Low-level environmental lead exposure and children's intellectual function: an international pooled analysis.Lead is a confirmed neurotoxin neurotoxin /neu·ro·tox·in/ (noor´o-tok?sin) a substance that is poisonous or destructive to nerve tissue. neu·ro·tox·in n. See neurolysin. , but questions remain about lead-associated intellectual deficits at blood lead levels < 10 [micro]g/dL and whether lower exposures are, for a given change in exposure, associated with greater deficits. The objective of this study was to examine the association of intelligence test scores and blood lead concentration, especially for children who had maximal measured blood lead levels < 10 [micro]g/dL. We examined data collected from 1,333 children who participated in seven international population-based longitudinal cohort studies A cohort study is a form of longitudinal study used in medicine and social science. It is one type of study design. In medicine, it is usually undertaken to obtain evidence to try to refute the existence of a suspected association between cause and disease; failure to refute , followed from birth or infancy until 5-10 years of age. The full-scale IQ score was the primary outcome measure. The 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. blood lead concentration of the children peaked at 17.8 [micro]g/dL and declined to 9.4 [micro]g/dL by 5-7 years of age; 244 (18%) children had a maximal max·i·mal adj. 1. Of, relating to, or consisting of a maximum. 2. Being the greatest or highest possible. blood lead concentration < 10 [micro]g/dL, and 103 (8%) had a maximal blood lead concentration < 7.5 [micro]g/dL. After adjustment for covariates, we found an inverse relationship A inverse or negative relationship is a mathematical relationship in which one variable decreases as another increases. For example, there is an inverse relationship between education and unemployment — that is, as education increases, the rate of unemployment between blood lead concentration and IQ score. Using a log-linear model log-linear model a statistical model which models frequency counts in contingency tables by using an analysis of variance approach. , we found a 6.9 IQ point decrement To subtract a number from another number. Decrementing a counter means to subtract 1 or some other number from its current value. [95% 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%. (CI), 4.2-9.4] associated with an increase in concurrent blood lead levels from 2.4 to 30 [micro]g/dL. The estimated IQ point decrements associated with an increase in blood lead from 2.4 to 10 [micro]g/dL, 10 to 20 [micro]g/dL, and 20 to 30 [micro]g/dL were 3.9 (95% CI, 2.4-5.3), 1.9 (95% CI, 1.2-2.6), and 1.1 (95% CI, 0.7-1.5), respectively. For a given increase in blood lead, the lead-associated intellectual decrement for children with a maximal blood lead level < 7.5 [micro]g/dL was significantly greater than that observed for those with a maximal blood lead level [greater than or equal to] 7.5 [micro]g/dL (p = 0.015). We conclude that environmental lead exposure in children who have maximal blood lead levels < 7.5 [micro]g/dL is associated with intellectual deficits. Key words: blood lead concentration, children, environment, epidemiology, intelligence, lead, lead toxicity. doi:10.1289/ehp.7688 available via http://dx.doi.org/[Online 18 March 2005] ********** The preponderance pre·pon·der·ance also pre·pon·der·an·cy n. Superiority in weight, force, importance, or influence. Noun 1. preponderance of experimental and human data indicates that there are persistent and deleterious deleterious adj. harmful. effects of blood lead levels > 10 [micro]g/dL on brain function, including lowered intelligence, behavioral problems, and diminished school performance (Baghurst et al. 1992; Bellinger et al. 1992; Cory-Slechta 1997; Dietrich et al. 1993; Ernhart et al. 1989; National Research Council 1993; Needleman and Gatsonis 1990; Pocock et al. 1994; Rice 1993; Wasserman et al. 1997; Yule et al. 1981). Lead toxicity, defined as whole blood lead [greater than or equal to] 10 [micro]g/dL, was based on numerous cross-sectional and prospective studies [Bellinger et al. 1987; 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 ) 1991; World Health Organization (WHO) 1995]. These studies generally, but not always, found adverse consequences of childhood lead exposure (CDC 1991; WHO 1995). Still, most of the children in those studies had blood lead levels > 10 [micro]g/dL. The WHO and the CDC recognized that there was no discernable threshold for the adverse effects of lead exposure, but too few studies had examined children with blood lead levels < 10 [micro]g/dL to support any firm conclusions (CDC 1991; WHO 1995). There is emerging evidence that lead-associated intellectual deficits occur at blood lead levels < 10 [micro]g/dL. In the Rochester Longitudinal Study longitudinal study a chronological study in epidemiology which attempts to establish a relationship between an antecedent cause and a subsequent effect. See also cohort study. , there was an estimated reduction of 7.4 IQ points associated with an increase in lifetime mean blood lead from 1 to 10 [micro]g/dL (Canfield can·field n. Games A form of solitaire. [After Richard Albert Canfield (1855-1914), American gambler.] Noun 1. et al. 2003). In a reanalysis of a Boston, Massachusetts “Boston” redirects here. For other uses, see Boston (disambiguation). Boston is the capital and most populous city of Massachusetts.[3] The largest city in New England, Boston is considered the unofficial economic and cultural center of the entire New , cohort, a similar finding was observed among children whose maximal blood lead level was < 10 [micro]g/dL (Bellinger and Needleman 2003). Questions about an effect of lead at blood lead levels < 10 [micro]g/dL persist, however, because of the relatively small numbers of children with maximal blood lead levels < 10 [micro]g/dL in the Rochester Longitudinal Study (Rogan and Ware 2003). Other studies were limited because they involved children whose blood lead levels may have exceeded 10 [micro]g/dL at some point in their lifetime or because important covariates, such as maternal IQ scores, were not always available (Fulton et al. 1987; Lanphear et al. 2000; Schwartz 1994; Schwartz and Otto 1991; Walkowiak et al. 1998). Because of the policy implications of this research, it is critical to estimate with greater precision the exposure-response relationship at blood lead levels < 10 [micro]g/dL. The primary objective of this pooled analysis was to estimate the quantitative relationship between children's performance on IQ tests and selected measures of blood lead concentration among children followed prospectively, from infancy through 5-10 years of age in seven prospective cohort studies. We also sought to test whether the lead-associated IQ deficit was greater for a given change in exposure among children who had maximal blood lead levels < 10 [micro]g/dL compared with children who had higher blood lead concentrations. Materials and Methods We contacted investigators for all eight prospective lead cohorts that were initiated before 1995, and we were able to retrieve data sets and collaboration from seven. The participating sites were Boston (Bellinger et al. 1992); Cincinnati (Dietrich et al. 1993) and Cleveland, Ohio "Cleveland" redirects here. For the Cleveland metropolitan area, see . For other uses, see Cleveland (disambiguation). Cleveland is a city in the U.S. state of Ohio and the county seat of Cuyahoga County, the most populous county in the state. (Ernhart et al. 1989); Mexico City Mexico City Spanish Ciudad de México City (pop., 2000: city, 8,605,239; 2003 metro. area est., 18,660,000), capital of Mexico. Located at an elevation of 7,350 ft (2,240 m), it is officially coterminous with the Federal District, which occupies 571 sq mi , Mexico (Schnaas et al. 2000); Port Pirie Port Pirie (pĭr`ē), city (1991 pop. 14,110), South Australia, S Australia, on an inlet of Spencer Gulf. It is a railroad center and has uranium refineries and smelting works for the silver-lead mines at