Diagnostic Chelation Challenge with DMSA: A Biomarker of Long-Term Mercury Exposure?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 challenge testing has been used to assess the body burden of various metals. The best-known example is EDTA EDTA: see chelating agents. challenge in lead-exposed individuals. This study assessed diagnostic chelation challenge with 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. ) as a measure of mercury body burden among mercury-exposed workers. Former employees at a chloralkali plant, for whom detailed exposure histories were available (n = 119), and unexposed controls (n = 101) completed 24-hr urine collections before and after the administration of two doses of DMSA, 10 mg/kg. The urinary response to DMSA was measured as both the absolute change and the relative change in mercury excretion excretion, process of eliminating from an organism waste products of metabolism and other materials that are of no use. It is an essential process in all forms of life. In one-celled organisms wastes are discharged through the surface of the cell. . The average 24-hr mercury excretion was 4.3 [micro]g/24 hr before chelation, and 7.8 [micro]g/24 hr after chelation. There was no association between past occupational mercury exposure and the urinary excretion of mercury either before or after DMSA administration. There was also no association between urinary mercury excretion and the number of dental amalgam dental amalgam Dentistry A filling material that contains up to 50% mercury, silver and other metals. See Alternative dentistry, Fluoridation, Gutta percha, Mercury. surfaces, in contrast to recent published results. We believe the most likely reason that DMSA chelation challenge failed to reflect past mercury exposure was the elapsed time e·lapsed time n. The measured duration of an event. Noun 1. elapsed time - the time that elapses while some event is occurring (several years) since the exposure had ended. These results provide normative values for urinary mercury excretion both before and after DMSA challenge, and suggest that DMSA chelation challenge is not useful as a biomarker biomarker /bio·mark·er/ (bi´o-mahr?ker) 1. a biological molecule used as a marker for a substance or process of interest. 2. tumor marker. bi·o·mark·er n. 1. of past mercury exposure. Key words: biomarkers, chelation, chloralkali, DMSA, environmental diseases, mercury, neurotoxicity neurotoxicity /neu·ro·tox·ic·i·ty/ (noor?o-tok-sis´it-e) the quality of exerting a destructive or poisonous effect upon nerve tissue. , occupational diseases, renal toxicity, succimer. Environ Health Perspect 109:167-171 (2001). [Online 25 January 2001] http://ehpnet1.niehs.nih.gov/docs/2001/109p167-171frumkin/abstract.html Assessment of biological exposure is a key challenge in evaluating metal toxicity, for both clinicians and epidemiologists. Blood and urine measurements traditionally have been used, but these have several shortcomings A shortcoming is a character flaw. Shortcomings may also be:
Because chelating agents chelating agents (kē`lātĭng). Certain organic compounds are capable of forming coordinate bonds (see chemical bond) with metals through two or more atoms of the organic compound; such organic compounds are called chelating agents. bind metals and promote their urinary excretion, theoretically they can be used in challenge tests to assess metal levels. The rationale for diagnostic chelation challenge is straightforward: If a person has an elevated body burden of a metal, then administration of a chelating agent chelating agent a substance which combines with a metallic ion to produce an inert chelate, e.g. ethylenediamine tetra-acetic acid, penicillamine. should cause a short-term increase in the urinary excretion of that metal. The most commonly used chelation challenge test has been EDTA administration following lead exposure (6,7), although British Anti-Lewisite Brit·ish anti-lewisite n. See dimercaprol. and penicillamine penicillamine /pen·i·cil·la·mine/ (pen?i-sil´ah-men) a degradation product of penicillin that chelates certain heavy metals and also binds cystine and promotes its excretion; used in the treatment of Wilson's disease, cystinuria, have also been used (8). More recently, attention has focused on dimercaptosuccinic acid (DMSA), or succimer, a chelating agent approved by the U.S. Food and Drug Administration (U.S. FDA FDA abbr. Food and Drug Administration FDA, n.pr See Food and Drug Administration. FDA, n.pr the abbreviation for the Food and Drug Administration. ) in 1991 for the treatment of pediatric pediatric /pe·di·at·ric/ (pe?de-at´rik) pertaining to the health of children. pe·di·at·ric adj. Of or relating to pediatrics. lead toxicity. DMSA is used primarily in the treatment of metal toxicity, rather than in diagnosis. The most common therapeutic use has been in treating lead toxicity (9-11), but DMSA has also been used to treat a variety of other metal overexposures (12-14). Besides its treatment role, DMSA offers considerable diagnostic potential as a chelation challenge agent. First, it is convenient: DMSA is an oral agent, whereas EDTA must be administered parenterally par·en·ter·al adj. 1. Physiology Located outside the alimentary canal. 