Intersubject variability of risk from perchlorate in community water supplies.This article is a brief review and summary of the estimated incremental Additional or increased growth, bulk, quantity, number, or value; enlarged. Incremental cost is additional or increased cost of an item or service apart from its actual cost. risks (increases in 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. or decreases in thyroid thyroid /thy·roid/ (thi´roid) 1. the thyroid gland; see under gland. 2. pertaining to the thyroid gland. 3. scutiform. 4. uptake of iodine iodine (ī`ədīn, –dĭn) [Gr.,=violet], nonmetallic chemical element; symbol I; at. no. 53; at. wt. 126.9045; m.p. 113.5°C;; b.p. 184.35°C;; sp. gr. 4.93 at 20°C;; valence −1, +1, +3, +5, or +7. ) to pregnant women (and hence their fetuses) associated with perchlorate perchlorate: see chlorate. exposure in community water supplies (CWSs). The analysis draws on the recent health effects review published in 2005 by the National Research Council (NRC NRC abbr. 1. National Research Council 2. Nuclear Regulatory Commission Noun 1. NRC - an independent federal agency created in 1974 to license and regulate nuclear power plants ). We focus on the potential level of risk borne by the NRC-identified most sensitive subpopulation sub·pop·u·la·tion n. A part or subdivision of a population, especially one originating from some other population: microbial subpopulations. Noun 1. (pregnant women and hence their fetuses). Other members of the population should be at a level of risk below that calculated here, and so protection of the sensitive subpopulation would protect the general public health. The analysis examines the intersubject distribution of risks to this sensitive subpopulation at various potential 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. concentrations of perchlorate and also draws on estimates of the national occurrence of perchlorate in U.S. CWSs to estimate the variability of risks under defined regulatory scenarios. Results suggest that maximum contaminant levels Maximum Contaminant Levels are standards that are set by the United States Environmental Protection Agency (EPA) for drinking water quality. A Maximum Contaminant Level (MCL) is the legal threshold limit on the amount of a hazardous substance that is allowed in drinking water under (MCLs) of up to 24.5 [micro]g/L should pose little or no incremental risk to the large majority of individuals in the most sensitive subpopulations exposed in the 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. at current levels of perchlorate in water. The protectiveness of an MCL MCL - Macintosh Common LISP of 24.5 [micro]g/L depends, however, on whether the study subjects in the health effects data used here may be assumed to have been exposed to background (non-drinking water) contributions of perchlorate. Key words: Monte Carlo Monte Carlo (môNtā` kärlō`), town (1982 pop. 13,150), principality of Monaco, on the Mediterranean Sea and the French Riviera. analysis, perchlorate, risk, sensitive subpopulations, water. Environ Health Perspect 114:975-979 (2006). doi:10.1289/ehp.8459 available via http://dx.doi.org/ [Online 27 February 2006] ********** Perchlorate is an inorganic compound inorganic compound Any substance in which two or more chemical elements other than carbon are combined, nearly always in definite proportions (see bonding), as well as some compounds containing carbon but lacking carbon-carbon bonds (e.g., carbonates, cyanides). that has been manufactured and used as a solid rocket fuel for several decades. Initial detection of perchlorate in drinking waters was associated with proximity to military and industrial sites where the compound was produced, stored, and/or used. More recent data collection efforts suggest perchlorate is more widespread than initially thought and in some locations may be associated with sources other than military rocket fuels. In some locations, perchlorate may be present from commonly used explosive devices (e.g., fireworks fireworks: see pyrotechnics. fireworks Explosives or combustibles used for display. Of ancient Chinese origin, fireworks evidently developed out of military rockets and explosive missiles and accompanied the spread of military explosives westward to , road blasting materials) and in other locations the compound may be formed naturally under suitable atmospheric and soil conditions. For example, some researchers hypothesize hy·poth·e·size v. hy·poth·e·sized, hy·poth·e·siz·ing, hy·poth·e·siz·es v.tr. To assert as a hypothesis. v.intr. To form a hypothesis. that lightning interactions with desert soils containing certain salt compounds may be responsible for perchlorate levels detected in western Texas (Dasgupta et al. 2005). Similar natural forces may explain the presence of perchlorate in the Atacama Desert Atacama Desert (ätäkä`mä), arid region, c.600 mi (970 km) long, N Chile, extending south from the border of Peru. The desert itself, c. region of Chile, and fertilizers mined from the Chilean desert may contribute to perchlorate found in some areas of the United States where those products were applied. Perchlorate is among a class of goitergens that inhibit the uptake of iodide iodide /io·dide/ (i´o-did) a binary compound of iodine. i·o·dide n. A compound of iodine with a more electropositive element or group. by the thyroid and thereby cause goiter goiter: see thyroid gland. and related iodine deficiency disorders iodine deficiency disorder Any condition–eg, cretinism and brain damage, goiter, or hypothyroidism, attributable to iodine deficiency and corrected by adequate dietary iodine. See Iodine. (IDDs), including, in extreme cases, cretinism cretinism (krē`tənĭz'əm), condition produced in infants and children due to lack of thyroid hormone. It usually results from a congenital defect (e.g. . IDD (1) (International Direct Dial) Long distance dialing between countries without operator intervention. Also known as international standard dialing (ISD). is no longer