Background
Due to environmental negligence of previous administration and to very strict ban of any reports on possible adverse health effects of environmental pollution until about 1990, the population of east Slovakian district of Michalovce has been exposed to heavy waterborn and airborn industrial pollution by polychlorinated biphenyls (PCB), tetrachloro-dibenzodioxins (TCDD) and dibenzofurans (TCDF) as well as to extensive agricultural pollution by several pesticides and fungicides such as dichlorodiphenyl-dichloroethylene (DDE) and hexachlorobenzene (HCB) for several decades. Such pollution resulted in very high environmental and blood levels of the above listed toxic substances [1‐5] and their hydroxylated and methysulfonated metabolites [6, 7].
Within previous extensive field surveys we found several adverse thyroid [8‐13] and metabolic signs [14‐16] related to increasing levels of PCBs which we used as a marker of increased level of all components of the above presented POPs cocktail. Recently, we also suggested a possibility of transgenerational transmission of such effects from their highly exposed parents [14]. Such possibility was also supported by the findings of high POPs level in cord blood [7] and also by a significant association of high prenatal PCB exposure with smaller thymic volume in newborns from the same area [17].
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The aim of this report is to evaluate the prevalence of multiple adverse health signs in individual subjects and to compare such findings with the level of PCBs.
Methods
Subjects
A total of 2046 adults (834 males and 1212 females; age range of 21–75 years), were examined in polluted area of Michalovce district (POLL) and area of Svidnik and Stropkov districts with much lower level of background pollution (BCGR). Since, however, in spite of striking difference in POPs levels between those two areas we still found a certain spillover, we rather preferred the evaluation based on pooled subjects from both areas as stratified in quintiles of PCBs level thus showing a strikingly increasing proportion of subjects from polluted area in individual quintiles. Thus, in the first quintile only 9.8% subjects belong to the polluted area and such proportion is increasing to 19.0, 44.4, 84.2 and 97.9 percent in following quintiles. By such a way each quintile covers the subjects from both areas with the same range of PCB level. Highly significant correlation (p < 0.001) was found between individual major POPs such as PCB with DDE (r = 0.245), DDE with HCB (r = 0.394) and PCB with HCB (r = 0.199) and thus the level of PCBs was used as a marker of the presence of other organochlorines.
List and cut/off levels used for the evaluation of individual adverse health signs
1. Thyroid volume (ThV): arbitrary cut/off level was 75th percentile for each appropriate sex and age group, such as 9.0 ml for females <35 yrs and 11.0 ml for these >35 yrs, while 11.0 ml was used for males <35 yrs and 13.5 ml for these >35 yrs; 2. TPOab: >37 U/ml; 3. TRab: >1.7 mU/ml; 4. FT4: 19 pmol/l; 5. TT3: 2.1 nmol/l; 6. Increased TSH: >4.0 mU/l; 7. Decreased TSH: < 0.5 mU/l; 8. Increased thyroglobulin: >40 ng/ml; 9. Increased fasting glucose: including impaired fasting glucose (5.6–6.9 mmol/l) plus diabetes (>6.9 mmol/l); 10. Fasting insulin: >10 mIU/ml; 11. Cholesterol: >6.0 mmol/l; 12. Triglycerides: >2.0 mmol/l; 13. BMI: arbitrary cut/off level was 75th percentile for each appropriate sex and age group, such as 25.00 for females >35 yrs and 31.00 ml for these >35 yrs, while 26.50 ml for males >35 yrs and 31.00 ml for these >35 yrs.
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Chlorinated substances
From each subject 20 ml of blood was withdrawn and centrifuged in a refrigerated centrifuge. The aliquots of serum and urine were transported in portable freezer to the laboratory and kept frozen at -20°C until assayed. In serum of all subjects fifteen PCB congeners (IUPAC numbers 28, 52, 101, 105, 114, 118, 123, 138+163, 153, 156+171, 157, 167, 170, 180 and 189) and also p,p'-DDE (2,2'-bis(4-chlorophenyl)-1,1-dichloroethylene), p,p'-DDT (2,2'-bis(4-chlorophenyl)-1,1,1-trichloro-ethane), hexachlorobenzene (HCB) were determined by high resolution gas chromatography/mass spectrometry as repeatedly described in detail elsewhere [2‐4, 7].
An enzymatic summation method based on the determination of total and free cholesterol, phospholipids and triglycerides was used to determine total lipids in all the serum samples analyzed [18] and serum levels of OCs were adjusted per g of serum total lipids.
Thyroid volume (ThV)
The estimation of ThV was carried out by a single observer (M.T.) with two decades of thyroid ultrasound experience, intra-observer variation being 3.9 ± 3.5% [for details see [11]] using real time sonography and the ellipsoid method [19] with the aid of portable apparatus Aloka (Japan) and 7.5 mHz linear transducer.
