Associations among lead dose biomarkers, uric acid, and renal function in Korean lead workers.Recent research suggests that both uric acid uric acid (y  r`ĭk), white, odorless, tasteless crystalline substance formed as a result of purine degradation in man, other primates, dalmatians, birds, snakes, and lizards. and lead may be
nephrotoxic nephrotoxic /neph·ro·tox·ic/ (nef´ro-tok?sik) destructive to kidney cells. Nephrotoxic Toxic, or damaging, to the kidney. at lower levels than previously recognized. We analyzed data from 803 current and former lead workers to determine whether lead biomarkers were associated with uric acid and whether previously reported associations between lead dose and renal outcomes were altered after adjustment for uric acid. Outcomes included uric acid, blood urea nitrogen blood urea nitrogen n. Abbr. BUN Nitrogen in the form of urea in the blood or serum, used as a indicator of kidney function. Blood urea nitrogen (BUN) , serum creatinine creatinine /cre·at·i·nine/ (kre-at´i-nin) an anhydride of creatine, the end product of phosphocreatine metabolism; measurements of its rate of urinary excretion are used as diagnostic indicators of kidney function and muscle mass. , measured and calculated creatinine clearances creatinine clearance n. The volume of serum or plasma that would be cleared of creatinine by one minute's excretion of urine. creatinine clearance , and urinary N-acetyl-[beta]-D-glucosaminidase (NAG 1. NAG - Numerical Algorithms Group. 2. NAG - The Linux Network Administrators' Guide. ) and retinol-binding protein. Mean ([+ or -] SD) uric acid, tibia tibia: see leg. lead, and blood lead levels were 4.8 [+ or -] 1.2 mg/dL, 37.2 [+ or -] 40.4 [micro]g/g bone mineral, and 32.0 [+ or -] 15.0 [micro]g/dL, respectively. None of the lead measures (tibia, blood, and dimercaptosuccinic-acid-chelatable lead) was associated with uric acid, after adjustment for age, sex, body mass index, and alcohol use. However, when we examined 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 by age on these relations, both blood and tibia lead were significantly associated ([beta] = 0.0111, p < 0.01 and [beta] = 0.0036, p = 0.04, respectively) in participants in the oldest age tertile. These associations decreased after adjustment for blood pressure and renal function In medicine (nephrology) renal function is an indication of the state of the kidney and its role in physiology. Indirect markers Most doctors use the plasma concentrations of creatinine, urea, and electrolytes to determine renal function. , although blood lead remained significantly associated with uric acid ([beta] = 0.0156, p = 0.01) when the population was restricted to the oldest tertile of workers with serum creatinine greater than the median (0.86 mg/dL). Next, in models of renal function in all workers, uric acid was significantly (p < 0.05) associated with all renal outcomes except NAG. Finally, in the oldest tertile of workers, associations between lead dose and NAG were unchanged, but fewer associations between the lead biomarkers and the clinical renal outcomes remained significant (p [less than or equal to] 0.05) after adjustment for uric acid. In conclusion, our data suggest that older workers comprise a susceptible population for increased uric acid due to lead. Uric acid may be one, but not the only, mechanism for lead-related nephrotoxicity neph·ro·tox·ic·i·ty n. The quality or state of being toxic to kidney cells. nephrotoxicity(ne·fr . Key words: kidney function, mechanisms, occupational lead exposure, renal early biologic effect markers, uric acid. doi:10.1289/ehp.7317 available via http://dx.doi.org/ [Online 30 September 2004] ********** Historically, gout gout, condition that manifests itself as recurrent attacks of acute arthritis, which may become chronic and deforming. It results from deposits of uric acid crystals in connective tissue or joints. was common among patients with lead poisoning lead poisoning or plumbism (plŭm`bĭz'əm), intoxication of the system by organic compounds containing lead. (Batuman 1993). More recently, associations between various measures of lead dose and serum uric acid (urate urate (ur´at) any salt or anion of uric acid (q.v.). u·rate n. A salt of uric acid. urate a salt of uric acid. ) levels have been reported in studies of occupationally exposed populations (Ehrlich et al. 1998; Wang et al. 2002) as well as in general population studies (Lin et al. 2002; Shadick et al. 2000). These associations are present at much lower lead doses than those associated with gout in historical lead poisoning. Lead exposure also increases the risk for adverse renal outcomes. Lead has been reported to cause nephrotoxicity by several mechanisms, although it is not known which of these is the predominant pathway (Nolan and Shaikh 1992; Sanchez-Fructuoso et al. 2002; Vaziri 2002). Uric acid is also a nephrotoxicant, and increasing evidence suggests that this toxicity occurs at lower levels than previously recognized (Johnson et al. 2003). Several adverse renal and vascular outcomes have been reported in a recently developed rodent rodent, member of the mammalian order Rodentia, characterized by front teeth adapted for gnawing and cheek teeth adapted for chewing. The Rodentia is by far the largest mammalian order; nearly half of all mammal species are rodents. model of low-level hyperuricemia hyperuricemia /hy·per·uri·ce·mia/ (-u?ri-se´me-ah) uricemia; an excess of uric acid in the blood.hyperurice´mic hy·per·u·ri·ce·mi·a n. An unusually high concentration of uric acid in the blood. , including hypertension and tubulointerstitial fibrosis (Mazzali et al. 2001a), renal afferent afferent /af·fer·ent/ (af´er-ent) 1. conveying toward a center. 2. something that so conducts, such as a fiber or nerve. af·fer·ent adj. arteriolopathy (Mazzali et al. 2002), glomerular glomerular /glo·mer·u·lar/ (glo-mer´u-ler) pertaining to or of the nature of a glomerulus, especially a renal glomerulus. glo·mer·u·lar adj. 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. , glomerulosclerosis (Nakagawa et al. 2003), and glomcrular hypertension (Sanchez-Lozada et al. 2002). More important, uric acid in this model accelerates renal dysfunction from other causes (Kang et al. 2002; Mazzali et al. 2001b). This raises the intriguing possibility that increased uric acid is tree mechanism by which lead causes nephrotoxicity. In our recently reported analyses of data from the first of three evaluations in a 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. of the health effects of inorganic lead exposure in 803 current and former lead workers (Weaver et al. 2003), we found associations between lead exposure and dose measures and adverse renal function outcomes. Lead measures were associated with decreased renal function, primarily in the oldest tertile of workers (> 46 years of age). Therefore, we analyzed data from the entire population of lead workers and conducted separate analyses of the oldest tertile of workers in some models to determine whether the lead biomarkers were associated with uric acid and whether uric acid levels were associated with renal function outcomes. In addition, we evaluated whether relations between the lead biomarkers and renal outcomes were altered after adjustment for uric acid. Materials and Methods Study overview and design. We report data from 803 current and former lead workers who completed the first of three annual evaluations in a longitudinal study of the renal, vascular, hematopoietic hematopoietic /he·ma·to·poi·et·ic/ (-poi-et´ik) 1. pertaining to hematopoiesis. 