considered a public health concern in the United States because the large majority of Americans have ample iodide uptake through their normal diet to prevent IDD. There is, however, a fraction of pregnant women, between 10 and 15%, whose urinary excretion excretion, process of eliminating from an organism waste products of metabolism and other materials that are of no use. It is an essential process in all forms of life. In one-celled organisms wastes are discharged through the surface of the cell. rates are elevated (Hollowell et al. 1998). If this increased urinary excretion rate is interpreted as indicating a deficit of iodine uptake (this link is not established in the cited report), these women are likely to be the sensitive subpopulation for perchlorate exposures. Iodide intake is sufficient to typically enable the thyroid to compensate and overcome any adverse effects from goitergen exposure. It is important to note that the effects of perchlorate are therefore dependent on the total pool of goitergens to which individuals are exposed. Goitergen exposure in humans is from a variety of routes, including both water ingestion ingestion /in·ges·tion/ (-chun) the taking of food, drugs, etc., into the body by mouth. in·ges·tion n. 1. The act of taking food and drink into the body by the mouth. 2. and consumption of food products found in the diet containing those with relatively high levels of nitrate (fruits, vegetables, grains, drinking water, and smoked meats For the general process, see . Smoked meat is a method of preparing fish and meat which originates in prehistory. Its purpose is to preserve these protein rich foods, which would otherwise spoil quickly, for long periods of possibly lean times. ), thiocyanates (broccoli broccoli (brŏk`əlē) [Ital.,=sprouts], variety of cabbage grown for the edible immature flower panicles. It is the same variety (Brassica oleracea botrytis) as the cauliflower and is similarly cultivated. , cabbage, corn, yams, sorghum sorghum, tall, coarse annual (Sorghum vulgare) of the family Gramineae (grass family), somewhat similar in appearance to corn (but having the grain in a panicle rather than an ear) and used for much the same purposes. , and milk), isoflavones isoflavones (īˑ·sō·flāˈ·vōnz), n.pl phytoestrogenic compounds found in various plants, including red clover and soy. (soy, beans, and peas), bromide bromide, any of a group of compounds that contain bromine and a more electropositive element or radical. Bromides are formed by the reaction of bromine or a bromide with another substance; they are widely distributed in nature. (drinking water), and disulfides (onions, garlic, and peas). Goitergen intake from perchlorate exposure in water must be compared against this background of exposure to other goitergens, with risks from perchlorate resulting from the incremental effect of iodine uptake inhibition above and beyond the inhibition caused by the intake of other goitergens. Presently, the relative effectiveness of these different routes of exposure at producing decreases in iodine uptake has not been assessed, so it is not possible to specify the fraction of total decrease due solely to perchlorate exposures. Overall goitergen exposure would need to be quite high for iodide uptake to be inhibited to a degree sufficient to elevate IDDs to a matter of health concern, although again, this level of exposure is not known at present and may be significantly lower for the sensitive subpopulation. The National Research Council (NRC) examined the risks posed by perchlorate ingestion (NRC 2005) and indicated in their executive summary, "To cause declines in thyroid hormone Thyroid hormone Any of the chemical messengers produced by the thyroid gland, including thyrocalcitonin, a polypeptide, and thyroxine and triiodothyronine, which are iodinated thyronines. See Hormone, Thyrocalcitonin, Thyroid gland, Thyroxine production that would have adverse health effects, iodide uptake would most likely have to be reduced by at least 75% for months or longer." The mode of action for perchlorate exposure and human health risk is summarized here in the Appendix, based on the mode of action described in the NRC (2005) report. The NRC expert panel developed an oral reference dose (RfD) of 0.0007 mg perchlorate per kilogram kilogram, abbr. kg, fundamental unit of mass in the metric system, defined as the mass of the International Prototype Kilogram, a platinum-iridium cylinder kept at Sèvres, France, near Paris. of body weight per day (mg/kg/day). This oral RfD is intended to reflect a safe threshold dose at which no risk of adverse health effect is anticipated for an iodide-deficient pregnant woman and any developing fetus fetus, term used to describe the unborn offspring in the uterus of vertebrate animals after the embryonic stage (see embryo). In humans, the fetal stage begins seven to eight weeks after fertilization of the egg, when the embryo assumes the basic shape of the newborn she might be carrying. As stated by the NRC (2005): "The committee concludes that an RfD of 0.0007 mg/kg per day should protect the health of even the most sensitive populations." This RfD is based on observing no significant inhibition of thyroid uptake of iodide at a perchlorate dose of 0.007 mg/kg/day in human subjects (Greer et al. 2002). A total uncertainty factor of 10 then was applied to ensure protection of the sensitive subpopulation: iodide-deficient pregnant women (and their fetuses). Such a subpopulation could be exposed to perchlorate levels up to the RfD of 0.0007 mg/kg/day and not be expected to face a significant risk of adverse health effect. Because this is the most sensitive population, this RfD also would be protective of all other exposed individuals (including infants). The need for a larger uncertainty factor was precluded (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 NRC committee) by the use of a precursor to adverse effect (iodine uptake inhibition) in establishing a threshold for exposure, which was