2 81.5
Carbon 14.6 1.49 12.7 24.8 40.3
tetrachloride
Chloroform 101 2.33 53.5 183 695
Ethylbenzene 1.61 0.29 0.98 3.67 10.0
Methylene 1.36 0.03 0.45 3.68 8.95
chloride
MTBE 1.80 0.05 0.71 3.67 13.6
Styrene 1.36 0.03 0.21 4.48 11.6
Perc 14.2 0.46 2.78 31.6 141
TCE 0.61 0.10 0.30 0.95 4.97
VOC Personal monitoring
pollutant Mean Min Median 90th (b) Max
Benzene 31.2 5.38 22.6 56.2 133
Carbon 14.1 4.48 12.3 25.4 31.3
tetrachloride
Chloroform 111 6.98 53.3 181 801
Ethylbenzene 2.21 0.56 1.27 4.73 13.4
Methylene 0.99 0.02 0.44 2.66 6.39
chloride
MTBE 4.12 0.16 1.47 2.66 41.4
Styrene 1.25 0.03 0.65 3.70 5.25
Perc 16.7 0.56 5.05 45.7 135
TCE 0.70 0.10 0.34 1.40 4.36
Abbreviations: Max, maximum; Min, minimum.
(a) ASPEN concentrations weighted by the number of exposure
monitoring samples taken per census tract. (b) Percentiles.
Table 4. Comparison of cumulative cancer risk by exposure category
for the VOC pollutants
Cumulative risk (per 1 million)
Min Average Median 90th percent Max
ASPEN model 8 47 42 85 86
Outdoor concentrations 16 43 36 69 124
Indoor concentrations 26 165 120 193 740
Personal exposures 33 183 120 337 862
Corresponding number of cancer cases (over a lifetime)
Min Average Median 90th Percent Max
ASPEN model 0 1 1 2 2
Outdoor concentrations 0 1 1 2 3
Indoor concentrations 1 4 3 7 18
Personal exposures 1 4 3 8 21
Abbreviations: Max, maximum; Min, minimum.
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Woodruff T, Axelrad D, Caldweg J, Morello-Frosch R, Rosenbaum A. 1998. Public health implications of 1990 air toxics concentrations across the United States. Environ Health Perspect 106:249-251. Woodruff T, Caldwell J, Cogliano V, Axelrad D. 2000. Estimating cancer risk from outdoor concentrations of hazardous air pollutants in 1990. Environ Res 82:194=200. Devon C. Payne-Sturges, (1) Thomas A. Burke
(1) Department of Environmental Health Sciences, (2) Department of Health Policy and Management, and (3) Department of Biostatistics biostatistics /bio·sta·tis·tics/ (-stah-tis´tiks) biometry. bi·o·sta·tis·tics n. The science of statistics applied to the analysis of biological or medical data. , Bloomberg School of Public Health, Johns Hopkins University, Baltimore, Maryland, USA Address correspondence to D. Payne-Sturges, National Center for Environmental Economics, Office of Policy, Economics and Innovation, Ariel Rios Building The Ariel Rios Building is across 12th Street from the Old Post Office, in the Federal Triangle in Washington, D.C.. The Rios Building is now the headquarters of the U.S. Environmental Protection Agency. MC 1809T, 1200 Pennsylvania Ave. NW, Washington, DC 20460 USA. Telephone: (202) 566-2316. Fax: (202) 566-2336. E-mail: payne-sturges.devon@epa.gov We dedicate ded·i·cate tr.v. ded·i·cat·ed, ded·i·cat·ing, ded·i·cates 1. To set apart for a deity or for religious purposes; consecrate. 2. this article to D. McGuigan, a South Baltimore community leader who fought generously and tirelessly tire·less adj. Not yielding to fatigue; untiring or indefatigable. tire  less·ly adv. for community
environmental health concerns. We thank all the community residents who
gave their time and opened their homes to participate in this study. We
are grateful to A. O'Malley for her invaluable assistance in
recruiting study subjects. Members of our community advisory committee,
including the late D. McGuigan, M. Rosso, D. Schuyler, R. Kolber, and
the late A. Bonenberger, provided valuable insight and advice. We also
thank S. Kim for conducting the laboratory analysis and D. Williams for
her assistance in developing a GIS (1) (Geographic Information System) An information system that deals with spatial information. Often called "mapping software," it links attributes and characteristics of an area to its geographic location. map of South Baltimore.This work is based on a community-based exposure study that was conducted through initial pilot funding by the U.S. Environmental Protection Agency Region III (grant MM993948) followed by funding by the Mickey Leland National Center for Urban Air Toxics Research. Additional support has been provided through the Johns Hopkins Noun 1. Johns Hopkins - United States financier and philanthropist who left money to found the university and hospital that bear his name in Baltimore (1795-1873) Hopkins 2. Risk Science and Public Policy Institute, the Johns Hopkins Center in Urban Environmental Health (P30 ES 03819), and the Maryland Cigarette Restitution In the context of Criminal Law, state programs under which an offender is required, as a condition of his or her sentence, to repay money or donate services to the victim or society; with respect to maritime law, the restoration of articles lost by jettison, done when the Fund. The views expressed in this document are those of the authors and do not represent official U.S. EPA Policy. The authors declare they have no competing financial interests. Received 3 June 2003; accepted 22 December 2003. |
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