Serum hormones, antibodies, glucose and lipids
Serum level of free thyroxine (FT4), total triiodothyronine (TT3) and antibodies against thyroperoxidase (TPOab) was estimated by electrochemiluminiscent immunoassay using automatic system Elecsys (Roche, Germany).
Thyrotropin receptor antibodies (TRab) were estimated by ELISA using the kit TRab from IASON (Graz, Austria) and the apparatus Stat Fax 3200 (Awareness Technology, Palm City, FL). The cut/off level for positive TPOab was 37.0 U/ml and that for TRab was 1.9 IU/ml.
The level of serum glucose was estimated by routine glucose oxidase method. The cases with impaired fasting glucose (IFG) level (i.e. 5.6 – 6.9 mmol/l) and diabetes (>6.9 mmol/l were evaluated according to the guidelines of American Diabetes Association [20].
Statistical evaluation
For the evaluation of differences between the number of cases in PCB level quintiles in pooled areas (Table 1) as well as for these in the prevalence of adverse signs between individual areas (Tables 2 and 3) chi-squared test for independence and binomial proportion test has been used.
Table 1
Adverse health signs in quintiles of stratified PCB level in a total of 2046 examined males and females
Quintiles of serum PCB level | |||||||
|---|---|---|---|---|---|---|---|
1 (n = 409) | 2 (n = 409) | 3 (n = 410) | 4 (n = 410) | 5 (n = 408) | |||
Adverse signs
1)
|
Upper PCBs level for each quintile(ng/g lipid)
|
Chi-square
|
p
| ||||
627 | 906 | 1341 | 2343 | 101,413 | |||
Number of adverse health cases per quintile
| |||||||
1. Increased thyroid volume | 79 | 79 | 84 | 122 | 124 | 29.30 | 0.0000 |
2. Positive TPOab | 83 | 98 | 88 | 126 | 116 | 17.56 | 0.0015 |
3. Positive TRab | 82 | 93 | 97 | 84 | 69 | 6.88 | 0.1423 |
4. Increased free T4 | 70 | 84 | 114 | 104 | 128 | 28.58 | 0.0000 |
5. Increased total T3 | 100 | 105 | 116 | 139 | 132 | 13.44 | 0.0093 |
6. Decreased TSH | 4 | 5 | 12 | 7 | 20 | 18.56 | 0.0010 |
7. Increased TSH | 55 | 65 | 48 | 56 | 45 | 5.17 | 0.2701 |
8. Increased thyroglobulin | 38 | 44 | 27 | 38 | 42 | 5.11 | 0.2759 |
9. Increased fasting glucose | 171 | 190 | 235 | 272 | 295 | 110.55 | 0.0000 |
10. Increased fasting insulin | 88 | 86 | 94 | 105 | 122 | 11.89 | 0.0182 |
11. Increased cholesterol | 89 | 119 | 127 | 142 | 134 | 8.76 | 0.0673 |
12. Increased triglycerides | 89 | 119 | 127 | 142 | 134 | 19.36 | 0.0007 |
13. Increased BMI | 131 | 157 | 149 | 146 | 161 | 5.84 | 0.2118 |
Table 2
Prevalence of cases with various numbers of adverse signs as sorted in terms of areas and PCB level quintiles
Numbers of subjects from polluted and background area with increasing number of multiple adverse signs in quintiles of PCB level | ||||||||
|---|---|---|---|---|---|---|---|---|
Area | Quintile of PCB level | Numbers of multiple adverse signs | Range of serum PCB level (ng/g lipid) | |||||
0–1 | 2–3 | 4–5 | 6–7 | 8–9 | 10–11 | |||
POLLUTED | 1 | 32 | 69 | 62 | 29 | 8 | 1 | 337 – 1136 |
2 | 26 | 66 | 61 | 32 | 13 | 3 | 1136 – 1619 | |
3 | 25 | 57 | 61 | 45 | 12 | 2 | 1670 – 2279 | |
4 | 19 | 74 | 60 | 38 | 19 | 1 | 2290 – 3395 | |
5 | 23 | 62 | 55 | 51 | 11 | ---- | 3616 – 101,413 | |
TOT = 1008
|
125
|
328
|
299
|
195
|
54
|
7
| ||
BACKGROUND | 1 | 68 | 76 | 50 | 10 | 3 | ---- | 149 – 521 |
2 | 55 | 70 | 60 | 19 | 3 | ---- | 523 – 661 | |
3 | 57 | 77 | 47 | 19 | 8 | ---- | 661 – 825 | |
4 | 42 | 79 | 61 | 20 | 6 | ---- | 826 – 1072 | |
5 | 50 | 85 | 55 | 16 | 2 | ---- | 1075 – 16,391 | |
TOT = 1038
|
272
|
387
|
273
|
84
|
22
| ---- | ||
Table 3
Percentage distribution of cases with various numbers of adverse signs as sorted in terms of areas, genders and age
Group of subjects | Sum of subjects with indicated numbers of adverse signs as percent of total number per group | ||||||||
|---|---|---|---|---|---|---|---|---|---|
Line | Name1)
| Total number | Numbers of multiple adverse signs | Serum PCB (ng/g lipid) 5% – 95% | |||||