considered by the committee to represent a health-protective assumption causing the recommended RfD to be based on a no observed effect level (NOEL) rather than the more commonly used no observed adverse effects level (NOAEL NOAEL, n ‘no-observed-adverse-effect-level,’ the maximum concentration of a substance that is found to have no adverse effects upon the test subject. ). A NOAEL is by definition an adverse effect equal to or higher than a NOEL where the effect used to establish the NOEL is a precursor to the adverse effect of interest in establishing a NOAEL. A possible argument is that a larger uncertainty factor still is warranted because we do not know the precise level at which a decrease in iodine uptake becomes adverse, and so it is possible that even small decreases may be adverse in the sense implied by the NOAEL and the lowest observed adverse effect level (LOAEL LOAEL Lowest Observed Adverse Effect Level ). This would be true especially in the case of women who already are iodine deficient. The authors of the present article believe this confuses the concept of an uncertainty factor as originally developed to argue for RfDs based on effects judged adverse. The question is not whether a given decrease in iodine uptake does or does not lead to adverse effects in some percentage of the population but whether such a decrease in and of itself, absent any sequellae, is to be taken as an adverse effect. Our position here is that such a decrease is not adverse in and of itself and so does not warrant the application of uncertainty factors developed originally to reason from NOAELs and LOAELs. The NRC committee appears to agree, whether explicitly or implicitly. After the NRC report, 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. 2005) issued a statement accepting the NRC's RfD and announcing that it had developed a drinking water equivalent level (DWEL DWEL Drinking Water Equivalent Level ). The DWEL converts the RfD (represented in units of mg/kg/day) into an associated concentration in drinking water (in units of micrograms per liter), taking into account the relative source contribution (RSC RSC Royal Society of Chemistry (UK) RSC Royal Shakespeare Company RSC Responsabilidad Social Corporativa (Spanish: corporate social responsibility) RSC Royal Society of Canada ) from water versus other exposure routes. The DWEL was established by the EPA at 24.5 [micro]g/L (U.S. EPA 2005) and is derived assuming a 70-kg adult consuming 2 L of drinking water per day. This gives an intake rate (of water) per unit body mass of 0.029 L/kg/day, which is slightly above the mean value for women of child-bearing age when both direct and indirect water ingestion are considered (U.S. EPA 2004, table 6.1.A2). Hence, use of this value may be considered conservative (in the sense of being health protective) for the sensitive subpopulation. The present article places the NRC assessment into the framework of probabilistic risk assessment Probabilistic risk assessment (PRA) (or probabilistic safety assessment/analysis) is a systematic and comprehensive methodology to evaluate risks associated with a complex engineered technological entity (such as airliners or nuclear power plants). . The question addressed here is what the distribution of risks is in the sensitive subpopulation of pregnant women in the United States resulting from exposure to perchlorate in water from community water supplies (CWSs). The term "risk" in this article has two metrics: a hazard quotient (HQ) and a percentage reduction in iodide uptake. These risks then are examined using Monte Carlo analysis to produce intersubject variability distributions under a variety of scenarios of regulatory interest. Materials and Methods Exposure assessment. The occurrence of perchlorate in drinking waters has recently been reported in a study sponsored by the American Water Works Association's Water Industry Technical Action Fund (Brandhuber and Clark 2004). The study relied principally on data collected under the U.S. EPA unregulated contaminant contaminant /con·tam·i·nant/ (kon-tam´in-int) something that causes contamination. contaminant something that causes contamination. monitoring rule (UCMR UCMR Unregulated Contaminant Monitoring Rule UCMR Upon Completion, Return To ), supplemented with monitoring data collected by the Massachusetts Department of Environmental Protection (MDEP MDEP Mitglied des Europäischen Parlaments (German: member of European Parliament) MDEP Maine Department of Environmental Protection MDEP Management Decision Package MDEP Management Decision Evaluation Package ), by the California Department of Health Services Department of Health Services may refer to:
po·ta·ble adj. Fit to drink; drinkable. potable fit to drink. or nonpotable or whether it was part of a water system. Unfortunately, the data are insufficient at present to develop a fully probabilistic (probability) probabilistic - Relating to, or governed by, probability. The behaviour of a probabilistic system cannot be predicted exactly but the probability of certain behaviours is known. Such systems may be simulated using pseudorandom numbers. population-weighted distribution of concentrations in CWSs, and so the present analysis assumes no correlation between system size (and hence size of population served) and perchlorate concentration. The UCMR used analytic methods with a detection limit of 4 [micro]g/L (micrograms per liter are essentially the same as parts per billion), and drew four quarterly samples from each entry point to the distribution system (EPDS EPDS Edinburgh Postnatal Depression Scale EPDS Electrical Power & Distribution System EPDS Electronic Processing and Dissemination System EPDS Emergency Personnel Decontamination Station EPDS Emergency Priority Dispatch System ) for every CWS CWS Chicago White Sox CWS College World Series CWS Church World Service CWS Child Welfare Services CWS Canadian Wildlife Service CWS Community Water System (EPA) CWS Canada-Wide Standard CWS Compressed Work