Broken Hill. , Australia (Baghurst et al. 1992); Rochester, New York This article is about the city of Rochester in Monroe County. For the town in Ulster County, see Rochester, Ulster County, New York. Rochester, once known as The Flour City, and more recently as The Flower City or (Canfield et al. 2003); and Yugoslavia (Wasserman et al. 1997). The Sydney, Australia, study was not included because we were unable to contact the investigators (Cooney et al. 1989). The data for the Rochester Longitudinal Study and for Mexico City, collected when the children were about 6 years of age, have not been published elsewhere. The eligibility criteria and methods for each of the cohorts are described elsewhere (Baghurst et al. 1992; Bellinger et al. 1992; Canfield et al. 2003; Dietrich et al. 1993; Ernhart et al. 1989; Schnaas et al. 2000; Wasserman et al. 1997). All studies were approved by their respective institutional review boards. Outcome measures. The primary outcome measure was the full-scale IQ, which is a composite score of verbal and performance tests. The children were administered a version of the Wechsler Intelligence Scales for Children [Wechsler Intelligence Scale for Children--Revised (WISC-R WISC-R Weschler Intelligence Scale for Children - Revised ; Wechsler 1974), Wechsler Intelligence Scale for Children-III (WISC-III WISC-III Wechsler Intelligence Scales for Children, 3rd Edition ; Wechsler 1991), Wechsler Preschool and Primary Scales of Intelligence (WPPSI WPPSI Wechsler Preschool & Primary Scale of Intelligence ; 1967), and Wechsler Intelligence Scale for Children--Spanish Version (WISC-S; Wechsler 1981)] under uniform conditions within each study. The IQ test was administered when the children were between 4 years 10 months and 7 years of age for all but one cohort. In the Boston cohort, we used blood lead tests taken at 5 years of age and the nearest available full-scale IQ score, which was done at 10 years of age. Venous or fingerstick capillary capillary (kăp`əlĕr'ē), microscopic blood vessel, smallest unit of the circulatory system. Capillaries form a network of tiny tubes throughout the body, connecting arterioles (smallest arteries) and venules (smallest veins). blood samples were obtained using standard protocols. Cord blood cord blood n. Blood present in the umbilical vessels at the time of delivery. lead was collected in a subsample sub·sam·ple n. A sample drawn from a larger sample. tr.v. sub·sam·pled, sub·sam·pling, sub·sam·ples To take a subsample from (a larger sample). of the subjects. During each child's examination, demographic and health information were obtained from the parent (usually the biologic mother). IQ tests were administered to the mother. We also obtained data on other factors that might confound con·found tr.v. con·found·ed, con·found·ing, con·founds 1. To cause to become confused or perplexed. See Synonyms at puzzle. 2. the relation of lead exposure and IQ, including child's sex, birth order, birth weight, maternal education, maternal age maternal age, n the age of the mother at the period of conception. , marital status marital status, n the legal standing of a person in regard to his or her marriage state. , prenatal prenatal /pre·na·tal/ (-na´tal) preceding birth. pre·na·tal adj. Preceding birth. Also called antenatal. prenatal preceding birth. alcohol exposure, prenatal tobacco exposure, and the Home Observation for Measurement of the Environment (HOME) Inventory score. The HOME Inventory is an index that reflects the quality and quantity of emotional and cognitive stimulation in the home environment (Caldwell and Bradley 1984). Measures of exposure. We examined four measures of blood lead: concurrent blood lead (defined as the blood lead measured closest to the IQ test), maximum blood lead level (defined as the peak blood lead measured at any time before IQ test), average lifetime blood lead (defined as the mean blood lead from 6 months to concurrent blood lead tests), and early childhood blood lead (defined as the mean blood lead from 6 to 24 months). The blood sampling intervals varied across studies. To enhance comparability across studies, we used the following blood sampling intervals (based on children's age): 6, 12 (or 15), 36, 48, and 60 months. We used mean blood lead rather than area under the curve (AUC AUC area under curve ) to maintain the same units of analysis for all four lead indices. The AUC and mean provided essentially the same information about children's lead exposure (r = 0.97). Statistical methods. To estimate the quantitative relationship between children's performance on IQ tests and selected measures of blood lead concentration, we examined the potential confounding confounding when the effects of two, or more, processes on results cannot be separated, the results are said to be confounded, a cause of bias in disease studies. confounding factor effects of other factors associated with IQ scores using multiple regression Multiple regression The estimated relationship between a dependent variable and more than one explanatory variable. analysis. Ten factors were available from individual sites: HOME Inventory, child's sex, birth weight, birth order, maternal education, maternal IQ, maternal age, marital status, prenatal smoking status, and prenatal alcohol use. The development of the regression model involved a multistep process beginning with a simple unadjusted model relating each blood lead measure to IQ while controlling for site. The first step was to test whether the linear model of the relationship between blood lead and IQ, applied in most of the individual cohort analyses, provided a good fit over the wider range of blood lead levels represented in the pooled data. First, a linear model adjusted for the seven sites was estimated, and then quadratic quadratic, mathematical expression of the second degree in one or more unknowns (see polynomial). The general quadratic in one unknown has the form ax2+bx+c, where a, b, and c are constants and x is the variable. and cubic terms for blood lead were added to test for linearity. A restricted cubic spline In computer graphics, a smooth curve that runs through a series of given points. The term is often used to refer to any curve, because long before computers, a spline was a flat, pliable strip of wood or metal that was bent into a desired shape for drawing curves on paper. See Bezier and B-spline. function was fit to the data to produce a curve that followed the data in the absence of any assumptions about the functional form of the relationship. After an initial model was chosen, we examined each of the 10 available confounders individually and in combination with the other covariates to assess potential confounding of the IQ-blood lead relationship. Careful attention was paid to the stability of the parameter estimates as each additional term was added. This process was halted when either no more significant terms (p < 0.10) entered the model or the inclusion of additional terms caused no substantial change (i.e., > 10%) in the blood lead coefficient. In all models, we tested the interaction of blood lead and site to determine whether a summary measure of the IQ-blood lead relationship could be used for all cohorts. After an initial model was selected, the tests of linearity and the restricted cubic spline models were recomputed to ensure that our initial model was still appropriate after adjustment for covariates (Harrell 2001). We also produced separate linear models for each of the seven cohorts adjusted for the covariates selected in the combined model. After the multiple regression models were developed, regression diagnostics were employed to ascertain whether the lead coefficient was affected by collinearity collinearity very high correlation between variables. or influential observations (Belsley et al. 1980). After regression diagnostics were examined and homogeneity Homogeneity The degree to which items are similar. of the blood lead coefficients across sites was evaluated, the fit of all four measures of blood lead was compared using the magnitude of the model [R.sup.2]. The