2. Medicine Taken into the body or administered in a manner other than through the digestive tract, as by intravenous or intramuscular . Second, DMSA has an excellent safety profile. Third, DMSA has been shown to mobilize a range of metals effectively in both animals and humans. Fourth, DMSA acts quickly. The blood concentration of DMSA peaks in 3 hr, and the half-life is 3.2 hr (15). DMSA-induced excretion of both lead (16) and mercury (17) peaks within 2 hr. In the clinical setting, chelation challenge would therefore require urinary collection only over several hours. For these reasons, DMSA chelation challenge could be a convenient, safe approach to assessing the biological burden of various metals. Indeed, DMSA chelation challenge has been used in several studies (16,18,19) and in clinical settings to assess lead burden. Another metal that might be assessed in this way is mercury. DMSA mobilizes mercury effectively in both animals (20-25) and in humans (8,17,26-31). However, unlike lead, mercury undergoes relatively little bioaccumulation bi·o·ac·cu·mu·la·tion n. The increase in the concentration of a substance, especially a contaminant, in an organism or in the food chain over time. . It is excreted with a half-life of 1-2 months (17,32-35). This suggests that the primary use of DMSA chelation challenge for mercury would occur in the first weeks after exposure. However, a long terminal elimination phase has been described (36), with mercury retention in nervous system, kidneys, and other soft tissues. Consequently, there could also be a role for DMSA chelation challenge some time after mercury exposure, especially if exposure had been prolonged and intense. Support for this notion comes from animal evidence (37) that DMSA draws mercury with special avidity avidity /avid·i·ty/ (ah-vid´i-te) 1. the strength of an acid or base. 2. in immunology, an imprecise measure of the strength of antigen-antibody binding based on the rate at which the complex is formed. Cf. from the kidneys--an important mercury storage site known to have a relatively slow turnover (38). Indeed, DMSA chelation challenge has been used clinically on a limited basis following mercury exposure (15,26,39). A related agent used in Europe, 2,3-dimercaptopropane-1-sulfonic acid (DMPS DMPS dimercaptopropane sulfonate DMPS Defense Meteorological Satellite Program DMPS Dual Modular Power System DMPS Device Manager Proxy Stub ), has been used in a similar manner (40,41). At present the interpretation of DMSA challenge tests for mercury is difficult because we lack reliable data on ,the normal range of mercury excretion in unexposed people following DMSA, the expected range of elevations following mercury exposure, the correlation between DMSA response and other measures of mercury exposure, and the clinical significance of elevations. Such data would be necessary to validate the DMSA chelation challenge response as a practical, informative biomarker of mercury exposure. In this paper we report a study of DMSA chelation challenge testing among workers with long-term, high-level exposure to mercury in a chloralkali plant and among a comparison population of unexposed workers. Methods Study subjects. This study was conducted as part of a larger study of the health effects of mercury among former employees of a chloralkali plant in Brunswick, Georgia Brunswick is a city in the U.S. state of Georgia and the county seat of Glynn CountyGR6. It is a major port city on the Atlantic Coast. It is the principal city of the 'Brunswick, Georgia Metropolitan Statistical Area' which encompasses all of Brantley, (42). The plant had operated from 1956 to 1994. We identified 221 former employees who had worked in the plant for at least a year, who were still alive at the time of the study in 1998, and who could be contacted. We also identified a large pool of unexposed persons who worked for three local employers: a local government, a quasi-governmental tourist authority, and a paper company. Individuals from this pool were selected according to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. a scheme that matched their age-race-sex distribution to that of the exposed subjects, and were invited to participate in the study. Participation consisted of completing a detailed questionnaire, physical examination, neurological neurological, neurologic pertaining to or emanating from the nervous system or from neurology. neurological assessment evaluation of the health status of a patient with a nervous system disorder or