0+1 | 2+3 | 4+5 | 6+7 | 8+9 | 10+11 | ||||
1 | POLL all | 1008 | 12.4 | 32.5 | 29.6 | 19.3 | 5.3 | 0.7 | 672 – 9103 |
2 | POLL all M | 432 | 9.9 | 32.4 | 29.3 | 21.7 | 5.5 | 0.9 | 736 – 11745 |
3 | POLL all F | 576 | 14.2 | 32.6 | 30.1 | 17.5 | 5.2 | 3.5 | 632 – 7075 |
4 | POLL yng M | 133 | 15.1A
| 40.7C
| 30.8 | 11.3E
| 2.2A
| ----- | 545 – 5687 |
5 | POLL old M | 299 | 7.7A
| 28.7C
| 28.7 | 26.4E
| 6.9A
| 1.3 | 1129 – 13801 |
6 | POLL yng F | 157 | 21.1C
| 40.1D
| 26.1 | 9.4C
| 1.9B
| ----- | 507 – 4141 |
7 | POLL old F | 419 | 11.7C
| 29.6D
| 32.3 | 20.5C
| 6.4B
| ----- | 818 – 8430 |
8 | BCGR all | 1038 | 27.2 | 37.3 | 27.1 | 8.1 | 2.1 | ----- | 354 – 1698 |
9 | BCGR all M | 402 | 21.9 | 40.8 | 27.6 | 7.9 | 1.4 | ----- | 430 – 1992 |
10 | BCGR all F | 635 | 28.9 | 34.9 | 25.3 | 8.1 | 0.3 | ----- | 321 – 1380 |
11 | BCGR yng M | 116 | 38.2E
| 47.8A
| 13.1E
| 2.6A
| ----- | ----- | 343 – 1129 |
12 | BCGR old M | 286 | 15.7E
| 38.1A
| 33.9E
| 9.8A
| 2.1 | ----- | 587 – 2467 |
13 | BCGR yng F | 172 | 46.2F
| 35.8 | 15.1F
| 2.9C
| ----- | ----- | 251 – 1194 |
14 | BCGR old F | 463 | 22.5F
| 34.8 | 28.9F
| 10.4C
| 3.4 | ----- | 369 – 1578 |
Results
Table 1 shows the prevalence of individual thyroid and metabolic health signs (as defined in Materials and Methods) in pooled cohort of subjects from both areas as sorted in terms of quintiles of stratified sum of 15 PCB congeners level. However, it should be underlined that in this case the main target is not the individual area, but rather the level of PCBs which shows a certain spillover between both areas with strikingly increasing proportion of subjects from polluted area in individual quintiles. Thus, in the first quintile only 9.8% subjects belong to the polluted area and such proportion is increasing to 19.0, 44.4, 84.2 and 97.9 percent in following quintiles. However, in spite of that each quintile covers the subjects from both areas with the same range of PCB level.
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Table 1 further shows that increasing PCBs level, as sorted in terms of quintiles, results in highly significant increase in the number of cases with increased ThV (p < 0.0015), positive TPOab (p < 0.0015), increased FT4 (p < 0.0000), increased TT3 (p < 0.0093), decreased TSH (p < 0.0010), increased fasting glucose (p < 0.0000) and fasting insulin (p < 0.0182) as well as increased triglycerides (p < 0.0007). In contrast, no changes were found in increased TRab, TSH and thyroglobulin level, while increasing proportion of high cholesterol level was slightly above the limit of significance (p < 0.0673).
Table 2 shows the differences in the number of subjects with increasing number of cumulated multiple adverse signs in individual areas. Although the subjects were stratified in terms of PCB level quintiles as well as in terms of increasing number of cumulated adverse health signs for each area separately, any considerable differences related to increasing PCB level quintiles did not appear. However, some considerable differences in the prevalence of cumulated adverse health signs were found. Thus, the number of subjects with zero or one adverse signs in BCGR was more than twice as high (272/1038 = 26.2%) than that in POLL (125/1008 = 14.8%; p < 0.001). However, in contrast, the number of subjects with 6 or 7 signs was about twice as high in POLL than in BCGR (195/1008 = 19.3% vs. 84/1038 = 8.1%; p < 0.001) and the same is true for more than twice as high number of subjects with 8 or 9 adverse signs (54/1008 = 5.3% vs. 22/1038 = 2.1%; p < 0.001) as well as for 7 subjects with 10 or 11 signs from polluted area versus zero in background area. In addition, no differences between polluted and background area were found in the number of subjects with 2 or 3 (328 vs. 387, respectively) and with 4 or 5 signs (299 vs. 281, respectively).