blood lead measure with the largest [R.sup.2] (adjusted for the same covariates) was selected a priori a priori In epistemology, knowledge that is independent of all particular experiences, as opposed to a posteriori (or empirical) knowledge, which derives from experience. as the preferred blood lead index relating blood lead to IQ. Several approaches were investigated to evaluate the stability of the final model. Although the seven cohorts were not randomly sampled from a larger population of studies, an assumption could be made that they were representative of a larger population of children. Accordingly, we evaluated the results of applying a random-effects model (with sites random) rather than a fixed-effects model (Littell et al. 1996). We also examined the effect of any one site on the overall model by calculating the blood lead coefficient in seven identical models, each omitting one of the seven cohorts (Efron and Tibshirani 1993). After the final model was selected using the full-scale IQ as the outcome variable, we fit similar models for verbal and performance IQ scores. We also examined interactions of covariates with blood lead concentration (effect modification effect modification Epidemiology An interaction among multiple possible cause-and-effect relationships, where the estimate of the effect of one factor on a disease process depends on other factors in the study ) and tested the effect of including race as a confounder con·found tr.v. con·found·ed, con·found·ing, con·founds 1. To cause to become confused or perplexed. See Synonyms at puzzle. 2. in the U.S. cohort studies. Finally, we examined the relationship of prenatal lead exposure (cord blood) and IQ score in the subsample for which cord blood lead tests were available. Results Of the 1,581 eligible children from the seven cohorts, data on all 10 covariates were available for 1,308 (83%) children; 1,333 (84%) children had data on the four major covariates that were selected for the final model (Table 1). Blood lead levels were highest in Yugoslavia and lowest in Rochester and Boston for all lead exposure indices (Table 2). The median peak or maximal blood lead concentration was 18 [micro]g/dL; the mean age when children's blood lead levels peaked was 2.5 years. By 5-7 years of age, the median blood level had declined to 9.7 [micro]g/dL (concurrent blood lead concentration). The lifetime average blood lead concentration was 12.4 [micro]g/dL; 244 (18%) children had a maximal blood lead concentration < 10 [micro]g/dL, and 103 (8%) had a maximal blood lead concentration < 7.5 [micro]g/dL. The mean IQ of all children was approximately 93. Child IQ was highest in the Boston cohort and lowest in the Yugoslavia cohort (Table 2). In univariate regression analyses, children's IQ was significantly related to site, maternal IQ, the HOME score, maternal education, marital status, birth weight, maternal age, birth order, race (for U.S. cohorts only), and prenatal tobacco exposure. In contrast, child's sex and prenatal alcohol consumption were not significantly associated with a deficit in IQ score (Table 3). We examined the relationship of the four blood lead indices with IQ (Table 4). Although all four blood lead measures were highly correlated (r range = 0.74-0.96), the concurrent blood lead variable exhibited the strongest relationship with IQ, as measured by [R.sup.2]. Although the means differed for the different blood lead indices, the results of the regression analyses were very similar. In all subsequent analyses and figures, the concurrent blood lead measure was used as the primary lead exposure index. The shape of the exposure--response relationship was determined to be nonlinear A system in which the output is not a uniform relationship to the input. nonlinear - (Scientific computation) A property of a system whose output is not proportional to its input. insofar in·so·far adv. To such an extent. Adv. 1. insofar - to the degree or extent that; "insofar as it can be ascertained, the horse lung is comparable to that of man"; "so far as it is reasonably practical he should practice as the quadratic and cubic terms for concurrent blood lead were statistically significant (p < 0.001 and p = and 0.003, respectively). Because the restrictive cubic spline indicated that a log-linear model provided a good fit to the data, we used the log of concurrent blood lead in all subsequent analyses of the pooled data (Figure 1). [FIGURE 1 OMITTED] The multivariable analysis resulted in a six-term model: log of concurrent blood lead, site, maternal IQ, HOME Inventory, birth weight, and maternal education, which we consider our preferred model (Table 4). Linear models of concurrent blood lead and IQ are shown for each of the seven cohorts, adjusted for the same covariates (Figure 2). The additional six terms we considered (child's sex, birth order, maternal age, marital status, prenatal smoking status, and prenatal alcohol use) contributed very little to the overall fit of the model, and their inclusion in the model resulted in virtually no change to the coefficient for blood lead (i.e., < 5%). None of the six terms was statistically significant (data not shown). [FIGURE 2 OMITTED] The shape of the log-linear model and the spline function indicated that the steepest declines in IQ were at blood lead levels < 10 [micro]g/dL (Figures 3 and 4). The log-linear model estimated a decrement of 6.9 IQ points [95% confidence interval (CI), 4.2-9.4] for an increase in concurrent blood lead levels from 2.4 to 30 [micro]g/dL, representing the 5th to 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 for blood lead values in the data set (Table 4). But the lead-associated decrement was greatest in the lower ranges of blood lead. The estimated IQ decrements associated with an increase in blood lead from 2.4 to 10 [micro]g/dL, 10 to 20 [micro]g/dL, and 20 to 30 [micro]g/dL were 3.9 (95% CI, 2.4-5.3), 1.9 (95% CI, 1.2-2.6), and 1.1 (95% CI, 0.7-1.5), respectively (Table 4). [FIGURES 3-4 OMITTED] To investigate further whether the lead-associated decrement was greater at lower blood lead concentrations, we divided the data at two cut-points a priori (i.e., maximal blood lead above and below 10 [micro]g/dL, and maximal blood lead above and below 7.5 [micro]g/dL) (Figure 4). We then fit separate linear models to the data in each of these ranges and compared the blood lead coefficients for the concurrent blood lead index. The coefficient for the 103 children with maximal blood lead levels < 7.5 [micro]g/dL was significantly greater than the coefficient for the 1,230 children with a maximal blood lead [greater than or equal to] 7.5 [micro]g/dL [linear [beta] = -2.94 (95% CI, -5.16 to -0.71) vs. -0.16 (95% CI, -2.4 to -0.08); p = 0.015]. The coefficient for the 244 children who had a maximal blood lead < 10 [micro]g/dL was not significantly greater than the coefficient for the 1,089 children who had a maximal blood lead [greater than or equal to] 10 [micro]g/dL [linear [beta] = -0.80 (95% CI, -1.74 to -0.14) vs. [beta] = -0.13 (95% CI, -2.3 to -0.03); p = 0.103]. To assess the model stability, we employed a random-effects model with sites assumed to be randomly selected from a larger set of populations. Results were similar to the preferred fixed-effects model, with the random-effects model producing a blood lead coefficient that was 3.7% lower (-2.6 vs. -2.7). As an additional measure of model stability, we fit seven identical log-linear models with each model omitting data from one of the sites. The range of coefficients leaving one site out at a time was -2.36 (Rochester) to -2.94 (Yugoslavia), or a percent change ranging from -2.6 to +8.9%. These analyses provide evidence of the stability of our final preferred fixed-effects model and indicate that the results of the pooled analysis did not depend on the data from any single study. We also examined the relation of blood lead concentration to verbal and performance IQ scores, adjusting for the same covariates used in the full-scale IQ model. The coefficient for the log of blood lead related to performance IQ was similar to