dysfunction. and neurobehavioral testing, and blood and urine testing, in addition to the portions of the study specifically related to the chelation challenge. These elements of the study are reported in detail in the companion paper (42). Of note, the questionnaire and physical examination were designed to assess several sources of exposure to mercury. The questionnaire asked about other occupational sources of mercury exposure and about dietary sources, including fish. The physical examination included a count of the number of tooth surfaces The tooth surface (flank) forms the side of a gear tooth.1 It is convenient to choose one face of the gear as the reference face and to mark it with the letter “I”. The other non-reference face might be termed face “II”. with mercury amalgam fillings. We performed an extensive exposure assessment as part of the larger study. Using personnel records, we recorded each former employee's job history within the plant. We also identified the air mercury exposure levels at each part of the plant, for each job title, for each year of the plant's operation. These estimates, generated from historical air sampling data, were validated by comparison with available urinary mercury sampling and with modeled air levels based on mercury throughput data and room air change parameters (43). We then created a job-exposure-year matrix and reconstructed an exposure profile for each former employee. We used three metrics of exposure: average exposure (in micrograms per cubic meter Noun 1. cubic meter - a metric unit of volume or capacity equal to 1000 liters cubic metre, kiloliter, kilolitre metric capacity unit - a capacity unit defined in metric terms ), cumulative exposure (in micrograms per cubic meter per year), and peak exposure (in micrograms per cubic meter). Mercury exposure had been high in the cell room and in other parts of the plant, with air levels averaging above 100 [micro]g/[m.sup.3] for some employees (43), comparable to the exposures reported from contemporary chloralkali plants (44-46). Sample collection and analysis. Each subject collected a baseline 24-hr urine sample. Approximately 2 weeks later the subjects returned for a second test session. At that time we administered two doses of DMSA, 10 mg/kg, at 8-hr intervals. Each subject commenced a second 24-hr urine collection at the time of the first dose. Both urine collections, the baseline and the post-DMSA, used plastic containers provided by the Centers for Disease Control and Prevention Centers for Disease Control and Prevention (CDC), agency of the U.S. Public Health Service since 1973, with headquarters in Atlanta; it was established in 1946 as the Communicable Disease Center. (CDC See Control Data, century date change and Back Orifice. CDC - Control Data Corporation ; Atlanta, GA); all lots were tested to confirm that they were metal-free. Both the baseline and the post-DMSA urine samples were kept refrigerated re·frig·er·ate tr.v. re·frig·er·at·ed, re·frig·er·at·ing, re·frig·er·ates 1. To cool or chill (a substance). 2. To preserve (food) by chilling. during the collection and were returned on the day the collection was completed (or, in rare cases, on the following day). We measured the volume of each 24-hr collection and then decanted approximately 50 mL into metal-free plastic specimen containers for transfer to the laboratory. The specimens were kept refrigerated throughout. If a 24-hr urine collection had a volume [is less than] 500 mL or a total 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. [is greater than] 700 mg it was considered incomplete and was excluded. On each sample we measured the creatinine and the mercury levels. All measurements were performed at the laboratories of the CDC National Center for Environmental Health in Atlanta. We measured mercury in undigested urine by cold vapor atomic absorption analysis based on the method of Littlejohn et al. (47) using modified reagents as described by Greenwood et al. (48). Standard quality-assurance procedures, including replicate testing and the use of blanks and standards, were followed. Urinary mercury concentration was standardized to creatinine concentration and expressed in units of milligrams per gram creatinine. Data analysis. We considered three metrics of urinary mercury response to DMSA: the absolute amount of mercury excreted in response to DMSA (in micrograms per 24 hr), the change in mercury excreted following DMSA (postchelation mercury excretion minus baseline mercury excretion, in micrograms per 24 hr, henceforth From this time forward. The term henceforth, when used in a legal document, statute, or other legal instrument, indicates that something will commence from the present time to the future, to the exclusion of the past. referred to as difference), and the ratio of the mercury output in the second collection to the mercury output in the