2. an agent that promotes hematopoiesis. hematopoietic 1. pertaining to or affecting the formation of blood cells. , and nervous system effects of inorganic lead exposure. Participants were evaluated between 24 October 1997 and 19 August 1999. All participants provided written, informed consent. The study protocol was approved by institutional review boards at the SoonChunHyang University Officially founded as a medical college in 1978, Soonchunhyang University is now recognized as an excellent educational renovation institution of higher education. Undergraduate programs are offered through five colleges: Humanities, Social Sciences, Natural Sciences, Engineering and the Johns Hopkins University Johns Hopkins University, mainly at Baltimore, Md. Johns Hopkins in 1867 had a group of his associates incorporated as the trustees of a university and a hospital, endowing each with $3.5 million. Daniel C. Bloomberg School of Public Health. Participation in the study was voluntary, and workers were paid approximately $30 for their time and effort. Study population. As previously described (Schwartz et al. 2001; Weaver et al. 2003), workers were recruited from 26 different plants that produced lead batteries, lead oxide, lead crystal, or radiators or were secondary lead smelters. Workers were designated as lead workers based on the potential for exposure to lead in the manufacturing process. No medical exclusionary criteria were used. Study participants were not currently occupationally exposed to other known renal toxicants. Data collection. Data collection was completed either at the Institute of industrial Medicine of the SoonChunHyang University in Chonan or at the study plants, using previously reported methods (Schwartz et al. 2001; Weaver et al. 2003). Data and biologic specimens collected included a standardized questionnaire on demographics, medical history, and occupational history; blood pressure measured with a Hawksley random zero sphygmomanometer sphygmomanometer /sphyg·mo·ma·nom·e·ter/ (sfig?mo-mah-nom´e-ter) an instrument for measuring arterial blood pressure. sphyg·mo·ma·nom·e·ter or sphyg·mom·e·ter n. (Lee et al. 2001); height and weight measurement; a blood specimen [for blood lead, blood urea nitrogen (BUN), serum creatinine, and uric acid]; a spot urine sample [for N-acetyl-[beta]-D-glucosaminidase (NAG), retinol-binding protein (RBP RBP Retinol Binding Protein RBP Regular Baptist Press RBP Retinoblastoma Binding Protein RBP Risk-Based Pricing RBP Royal Black Preceptory (Loyal Orange Lodge Offshoot) RBP Rated Burst Pressure RBP Registered Biosafety Professional ), and creatinine]; and tibia lead concentration. A 4-hr urine collection after oral administration of 10 mg/kg dimercaptosuccinic acid Dimercaptosuccinic acid, or DMSA, is the chemical compound with the formula HO2CCH(SH)CH(SH)CO2H. This colourless solid contains two carboxylic acid and two thiol groups, the latter being responsible for the mildly unpleasant odour of this dicarboxylic acid. (DMSA DMSA dimercaptosuccinic acid. ) was also obtained to measure DMSA chelatable lead and creatinine clearance (787 participants completed this collection). Laboratory methods. The lead biomarkers and renal outcomes were measured using previously reported assays (Schwartz et al. 2001; Weaver et al. 2003). In brief, blood lead was measured (Fernandez 1975) with an Hitachi 8100 Zeeman background-corrected atomic absorption spectrophotometer spectrophotometer, instrument for measuring and comparing the intensities of common spectral lines in the spectra of two different sources of light. See photometry; spectroscope; spectrum. (Hitachi Ltd. Instruments, Tokyo, Japan) at the Institute of Industrial Medicine, a certified reference laboratory for lead in South Korea. Tibia lead was assessed via a 30-min measurement of the left mid-tibia diaphysis using [sup.109]Cd in a back-scatter geometry to fluoresce fluo·resce intr.v. fluo·resced, fluo·resc·ing, fluo·resc·es To undergo, produce, or show fluorescence. [Back-formation from fluorescence. the K-shell X rays of lead. The lead X rays were recorded with a radiation detector and then quantified and compared with calibration data to estimate the concentration of lead in bone (Todd and Chettle 1994; Todd and McNeill 1993). The emitted K-shell X rays were attenuated Attenuated Alive but weakened; an attenuated microorganism can no longer produce disease. Mentioned in: Tuberculin Skin Test attenuated having undergone a process of attenuation. as they passed through bone and overlying overlying suffocation of piglets by the sow. The piglets may be weak from illness or malnutrition, the sow may be clumsy or ill, the pen may be inadequate in size or poorly designed so that piglets cannot escape. tissues. The lead X rays were therefore normalized to the amount of elastic scattering In scattering theory and in particular in particle physics, elastic scattering is one of the specific forms of scattering. In this process, the energy of the incident photon or particle (electron, positron, or neutron) is conserved and its propagating direction is changed by the from the bone itself to yield a measurement accuracy that is independent of the distance between the radiation source and the subject, subject positioning, small subject movements, overlying tissue thickness, and bone size, shape, geometry, and density (Todd 2000a, 2000b; Todd and Chettle 1994; Todd and McNeill 1993). All point estimates, including negative values, were retained in the statistical analyses in order to minimize bias and to avoid censoring censoring in epidemiology, a loss of information from a study, whether by subjects dropping out of the study or because of infrequent measurement. of data (Kim et al. 1995). Urine lead levels in the 4-hr collection were measured at the Wadsworth Center of the New York New York, state, United States New York, Middle Atlantic state of the United States. It is bordered by Vermont, Massachusetts, Connecticut, and the Atlantic Ocean (E), New Jersey and Pennsylvania (S), Lakes Erie and Ontario and the Canadian province of State Department of Health (Albany, NY, USA) by electrothermal e·lec·tro·ther·mal adj. 1. Of, relating to, or involving both electricity and heat. 2. Of or relating to the production of heat by electricity. atomic absorption spectrometry Absorption spectrometry A scientific procedure to determine chemical makeup of samples. Mentioned in: Herbalism, Traditional Chinese with Zeeman background correction (model 4100ZL; Perkin Elmer, Norwalk, CT, USA) (Parsons Parsons, city (1990 pop. 11,924), Labette co., SE Kans.; inc. 1871. It is a shipping point for dairy products, grain, and livestock. Manufactures include ammunition, wire and paper products, plastics, and appliances. and Slavin 1999). BUN, serum creatinine, and uric acid were measured via an automatic chemical analyzer (model TBA TBA See: To be announced 40FR Biochemical Analyzer; Toshiba, Tokyo, Japan). Urine creatinine was measured in spot samples (for adjustment of NAG and RBP) and in the 4-hr sample after DMSA (for determination of measured creatinine clearance and adjustment of DMSA-chelatable lead levels), using a modification of the Sigma kit (Sigma Chemical Company, St. Louis, MO, USA) assay (Weaver et al. 2000). Measured creatinine clearance was defined as [(urinary creatinine in milligrams per deciliter deciliter /dec·i·li·ter/ (dL) (des´i-le?ter) one tenth (10minus;1) of a liter; 100 milliliters. Deciliter (dL) 100 cubic centimeters (cc). Mentioned in: Hypercholesterolemia x urine volume in milliliters) / serum creatinine in milligrams per deciliter] / collection time in minutes. Calculated creatinine clearance was obtained from the Cockcroft-Gault equation (Cockcroft and Gault n. 1. (Geol.) A series of beds of clay and marl in the South of England, between the upper and lower greensand of the Cretaceous period. 