the coefficient for log of blood lead in the full-scale IQ model ([beta] = -2.73 vs. -2.70), whereas the coefficient for log of blood lead related to verbal IQ was somewhat lower than the coefficient for the log of blood lead in the full-scale IQ model ([beta] = -2.07 vs. -2.70). The difference between the coefficient for verbal and performance IQ was not statistically significant (p = 0.196). We did not identify any significant interactions between the covariates and the log of concurrent blood lead. In the U.S. sites, race was not significantly associated with IQ after inclusion of the four covariates in the preferred model, nor did it alter the estimated relationship of blood lead concentration and IQ. In unadjusted analyses involving the 696 children who had cord blood lead levels, the log of cord blood lead concentration was significantly associated with child's IQ ([beta] = -1.69, SE = 0.60; p = 0.005). After adjusting for the log of concurrent blood concentration, the log of cord blood lead was no longer associated with children's IQ scores (p = 0.21). In contrast, the log of concurrent blood lead was significantly associated with children's IQ scores even with log cord blood lead concentration in the model ([beta] = -1.73, SE = 0.74; p = 0.019). Finally, we identified and removed 65 potentially influential observations from the data and refit the model. The change in the coefficient for log of blood lead was 1.4%, from -2.70 to -2.74. Discussion Before 1970, undue lead exposure was defined by a blood lead level of 60 [micro]g/dL or higher--a level often associated with overt signs or symptoms of lead toxicity, such as abdominal colic abdominal colic Clinical medicine A condition characterized by intense cramping or colicky pain, which may be accompanied by nausea and vomiting Etiology Urinary stones, far less commonly, heavy metal–arsenic, lead, thallium, mushroom, or organophosphate , anemia, encephalopathy encephalopathy /en·ceph·a·lop·a·thy/ (en-sef?ah-lop´ah-the) any degenerative brain disease. AIDS encephalopathy HIV e. anoxic encephalopathy hypoxic e. , and death. Since then, the blood lead concentration for defining undue lead exposure has been reduced: from 60 to 40 [micro]g/dL in 1971, to 30 [micro]g/dL in 1978, and to 25 [micro]g/dL in 1985 (CDC 1991). In 1991, the CDC, and subsequently the WHO (1995), further reduced the blood lead value defining undue lead exposure to 10 [micro]g/dL (CDC 1991). These ongoing reductions in the acceptable levels of children's blood lead were motivated by evidence showing that blood lead concentrations as low as 10 [micro]g/dL were associated with adverse effects, such as lower intelligence (CDC 1991; WHO 1995). In this pooled analysis, we found evidence of lead-related intellectual deficits among children who had maximal blood lead levels < 7.5 [micro]g/dL. Indeed, we found no evidence of a threshold. Other studies reported a similar finding, but questions about the relationship at lower levels remained because they involved smaller numbers of children with blood lead < 10 [micro]g/dL or they did not adjust for important covariates (Canfield et al. 2003; Fulton et al. 1987; Lanphear et al. 2000; Schwartz 1994; Schwartz and Otto 1991; Walkowiak et al. 1998). In the pooled analysis, we estimated the blood lead--IQ relationship with data from the 5th to 95th percentile of the concurrent blood lead level at the time of IQ testing, which tends to underestimate the adverse effects of blood lead levels. For the entire pooled data set, the observed decline of 6.2 IQ points (95% CI, 3.8-8.6) for an increase in blood lead levels from < 1 to 10 [micro]g/dL was comparable with the 7.4 IQ decrement for an increase in lifetime mean blood lead levels from < 1 to 10 [micro]g/dL observed in the Rochester Longitudinal Study (Canfield et al. 2003). Consistent with other studies (Bellinger and Needleman 2003; Canfield et al. 2003; Fulton et al. 1987; Lanphear et al. 2000; Schwartz 1994; Schwartz and Otto 1991; Walkowiak et al. 1998), the lead-associated IQ deficits observed in this pooled analysis were significantly greater at lower blood lead concentrations. In a meta-analysis, the observed decrement was greater in study cohorts in which children with blood lead levels < 15 [micro]g/dL were more heavily represented (Schwartz 1994). In the Rochester Longitudinal Study, there was an estimated reduction of 7.4 IQ points for an increase in lifetime mean blood lead from 1 to 10 [micro]g/dL (Canfield et al. 2003). In contrast, IQ scores declined 2.5 points for an increase in blood lead concentration from 10 to 30 [micro]g/dL (Canfield et al. 2003). The larger sample size of this pooled analysis permitted us to show that the lead-associated intellectual decrement was significantly greater for children with a maximal blood lead of < 7.5 [micro]g/dL than for those who had a maximal blood lead of [greater than or equal to] 7.5 [micro]g/dL. Although the difference in coefficients associated with the IQ decrement for children who had a maximal blood lead concentration < 10 [micro]g/dL versus [greater than or equal to] 10 [micro]g/dL was not statistically significant, the results were consistent with the analysis using 7.5 [micro]g/dL as a cut-point. We found that concurrent blood lead levels or average lifetime estimates of lead exposure were generally stronger predictors of lead-associated intellectual deficits than was maximal measured (peak) or early childhood blood lead concentration. Although this finding conflicts with the widely held belief that 2-year (or peak) blood lead levels are the most salient measure of lead toxicity, there is increasing evidence that lifetime mean blood lead and concurrent blood lead levels are stronger predictors of IQ in older children (Baghurst et al. 1992; Canfield et al. 2003; Dietrich et al. 1993; Factor-Litvak et al. 1999). The stronger effects of concurrent and lifetime measures of lead exposure may be due to chronicity of exposure (Bellinger and Dietrich 1994). Alternatively, the weaker association with blood lead measured during early childhood may be due to exposure misclassification from the greater within-child variability of blood lead in younger children. Nevertheless, because blood lead concentrations taken in early childhood track closely with subsequent blood lead levels (Baghurst et al. 1992; Canfield et al. 2003; Dietrich et al. 1993), we cannot entirely resolve the question of whether children are more vulnerable to lead exposure during the first 2 years of life. Still, young children do ingest in·gest tr.v. in·gest·ed, in·gest·ing, in·gests 1. To take into the body by the mouth for digestion or absorption. See Synonyms at eat. 2. more lead during the first 2 years of life and may absorb it more efficiently than do older children and adults (Clark et al. 1985; Lanphear et al. 2002; Ziegler et al. 1978). Thus, efforts to prevent lead exposure must occur before pregnancy or a child's birth. The specific mechanisms for lead-induced intellectual deficits have not been fully elucidated. There are several plausible mechanisms for the greater lead-associated intellectual deficits observed at blood lead levels < 10 [micro]g/dL (Lidsky and Schneider 2003; Markovac and Goldstein 1988; Schneider et al. 2003), but it is not yet possible to link any particular mechanism with the deficits observed in this pooled analysis. Nevertheless, efforts can be taken to reduce environmental lead exposure without full elucidation e·lu·ci·date v. e·lu·ci·dat·ed, e·lu·ci·dat·ing, e·lu·ci·dates v.tr. To make clear or plain, especially by explanation; clarify. v.intr. To give an explanation that serves to clarify. of the underlying mechanism (Wynder 1994). The observational design of this study limits our ability to draw causal inferences. Instead, we must rely on the consistency of findings from numerous epidemiologic and experimental studies in rodents and nonhuman primates nonhuman primate see primate. , including evidence that environmental lead exposure is associated with intellectual deficits at blood lead levels < 10 [micro]g/dL. There are potential limitations