Schedule > 10,000 persons served in the United States. Data also were collected for a sample of 771 smaller systems, but this sample may be too small to provide a sound basis for statistical inference Inferential statistics or statistical induction comprises the use of statistics to make inferences concerning some unknown aspect of a population. It is distinguished from descriptive statistics. . These data suggest a slightly higher concentration in the smallest water supplies, and so the analysis of Brandhuber and Clark (2004) may underestimate exposures (by up to 20%) in the small percentage of the population using these small systems serving fewer than 10,000 people. The results reported by Brandhuber and Clark (2004) and used here reflect the UCMR database compiled as of August 2004, when the database did not yet contain all the data from all quarters for all EPDSs. Hence, the final UCMR data set may suggest results that differ slightly from those discussed here. The UCMR data reveal detectable amounts ([greater than or equal to] 4 [micro]g/L) in 1.9% of the samples taken. Because most CWSs have more than one EPDS, and samples were taken for each EPDS, a higher percentage of CWSs (> 1.9%) were found to have at least one EPDS with detectable levels of perchlorate. The UCMR data suggest that perchlorate occurs in detectable amounts in at least one EPDS associated with 5.4% of CWSs. In systems serving > 10,000 people, perchlorate was detected in 6.1% of groundwater-based CWSs and in 4.9% of the surface-water-fed systems. Although > 5% of large CWSs in the UCMR database had some detectable perchlorate in at least one of the EPDS-finished waters, the levels observed were generally quite low. More than two-thirds (68%) of the measurable perchlorate concentrations were in the 4-8 ppb ppb abbr. parts per billion range, and 86% were < 12 [micro]g/L. Only 2.6% of the detected samples had concentrations > 24 [micro]g/L (Brandhuber and Clark 2004), which is near the U.S. EPA-designated DWE DWE Doppler Wind Experiment DWE Douglas Wright Engineering Building (University of Waterloo) DWE Difficulty with Evacuation DWE Deferred Work Element DWE Duration Weighted Exposure DWE Detailed Work Estimate of 24.5 [micro]g/L (U.S. EPA 2005). The highest observed level in the UCMR data was 420 [micro]g/L. In Massachusetts, samples were analyzed with a more sensitive detection limit that yielded quantifiable results [greater than or equal to] 1 [micro]g/L and "trace" observations for levels < 1 [micro]g/L. This method revealed that 2.4% of treated drinking water samples contained detectable levels of perchlorate. However, the vast majority of the Massachusetts detections in treated waters were at or near the 1-[micro]g/L limit of detection: 66% of detects in treated drinking water were at trace levels ([less than or equal to] 1 [micro]g/L), 83% of detects were [less than or equal to] 2 [micro]g/L, and 90% were [less than or equal to] 4 [micro]g/L (Brandhuber and Clark 2004). The above data were fit by a lognormal distribution Lognormal distribution Pattern of frequency of occurrence in which the logarithm of the variable follows a normal distribution. Lognormal distributions are used to describe returns calculated over periods of a year or more. . The resulting distribution is characterized by a median of 0.03 [micro]g/L and a geometric standard deviation In probability theory and statistics, the geometric standard deviation describes how spread out are a set of numbers whose preferred average is the geometric mean. If the geometric mean of a set of numbers is denoted as μg (GSD GSD German Shepherd Dog GSD Graduate School of Design GSD Glycogen Storage Disease GSD General Services Division GSD Gundam Seed Destiny (anime) GSD Ground Sample Distance GSD Geometric Standard Deviation ) of 13. The assumption here is that the properties of the distribution identified at the higher levels of exposure ([greater than or equal to] 1 [micro]g/L) continue to apply in water supplies at concentrations below the detection limit. Based on the NRC review, potential for risk arises only if a person from the sensitive subpopulation ingests perchlorate at an incremental rate (i.e., above background) that exceeds the identified threshold for effect. The average daily rate of intake (ADRI ADRI Animal Diseases Research Institute (Tanzania) ADRI ARC Digitial Raster Imagery ADRI Arc Digitized Raster Images ) for any individual is based on how much tap water they consume, the concentration of perchlorate in their tap water, and their body weight. These three factors vary across the U.S. population of pregnant women. Using available data, the distributions for these variables can be included in a Monte Carlo analysis to develop a combined distribution of ADRI values across this subpopulation. The distribution of water ingestion rates used here is based on total CWS consumption values for adults established by the U.S. EPA (2004), which provides values associated with given percentiles of the variability distribution. Data on water ingestion for pregnant women were too limited to use reliably in this analysis, but the existing data suggest that using the data for U.S. adults does not understate un·der·state v. un·der·stat·ed, un·der·stat·ing, un·der·states v.tr. 1. To state with less completeness or truth than seems warranted by the facts. 