The Impact of Exposure to Iodine and Fluorine in Drinking Water on Thyroid Health and Intelligence in School-Age Children: A Cross-Sectional Investigation.

Iodine and fluorine, as halogen elements, are often coexisting in water environments, with nearly 200 million people suffering from fluorosis globally, and, in 11 countries and territories, adolescents have iodine intakes higher than that required for the prevention of iodine deficiency disorders. It has been suggested that excess iodine and/or fluorine can affect thyroid health and intellectual development, especially in children, but their combined effect has been less studied in this population. This study investigated 399 school-age children in Tianjin, China, collected drinking water samples from areas where the school-age children lived, and grouped the respondents according to iodine and fluorine levels. Thyroid health was measured using thyroid hormone levels, thyroid volume, and the presence of thyroid nodules; intelligence quotient (IQ) was assessed using the Raven's Progressive Matrices (CRT) test; and monoamine neurotransmitter levels were used to explore the potential relationship between thyroid health and intelligence. Multiple linear regression and restricted cubic spline (RCS) analyses showed that iodine and fluorine were positively correlated with thyroid volume and the incidence of thyroid nodules in school-age children, and negatively correlated with IQ; similar results were obtained in the secondary subgroups based on urinary iodine and urinary fluoride levels. Interaction analyses revealed a synergistic effect of iodine and fluorine. A pathway analysis showed that iodine and fluorine were negatively associated with the secretion of free triiodothyronine (FT3) and free tetraiodothyronine (FT4), which in turn were negatively associated with the secretion of thyroid-stimulating hormone (TSH). Iodine and fluorine may affect IQ in school-aged children through the above pathways that affect thyroid hormone secretion; of these, FT3 and TSH were negatively correlated with IQ, whereas FT4 was positively correlated with IQ. The relationship between thyroid hormones and monoamine neurotransmitters may involve the hypothalamic-pituitary-thyroid axis, with FT4 hormone concentrations positively correlating with dopamine (DA), norepinephrine (NE), and 5-hydroxytryptophan (5-HT) concentrations, and FT3 hormone concentrations positively correlating with DA concentrations. Monoamine neurotransmitters may play a mediating role in the effects of iodine and fluoride on intelligence in schoolchildren. However, this study has some limitations, as the data were derived from a cross-sectional study in Tianjin, China, and no attention was paid to the reciprocal effects of iodine and fluorine at different doses on thyroid health and intelligence in schoolchildren in other regions.

A Meta-Analysis of the Prevalence of Children Goiter in High Water Iodine Areas of China.

Although there are now a large number of studies confirming that high iodine levels can cause goiter, there is controversy and a lack of quantitative data. A systematic search of PubMed, Web of Science, China National Knowledge Infrastructure, Wanfang Database, and China Biomedical Database for literature on high iodine and goiter in children was performed with a time limit from January 2013 to October 2023. After screening the literature based on the inclusion criteria, extracting the literature data, and evaluating the risk of bias of the included studies, a single-arm meta-analysis was performed using R 4.0.4 software. Twenty-three studies with a total of 50,980 subjects were included. Meta-analysis showed that the prevalence of goiter among children in water-borne iodine-excess areas was 6.0% [95% CI (4.3%, 7.6%)], and subgroup analyses showed that the prevalence of goiter in children with water iodine 100.1-150 µg/L, 150.1-300 µg/L, and > 300 µg/L was 7.5% [95% CI (0.0%, 15.8%)], 5.5% [95% CI (3.1%, 8.0%)], and 10.2% [95% CI (6.7%, 13.6%)], respectively, and the difference was statistically significant (P < 0.01); The prevalence of goiter among children in the northern China (5.8% [95% CI (4.1%, 7.5%)]) was higher than that in the southern China (3.5% [95% CI (1.0%, 6.0%)]) (P < 0.01); the prevalence of goiter in children with urinary iodine levels 100-199 µg/L, 200-299 µg/L, and ≥ 300 µg/L was 2.4% [95% CI (1.9%, 2.9%)], 3.3% [95% CI (1.9%, 4.8%)], and 7.3% [95% CI (4.4%, 9.9%)], respectively, the difference was statistically significant (P < 0.01); the prevalence of goiter in children aged 8, 9, 10, 11, and 12 years old was 5.1% [95% CI (3.9%, 6.4%)], 8.0% [95% CI (4.0%, 11.9%)], 6.2% [95% CI (3.9%, 8.5%)], 5.5% [95% CI (0.0%, 13.2%)], and 5.4% [95% CI (0.0%, 15.1%)], and when age ≥ 9 years, the relationship between goiter prevalence and age showed a trend toward decreasing with age, but the relationship between different age was no statistical difference in the prevalence of goiter between ages. urinary iodine. The prevalence of goiter in children was higher in areas with high water iodine; the prevalence of goiter in children in the north was significantly higher than that in the south; the prevalence of goiter in children tends to increase with increased urinary iodine levels.