first collection, henceforth referred to as the ratio. We characterized the distribution of each variable among the exposed and the unexposed, and the entire study group. We then undertook four analyses to assess the association between mercury exposure and chelation response. First, we examined the correlation of exposure ranks and chelation challenge response ranks. We reasoned that if exposure were associated with chelation challenge response, the subjects exposed most heavily would have some of the highest chelation challenge response ranks and, similarly, that those with the most active response to chelation challenge would have some of the highest exposure ranks. We therefore identified the 15 most heavily exposed former workers, according to each of the three exposure metrics we used (average, cumulative, and peak exposure), arrayed them according to their exposure ranks, and observed their chelation challenge response ranks. Conversely, we identified the 15 most active responders to chelation challenge, in terms of both difference and ratio, arrayed them according to their chelation challenge response ranks, and observed their exposure ranks. Second, in a more formal assessment of this correlation, we calculated the Spearman spear·man n. A man, especially a soldier, armed with a spear. rank--order correlation coefficients Correlation Coefficient A measure that determines the degree to which two variable's movements are associated. The correlation coefficient is calculated as: for the association between exposure and chelation challenge response, using ranks. We selected this nonparametric test because not all variables were normally distributed. We repeated this analysis for three metrics of exposure--cumulative, mean, and peak--and for two metrics of chelation challenge response--difference and ratio--producing six correlation coefficients. Third, in an extension of this approach, we carried out multiple linear regression Linear regression A statistical technique for fitting a straight line to a set of data points. , with occupational mercury exposure and number of dental amalgam surfaces as independent variables, and chelation challenge response as the dependent variable. In this analysis, the occupational mercury exposure was set at zero for all unexposed subjects. To satisfy the linear regression assumption that the residuals follow a normal distribution, both metrics of chelation challenge response--difference and ratio--were transformed. Van der Waerden's transformation into the normalized rank was applied to the difference, and the ratio was transformed using the natural logarithm Natural logarithm Logarithm to the base e (approximately 2.7183). . This regression was run on the combined group of exposed and unexposed subjects, and on the exposed and unexposed subsets separately. Finally, because a possible association might be apparent only in subjects with relatively recent exposure, we repeated all analyses, restricting them to those former employees whose employment had lasted into the five years before our testing. Results Of the 221 eligible former employees of the chloralkali plant, 156 participated completely or partly in the study. There were nine subjects with diabetes, one with renal failure renal failure n. Acute or chronic malfunction of the kidneys resulting from any of a number of causes, including infection, trauma, toxins, hemodynamic abnormalities, and autoimmune disease, and often resulting in systemic symptoms, especially edema, , and 27 who did not provide two usable 24-hr urine collections or who had missing data, leaving 119 exposed subjects. Of the 190 unexposed subjects invited to participate based on the age-race-sex distribution of the former employees, 138 participated. There were two unexposed subjects with diabetes, and 35 who did not provide two usable 24-hr urine collections or who had missing data, leaving 101 unexposed subjects. The results are based on data from these two groups. The exposed workers who participated in the chelation study had an exposure profile virtually identical to that of the larger population of exposed workers, as reported elsewhere (42). The mean duration of exposure was 7.0 years, and the mean time since last exposure was 6.1 years. The mean workplace mercury exposure level was 33.8 [micro]g/[m.sup.3], the mean of the peak exposure levels was 71.9 [micro]g/[m.sup.3], and the mean cumulative exposure was 236.8 [micro]g/[m.sup.3]-years. Table 1 shows data on urinary mercury for the exposed and unexposed groups. Although the exposed workers tend to have greater mercury excretion than the unexposed workers, the differences do not reach statistical significance. Among the exposed workers, only one subject had a relatively high postchelation urinary mercury output; otherwise the distributions of the exposed and unexposed subjects were nearly identical.