2. exposures in pregnant women. As demonstrated in the U.S EPA Exposure Factors Handbook (U.S. EPA 1997), the difference in intake rates of tap water for the general population of women of child-bearing age and pregnant women is small (mean of 1.16 vs. 1.19 L/day), and so the former is assumed to approximate the latter intake rates in this analysis. The distribution of body weight for 25-year-old women (representing women 18-40 years of age, who largely make up the child-bearing-age population) is taken from the U.S. EPA Exposure Factors Handbook (U.S. EPA 1999). The data on water ingestion rate per unit body weight described above then were fitted by a lognormal distribution, with a best fit showing a median of 0.0182 L/kg/day and a GSD of 1.8. This distribution is consistent with the mean value assumed in regulatory calculations. The U.S. EPA typically employs an RSC of drinking water, expressed as the percentage of total contaminant dose that is provided by drinking water, to estimate total risk from all routes of exposure (i.e., aggregate risk). These RSCs for drinking water generally are in the range of 20-80%. The relevance of applying an RSC here depends on how one interprets the human subject perchlorate study conducted by Greer et al. (2002) that forms the basis of the risk coefficients. An RSC is appropriate when the study on which risk coefficients are based includes only exposures through one route, whereas exposures through other routes will be present in exposure situations envisioned in regulatory decisions (and so must be factored in when regulating exposures by the first route). If one assumes that the individuals in the study by Greer et al. (2002) were exposed to the same background levels of perchlorate as the rest of the U.S. population (there is nothing in their diets or in the study design to preclude this), then no further RSC adjustment is needed to reflect total exposures via all routes because the risk coefficient from the study already reflects the incremental risk from ingestion of perchlorate in water above and beyond the contributions to perchlorate exposure via the other routes. Similarly, because the study population presumably pre·sum·a·ble adj. That can be presumed or taken for granted; reasonable as a supposition: presumable causes of the disaster. was exposed to the complement of goitergens other than perchlorate, the study by Greer et al. (2002) also reflects the incremental risk from ingestion of the goitergen perchlorate above and beyond the contributions from these other goitergens. This is the scenario we employ in our analysis. Unfortunately, adequate data are not available at present to estimate the RSC for water exposures reliably. Risk characterization. A standard metric of potential health risk for threshold contaminants like perchlorate is the HQ. The HQ is equal to the estimated ADRI (in units of milligrams per kilogram per day) divided by the RfD. An HQ value of 1.0 thus means that a person is receiving an ADRI equal to the RfD. Any HQ value [greater than or equal to] 1.0 indicates that exposure is at or below the "no risk" threshold (the term "no risk" here meaning a risk judged to be nonsignificant non·sig·nif·i·cant adj. 1. Not significant. 2. Having, producing, or being a value obtained from a statistical test that lies within the limits for being of random occurrence. ), and thus no significant risk of adverse health effect is anticipated. An HQ value > 1.0 indicates an ADRI above the RfD and suggests that there may be some nonzero non·ze·ro adj. Not equal to zero. nonzero Not equal to zero. risk of adverse health effect (although, because of the uncertainty factors in the RfD, which produce a margin of safety, the risk may be zero even for exposures yielding HQ values < 1.0). In the present article, we use the value of RfD suggested by the NRC (2005): 0.0007 mg/kg/day. Another measure of effect used in this analysis is the estimated percent decrease in iodide uptake by the thyroid (the critical effect used originally to establish the RfD). This is estimated based on fitting a 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 to the data from Greer et al. (2002), relating the ADRI to the percent decrease in iodide uptake. The resulting curve is shown in Figure 1. The best model fit is as follows: Percent decrease in iodide uptake = 70 x {1 - exp exp abbr. 1. exponent 2. exponential [-14 x (ADRI - 0.005)]}, where ADRI is in units of mg/kg/day. Note that this model suggests a threshold at 0.005 mg/kg/day, which is slightly below the NOEL for the study at 0.007 mg/kg/day. This is because there is a measured decrease in iodine uptake (1.8%) even at the NOEL, although this decrease is not statistically significant. A comparison point for risk here is the NRC (2005) observation that a 75% decrease in iodide uptake would be required to initiate a potential health effect, although again, it must be noted that the percent decrease required in the sensitive subpopulation currently is unknown and is likely to be less than this value. As before, note that our assumption here is that the dose-response data from Greer et al. (2002) reflect the incremental decrease in iodide uptake per unit incremental increase in exposure to perchlorate through water alone, above and beyond the modifying effects of the background perchlorate exposures through other routes. Results The Monte Carlo assessment was conducted for hypothetical MCLs of 1, 2, 5, 6, 10, 20, 24.5, and 50 [micro]g/L (values of 6 and 24.5 were included to reflect potential limits by 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] Then we focused on intersubject variability of doses and risk metrics for people possibly exposed to water mitigated to exactly a potential MCL to reflect risk distributions only within those CWSs that currently have elevated perchlorate concentrations and might therefore be expected to reduce concentrations down to the MCL. The Monte Carlo process is the same as described previously (including the focus on the sensitive subpopulation), with the exception that all individuals are exposed at the same concentration of perchlorate in water, equal to the MCL. Both sets of results are described below. National occurrence results. The HQ results using the national occurrence analysis are summarized in Table 1. For example, at the 95th 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 of the sensitive subpopulation, the HQ value was 0.02 (i.e., dose was 2% of the RfD no risk threshold), even at an MCL of 50 [micro]g/L. Note from this same table that the percent decrease in iodine uptake, using the model in Figure 1, is zero for all MCL values and