of the tools we used to measure important covariates. The HOME Inventory was not conducted at the same age for children in all of the sites, and the HOME Inventory and IQ tests have not been validated in all cultural or ethnic communities. Nonetheless, because these covariates were standardized standardized pertaining to data that have been submitted to standardization procedures. standardized morbidity rate see morbidity rate. standardized mortality rate see mortality rate. and adjusted for study site, these problems do not pose any limitations to the interpretation of the pooled analysis results. There are other predictors of neurodevelopmental outcomes that we did not examine in this pooled analysis, such as maternal depression. The omission of unmeasured variables may produce residual confounding (Pocock et al. 1994). Still, in studies that did examine other relevant covariates, such as breast-feeding breast-feeding /breast-feed·ing/ (brest´fed?ing) nursing; the feeding of an infant at the mother's breast. and iron status, the estimated effect of lead was not altered appreciably (Canfield et al. 2003; Needleman et al. 1990; Tong tong 1 tr.v. tonged, tong·ing, tongs To seize, hold, or manipulate with tongs. [Back-formation from tongs. and Lu 2000). Finally, each of the cohorts has unique limitations that raise questions about the validity and generalizability of their findings. Nevertheless, the results of these analyses indicate that the results are robust and not dependent on the data from any one site. The impact of low-level environmental lead exposure on the health of the public is substantial. This pooled analysis focused on intellectual deficits, but environmental lead exposure has been linked with an increased risk for numerous conditions and diseases that are prevalent in industrialized in·dus·tri·al·ize v. in·dus·tri·al·ized, in·dus·tri·al·iz·ing, in·dus·tri·al·iz·es v.tr. 1. To develop industry in (a country or society, for example). 2. society, such as reading problems, school failure, delinquent behavior, hearing loss, tooth decay Tooth Decay Definition Tooth decay, which is also called dental cavities or dental caries, is the destruction of the outer surface (enamel) of a tooth. , spontaneous abortions spon·ta·ne·ous abortion n. A naturally occurring termination of a pregnancy. Also called miscarriage. spontaneous abortion , renal disease Renal disease Kidney disease. Mentioned in: Glycogen Storage Diseases hypertension High blood pressure Cardiovascular disease An abnormal ↑ systemic arterial pressure, corresponding to a systolic BP of > 160 mm Hg , and cardiovascular disease Cardiovascular disease Disease that affects the heart and blood vessels. Mentioned in: Lipoproteins Test cardiovascular disease (Borja-Aburto et al. 1999; Dietrich et al. 2001; Factor-Litvak et al. 1999; Lin et al. 2003; Moss et al. 1999; Nash et al. 2003; Needleman et al. 2002; Schwartz and Otto 1991). Although only a few studies have examined the association of these conditions or diseases among individuals with blood lead levels < 10 [micro]g/dL (Borja-Aburto et al. 1999; Lanphear et al. 2000; Moss et al. 1999; Schwartz and Otto 1991), the evidence is growing. In conclusion, the results of this pooled analysis 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 increasing importance of primary prevention as the consequences of lower blood lead concentrations are recognized. Although blood lead concentrations < 10 [micro]g/dL in children are often considered "normal," contemporary blood lead levels in children are considerably higher than those found in pre-industrial humans (Patterson et al. 1991). Moreover, existing data indicate that there is no evidence of a threshold for the adverse consequences of lead exposure. Collectively, these data provide sufficient evidence to eliminate childhood lead exposure by banning all nonessential non·es·sen·tial adj. Being a substance required for normal functioning but not needed in the diet because the body can synthesize it. uses of lead and further reducing the allowable levels of lead in air emissions, house dust, soil, water, and consumer products (Lanphear 1998; Rosen and Mushak 2001). This study was funded, in part, by the National Institute of Environmental Health Sciences The National Institute of Environmental Health Sciences (NIEHS) is one of 27 Institutes and Centers of the National Institutes of Health (NIH),which is a component of the Department of Health and Human Services (DHHS). The Director of the NIEHS is Dr. David A. Schwartz. , the Centers for Disease Control and Prevention, and 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 . The authors declare they have no competing financial interests. Received 22 October 2004; accepted 17 March 2005. REFERENCES Baghurst PA, McMichael AJ, Wigg NR, Vimpani GV, Robertson EF, Roberts RJ, et al. 1992. 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In the United States, definitions and age limits of juveniles vary, the maximum age being set at 14 years in some states and as high as 21 . Neurotoxicol Teratol 23:511-518. Efron B, Tibshirani RJ. 1993. An Introduction to the Bootstrap See boot. (operating system, compiler) bootstrap - To load and initialise the operating system on a computer. Normally abbreviated to "boot". From the curious expression "to pull oneself up by one's bootstraps", one of the legendary feats of Baron von Munchhausen. . New York:Chapman & Hall. Ernhart CB, Morrow-Tlucak M, Wolf AW, Super D, Drotar D. 1989. Low level lead exposure in the prenatal and early preschool periods: intelligence prior to school entry. Neurotoxicol Teratol 11:161-170. Factor-Litvak P, Wasserman G, Kline JK, Graziano J. 1999. The Yugoslavia prospective study of environmental lead exposure. Environ Health Perspect 107:9-15. Fulton M, Raab G, Thomson G, Laxen D, Hunter R, Hepburn W. 1987. 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Picomolar concentrations of lead stimulate brain protein kinase C Protein kinase C ('PKC', EC 2.7.11.13) is a family of protein kinases consisting of ~10 isozymes.[1] They are divided into three subfamilies: conventional (or classical), novel, and atypical based on their second messenger requirements. . Nature 334:71-73. Moss ME, Lanphear BP, Auinger P. 1999. Association of dental caries caries or tooth decay Localized disease that causes decay and cavities in teeth. It begins at the tooth's surface and may penetrate the dentin and the pulp cavity. and blood lead levels. JAMA JAMA abbr. Journal of the American Medical Association 281:2294-2298. Nash D, Magder L, Lustberg M, Sherwin RW, Rubin RJ, Kaufmann RB, et al. 2003. Blood lead, blood pressure, and hypertension in perimenopausal perimenopausal adjective Referring to a period of a ♀'s life–age 45 to 55-ish–in which menstrual periods become irregular; perimenopause is immediately before, during and after menopause. See Menopause. and postmenopausal post·men·o·paus·al adj. Of or occurring in the time following menopause. postmenopausal Change of life Gynecology adjective Referring to the time in ♀ when menstrual periods stop for ≥ 1 yr women. JAMA 289:1523-1532. National Research Council. 1993. Measuring Lead Exposure in Infants, Children and Other Sensitive Populations. Washington, DC:National Academy of Sciences. Needleman HL, Gatsonis CA. 1990. Low-level lead exposure and the IQ of children. A meta-analysis of modern studies. JAMA 263:673-678. Needleman HL, McFarland C, Ness RB, Fienberg SE, Tobin MJ. 2002. Bone lead levels in adjudicated delinquents. A case control study. Neurotoxicol Teratol 24:711-717. Needleman HL, Schell A, Bellinger D, Leviton A, Allred EN. 1990. The long-term effects of exposure to low doses of lead in childhood. An 11-year follow-up report. N Engl J Med 322:63-88. Patterson C, Ericson J, Manea-Krichten M, Shirahata H. 1991. Natural skeletal levels of lead in Homo sapiens Homo sapiens (Latin; “wise man”) Species to which all modern human beings belong. The oldest known fossil remains date to c. 120,000 years ago—or much earlier (c. sapiens sa·pi·ens adj. Of, relating to, or characteristic of Homo sapiens. [Latin sapi uncontaminated by technological lead. Sci Total Environ 107:205-236. Pocock SJ, Smith M, Baghurst PA. 1994. Environmental lead and children's intelligence: a systematic review of the epidemiological evidence. Br Med J 309:1189-1197. Rice DC. 1993. Lead-induced changes in learning: evidence for behavioral mechanisms from experimental animal studies. Neurotoxicology 14:167-178. Rogan WJ, Ware JH. 2003. Exposure to lead in children--how low is low enough? N Engl J Med 348:1515-1516. Rosen JF, Mushak P. 2001. Primary prevention of childhood lead poisoning--the only solution. N Engl J Med 344:1470-1471. 