Table 1. Mercury excretion before and after DMSA chelation.
Exposed Unexposed
Values (n = 119) (n = 101)
Baseline values
Urinary Hg concentration,
uncorrected ([micro]g
Hg/L)
Group mean [+ or -] SD 3.37 [+ or -] 2.51 2.89 [+ or -] 2.18
95% value 9.0 6.5
Maximum value 18.2 12.8
Urinary Hg concentration,
corrected ([micro]g Hg/g
creatinine)
Group mean [+ or -] SD 2.74 [+ or -] 2.05 2.26 [+ or -] 1.92
95% value 7.00 5.62
Maximum value 11.75 11.82
24-hr Hg excretion
([micro]g/24 hr)
Group mean [+ or -] SD 4.61 [+ or -] 3.85 3.94 [+ or -] 3.43
Maximum value 21.84 22.4
Postchelation values
24-hr Hg excretion
([micro]g/24 hr)
Group mean [+ or -] SD 7.87 [+ or -] 5.85 7.73 [+ or -] 5.58
Maximum value 46.81 27.94
Change in 24-hr Hg
excretion (post-DMSA-
baseline,
[micro]g/24 hr)
Group mean [+ or -] SD 3.25 [+ or -] 5.96 3.80 [+ or -] 5.53
Range -14.59, 39.66 -10.70, 25.39
Ratio of post-DMSA Hg
excretion to baseline
mercury excretion(a)
Group mean [+ or -] SD 2.40 [+ or -] 2.25 2.77 [+ or -] 2.58
Range 0.23, 16.66 0.26, 18.29
p-Value
for
Values difference
Baseline values
Urinary Hg concentration,
uncorrected ([micro]g
Hg/L)
Group mean [+ or -] SD 0.13
95% value
Maximum value
Urinary Hg concentration,
corrected ([micro]g Hg/g
creatinine)
Group mean [+ or -] SD 0.08
95% value
Maximum value
24-hr Hg excretion
([micro]g/24 hr)
Group mean [+ or -] SD 0.17
Maximum value
Postchelation values
24-hr Hg excretion
([micro]g/24 hr)
Group mean [+ or -] SD 0.87
Maximum value
Change in 24-hr Hg
excretion (post-DMSA-
baseline,
[micro]g/24 hr)
Group mean [+ or -] SD 0.48
Range
Ratio of post-DMSA Hg
excretion to baseline
mercury excretion(a)
Group mean [+ or -] SD 0.27
Range
(a) Excludes one unexpected subject whose baseline Hg excretion was 0.
Tables 2 and 3 show the results of the rank correlation In statistics, rank correlation is the study of relationships between different rankings on the same set of items. It deals with measuring correspondence between two rankings, and assessing the significance of this correspondence. analysis. These tables show data only for the exposed subjects, each of whom was ranked on several metrics of exposure and on the urinary mercury response to chelation. Table 2 shows the 15 highest-ranking subjects in terms of exposure (expressed in three ways: cumulative, mean, and peak exposure), with their respective ranks on chelation challenge response (expressed in two ways: as post/pre-chelation absolute difference and as the post:pre ratio). Table 3 shows the reverse: the 15 highest-ranking postchelation mercury excreters (expressed in two ways), with their respective exposure ranks (expressed in three ways). Because there are three exposure metrics and two metrics of chelation challenge response, each panel of the table shows six comparisons. In each case, visual inspection reveals that many of the highest-scoring subjects for one parameter had low scores on the other parameter.
Table 2. Association of exposure ranks and chelation challenge
response ranks among the most heavily exposed subjects.