percentiles examined because the ADRI was below the threshold in the model. Results for systems at the MCL. In this second set of calculations, all individuals in the sensitive subpopulation are assumed exposed at the concentration of a potential MCL. In other words Adv. 1. in other words - otherwise stated; "in other words, we are broke" put differently , in this analysis, we examine risks to the highly exposed portion of the sensitive subpopulation after the potential MCL has been established and all CWSs are mitigated down to that MCL. For the at-the-MCL analysis, some HQ values do exceed 1.0. As shown in Table 2, there were no HQ values > 1.0 at MCLs of [less than or equal to] 24.5 [micro]g/L for the percentiles of the cumulative distribution functions examined. In systems with perchlorate concentrations of 50 [micro]g/L, however, 28.6% of the sensitive subpopulation had an HQ value exceeding 1.0 (an HQ value of 1.0 was found at approximately the 71st percentile of the variability distribution for this population). At the 90th percentile, the HQ value at 50 [micro]g/L exposure was 1.54, and at the 95th percentile the HQ value was 1.89. There was, however, no reduction in iodide uptake estimated from the model at any MCL because all intake rates were below the threshold for the model in Figure 1. Sensitivity analyses. The above-described analyses and results are based on several assumptions that can be altered. We conducted several alternate Monte Carlo simulations Monte Carlo Simulation A problem solving technique used to approximate the probability of certain outcomes by running multiple trial runs, called simulations, using random variables. to reflect a mix of potential differences in selection of underlying data or in how those data are interpreted. The goal here was to determine an upper-bound estimate of the risks, and so more conservative assumptions were used than was the case in Tables 1 and 2. Specifically, in this new analysis, the amount of water consumed was increased to include total water intake (not just intake from CWSs), as obtained from the U.S. EPA Exposure Factors Handbook (U.S. EPA 1999). Using the national occurrence data for the concentration of perchlorate in the drinking water (i.e., assuming the non-CWS concentration was the same as that in the CWS for an individual), there is no appreciable difference between the base case results from Table 1 and the "upper-end" values calculated here. Results in Table 1 may therefore be assumed to represent upper-end risks when all water consumption, and not only drinking water, is considered in the exposure assessment. However, for the at-the-MCL analysis results (as shown in Table 3, and equivalent to Table 2), for those women consuming water with perchlorate at the potential MCLs, there are some elevated HQ values compared with those in the base analysis depicted in Table 2. In particular, there are now HQ values > 1.0 at the 95th percentile even at 20 [micro]g/L. Discussion and Conclusions Perchlorate in drinking water is more widespread than originally anticipated, with perhaps 2% of sources showing detectable levels [greater than or equal to] 4 [micro]g/L. Combining the newly emerging risk and occurrence information, we have modeled the percentage of the sensitive subpopulation (pregnant women) that may face (or whose infants may face) a risk of adverse health effects due to perchlorate in U.S. drinking waters. The results indicate that for any population using a CWS with a perchlorate concentration of 50 [micro]g/L (i.e., slightly more than twice the proposed U.S. EPA DWEL of 24.5 [micro]g/L), there would be an appreciable percentage of pregnant women who face a risk of adverse effects in themselves or their fetuses because they would have an HQ value > 1.0. When perchlorate concentrations are 50 [micro]g/L, between 28.6% (if only ingestion of drinking water is assumed) and 58.1% (if all water ingestion is assumed, with the non-CWS being similarly contaminated contaminated, v 1. made radioactive by the addition of small quantities of radioactive material. 2. made contaminated by adding infective or radiographic materials. 3. an infective surface or object. by perchlorate) of the sensitive subpopulation might face a dose exceeding the RfD. Values of the HQ > 1.0 at the 95th percentile of the intersubject variability distribution are predicted at 20 [micro]g/L perchlorate if ingestion of all water, and not only drinking water, is included in the exposure assessment. The results suggest that few women in the sensitive subpopulation would face a significant perchlorate risk from drinking water at MCLs [less than or equal to] 24.5 [micro]g/L if only drinking water is considered, but that the equivalent MCL would need to be slightly below 20 [micro]g/L if all water ingestion were considered. We caution the reader on the interpretation of these results. The present analysis falls within a framework of probabilistic risk assessment that differs in significant ways from traditional approaches to determining regulatory limits on exposure. In those traditional approaches, risks are estimated to maximally max·i·mal adj. 1. Of, relating to, or consisting of a maximum. 