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Manual for Wechsler Preschool and Primary Scale of Intelligence The Wechsler Preschool and Primary Scale of Intelligence (WPPSI) is an intelligence test designed for children ages 2 years 6 months to 7 years 3 months developed by David Wechsler in 1967. . San Antonio San Antonio (săn ăntō`nēō, əntōn`), city (1990 pop. 935,933), seat of Bexar co., S central Tex., at the source of the San Antonio River; inc. 1837. , TX:The Psychological Corporation. Wechsler D. 1974. Manual for Wechsler Intelligence Scale for Children--Revised. San Antonio, TX:The Psychological Corporation. Wechsler D. 1981. WISC-R-Espanol. Escala de intelligencia revisiada para el nivel escolar. Manual. Mexico City:El Manual Moderno, SA. Wechsler D. 1991. Manual for Wechsler Intelligence Scale for Children Wechsler intelligence scale for children n. A standardized intelligence test that is used for assessing children from 5 to 15 years old. . 3rd ed. San Antonio, TX:The Psychological Corporation. WHO. 1995. 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Pediatr Res 12:29-34. Bruce P. Lanphear, (1,2) Richard Hornung, (1,2,3) Jane Khoury, (1,2) Kimberly Yolton, (1) Peter Baghurst, (4) David C. Bellinger, (5) Richard L. Canfield, (6) Kim IV. Dietrich, (1,2) Robert Bornschein, (2) Tom Greene, (7) Stephen J. Rothenberg, (8,9) Herbert L. Needleman, (10) Lourdes Schnaas, (11) Gail Wasserman, (12) Joseph Graziano, (13) and Russell Roberts Russell Roberts refers to several people:
(1) Cincinnati Children's Hospital Medical Center Cincinnati Children's Hospital Medical Center is a hospital in Cincinnati, Ohio. In June of 1883, a meeting of women from parish communities around Cincinnati established a mission to create a Diocesan Hospital for Children. , Cincinnati, Ohio “Cincinnati” redirects here. For other uses, see Cincinnati (disambiguation). Cincinnati is a city in the U.S. state of Ohio and the county seat of Hamilton County. , USA; (2) Department of Environmental Health, University of Cincinnati The University of Cincinnati is a coeducational public research university in Cincinnati, Ohio. Ranked as one of America’s top 25 public research universities and in the top 50 of all American research universities,[2] College of Medicine, Cincinnati, Ohio, USA; (3) Institute for Health Policy and Health Services Research Health services research is the multidisciplinary field of scientific investigation that studies how social factors, financing systems, organizational structures and processes, health technologies, and personal behaviors affect access to health care, the quality and cost of health care, , Department of Environmental Health, University of Cincinnati, Cincinnati, Ohio, USA; (4) Women and Children's Hospital A children's hospital is a hospital which offers its services exclusively to children. The number of children's hospitals proliferated in the 20th century, as pediatric medical and surgical specialties separated from internal medicine and adult surgical specialties. , North Adelaide North Adelaide is a predominantly residential precinct of the City of Adelaide in South Australia, situated north of the River Torrens and within the Adelaide Park Lands. History , South Australia South Australia, state (1991 pop. 1,236,623), 380,070 sq mi (984,381 sq km), S central Australia. It is bounded on the S by the Indian Ocean. Kangaroo Island and many smaller islands off the south coast are included in the state. ; (5) Department of Neurology neurology (n  rŏl`əjē, ny–), study of the morphology, physiology, and pathology of the human nervous system. , Children's Hospital Boston Children's Hospital Boston is a children's hospital located in the Longwood Medical and Academic Area of Boston, Massachusetts. Located at 300 Longwood Avenue, Children's is adjacent both to its teaching affiliate, Harvard Medical School, and to Dana-Farber Cancer Institute. and Harvard
Medical School Harvard Medical School (HMS) is one of the graduate schools of Harvard University. It is a prestigious American medical school located in the Longwood Medical Area of the Mission Hill neighborhood of Boston, Massachusetts. , Boston, Massachusetts, USA; (6) Division of Nutritional
Sciences, Cornell University Cornell University, mainly at Ithaca, N.Y.; with land-grant, state, and private support; coeducational; chartered 1865, opened 1868. It was named for Ezra Cornell, who donated $500,000 and a tract of land. With the help of state senator Andrew D. , Ithaca, New York
For other places or objects named Ithaca, see Ithaca (disambiguation). , USA; (7) 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. and Epidemiology, Cleveland Clinic Cleveland Clinic (formally known as the Cleveland Clinic Foundation) is a multispecialty academic medical center located in Cleveland, Ohio, USA. Cleveland Clinic was established in 1921 by four physicians for the purpose of providing patient care, research, and medical Foundation, Cleveland, Ohio, USA; (8) Center for Research in Population Health, National Institute of Public Health, Cuernavaca, Morelos, Mexico; (9) Drew University, Los Angeles Los Angeles (lôs ăn`jələs, lŏs, ăn`jəlēz'), city (1990 pop. 3,485,398), seat of Los Angeles co., S Calif.; inc. 1850. , California, USA; (10) University of Pittsburgh School of Medicine The University of Pittsburgh School of Medicine is the medical school of the University of Pittsburgh, located in Pittsburgh, PA. As of 2007, the University of Pittsburgh School of Medicine consists of 589 medical students - 53% men and 47% women. , Pittsburgh, Pennsylvania “Pittsburgh” redirects here. For the region, see Pittsburgh Metropolitan Area. Pittsburgh (pronounced IPA: /ˈpɪtsbɚg/) is the second largest city in the Commonwealth of Pennsylvania. , USA; (11) National Institute of Perinatology perinatology /peri·na·tol·o·gy/ (-na-tol´ah-je) the branch of medicine (obstetrics and pediatrics) dealing with the fetus and infant during the perinatal period. per·i·na·tol·o·gy n. , Mexico City, Mexico; (12) Department of Child Psychiatry child psychiatry Branch of medicine concerned with mental, emotional, and behavioral disorders of childhood. It arose as a separate field in the 1920s, largely because of the pioneering work of Anna Freud. , Columbia University Columbia University, mainly in New York City; founded 1754 as King's College by grant of King George II; first college in New York City, fifth oldest in the United States; one of the eight Ivy League institutions. , New York, New York, USA; (13) Department of Environmental Health Sciences, Columbia University, New York, New York, USA; (14) School of Applied Psychology, Griffith University Griffith University is an Australian public university with five campuses in Queensland between Brisbane and the Gold Coast. In 2007 there were more than 33,000 enrolled students and 3,000 staff. , Queensland, Australia Address correspondence to B.P. Lanphear, Cincinnati Children's Hospital Medical Center, 3333 Burnet burnet, hardy perennial herb of the family Rosaceae (rose) found in temperate regions, usually with white or greenish flowers. The European species are sometimes cultivated for the leaves, which are used in salads, for flavoring, and formerly as a poultice to stop Ave., Mail Location 7035, Cincinnati, OH 452293039 USA. Telephone: (513) 636-3778. Fax: (513) 636-4402. E-mail: bruce.lanphear@cchmc.org
Table 1. Characteristics of the children and of
their mothers in the pooled analysis (n= 1,333).