1976). NAG activity (expressed in micromoles of substrate converted per hour) was measured using the PPR PPR peste des petitis ruminants. NAG test kit (PPR Diagnostics, Ltd., London, UK), and RBP was measured using a modification of the method of Topping et al. (1986). As previously reported by Weaver et al. (2003), the mean between-day coefficient of variation Coefficient of Variation A measure of investment risk that defines risk as the standard deviation per unit of expected return. (CV) for 138 random NAG samples assayed in duplicate was 6.0%; the CV for RBP was 7.4% (75 samples assayed in duplicate). Statistical analysis. The overall goal of our analysis was to develop models that would allow hypotheses to be generated regarding causal pathways involving lead, uric acid, blood pressure, and renal function. As shown in Figure 1, these variables are biologically interrelated in·ter·re·late tr. & intr.v. in·ter·re·lat·ed, in·ter·re·lat·ing, in·ter·re·lates To place in or come into mutual relationship. in . As a result, adjustment for covariates presents unique challenges. Adjustment for renal function and blood pressure likely results in overcontrol when associations between lead measures and uric acid are being evaluated. This is because renal dysfunction and elevated blood pressure are risk factors for increased uric acid (Wortmann and Kelley 2001), and both can be caused or exacerbated by lead dose; thus, they may be in the causal pathway between lead and uric acid. On the other hand, because non-lead-related factors contribute to both renal dysfunction and elevated blood pressure, lack of adjustment for these variables in such models likely results in residual 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 . The interrelatedness in·ter·re·late tr. & intr.v. in·ter·re·lat·ed, in·ter·re·lat·ing, in·ter·re·lates To place in or come into mutual relationship. in of these variables, as it relates to the potential for confounding versus causality causality, in philosophy, the relationship between cause and effect. A distinction is often made between a cause that produces something new (e.g., a moth from a caterpillar) and one that produces a change in an existing substance (e.g. , has been extensively discussed in the literature pertaining per·tain intr.v. per·tained, per·tain·ing, per·tains 1. To have reference; relate: evidence that pertains to the accident. 2. to uric acid as a risk factor for adverse cardiac, vascular, and renal outcomes (Johnson et al. 2003). Therefore, we have presented our data both with and without additional adjustment. [FIGURE 1 OMITTED] Analysis in these current and former lead workers was directed toward the following steps: a) to evaluate associations of three lead dose biomarkers (tibia lead, blood lead, and DMSA-chelatable lead) with uric acid, with and without control for blood pressure and renal function, while controlling for other covariates (Figure 2A); b) to evaluate associations between uric acid and six renal function outcomes (BUN, serum creatinine, measured creatinine clearance, calculated creatinine clearance, RBP, and NAG), with and without control for lead, while adjusting for blood pressure and other covariates (Figure 2B); and c) to determine whether relations among these lead biomarkers and the six renal outcomes were altered by adjustment for uric acid, while controlling for other covariates, including blood pressure (Figure 2C). Statistical analysis was completed using SAS (1) (SAS Institute Inc., Cary, NC, www.sas.com) A software company that specializes in data warehousing and decision support software based on the SAS System. Founded in 1976, SAS is one of the world's largest privately held software companies. See SAS System. software (SAS Institute SAS Institute Inc., headquartered in Cary, North Carolina, USA, has been a major producer of software since it was founded in 1976 by Anthony Barr, James Goodnight, John Sall and Jane Helwig. , Inc., Cary, NC, USA). [FIGURE 2 OMITTED] Initially, we examined variable distributions. The distributions of NAG and RBP showed departures from normality and were thus In-transformed; the adequacy of this transformation was subsequently confirmed by examination of the residuals from regression models. Linear regression Linear regression A statistical technique for fitting a straight line to a set of data points. modeling was used to evaluate associations between lead measures and both uric acid and renal function as outcomes, in separate models. Covariate selection for regression models of uric acid as the outcome used 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. variables [age, sex, and body mass index (BMI BMI body mass index. BMI abbr. body mass index Body mass index (BMI) A measurement that has replaced weight as the preferred determinant of obesity. ; weight in kilograms divided by the square of height in meters)] in modeling that initially included other biologically relevant variables in separate models. Variables with p-values < 0.1 were then modeled together, and those with significant p-values in the combined model were retained. The additional covariates assessed included diabetes and hypertension (both based on participant report of physician diagnosis), use of analgesics Analgesics Definition Analgesics are medicines that relieve pain. Purpose Analgesics are those drugs that mainly provide pain relief. (based on questionnaire data on medication use), work status (current vs. former lead worker), systolic Systolic The phase of blood circulation in which the heart's pumping chambers (ventricles) are actively pumping blood. The ventricles are squeezing (contracting) forcefully, and the pressure against the walls of the arteries is at its highest. and diastolic blood pressure Diastolic blood pressure Blood pressure when the heart is resting between beats. Mentioned in: Hypertension , renal function (BUN, serum creatinine, measured creatinine clearance, and calculated creatinine clearance), tobacco use, and alcohol consumption. Serum creatinine was selected as the measure of renal function in the uric acid models because the proportion of variance explained by the model when it was included ([r.sup.2]= 0.37) was the highest, compared with the other renal outcome measures. Continuous independent variables were centered at the mean or, for the effect modification models discussed below, at the tertile cut-point nearest to the mean. Covariate selection for the renal outcome models was previously reported (Weaver et al. 2003). Finally, models with cross-product terms of the lead measures and age (age was categorized cat·e·go·rize tr.v. cat·e·go·rized, cat·e·go·riz·ing, cat·e·go·riz·es To put into a category or categories; classify. cat by tertiles) were evaluated, in order to assess effect modification by age on associations between the lead biomarkers and uric acid. In these models, age was also entered into the model as a centered, continuous variable, in order to avoid residual confounding. We evaluated models for linear regression assumptions and the presence of outlying points using added variable plots (Weisberg 1985), which are graphical summaries of the relation between Y and a particular X (referred to as [X.sub.a] below), adjusted for all of the other covariates. Specifically, the residuals of the regression of Yon all of the covariates except [X.sub.a] are plotted on the y-axis. This is the part of Y not explained by those covariates. Next, the residuals from the regression of [X.sub.a] on all the other covariates are computed. This is the part of [X.sub.a] not explained by the other covariates. These residuals are plotted on the x-axis. For each plot, two lines were overlaid o·ver·laid v. Past tense and past participle of overlay1. : the regression line Noun 1. regression line - a smooth curve fitted to the set of paired data in regression analysis; for linear regression the curve is a straight line regression curve , and a line determined by a scatter plot See scatter diagram. smoothing method (lowess) that calculates a locally weighted least squares Weighted least squares is a method of regression, similar to least squares in that it uses the same minimization of the sum of the residuals: very high correlation between variables. through examination of variance inflation factors The Variance Inflation Factor (VIF) is a method of detecting the severity of Multicollinearity. More precisely, the VIF is an index which measures how much the variance of a coefficient(square of the standard error) is increased because of collinearity. and conditional indices. Results Selected demographics, exposure, and