2. Being the greatest or highest possible. n. Mathematics An element in an ordered set that is followed by no other. exposed individuals within sensitive subpopulations, and the concentration determined that produces an acceptable level of risk in those individuals. This level is independent of any consideration of the fraction of people in that subpopulation. The question being addressed traditionally is to what extent a proposed MCL will reduce the risk to an individual in this maximally exposed, sensitive subpopulation. Probabilistic risk assessment as conducted here, however, examines the intersubject variability distribution of risks in this subpopulation and asks what fraction of people in an exposed population have a risk (HQ or percentage decrease in iodide uptake) judged to be unacceptable. Such probabilistic distributions form the basis of cost-risk-benefit calculations, allowing society to determine how a given mode of risk reduction (e.g., controls on perchlorate exposures) compares against other modes of risk reduction. The goal then is to determine the total burden of disease in a population and to use this estimate of burden to determine whether the examined mode of risk reduction (here, control on perchlorate exposures) represents an effective way to allocate limited societal resources in improving the overall health of the public. We have not attempted here to draw any conclusions in that regard, but rather to present the probabilistic information on which such cost-risk-benefit assessments might be based. REFERENCES Brandhuber P, Clark S. 2004. Perchlorate Occurrence Mapping. Prepared for the American Water Works Association American Water Works Association (AWWA) is an international nonprofit professional organization dedicated to the improvement of drinking water quality and supply. It was founded in 1881 and, as of 2007, there are approximately 60,000 AWWA members world-wide. . Denver, CO:HDR (1) (High Data Rate) A wireless data technology from QUALCOMM that provides up to a 2.4 Mbps data rate in a standard 1.25MHz CDMA voice channel. HDR can be used to enhance data capabilities in existing cdmaOne networks or in stand-alone data networks. Engineering. Dasgupta P, Martinelango P, Jackson W, Anderson T, Tian Tian or T'ien (Chinese; “Heaven”) In indigenous Chinese religion, the supreme power reigning over humans and lesser gods. The term refers to a deity, to impersonal nature, or to both. T, Tock R, et al. 2005. The origin of naturally occurring perchlorate. Environ Sci Tech 39:1569-1575. Greer M, Goodman G, Pleus R, Greer S. 2002. Health effects assessment for environmental perchlorate contamination: the dose-response for inhibition of thyroidal thy·roid n. 1. The thyroid gland. 2. The thyroid cartilage. 3. A dried, powdered preparation of the thyroid gland of certain domestic animals, used in treatment of hypothyroid conditions. 4. radioiodine radioiodine /ra·dio·io·dine/ (-i´o-din) any radioactive isotope of iodine, particularly 123I, 125I, and 131I; used in diagnosis and treatment of thyroid disease and in scintiscanning. uptake in humans. Environ Health Perspect 110:927-937. Hollowell J, Staehling N, Hannon W, Flanders D, Gunter E, Maberly G, et al. 1998. Iodine nutrition in the United States. Trends and public health implications: iodine excretion data from National Health and Nutrition Examination Surveys I and III (1971-1974 and 1988-1994). J Clin Endocrinol Metab 83:3401-3408. NRC (National Research Council). 2005. Health Implications of Perchlorate Ingestion. Washington, DC:National Academy Press. Available:http://www.nap.edu/execsumm_pdf/11202.pdf [accessed 11 January 2006]. U.S. EPA. 1997. Exposure Factors Handbook. EPA/600/P-95/002F, a-c. Washington, DC:U.S. Environmental Protection Agency, Office of Research and Development. U.S. EPA. 1999. Exposure Factors Handbook. EPA/600/C-99/001. Washington, DC:U.S. Environmental Protection Agency, Office of Research and Development. U.S. EPA. 2004. Estimated Per Capita [Latin, By the heads or polls.] A term used in the Descent and Distribution of the estate of one who dies without a will. It means to share and share alike according to the number of individuals. Water Ingestion and Body Weight in the United States--An Update. EPA-822-R-00-001. Washington, DC:U.S. Environmental Protection Agency, Office of Water. U.S. EPA. 2005. EPA Sets Reference Dose for Perchlorate. Washington, DC:U.S. Environmental Protection Agency, Available: http://yosemite.epa.gov/opa/admpress.nsf/b1ab9f485b098972852562e7004dc686/c1a57d2077c4bfda85256fac005b8b32!OpenDocument [accessed 9 March 2005]. Appendix. Mode of action for perchlorate. There is broad scientific agreement that the mode of action for perchlorate is as follows: * Perchlorate binds to, and blocks, receptors for the movement of iodine from the bloodstream into the thyroid. This will reduce the movement of iodine into the thyroid. * The thyroid responds to this reduction either by producing less triiodothyronine triiodothyronine /tri·io·do·thy·ro·nine/ (tri?i-o?do-thi´ro-nen) one of the thyroid hormones, an organic iodine-containing compound liberated from thyroglobulin by hydrolysis. It has several times the biological activity of thyroxine. ([T.sub.3]) and thyroxine ([T.sub.4]) or by drawing on the pool of iodine stored in the thyroid. * Perchlorate can therefore reduce the production of [T.sub.3] and [T.sub.4] initially, although there are feedback mechanisms that can bring these levels in the circulating blood back to normal ranges over time. * The effect on [T.sub.4] is not significant because that molecule is an intermediary, and so the focus should be on changes in [T.sub.3]. * For some fraction of the population that has very little iodine Little Iodine, created as a supporting character for Jimmy Hatlo's single-panel newspaper comic strip They'll Do It Every Time, was an earlier, female equivalent of Hank Ketcham's Dennis the Menace. stored in the thyroid, there may be reduced ability to compensate for the reduction of iodine crossing from the bloodstream to the thyroid. This may reduce [T.sub.3] levels in the circulating blood, leading eventually to increased production of thyroid-stimulating hormone thyroid-stimulating hormone (TSH): see thyrotropin. (TSH TSH thyroid-stimulating hormone; see thyrotropin. TSH abbr. thyroid-stimulating hormone Thyroid-stimulating hormone (TSH) ) to try to correct the imbalance. * If the imbalance cannot be corrected, there could be changes in metabolic function Metabolic function Those processes necessary for the maintenance of a living organism. Mentioned in: Stress Reduction at any age of exposure, or abnormal fetal and child growth and development. The NRC committee (NRC 2005) disagreed as to where the U.S. EPA should draw the line between adverse and nonadverse effects. The agency considered