Characteristic Value
Child characteristics
Female (a) 669 (50.2)
Birth weight (b) (g) 3,286 [+ or -] 503
Gestation at delivery (b) (weeks) 39.6 [+ or -] 1.9
Birth order (c) 2.0 (1-5)
Blood lead concentration (d)
Concurrent 9.7 (2.5-33.2)
Peak 18.0 (6.2-47.0)
Early childhood 12.7 (4.0-34.5)
Lifetime average 12.4 (4.1-34.8)
Peak blood lead 244 (18.3)
concentration < 10 [micro]g/dL (a)
Peak blood lead 103 (7.7)
concentration < 7.5 [micro]g/dL (a)
IQ (b) 93.2 [+ or -] 19.2
Age at IQ testingb (years) 6.9 [+ or -] 1.2
Maternal characteristics
Age at delivery (b) (years) 25.4 [+ or -] 5.4
Maternal IQ (b) 88.2 [+ or -] 18.5
Education at delivery (b) (grade) 11.1 [+ or -] 2.8
HOME score (b) 37.0 [+ or -] 8.4
Married (a) 896 (7.3)
Smoked during pregnancy (a) 453 (34.1)
Alcohol use during pregnancy (a) 278 (21.2)
HOME score was standardized to preschool test. Early
childhood blood lead concentration was defined as the
mean of 6- to 24-month blood lead tests. Lifetime average
blood lead concentration was defined as the mean of blood
lead tests taken from 6 months through the concurrent
blood lead test.
(a) No. (%). (b) Mean [+ or -] SD. (c) Median (5th-95th percentiles).
Table 2. Characteristics of 1,333 children and their mothers in
seven cohort studies of environmental lead exposure and IQ.
Boston Cincinnati
Characteristic (n = 116) (n = 221)
Percent female (a) 60 (51.7) 108 (48.9)
Birth weight (b) (g) 3,412 [+ or -] 510 3,144 [+ or -] 457
Gestation at delivery 40.0 [+ or -] 1.8 39.6 [+ or -] 1.7
(b) (weeks)
Birth order (b) 1.6 [+ or -] 1.0 2.6 [+ or -] 1.4
IQ test WISC-R WISC-R
IQ score (b) 116.0 [+ or -] 14.2 87.0 [+ or -] 11.4
Age at IQ testing 10 7
(years)
Blood lead
concentrations (c)
Concurrent blood lead 5.4 7.5
(0.8-12.7) (3.5-20.0)
Peak blood lead 12.0 17.9
(5.4-27.0) (9.0-38.0)
Early childhood 8.1 12
(3.3-18.0) (6.6-26.6)
Lifetime mean 7.6 11.7
(3.6-15.2) (5.8-24.9)
Peak blood lead < 10 41 (35.3) 23 (0.4)
[micro]g/dL (a)
Peak blood lead < 7.5 13 (11.2) 1 (0.4)
[micro]g/dL (a)
Maternal characteristics
Age at delivery 30.5 [+ or -] 4.2 22.7 [+ or -] 4.3
(years) (b)
Race (nonwhite) (a) 5 (4.3) 197 (89.1)
Maternal IQ (b) 124.2 [+ or -] 16.2 75.2 [+ or -] 9.4
Education at delivery 15.2 [+ or -] 2.0 11.2 [+ or -] 1.4
(grade) (b)
HOME score (b) 50.5 [+ or -] 3.5 32.7 [+ or -] 6.2
Married (a) 107 (92.2) 30 (13.6)
Tobacco use during 29 (25.0) 111 (50.2)
pregnancy (a)
Alcohol use during 61 (52.6) 31 (14.0)
pregnancy (a)
Cleveland Mexico
Characteristic (n = 160) (n = 99)
Percent female (a) 73 (45.6) 50 (50.5)
Birth weight (b) (g) 3,199 [+ or -] 498 3,254 [+ or -] 432
Gestation at delivery 39.6 [+ or -] 1.2 40.2 [+ or -] 11.1
(b) (weeks)
Birth order (b) 2.2 [+ or -] 1.1 1.8 [+ or -] 0.9
IQ test WPPSI WISC-S
IQ score (b) 86.7 [+ or -] 16.2 107.8 [+ or -] 11.0
Age at IQ testing 4.8 7
(years)
Blood lead
concentrations (c)
Concurrent blood lead 14.2 7.0
(7.0-28.5) (3.0-16.5)
Peak blood lead 18.0 15.0
(9.0-34.0) (6.0-40.0)
Early childhood 13.4 11.4
(7.9-24.8) (4.3-26.8)
Lifetime mean 14.5 10.6
(8.1-25.3) (4.5-21.3)
Peak blood lead < 10 11 (6.9) 20 (20.2)
[micro]g/dL (a)
Peak blood lead < 7.5 1 (0.4) 8 (8.1)
[micro]g/dL (a)
Maternal characteristics
Age at delivery 22.2 [+ or -] 3.8 27.1 [+ or -] 5.9
(years) (b)
Race (nonwhite) (a) 69 (43.1) NA
Maternal IQ (b) 73.4 [+ or -] 13.2 93.4 [+ or -] 11.9
Education at delivery 10.6 [+ or -] 1.6 11.4 [+ or -] 3.5
(grade) (b)
HOME score (b) 38.1 [+ or -] 6.7 36.8 [+ or -] 6.7
Married (a) 82 (51.2) 88 (88.9)
Tobacco use during 128 (80.0) 6 (6.1)
pregnancy (a)
Alcohol use during 75 (46.9) 6 (6.1)
pregnancy (a)
Port Pirie Rochester
Characteristic (n = 324) (n = 182)
Percent female (a) 174 (53.7) 89 (48.9)
Birth weight (b) (g) 3,393 [+ or -] 502 3,226 [+ or -] 506
Gestation at delivery 39.9 [+ or -] 1.7 39.1 [+ or -] 1.8
(b) (weeks)
Birth order (b) 2.0 [+ or -] 1.1 2.4 [+ or -] 1.4
IQ test WISC-R WPPSI
IQ score (b) 106.0 [+ or -] 13.7 84.9 [+ or -] 14.4
Age at IQ testing 7 6
(years)
Blood lead
concentrations (c)
Concurrent blood lead 13.0 4.0
(6.0-24.0) (1.5-12.0)
Peak blood lead 27.0 9.0
(15.0-46.0) (3.5-23.3)
Early childhood 20.5 5.8
(11.0-33.3) (2.4-13.1)
Lifetime mean 18.6 5.5
(10.8-30.2) (2.4-12.8)
Peak blood lead < 10 0 (0.0) 103 (56.6)
[micro]g/dL (a)
Peak blood lead < 7.5 0 (0.0) 69 (37.9)
[micro]g/dL (a)
Maternal characteristics
Age at delivery 26.0 [+ or -] 4.2 24.8 [+ or -] 6.6
(years) (b)
Race (nonwhite) (a) NA 130 (71.4)
Maternal IQ (b) 94.4 [+ or -] 11.0 81.1 [+ or -] 12.6
Education at delivery 10.6 [+ or -] 1.0 12.2 [+ or -] 2.0
(grade) (b)
HOME score (b) 42.3 [+ or -] 4.6 31.9 [+ or -] 6.3
Married (a) 298 (92.0) 60 (33.2)
Tobacco use during 79 (24.6) 41 (22.6)
pregnancy (a)
Alcohol use during 82 (25.3) 9 (5.5)
pregnancy (a)
Yugoslavia
Characteristic (n = 231)
Percent female (a) 115 (49.8)
Birth weight (b) (g) 3,328 [+ or -] 526
Gestation at delivery 39.3 [+ or -] 2.9
(b) (weeks)
Birth order (b) 2.6 [+ or -] 1.7
IQ test WISC-III
IQ score (b) 74.2 [+ or -] 13.3
Age at IQ testing 7
(years)
Blood lead
concentrations (c)
Concurrent blood lead 15.9
(4.7-47.8)
Peak blood lead 23.8
(7.6-61.5)
Early childhood 14.1
(4.3-44.0)
Lifetime mean 15.8
(5.6-49.3)
Peak blood lead < 10 46 (19.9)
[micro]g/dL (a)
Peak blood lead < 7.5 11 (4.8)
[micro]g/dL (a)
Maternal characteristics
Age at delivery 26.6 [+ or -] 5.1
(years) (b)
Race (nonwhite) (a) NA
Maternal IQ (b) 87.3 [+ or -] 14.8
Education at delivery 8.8 [+ or -] 3.9
(grade) (b)
HOME score (b) 30.4 [+ or -] 6.8
Married (a) 231 (100)
Tobacco use during 59 (25.5)
pregnancy (a)
Alcohol use during 14 (6.1)
pregnancy (a)
NA, Not applicable. HOME score was standardized to preschool scale.