health outcome measures. Information on demographics, lead biomarkers, uric acid levels, renal function, and selected comorbid conditions is presented in Tables 1 and 2. Mean ([+ or -] SD) blood, tibia, and DMSA-chelatable lead levels were 32.0 [+ or -] 15.0 [micro]g/dL, 37.2 [+ or -] 40.4 [micro]g/g bone mineral, and 0.768 [+ or -] 0.862 mg/g creatinine, respectively. Values for these lead measures varied over a wide range. Mean values for uric acid and renal outcomes were normal, although the range for each included several abnormal outliers. Lead measure associations with uric acid levels. In linear regression modeling of uric acid levels in all 803 lead workers, after adjustment for age, sex, BMI, and alcohol use, none of the lead measures was associated (Table 3). Next, we performed regression modeling to evaluate whether age, divided into tertiles ([less than or equal to] 36 years, 36.1-46.0 years, > 46.0 years), modified relations between the lead biomarkers and uric acid levels. In models adjusted for age, sex, BMI, and alcohol use, we found evidence of effect modification by age (Table 4, method 1). Blood and tibia lead, in separate models, were associated with uric acid in participants in the oldest age tertile. As expected, because of the biologic interrelatedness of these variables (discussed in "Materials and Methods" and shown in Figures 1 and 2), both lead associations decreased after additional adjustment for systolic blood pressure Systolic blood pressure Blood pressure when the heart contracts (beats). Mentioned in: Hypertension (Table 4, method 2) and renal function (Table 4, method 3). However, blood lead remained associated with uric acid ([beta] = 0.0156, p = 0.01) when these associations were modeled in the 133 oldest workers who had serum creatinine greater than the median value Noun 1. median value - the value below which 50% of the cases fall median statistics - a branch of applied mathematics concerned with the collection and interpretation of quantitative data and the use of probability theory to estimate population (0.86 mg/dL). Associations between uric acid levels and renal outcomes. The six renal function measures were modeled as outcomes to evaluate whether uric acid was associated with renal function in this population of lead workers. Uric acid levels were associated in all renal outcome models except NAG (Table 5). Higher uric acid was associated with worse renal function as assessed by the clinical measures but, conversely, with lower RBP. These associations remained significant after the lead biomarkers were added into the models. Effect of uric acid adjustment on lead measure associations in renal function models. Associations between the lead biomarkers and the renal outcomes, after adjustment for uric acid, were modeled in the oldest tertile of workers because the associations of lead biomarkers with uric acid were in the oldest subset and the associations between higher lead dose and worse renal function were also primarily in this group. The median age of these 266 workers was 51.1 years with a range of 46.0-64.8 years. As shown in Table 6, associations between the lead measures and NAG were unchanged after adjustment for uric acid. However, fewer associations between lead biomarkers and clinical renal outcomes remained significant (p [less than or equal to] 0.05) after adjustment for uric acid. Discussion In this study, we used data from the first of three evaluations in a longitudinal study of Korean lead workers to develop hypotheses about causal pathways among lead biomarkers, uric acid, renal function, and blood pressure. First, we evaluated associations of three lead dose biomarkers with uric acid, with and without control for blood pressure and renal function, while controlling for other covariates (Figure 2A). Next, we evaluated associations between uric acid and six renal function outcomes, with and without control for lead, while adjusting for blood pressure and other covariates (Figure 2B). Finally, we examined the effect of uric acid adjustment on associations between the lead biomarkers and renal outcomes, while controlling for other covariates, including blood pressure (Figure 2C). Blood and tibia lead associations with uric acid were observed in participants in the oldest age tertile, after adjustment for age, sex, BMI, and alcohol 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. . These associations were diminished after adjustment for blood pressure and renal function, although blood lead remained significantly associated with uric acid in the 133 oldest workers who had serum creatinine greater than the median. Next, uric acid was significantly associated with all renal function outcomes except NAG. Lastly, after adjustment for uric acid, fewer associations between lead biomarkers and the clinical renal outcomes remained significant (p [less than or equal to] 0.05). It has been recognized for many years that individuals who have been heavily exposed to lead are at increased risk for both gout and 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 (Batuman 1993; Shadick et al. 2000). In high-level lead exposure, urate clearance is decreased to a greater extent than can be explained by decreased glomerular filtration alone (Emmerson and Ravenscroft 1975). A defect in tubular secretion of urate is thought to be the primary factor involved (Ball and Sorensen 1969; Emmerson 1965; Emmerson and Ravenscroft 1975), although excessive tubular reabsorption reabsorption /re·ab·sorp·tion/ (re?ab-sorp´shun) 1. the act or process of absorbing again, as the absorption by the kidneys of substances (glucose, proteins, sodium, etc.) already secreted into the renal tubules. 2. (Emmerson et al. 1971) and extrarenal mechanisms such as lead effects on porphyrin metabolism (Emmerson and Ravenscroft 1975) have also been considered. Associations between lead measures and uric acid have been examined in populations encompassing a wide range of lead doses (Table 7). Relations between lead dose and gout or uric acid have also been studied in various patient populations. Increased EDTA-chelatable lead burdens have been reported in patients who have both gout and renal disease compared with other groups such as patients with gout alone or with renal disease of known non-lead-related etiology (Batuman 1993; Miranda-Carus et al. 1997; Sanchez-Fructuoso et al. 1996). Lin et al. (2001) measured blood lead and EDTA-chelatable lead in 67 patients with chronic renal insufficiency renal insufficiency A defect in renal ability to 'clear' waste products, a sign of inadequate glomerular filtration and gout and 34 patients with chronic renal insufficiency only. Mean blood lead levels were similar in the two groups (5.4 and 4.4 [micro]g/dL, respectively), but mean EDTA-chelatable lead levels (138.1 and 64.2 [micro]g/72 hr, respectively) were significantly (p < 0.01) different. All four uric acid measures were associated with EDTA-chelatable lead after adjustment for age, sex, BMI, daily protein intake, and creatinine clearance. Next, 30 participants with chronic renal insufficiency, gout, and EDTA-chelatable lead levels between 80.2 and 361 [micro]g/72 hr were randomized ran·dom·ize tr.v. ran·dom·ized, ran·dom·iz·ing, ran·dom·iz·es To make random in arrangement, especially in order to control the variables in an experiment. to either a treatment group receiving 1 g EDTA EDTA: see chelating agents. per week for 4 weeks (n = 20) or a control group who received glucose in normal saline normal saline Physiologic saline solution, see there infusions. The two groups had similar uric acid, renal function, and lead measures prechelation. In the treated group, mean EDTA-chelatable lead declined from 159.2 to 41 [micro]g/72 hr; mean serum urate decreased from 10.2 to 8.6 mg/dL (p = 0.02 for percent change, compared with the control group), and mean urate clearance increased from 2.7 to 4.2 mL/min (p < 0.01 for percent change, compared with the control group). Mean creatinine clearance also increased