changes in [T.sub.3] and TSH levels to be adverse in and of themselves, or at least indications of, or biomarkers of, adverse effects. The NRC committee did not consider changes in [T.sub.3] and/or TSH adverse in and of themselves. Instead, the NRC committee claimed that changes in these levels must first produce thyroid hypertrophy hypertrophy (hīpûr`trəfē), enlargement of a tissue or organ of the body resulting from an increase in the size of its cells. Such growth accompanies an increase in the functioning of the tissue. or hyperplasia hyperplasia (hī'pərplā`zhə): see hypertrophy. , followed by hypothyroidism hypothyroidism: see thyroid gland. , which then will produce the final metabolic and growth/developmental effects mentioned above. The NRC committee considered the first effect that is adverse to be hypothyroidism rather than either the preceding thyroid hypertrophy/hyperplasia or the changes in [T.sub.3] and/or TSH. Doug Crawford-Brown, (1) Bob Raucher, (2) and Megan Harrod (2) (1) Department of Environmental Sciences and Engineering and Carolina Environmental Program, University of North Carolina at Chapel Hill The University of North Carolina at Chapel Hill is a public, coeducational, research university located in Chapel Hill, North Carolina, United States. Also known as The University of North Carolina, Carolina, North Carolina, or simply UNC , Chapel Hill, North Carolina Chapel Hill is a town in North Carolina and the home of the University of North Carolina at Chapel Hill (UNC-CH), the oldest state-supported university in the United States. As of the 2000 census, it had a population of 48,715. As of 2004 its estimated population was 52,440. , USA; (2) Stratus stratus: see cloud. (Stratus Technologies, Maynard, MA, www.stratus.com) A manufacturer of fault-tolerant computers founded in 1980. It supports both the VOS and FTX Unix operating systems on its XA/R line of i860-based systems. Consulting Inc., Boulder, Colorado The City of Boulder (, Mountain Time Zone) is a home rule municipality located in Boulder County, Colorado, United States. Boulder is the 11th most populous city in the State of Colorado, as well as the most populous city and the county , USA Address correspondence to D. Crawford-Brown, CB #1105, University of North Carolina at Chapel Hill, Chapel Hill, NC 27599-1105 USA. Telephone: (919) 966-6026. Fax: (919) 966-9920. E-mail: douglas_crawford-brown@unc.edu Funding for this project was provided by the Water Industry Technical Action Fund (WITAF). WITAF is administered by American Water Works Association and is funded through member dues. WITAF funds information collection and analysis and other activities in support of sound and effective legislation, regulation, and drinking water policies and programs. All authors have performed contract consulting work on the risks of perchlorate in national drinking water regulatory deliberations. This consulting was funded by the American Water Works Association. Received 1 July 2005; accepted 16 March 2006. Table 1. HQ values for pregnant women (the sensitive subpopulation): base case analysis, using national occurrence data (i.e., existing distribution of perchlorate in water, with only supplies currently above the proposed MCL mitigated down to the proposed MCL). MCL ([micro]g/L) Median (a) 90th percentile (b) 95th percentile (b) 1 0.01 0.02 0.02 2 0.01 0.02 0.02 5 0.01 0.02 0.02 6 0.01 0.02 0.02 10 0.01 0.02 0.02 20 0.01 0.02 0.02 24.5 0.01 0.02 0.02 50 0.01 0.02 0.02 MCL ([micro]g/L) Percent HQ < 1 (c) Percent decrease (d) 1 > 99 0 2 > 99 0 5 > 99 0 6 > 99 0 10 > 99 0 20 > 99 0 24.5 > 99 0 50 > 99 0 (a) The median for the variability distribution. (b) The 90th and 95th percentiles of the variability distribution. (c) The percentage of the population with an HQ value < 1. (d) The percent decrease in iodide uptake for individuals at the 95th percentile. The percent decrease is predicted using the equation in the text; a value of 0% indicates the modeled threshold of 0.005 mg/kg/day has not been exceeded. Table 2. HQ values for pregnant women (the sensitive subpopulation): base case analysis, for persons using CWSs at the MCL concentration (i.e., considering only supplies currently above a potential MCL, which are mitigated down to the potential MCL). MCL ([micro]g/L) Median (a) 90th percentile (b) 95th percentile (b) 1 0.01 0.03 0.04 2 0.03 0.06 0.08 5 0.07 0.15 0.19 6 0.08 0.19 0.22 10 0.14 0.30 0.38 20 0.29 0.62 0.76 24.5 0.33 0.70 0.90 50 0.73 1.54 1.89 MCL ([micro]g/L) Percent HQ < 1 (c) Percent decrease (d) 1 > 99 0 2 > 99 0 5 > 99 0 6 > 99 0 10 > 99 0 20 > 99 0 24.5 > 99 0 50 71.4 0 (a) The median for the variability distribution. (b) The 90th and 95th percentiles of the variability distribution. (c) The percentage of the population with an HQ value < 1. (d) The percent decrease in iodide uptake for individuals at the 95th percentile. The percent decrease is predicted using the equation in the text; a value of 0% indicates the threshold of 0.005 mg/kg/day has not been exceeded. Table 3. HQ values for pregnant women (the sensitive subpopulation): sensitivity analysis, high-end exposure scenarios for persons consuming all water, and not only drinking water, at the MCL. MCL ([micro]g/L) Median (a) 90th percentile (b) 95th percentile (b) 1 0.04 0.07 0.08 2 0.06 0.11 0.13 5 0.13 0.25 0.31 6 0.15 0.28 0.36 10 0.24 0.48 0.60 20 0.45 0.95 1.16 24.5 0.50 1.10 1.35 50 1.10 2.37 2.90 MCL ([micro]g/L) Percent HQ < 1 (c) Percent decrease (d) 1 > 99 0 2 > 99 0 5 > 99 0 6 > 99 0 10 > 99 0 20 91.2 0 24.5 88.3 0 50 41.9 0 (a) The median for the variability distribution. (b) The 90th and 95th percentiles of the variability distribution. (c) The percentage of the population with an HQ value < 1. (d) The percent decrease in iodide uptake for individuals at the 95th percentile. The percent decrease is predicted using the equation in the text; a value of 0% indicates the threshold of 0.005 mg/kg-day has not been exceeded. |
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