Concurrent blood lead tests taken at 5 years of age were used as
the concurrent blood lead test for the Boston cohort, and the IQ
test was done at 10 years. Test scores of children in the Yugoslavia
cohort are low because of adjustments in adapting tests where no
standardization existed; rather than deriving appropriate analogues,
some culturally driven items were removed, resulting in lower scores.
(a) No. (%). (b) Mean [+ or -] SD. (c) Geometric mean (5th-95th
percentiles).
Table 3. Concurrent blood lead concentration and mean IQ
scores by characteristics of children and their mothers (n = 1,333).
Median concurrent
blood lead ([micro]g/dL)
Covariate No. (5th-95th percentiles)
Child
Female 669 9.0 (2.4-31.4)
Male 664 9.9 (2.6-35.7)
Birth weight (g)
< 3,000 359 10.0 (2.2-28.7)
3,000 to < 3,500 519 9.9 (2.4-34.2)
[greater than or equal to] 3,500 455 9.1 (2.8-34.7)
Gestation at delivery (weeks)
< 38 144 8.9 (3.1-37.9)
38 to < 42 1,071 9.8 (2.5-33.2)
[greater than or equal to] 42 115 10.0 (3.2-24.8)
Birth order
1 479 9.0 (2.1-32.6)
2 407 10.0 (2.6-31.4)
[greater than or equal to] 3 446 10.0 (3.0-36.9)
Maternal
Race (only U.S. cohorts)
White 278 7.9 (1.3-22.0)
Nonwhite 401 7.1 (2.8-21.5)
Age at delivery (years)
< 25 650 10.5 (3.0-32.0)
[greater than or equal to] 25 683 9.0 (2.1-34.7)
Maternal IQ
< 85 618 10.0 (2.9-32.0)
[greater than or equal to] 85 715 9.0 (2.1-34.3)
Education at delivery (grade)
< 12 710 12.0 (4.1-35.5)
12 397 8.7 (2.4-34.3)
[greater than or equal to] 12 226 5.5 (1.1-15.2)
HOME score
< 30 276 9.4 (3.0-43.0)
30 to < 40 561 10.0 (2.8-32.2)
[greater than or equal to] 40 496 9.5 (2.0-22.0)
Married
Yes 896 10.0 (2.7-37.5)
No 436 8.1 (2.4-22.0)
Prenatal smoking
Yes 453 11.5 (3.2-33.2)
No 876 8.7 (2.2-33.6)
Prenatal alcohol ingestion
Yes 278 10.1 (2.2-25.0)
No 1,035 9.5 (2.7-34.3)
Covariate IQ [+ or -] SD
Child
Female 93.8 [+ or -] 18.3
Male 92.5 [+ or -] 20.0
Birth weight (g)
< 3,000 88.6 [+ or -] 18.0
3,000 to < 3,500 93.6 [+ or -] 19.3
[greater than or equal to] 3,500 96.3 [+ or -] 19.3
Gestation at delivery (weeks)
< 38 83.5 [+ or -] 18.6
38 to < 42 94.1 [+ or -] 18.6
[greater than or equal to] 42 96.3 [+ or -] 22.1
Birth order
1 96.7 [+ or -] 18.9
2 93.6 [+ or -] 19.2
[greater than or equal to] 3 89.0 [+ or -] 18.7
Maternal
Race (only U.S. cohorts)
White 100.6 [+ or -] 20.1
Nonwhite 84.9 [+ or -] 12.8
Age at delivery (years)
< 25 89.6 [+ or -] 17.2
[greater than or equal to] 25 96.5 [+ or -] 20.3
Maternal IQ
< 85 83.3 [+ or -] 15.0
[greater than or equal to] 85 101.6 [+ or -] 18.3
Education at delivery (grade)
< 12 90.4 [+ or -] 18.8
12 91.1 [+ or -] 17.7
[greater than or equal to] 12 105.5 [+ or -] 18.0
HOME score
< 30 77.9 [+ or -] 14.9
30 to < 40 88.3 [+ or -] 15.4
[greater than or equal to] 40 107.0 [+ or -] 15.8
Married
Yes 96.2 [+ or -] 20.5
No 87.0 [+ or -] 14.3
Prenatal smoking
Yes 89.5 [+ or -] 17.2
No 94.9 [+ or -] 19.9
Prenatal alcohol ingestion
Yes 99.3 [+ or -] 19.4
No 91.7 [+ or -] 18.8
Table 4. Mean unadjusted and adjusted (a) changes in full-scale
IQ score associated with an increase in blood lead concentration
(log scale), from the 5th to 95th percentile of the concurrent
blood lead level at the time of IQ testing.
Unadjusted Adjusted
estimates estimates
Blood lead variable [[beta] (95% CI)] [[beta] (95% CI)]
Early childhood -3.57 (-4.86 to -2.28) -2.04 (-3.27 to -0.81)
Peak -4.85 (-5.16 to -3.54) -2.85 (-4.10 to -1.60)
Lifetime average -5.36 (-6.69 to -4.03) -3.04 (-4.33 to -1.75)
Concurrent -4.66 (-5.72 to -3.60) -2.70 (-3.74 to -1.66)
Blood lead IQ deficits
concentration [5th to 95th
(5th to 95th percentile
Blood lead variable percentile, [micro]g/dL) (95% CI)]
Early childhood 4.1-34.8 4.4 (1.7-7.0)
Peak 4.0-34.5 6.1 (3.4-8.8)
Lifetime average 6.1-47.0 6.2 (3.6-8.8)
Concurrent 2.4-33.1 7.1 (4.4-9.8)
(a) Adjusted for site, HOME score, birth weight, maternal IQ,
and maternal education. The addition of child's sex, tobacco
exposure during pregnancy, alcohol use during pregnancy,
maternal age at delivery, marital status, and birth order did
not alter the estimate, and these were not included in the model.
The estimates for the covariates in the concurrent blood lead
model were HOME score ([beta] = 4.23, SE = 0.54), birth
weight/100 g ([beta] =1.53, SE = 0.35), maternal IQ ([beta] =
4.77, SE = 0.57), and maternal education ([beta] = 1.12, SE = 0.46).
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