from 50.8 to 54.2 mL/min (p = 0.06 for percent change, compared with the control group). Similar uric acid findings, including results from chelation Chelation The process by which a molecule encircles and binds to a metal and removes it from tissue. Mentioned in: Heavy Metal Poisoning chelation , were noted in a population of 111 participants with normal renal function, of whom 27 had gout (Linet al. 2002). The data discussed above and presented in Table 7 are generally consistent with the premise that in young, otherwise healthy workers, a higher lead dose, such as mean blood lead level > 50-60 [micro]g/dL [or perhaps higher, because neither Wang et al. (2002) nor Ehrlich et al. (1998) adjusted for blood pressure or renal function], is required before associations with uric acid are present. However, in studies that include participants with other risk Factors for elevated uric acid, such as older age or comorbid conditions, lower lead levels are associated with increases in uric acid. High levels of uric acid are known to be nephrotoxic; however, controversy exists as to whether observed relations between lower levels of uric acid and renal dysfunction are causal or due to confounding. Recently, a rodent model of hyperuricemia was developed (Mazzali et al. 2001a). As noted in the introductory remarks, a range of adverse renal and vascular outcomes, similar to those noted in humans with primary hypertension (Mazzali et al. 2002) and/or renal dysfunction (Nakagawa et al. 2003), was observed in these rats. In humans, uric acid was found to be associated with reduced renal blood flow In the physiology of the kidney, renal blood flow (RBF) is the volume of blood delivered to the kidneys per unit time. In humans, the kidneys together receive roughly 20% of cardiac output, amounting to 1 L/min in a 70-kg adult male. and increased renal vascular resistance vascular resistance, n the degree to which the blood vessels impede the flow of blood. High resistance causes an increase in blood pressure, which increases the workload of the heart. in patients with primary hypertension (Messerli et al. 1980). Thus, uric acid may be nephrotoxic at lower levels than previously recognized, as opposed to being simply a marker for other renal risk factors. Many mechanisms for the adverse affect of lead on the kidneys, either directly or through the vascular system, have been proposed (Nolan and Shaikh 1992; Sanchez-Fructuoso et al. 2002; Vaziri 2002). One mechanism not commonly considered in low to moderate lead exposure is increased uric acid. However, there are a number of similarities between the renal and vascular effects reported from low-level uric acid and those from lead exposure. Tubulointerstitial fibrosis, a classic (although nonspecific nonspecific /non·spe·cif·ic/ (non?spi-sif´ik) 1. not due to any single known cause. 2. not directed against a particular agent, but rather having a general effect. nonspecific 1. ) finding in lead exposure, has been observed in the uric acid model in the absence of the urate crystals Urate crystals Crystals formed by high levels of uric acid in the blood. Mentioned in: Gout that are commonly seen in this pathology at higher levels of hyperuricemia (Mazzali et al. 2001a). Glomerular hypertrophy was reported in hyperuricemic rodents (Nakagawa et al. 2003), and Inglis et al. (1978) reported this in adults who survived childhood lead poisoning. Afferent renal arterial thickening thick·en·ing n. 1. The act or process of making or becoming thick. 2. Material used to thicken: stir in a thickening of flour and water. 3. A thickened part. has also been observed in hyperuricemic rats (Mazzali et al. 2002). Renal vascular disease in lead-exposed humans has been reported in several case series (Inglis et al. 1978; Morgan et al. 1966; Wedeen et al. 1975). Sanchez-Fructuoso et al. (2002) recently reported hypertrophy of the medium and small renal arteries renal artery n. An artery with its origin in the aorta and with distribution to the kidney. and arterioles Arterioles Small blood vessels that carry arterial (oxygenated) blood. Mentioned in: Retinal Artery Occlusion arterioles, n in rats whose blood lead levels ranged from 52.9 to 33.2 [micro]g/dL at day 90 (when lead ingestion ceased). However, these vascular abnormalities were not observed in rats whose lead exposures, over a 12-month period, were either lower (blood lead levels ~ 20-30 [micro]g/dL) (Khalil-Manesh et al. 1993) or much higher (blood lead levels of 45.5-125.4 [micro]g/dL, averaged over a 12-month period) (Khalil-Manesh et al. 1992). Uric acid was not measured in these rodent studies; however, Goyer (1971) reported hyperuricemia that was not thought to be related to extent of renal insufficiency in lead-exposed rats, which suggests that lead may be one of the exposures that does increase uric acid in rats despite the presence of the uricase enzyme. Mazzali et al. (2001a) reported that increased systolic blood pressure was correlated with serum uric acid. Increased systolic blood pressure was associated with lead dose in the same Korean lead worker population studied in this report (Lee et al. 2001); similar associations have also been reported in other populations (Sharp et al. 1987). Increased juxtaglomerular juxtaglomerular /jux·ta·glo·mer·u·lar/ (-glo-mer´u-ler) near or next to a renal glomerulus. jux·ta·glo·mer·u·lar adj. Close to or adjoining a renal glomerulus. renin renin /re·nin/ (re´nin) a proteolytic enzyme synthesized, stored, and secreted by the juxtaglomerular cells of the kidney; it plays a role in regulation of blood pressure by catalyzing the conversion of angiotensinogen to angiotensin I. staining was present in the uric acid model (Mazzali et al. 2001a). Data suggest that lead exposure also increases renin; this effect may vary with length of exposure. Several reviews have concluded that renin is increased with short- to moderate-term lead exposure in both animals and humans but is normal or decreased with prolonged exposure (Gonick and Behari 2002; Sharp et al. 1987; Vander 1988). Decreased neuronal nitric oxide synthase neuronal nitric oxide synthase See nNOS. expression in the macula densa macula den·sa n. A densely packed group of modified epithelial cells in the distal tubule of a nephron, adjacent to the juxtaglomerular cells. was reported in rodents in the uric acid model (Mazzali et al. 2001a). In contrast, the effect of lead on NO does not involve decreased NO synthase synthase /syn·thase/ (-thas) a term used in the names of some enzymes, particularly lyases, when the synthetic aspect of the reaction is dominant or emphasized. syn·thase n. expression (Vaziri 2002). In fact, just the opposite occurs because lead exposure generates oxidants that deplete de·plete v. 1. To use up something, such as a nutrient. 2. To empty something out, as the body of electrolytes. NO, and NO synthase expression is up-regulated in response. Conclusion Our data suggest that, at the moderate levels of lead exposure present in our population, older workers comprise a susceptible population for increased uric acid. This is consistent with the published literature, as noted above. The impact of adjustment for renal function and blood pressure suggests that the effect of lead on uric acid may be mediated through these pathways (Figure 2A). However, because blood lead remained associated with uric acid in our most susceptible group (the oldest workers who had the greatest renal dysfunction), even after adjustment for renal function and blood pressure, mechanisms other than decreased glomerular filtration, such as decreased tubular secretion or even extrarenal mechanisms, may be involved at these exposure levels. Because our data [and those of others (Shadick et al. 2000)] suggest an effect of lead on uric acid beyond that due to renal dysfunction alone, and because uric acid was associated with adverse renal outcomes and resulted in reduced significance of lead biomarker associations in our population, uric acid may be one mechanism through which lead is nephrotoxic. However, this is not the only mechanism for lead-related nephrotoxicity. In our data, the association between blood lead and serum creatinine remained significant (p < 0.05) even after adjustment for uric acid. Associations between lead dose and NAG were unchanged, and uric acid was inversely associated with RBP. The effects of lead and uric acid on the NO system are also different. Thus, other mechanisms must be involved. Conclusions regarding causality in this study must be limited because it is cross-sectional. An additional limitation is that we were not able to adjust for the use of medications that influence uric acid because Koreans are not routinely provided with the names of their medications. However, few participants reported any prescription medication use. Our results do suggest that further evaluation of relations among the lead dose biomarkers, uric acid, and renal function in our longitudinal data set would be of value. This is particularly true because these mechanistic mech·a·nis·tic adj. 1. Mechanically determined. 