Cumulative
exposure Mean exposure
Exposure
rank Difference Ratio Difference Ratio
1 12 11 1 6
2 15 8 56 49
3 80 86 71 64
4 36 15 109 114
5 74 81 88 59
6 19 33 23 29
7 96 91 14 19
8 16 37 69 85
9 70 74 35 34
10 111 108 39 70
11 5 16 103 100
12 54 7 31 39
13 4 3 19 33
14 81 89 38 57
15 75 56 93 96
Peak exposure
Exposure
rank Difference Ratio
1 80 86
2 4 3
3 15 8
4 74 81
5 22 43
6 19 33
7 12 11
8 96 91
9 38 57
10 73 83
11 69 85
12 20 4
13 14 19
14 39 70
15 28 25
n = 119; ranks can range between 1 and 119.
Table 3. Association of exposure ranks and chelation challenge
response ranks among subjects with the highest chelation challenge
ranks.
Difference Ratio
Chelation
challenge
rank Cumulative Mean Peak Cumulative Mean Peak
1 99 1.0 26.0 59 88.0 71.5
2 59 88.0 71.5 48 101.0 103.0
3 32 87.0 78.5 13 27.0 4.5
4 13 27.0 4.5 66 30.0 11.5
5 11 55.0 18.5 69 38.0 53.5
6 94 66.0 103.0 99 1.0 26.0
7 100 89.5 94.0 12 20.5 18.5
8 48 101.0 103.0 2 49.0 4.5
9 69 38.0 53.5 100 89.5 94.0
10 73 108.0 97.0 31 36.0 46.5
11 27 93.0 93.0 1 24.0 4.5
12 1 24.0 4.5 19 58.0 51.0
13 74 48.0 86.0 104 40.0 63.5
14 29 7.0 11.5 94 66.0 103.0
15 2 49.0 4.5 4 47.0 46.5
n = 119; ranks can range between 1 and 119.
The analysis whose results appear in Tables 2 and 3 was limited to exposed subjects, since only they were eligible to be ranked on both exposure and chelation challenge response. However, we also constructed an alternative version of Table 3 that included unexposed subjects (data not shown). Of the top-scoring subjects in terms of chelation challenge response, eight (using the difference score) or nine (using the ratio score) were unexposed. Thus, more than half of the most active responders to chelation challenge had no history of occupational mercury exposure. Table 4 shows the Spearman rank-order correlation coefficients Noun 1. rank-order correlation coefficient - the most commonly used method of computing a correlation coefficient between the ranks of scores on two variables rank-difference correlation, rank-difference correlation coefficient, rank-order correlation for the associations between exposure and chelation challenge response. Two of the results--for the difference scores correlated with average and peak exposure--reached marginal statistical significance (p = 0.05 and 0.04, respectively). However, multiple comparisons were made, and a Bonferroni correction In statistics, the Bonferroni correction states that if an experimenter is testing n independent hypotheses on a set of data, then the statistical significance level that should be used for each hypothesis separately is 1/n procedure would reduce the statistical significance of these two results.
Table 4. Correlation coefficients for the association
between exposure and chelation challenge response.
Difference Ratio
CC p-Value CC p-Value
Cumulative 0.128 0.17 0.100 0.28
Mean 0.179 0.05 0.135 0.14
Peak 0.190 0.04 0.127 0.17
CC, correlation coefficient.
The multiple linear regression analysis, including both exposure scores and dental amalgam surfaces as independent variables, showed no significant associations between any measure of exposure and chelation challenge response (Table 5). There was a significant association between the number of dental amalgam surfaces and the chelation challenge when the two groups, exposed and unexposed, were analyzed together. However, this association went in the unexpected direction: More amalgam surfaces were associated with a lower post/pre ratio. When exposed and unexposed subjects were analyzed separately, the number of amalgam surfaces was not significantly associated with the chelation challenge response (data not shown).