From this follows that in BCGR there was a significantly higher prevalence of subjects with low number of adverse signs (such as these with zero or one sign), while the opposite is true for POLL in which a significantly higher prevalence of subjects with high number of multiple adverse signs (such as these with six to eleven signs) was found.
Table 3 shows that in males and females from individual areas the percentage distribution of adverse signs was about the same as that shown for pooled genders and, in addition, similar distribution was also found in old groups of both genders. However, in young males and females from both areas the prevalence of cases with the lowest number of adverse signs was significantly higher than that in the appropriate groups of old subjects, while, in contrast, the prevalence of subjects with increased number of adverse signs was significantly higher in old males and females.
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Discussion
We previously found several adverse thyroid and metabolic signs which were associated with increased PCBs level in serum. Since such PCB level was highly correlated with the other major organochlorines such as DDE and HCB (Spearman's rank correlation coefficient of 0.529, p < 0.001 and 0.294, p < 0.001, respectively), we are using PCB level as a marker of DDE and HCB presence. Thus, when using ultrasound for the first time to study possible effect of organochlorines on the thyroid, we repeatedly found significant positive association of thyroid volume with PCB in large cohorts [8, 9] and also demonstrated that there is an additional effect of PCB on thyroid volume other than that of age [11]. At this occasion it should be noted that any possible interfering effect of iodine deficiency in the increasing of thyroid volume should be ruled out, since Slovakia has been found as iodine replete country by European study [21] and also in one of our previous report no difference has been found in urinary iodine between the population of POLL and BCGR area [11].
We also repeatedly demonstrated increased prevalence of thyroperoxidase, thyroglobulin and thyrotropin receptor antibodies in the population from polluted area [8, 9], namely in males [11, 13, 14].
Considerably increasing serum level of free thyroxine and total triiodothyronine with PCB level higher than approximately 500 ng/g lipid was also recently described [12]. According to our experience and our previous findings, two possible mechanisms of organochlorine effect on the thyroid function could exist. The first one is definitely much more frequent and appears to be due to the impairment of immune system resulting in increased prevalence of thyroperoxidase antibodies followed by increased thyroid hypoechogenicity by ultrasound and finally by stepwise increase of TSH level thus contributing to subclinical and/or clinical hypothyroidism. Among subjects with highly increased PCB level such impairment was found more frequent in males than in females. For instance, in 5th quintile of PCB levels the frequency of hypoechogenicity in males was found about 10 times higher than that in the 1st quintile (23/223 or 10.4% vs. 1/101 or 1.0%; p < 0.001), while in females the frequency in the 5th quintile was only twice as high as in the 1st quintile and less significant (47/184 = 25.5% vs. 46/308 = 14.9%; p < 0.01), although the absolute number of cases in females was higher [11]. We also found similar differences between males and females as based on positive serum thyroperoxidase level [13].
The second effect of PCB on the thyroid function appears much less frequent. It depends on very high PCB level and is possibly due to a long-term disrupted equilibrium between total and free thyroxine level due to the displacement of thyroxine from protein binding resulting from the effect of PCB. Thus, in twelve cases of what we called "high PCB related subclinical hyperthyroidism" (8 females and 4 males, age of 54 ± 1.4) we found astonishing PCB level of 17,233 ± 7365 ng/g serum lipid (all following data are means ± SE), TSH level in thyrotoxic range of 0.16 ± 0.05 mU/l, increased level of free T4 of 23.3 ± 1.03 pmol/l and total T3 of 2.56 ± 0.07 nmol/l [12].
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The data presented in this study are in agreement with previous findings mentioned above and show that POPs appear to increase the prevalence of several subclinical and overt thyroid and metabolic disorders.
Acknowledgements
This study was supported by 5th Framework Program of EC "Quality of Life and Management of Living Resources" as part of the project PCBRISK (QLK4-2000-00488). The authors wish to express their appreciation to 28 district practitioners from Michalovce, Svidník and Stropkov districts and to Public Health authorities of these districts for their invaluable help in the planning, arrangement and carrying out the field survey. For excellent technical assistance
This article is published under license to BioMed Central Ltd. This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Competing interests
The authors declare that they have no competing interests.
Authors' contributions
PL author of the manuscript, co-author of PCBRISK project and workpackage coordinator, AK and BD measured organochlorines in serum samples, MT examined all thyroids by ultrasound, KS performed the statistical evaluations, ŽR, JK, LK and RI conducted field survey and made medical examinations, MH made estimations of all hormones, antibodies and metabolites, DG evaluated the data on dysglycemia, TT and IK participated in design and coordination of field survey and the study. All authors read and approved the manuscript.