2. Of or relating to the philosophy of mechanism, especially one that tends to explain phenomena only by reference to physical or biological causes. relations may be clinically important. EDTA chelation has been reported to improve both renal function and urate clearance in patients with renal insufficiency and gout, even when EDTA-chelatable lead body burdens were quite low (Lin et al. 2001). If this work is replicated in other populations and low-level uric acid is found to be nephrotoxic, uric acid should also be monitored in patients who are in the early stages of diseases such as early chronic renal insufficiency and whose lead body burdens are amenable to chelation. Address correspondence to B.-K. Lee, Institute of Industrial Medicine, SoonChunHyang University, 646 Eupnae-Ri, Shinchang-Myun, Asan-Si, Choongnam, 336-745 South Korea. Telephone: 82-41-530-1760. Fax: 82-41-530-1778. E-mail: leebkk@asan.sch.ac.kr We thank Y.-B. Kim, G.-S. Lee, and B.-K. Jang for assistance with data collection in South Korea. This research was supported by grants ES07198 (B.S.S.) and 2 ES07198 (V.M.W.) from 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. ; grant KRF-2000-00545 (B.-K.L.) from the Korea Research Foundation The Korea Research Foundation is a grant organization supported by the South Korean Ministry of Culture and Tourism. It provides support for research into new theories for the advancement of science, the arts, and the Korean culture in general. ; and the Richard Ross Clinician Scientist Award from the Johns Hopkins University School of Medicine The Johns Hopkins University School of Medicine, located in Baltimore, Maryland, USA, is a highly regarded medical school and biomedical research institute in the United States. (B.G.J.). The authors declare they have no competing financial interests. Received 8 June 2004; accepted 30 September 2004. REFERENCES Baker MD, Johnston JR, Maclatchy AE, Bezuidenhout BN. 1981. The relationship of serum uric acid to subclinical subclinical /sub·clin·i·cal/ (sub-klin´i-k'l) without clinical manifestations. sub·clin·i·cal adj. 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Vaziri ND. 2002, Pathogenesis of lead-induced hypertension: role of oxidative stress oxidative stress, n an imbalance of the prooxidant antioxidant ratio in which too few antioxidants are produced or ingested or too many oxidizing agents are produced. , J Hypertension 20:S15-S20. Wang VS, Lee MT, Chiou JY, Guu CF, Wu CC, Wu TN, et al. 2002. Relationship between blood lead levels and renal function in lead battery workers. Int Arch Occup Environ Health 76:569-575. Weaver VM, Buckley T, Groopman JD. 2000. Lack of specificity of trans, trans-muconic acid as a benzene benzene (bĕn`zēn, bĕnzēn`), colorless, flammable, toxic liquid with a pleasant aromatic odor. It boils at 80.1°C; and solidifies at 5.5°C;. Benzene is a hydrocarbon, with formula C6H6. biomarker after ingestion of sorbic acid-preserved foods. Cancer Epidemiol Biomarkers Prey 9:749-755. Weaver VM, Lee B-K, Ahn K-D, Lee G-S, Todd AC, Stewart WF, et al. 2003. Associations of lead biomarkers with renal function in Korean lead workers. Occup Environ Med 60:551-562. Wedeen RP, Maesaka JK, Weiner B, Lipat GA, Lyons MM, Vitale LF, et al. 1975. Occupational lead nephropathy. Am J Med 59:630-641. Weisberg S. 1985. Applied Linear Regression. New York: John Wiley John Wiley may refer to:
Wortmann RL, Kelley WN. 2001. Gout and hyperuricemia. In: Kelley's Textbook of Rheumatology rheumatology /rheu·ma·tol·o·gy/ (-tol´ah-je) the branch of medicine dealing with rheumatic disorders, their causes, pathology, diagnosis, treatment, etc. rheu·ma·tol·o·gy n. (Ruddy S, Harris ED Jr, Sledge CB, eds). 6th ed. Philadelphia: W.B. Saunders, 1339-1346. Virginia M. Weaver, (1,2) Bernard G. Jaar, (2,3) Brian S. Schwartz, (1,2,3) Andrew C. Todd, (4) Kyu-Dong Ahn, (5) Sung-Soo Lee, (5) Jiayu Wen, (1) Patrick J. Parsons, (6) and Byung-Kook Lee (5) (1) Division of Occupational and Environmental Health, Department of Environmental Health Sciences, Johns Hopkins University Bloomberg School of Public Health, Baltimore, Maryland "Baltimore" redirects here. For the surrounding county, see Baltimore County, Maryland. For other uses, see Baltimore (disambiguation). Baltimore is an independent city located in the state of Maryland in the United States. , USA; (2) Department of Medicine, Johns Hopkins University School of Medicine, Baltimore, Maryland, USA; (3) Department of Epidemiology, Johns Hopkins University Bloomberg School of Public Health, Baltimore, Maryland, USA; (4) Department of Community and Preventive Medicine preventive medicine, branch of medicine dealing with the prevention of disease and the maintenance of good health practices. Until recently preventive medicine was largely the domain of the U.S. , Mount Sinai School of Medicine
Mount Sinai School of Medicine is a medical school found in the borough of Manhattan in New York City. , New York, New York, USA; (5) Institute of Industrial Medicine, SoonChunHyang University, Asan, South Korea; (6) Lead Poisoning/Trace Elements Laboratory, Wadsworth Center, New York State Department of Health, Albany, New York For other uses, see Albany. Albany is the capital of the State of New York and the county seat of Albany County. Albany lies 136 miles (219 km) north of New York City, and slightly to the south of the juncture of the Mohawk and Hudson Rivers. , USA
Table 1. Selected demographic, exposure, and
health outcome measures (categorical variables)
of 803 current and former lead workers in South
Korea.
Characteristic No. (%)
Sex
Male 639 (79.6)
Female 164 (20.4)
Work status
Current lead worker 709 (88.3)
Former lead worker 94 (11.7)
Diabetes 6 (0.8)
Hypertension 58 (7.2)
Regular analgesic use 16 (2.0)
Alcohol use
Never 233 (29.1)
Current use 521 (65.0)
Past use 48 (6.0)
Tobacco use
Never 255 (31.8)
Current use 458 (57.1)
Past use 89 (11.1)
Table 2. Selected demographic, exposure, and health outcome measures
(continuous variables) of 803 current and former lead workers in
South Korea.
Health outcome Mean [+ or -] SD Range
Age (years) 40.4 [+ or -] 10.1 17.8-64.8
BMI (kg/[m.sup.2]) 23.0 [+ or -] 3.0 15.7-34.2
Systolic blood pressure (mm Hg) 123.2 [+ or -] 16.3 83.7-215.3
Diastolic blood pressure (mm Hg) 75.7 [+ or -] 12.0 36.0-126.7
Blood lead ([micro]g/dL) 32.0 [+ or -] 15.0 4.3-85.7
Tibia lead ([micro] Pb/g bone
mineral) 37.2 [+ or -] 40.4 -7.4-337.6
DMSA-chelatable lead (mg Pb/g
creatinine) (a) 0.768 [+ or -] 0.862 0.02-8.98
Lead job duration (years) 8.2 [+ or -] 6.5 < 1-36.2
Uric acid (mg/dL) 4.8 [+ or -] 1.2 1.4-12.3
BUN (mg/dL) 14.4 [+ or -] 3.7 6-32.2
Serum creatinine (mg/dL) 0.90 [+ or -] 0.16 0.48-2.5
Measured creatinine clearance
(mL/min) (a) 114.7 [+ or -] 33.6 11.8-338.9
Calculated creatinine clearance
(mL/min) 94.7 [+ or -] 20.7 41.1-184.5
NAG ([micro]mol/hr/g creatinine) 215.3 [+ or -] 188.5 13.8-2577.0
RBP ([micro]g/g creatinine) 63.6 [+ or -] 190.6 5.2-4658.7
(a) n = 787.