Table 5. Occupational Hg exposure and dental amalgam surfaces as
predictors of chelation challenge response: results of linear
regression.
Hg exposure
Coefficient p-Value
Difference in Hg excretion
after and before chelation
Cumulative 0.0002 0.67
Mean 0.0022 0.45
Maximum 0.0010 0.51
Ratio of Hg excretion
after to before chelation
Cumulative 0.0001 0.83
Mean 0.0003 0.88
Maximum 0.0001 0.94
Dental amalgam
surfaces
Coefficient p-Value
Difference in Hg excretion
after and before chelation
Cumulative -0.0098 0.36
Mean -0.0095 0.37
Maximum -0.0096 0.37
Ratio of Hg excretion
after to before chelation
Cumulative -0.0182 0.03
Mean -0.0184 0.03
Maximum -0.0184 0.03
Finally, when we repeated the analyses including only the 88 former workers who had been employed within the 5 years before the study, we found no significant associations between any measure of occupational mercury exposure and any measure of chelation challenge response. In particular, the two borderline borderline /bor·der·line/ (-lin) of a phenomenon, straddling the dividing line between two categories. borderline statistically significant findings shown in Table 2 became nonsignificant non·sig·nif·i·cant adj. 1. Not significant. 2. Having, producing, or being a value obtained from a statistical test that lies within the limits for being of random occurrence. (p = 0.61 and 0.42, respectively). In addition, the significant (if unexpected) associations shown in Table 5 between dental amalgam surfaces and chelation challenge response became nonsignificant. Discussion Our study hypothesis was that DMSA chelation challenge might indicate the body burden of mercury in a population with chronic occupational mercury exposure, tested several years after the end of exposure. The results do not support this hypothesis, and suggest that DMSA chelation challenge is not useful in quantifying past mercury exposure. Our results do provide useful normative data on urinary mercury levels, both pre-and postchelation. Subjects in this study excreted an average of approximately 4 lag of mercury in 24 hr before the administration of DMSA, a quantity that roughly doubled following two doses of DMSA (Table 1). These results did not vary with past occupational exposure status. Given our observed standard deviations In statistics, the average amount a number varies from the average number in a series of numbers. (statistics) standard deviation - (SD) A measure of the range of values in a set of numbers. (SDs), and assuming a normal range that extends to 2 SDs above the mean, the normal upper limit of 24-hr urinary mercury excretion would be approximately 12 lag without chelation treatment, and 20 lag after two doses of DMSA. We believe these are the first population data published on the mercury response to DMSA chelation challenge. It is possible that our negative findings were due to misclassification of past exposures. However, we believe that such error is unlikely to explain our results; our exposure assessment was based on a large body of direct measurements, verified by internal validation procedures, and consistent with other studies of mercury levels in chloralkali plants (43). Moreover, exposure misclassification would not account for the fact that our exposed and unexposed subjects had similar profiles of urinary mercury excretion. It is also possible that our urinary collection procedure--specifically, collecting urine for 24 hr rather than a shorter interval--accounted for the negative findings. Other studies have collected urine for shorter intervals, in the range of 8 hr, based on the rapid action of DMSA in effecting mercury excretion [e.g., Aposhian et al. (49)]. A longer collection may have diluted our results by diluting the mercury in our specimens, causing the results for the highly exposed and the unexposed to converge. However, given the uniformly low levels of urinary mercury among both exposed and unexposed individuals, we believe it is unlikely that a shorter collection period would have altered our findings substantially. We believe that the most likely cause of the inability of DMSA chelation challenge to quantify past mercury exposures was the elapsed time between the exposures and the testing. As discussed above, most mercury is cleared within 1-2 months, apparently to levels too low to be assayed by DMSA challenge. Other approaches to retrospective exposure assessment will be required in future studies of mercury epidemiology. We also