Table 3. Linear regression models to evaluate associations of lead dose
biomarkers with uric acid levels (n = 803).
[Beta]- SE
Model Lead variable coefficient [beta]
1 Tibia lead ([micro]g Pb/g bone
mineral) -0.0005 0.0010
2 Blood lead ([micro]g/dL) 0.0027 0.0027
3 DMSA-chelatable lead 0.0259 0.0431
([micro]g Pb/g creatinine)
Model
Model Lead variable p-Value [r.sup.2]
1 Tibia lead ([micro]g Pb/g bone
mineral) 0.62 0.32
2 Blood lead ([micro]g/dL) 0.32 0.31
3 DMSA-chelatable lead 0.55 0.31
([micro]g Pb/g creatinine)
Uric acid was modeled separately as the outcome, with one of the three
lead biomarkers included per model. Regression results from each model
are presented only for the association of the lead biomarker with uric
acid. Models were also adjusted for age, sex, BMI, and alcohol age.
Table 4. Linear regression models to evaluate effect modification by
age in tertiles on associations of blood and tibia lead with uric
acid in all lead workers, with outliers removed (method 1), and with
additional control for systolic blood pressure (method 2) and serum
creatinine (model 3) (n = 803).
Method 1
[beta]-
Variable coefficient SE [beta] p-Value
Blood lead model
Intercept 4.9217 0.0757 <0.01
Age (years) -0.0182 0.0039 <0.01
Systolic blood pressure (mm Hg) -- -- --
Serum creatinine (mg/dL) -- -- --
Blood lead ([micro]g/dL) 0.0111 0.0041 <0.01
Blood lead x age category 2 -0.0109 0.0057 0.05
Blood lead x age category 1 -0.0150 0.0058 0.01
Tibia lead model
Intercept 4.8932 0.0749 <0.01
Age (years) -0.0155 0.0039 <0.01
Systolic blood pressure (mm Hg) -- -- --
Serum creatinine (mg/dL) -- -- --
Tibia lead ([micro]g Pb/g bone
mineral) 0.0036 0.0018 0.04
Tibia lead x age category 2 0.0057 0.0028 0.04
Tibia lead x age category 1 0.0071 0.0029 0.02
Method 2
[beta]-
Variable coefficient SE [beta] p-Value
Blood lead model
Intercept 4.9350 0.0759 <0.01
Age (years) -0.0199 0.0040 <0.01
Systolic blood pressure (mm Hg) 0.0047 0.0023 0.04
Serum creatinine (mg/dL) -- -- --
Blood lead ([micro]g/dL) 0.0105 0.0041 0.01
Blood lead x age category 2 -0.0107 0.0056 0.06
Blood lead x age category 1 -0.0148 0.0058 0.01
Tibia lead model
Intercept 4.9087 0.0750 <0.01
Age (years) -0.0174 0.0040 <0.01
Systolic blood pressure (mm Hg) 0.0052 0.0022 0.02
Serum creatinine (mg/dL) -- -- --
Tibia lead ([micro]g Pb/g bone
mineral) 0.0031 0.0018 0.08
Tibia lead x age category 2 -0.0053 0.0028 0.06
Tibia lead x age category 1 -0.0067 0.0029 0.02
Method 3
[beta]-
Variable coefficient SE [beta] p-Value
Blood lead model
Intercept 4.8528 0.0736 <0.01
Age (years) -0.0210 0.0039 <0.01
Systolic blood pressure (mm Hg) 0.0046 0.0022 0.04
Serum creatinine (mg/dL) 2.1830 0.2666 <0.01
Blood lead ([micro]g/dL) 0.0071 0.0039 0.07
Blood lead x age category 2 -0.0063 0.0054 0.25
Blood lead x age category 1 -0.0107 0.0056 0.06
Tibia lead model
Intercept 4.8430 0.0735 <0.01
Age (years) -0.0184 0.0038 <0.01
Systolic blood pressure (mm Hg) 0.0048 0.0022 0.03
Serum creatinine (mg/dL) 2.1808 0.3189 <0.01
Tibia lead ([micro]g Pb/g bone
mineral) 0.0019 0.0017 0.28
Tibia lead x age category 2 -0.0019 0.0028 0.49
Tibia lead x age category 1 -0.0044 0.0029 0.13
--, Variable not included in method. Models were also adjusted for sex,
BMI, and alcohol use. The oldest age tertile is the reference category.
Slopes in the middle (age category 2) and youngest (age category 1)
age categories are obtained by adding their respective
[beta]-coefficients (of the cross-product term for age x lead) to the
[beta]-coefficient of the reference category (oldest age group).
p-Values for the cross-product terms reflect the statistical
significance of the difference between the slopes of the regression
line in that age category and the regression line for the oldest age
group.
Table 5. Linear regression models to evaluate associations of uric
acid with renal outcomes while controlling for covariates (n = 803).
Uric acid
[beta]-
Model Renal function outcome coefficient
1 BUN (mg/dL) 0.4186
2 Serum creatinine (mg/dL) 0.0267
3 Measured creatinine clearance (mL/min) -2.5300
4 Calculated creatinine clearance (mL/min) -2.1700
5 In NAG [ln ([micro]mol/hr/g creatinine)] -0.0262
6 In RBP [ln ([micro]g/g creatinine)] -0.1067
Model Renal function outcome SE [beta]
1 BUN (mg/dL) 0.1246
2 Serum creatinine (mg/dL) 0.0038
3 Measured creatinine clearance (mL/min) 0.9791
4 Calculated creatinine clearance (mL/min) 0.4662
5 In NAG [ln ([micro]mol/hr/g creatinine)] 0.0210
6 In RBP [ln ([micro]g/g creatinine)] 0.0254
Model Renal function outcome p-Value
1 BUN (mg/dL) <0.01
2 Serum creatinine (mg/dL) <0.01
3 Measured creatinine clearance (mL/min) 0.01
4 Calculated creatinine clearance (mL/min) <0.01
5 In NAG [ln ([micro]mol/hr/g creatinine)] 0.21
6 In RBP [ln ([micro]g/g creatinine)] <0.01
Each renal outcome was modeled separately. Regression results from each
model are presented only for the association of uric acid with the
renal outcome. BUN, serum creatinine, measured creatinine clearance,
and calculated creatinine clearance models were adjusted for age,
sex, BMI, current/former worker status, and hypertension. NAG and
RBP models were adjusted for age, sex, BMI, systolic blood pressure,
current/former worker status, alcohol ingestion, and diabetes.
Table 6. Linear regression models to evaluate associations of lead dose
biomarkers and uric acid levels with renal outcomes in 266 lead workers
in the oldest tertile of age.
Method 1
(lead biomarker models)
[beta]
coeffi-
Independent variables cient SE [beta] p-Value
BUN (mg/dL) models
Blood lead ([micro]g/dL) 0.0352 0.0183 0.05
Uric acid (mg/dL) -- -- --
Serum creatinine (mg/dL)
models
Blood lead ([micro]g/dL) 0.0016 0.0006 <0.01
Uric acid (mg/dL) -- -- --
Tibia lead ([micro]g Pb/g bone 0.0004 0.0002 0.03
mineral)
Uric acid (mg/dL) -- -- --
Measured creatinine clearance
(mL/min) models
Blood lead ([micro]g/dL) 0.1187 0.1177 0.31
Uric acid (mg/dL) -- -- --
Calculated creatinine clearance
(mL/min) models
Blood lead ([micro]g/dL) -0.1221 0.0594 0.04
Uric acid (mg/dL) -- -- --
In NAG [In ([micro]mol/hr/g
creatinine)] models
Blood lead ([micro]g/dL) 0.0089 0.0028 <0.01
Uric acid (mg/dL) -- -- --
Tibia lead ([micro]g Pb/g 0.0023 0.0008 <0.01
bone mineral)
Uric acid (mg/dL) -- -- --
DMSA-chelatable lead (mg 0.1931 0.0511 <0.01
Pb/g creatinine)
Uric acid (mg/dL) -- -- --
Method 2
(uric acid models)
[beta]
coeffi-
Independent variables cient SE [beta] p-Value
BUN (mg/dL) models
Blood lead ([micro]g/dL) -- -- --
Uric acid (mg/dL) 0.4663 0.2307 0.04
Serum creatinine (mg/dL)
models
Blood lead ([micro]g/dL) -- -- --
Uric acid (mg/dL) 0.0245 0.0072 <0.01
Tibia lead ([micro]g Pb/g bone -- -- --
mineral)
Uric acid (mg/dL) 0.0246 0.0072 <0.01
Measured creatinine clearance
(mL/min) models
Blood lead ([micro]g/dL) -- -- --
Uric acid (mg/dL) -2.4871 1.4456 0.09
Calculated creatinine clearance
(mL/min) models
Blood lead ([micro]g/dL) -- -- --
Uric acid (mg/dL) -2.0384 0.7487 <0.01
In NAG [In ([micro]mol/hr/g
creatinine)] models
Blood lead ([micro]g/dL) -- -- --
Uric acid (mg/dL) -0.0115 0.0364 0.76
Tibia lead ([micro]g Pb/g -- -- --
bone mineral)
Uric acid (mg/dL) -0.0070 0.0366 0.85
DMSA-chelatable lead (mg -- -- --
Pb/g creatinine)
Uric acid (mg/dL) -0.0182 0.0373 0.63
Method 3
(uric acid models)
[beta]
coeffi-
Independent variables cient SE [beta] p-Value
BUN (mg/dL) models
Blood lead ([micro]g/dL) 0.0293 0.0185 0.11
Uric acid (mg/dL) 0.3963 0.2343 0.09
Serum creatinine (mg/dL)
models
Blood lead ([micro]g/dL) 0.0012 0.0006 0.03
Uric acid (mg/dL) 0.0215 0.0073 <0.01
Tibia lead ([micro]g Pb/g bone 0.0003 0.0002 0.06
mineral)
Uric acid (mg/dL) 0.0233 0.0072 <0.01
Measured creatinine clearance
(mL/min) models
Blood lead ([micro]g/dL) 0.1697 0.1198 0.16
Uric acid (mg/dL) -2.9352 1.4769 0.05
Calculated creatinine clearance
(mL/min) models
Blood lead ([micro]g/dL) -0.0950 0.0600 0.11
Uric acid (mg/dL) -1.8095 0.7604 0.02
In NAG [In ([micro]mol/hr/g
creatinine)] models
Blood lead ([micro]g/dL) 0.0092 0.0028 <0.01
Uric acid (mg/dL) -0.0289 0.0361 0.42
Tibia lead ([micro]g Pb/g 0.0023 0.0008 <0.01
bone mineral)
Uric acid (mg/dL) -0.0094 0.036 0.80
DMSA-chelatable lead (mg 0.1944 0.0512 <0.01
Pb/g creatinine)
Uric acid (mg/dL) -0.0235 0.0363 0.52
BUN, serum creatinine, measured creatinine clearance, and calculated
creatinine clearance models were also adjusted for age, sex, BMI,
current/former worker status, and hypertension. NAG and RBP models
were adjusted for age, sex, BMI, systolic blood pressure,
current/former worker status, alcohol ingestion, and diabetes.
Only models in which p [less than or equal to] 0.05 for the lead
variable without uric acid adjustment are shown, with the exception
of the measured creatinine clearance model; this model is included
because the p-value for the [beta]-coefficient of the uric acid
variable decreased to [less than or equal to] 0.05 after adjustment
for blood lead.
Table 7. Summary of selected publications (a) that have evaluated lead
measure associations with uric acid.
Mean age Mean blood
Study No. (years) or bone lead (b)
Wang et al. 2002 229 65% 67.7 [micro]g/dL, males
<40 48.6 [micro]g/dL, females
Ehrlich et al. 1998 382 41 53.5 [micro]g/dL
69.7 [micro]g/g
Roels et al. 1994 76 (c) 44 43.0 [micro]g/dL; 66
[micro]g/g
68 (d) 43 14.1 [micro]g/dL; 21
[micro]g/g
Baker et al. 1981 318 36 (e) 22.4 [micro]g/[dL.sup.e]
37 (f) 24.0 [micro]g/[dL.sup.f]
Smith et al. 1995 691 48 7.8 [micro]g/dL
Shadick et al. 2000 777 67 5.9 [micro]g/dL
30.2 [micro]g/g patella
20.8 [micro]g/g tibia
p-Value of
Study Association lead measure
Wang et al. 2002 10 [micro]g/dL increase in 0.02
blood lead associated with a
0.085 mg/dL increase in
uric acid
Ehrlich et al. 1998 Current and historical blood [less than or
lead in quintiles associated equal to] for
with uric acid trend
Roels et al. 1994 Continuous lead measures NS
(workers plus controls)
with uric acid
Baker et al. 1981 Continuous blood lead with NS
uric acid
Smith et al. 1995 Continuous blood lead with NS
uric acid
Shadick et al. 2000 Blood lead and uric acid 0.1
Patella lead and uric acid 0.02
Tibia lead and uric acid 0.06
Covariates
Study controlled for Comments
Wang et al. 2002 Sex and body weight Alcohol apparently
not significant
Ehrlich et al. 1998 Age, height, and Tibia lead measured
weight on a random sample
of 40 participants
Roels et al. 1994 Not reported
Baker et al. 1981 Age
Smith et al. 1995 Age, alcohol, ALAD
Shadick et al. 2000 Age, BMI, diastolic Normative Aging
blood pressure, Study
alcohol, serum
creatinine
Abbreviations: ALAD, [delta]-aminolevulinic acid dehydrase; NS, not
significant.
(a) Based on sample size and extent of statistical analysis.
(b) [micro]g/g indicates tibia lead per bone mineral unless noted as
patella. (c) Lead workers. (d) Controls. (e) Rural residence.
(f) Urban residence.
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