found that the response to DMSA chelation challenge did not increase with the number of mercury amalgam filling surfaces. Prior evidence suggests that dental amalgam fillings do cause systemic mercury absorption (50-52). In addition, at least two studies have reported an association between dental amalgam fillings and mercury excretion following chelation with either DMPS (49) or DMSA (29). The negative finding in our study may indicate that dental amalgam fillings do not create enough systemic mercury absorption to be detected by DMSA chelation with the protocol we used. It is also possible that our assessment of dental amalgam (counting surfaces rather than measuring surface area) or our challenge protocol (the DMSA dose we used and/or the timing of our collection) limited our ability to detect a true association. We attempted to validate a, potential biomarker of long-term occupational mercury exposure, the DMSA chelation challenge response, by studying the association of this biomarker with quantitative estimates of exposure in a cohort of exposed and unexposed individuals. The biomarker could not distinguish exposed and unexposed subjects, and it was not associated with the magnitude of exposure. We conclude that DMSA chelation challenge, according the protocol described here, is not useful in retrospective exposure assessment among mercury workers. REFERENCES AND NOTES (1.) Lauwerys RR, Hoet P. Industrial Chemical Exposure: Guidelines for Biological Monitoring. 2nd ed. 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Urinary mercury after administration of 2,3-dimercaptopropane-1-sulfonic acid: correlation with the dental amalgam score. FASEB FASEB Federation of American Societies for Experimental Biology J 6:2472-2476 (1992). (50.) Lorscheider FL, Vimy MJ, Summers AD. Mercury exposure from "silver" tooth fillings: emerging evidence questions a traditional dental paradigm. FASEB J 9:504-508 (1995). (51.) Bergdahl IA, Schutz A, Ahlqwist M, Bengtsson C, Lapidus L, Lissner L, Hulten B. Methylmercury and inorganic mercury in serum--correlation to fish consumption and dental amalgam in a cohort of women born in 1922. Environ Res 77:20-24 (1998). (52.) Halbach S, Kremers L, Willruth H, Mehl A, Welzl G, Wack FX, Hickel R, Greim H. Systemic transfer of mercury from amalgam fillings before and after cessation of emission. Environ Res 77:115-123 (1998). Address correspondence to H. Frumkin, Department of Environmental and Occupational Health, Rollins School of Public Health The Rollins School of Public Health (RSPH) is the public health school of Emory University. Founded in 1990, RSPH has more than 850 students pursuing master's degrees (MPH/MSPH) and over 100 students pursuing doctorate degrees (PhD). , Emory University Emory University (ĕm`ərē), near Atlanta, Ga.; coeducational; United Methodist; chartered as Emory College 1836, opened 1837 at Oxford. It became Emory Univ. in 1915 and in 1919 moved to Atlanta. , 1518 Clifton Road Clifton Road is main street in Clifton neighborhood of Saddar Town in Karachi, Sindh, Pakistan. Its name dates from the British Colonial rule, and its market is posh areas of Karachi. , Atlanta, GA 30322 USA. Telephone: (404) 727-3697. Fax (404) 727-8744. E-mail: medhf@sph.emory.edu This study was funded by grant 1 RO1 ES08346 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. . Received 7 July 2000; accepted 28 September 2000. Howard Frumkin,(1) Claudine C. Manning,(2) Phillip L. Williams,(3) Amanda Sanders,(1) B. Brooks Taylor,(4) Marsha Pierce,(4) Lisa Elon,(2) and Vicki S. Hertzberg(2) (1) Department of Environmental and Occupational Health, (2) 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. , Rollins School of Public Health, Emory University, Atlanta, Georgia, USA; (3) Department of Environmental Health Science, University of Georgia Organization The President of the University of Georgia (as of 2007, Michael F. Adams) is the head administrator and is appointed and overseen by the Georgia Board of Regents. , Athens, Georgia Athens-Clarke County is a unified city-county in Georgia, U.S., in the northeastern part of the state, at the eastern terminus of Georgia 316. The University of Georgia is located in this college town and is responsible for the initial creation of Athens and its subsequent growth. , USA; (4) Coastal Health District, Georgia Division of Public Health, Brunswick, Georgia, USA |
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