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Arquivos Brasileiros de Endocrinologia & Metabologia

Print version ISSN 0004-2730

Arq Bras Endocrinol Metab vol.51 no.5 São Paulo July 2007

http://dx.doi.org/10.1590/S0004-27302007000500007 

REVISÃO

 

Relevance of iodine intake as a reputed predisposing factor for thyroid cancer

 

Relevância da ingestão de iodo como fator predisponente ao câncer de tireóide

 

 

Meyer KnobelI; Geraldo Medeiros-NetoII

IThyroid Unit, Division of Endocrinology and Metabolism, Hospital das Clínicas
IIDepartment of Internal Medicine University of São Paulo Medical School, São Paulo, SP

Address for correspondence

 

 


ABSTRACT

Iodine is a trace element that is essential for the synthesis of thyroid hormone. Both chronic iodine deficiency and iodine excess have been associated with hypertrophy and hyperplasia of follicular cells, attributed to excessive secretion of TSH. This may be associated to thyroid cancer risk, particularly in women. Experimental studies have documented thyroid cancer induction by elevation of endogenous TSH, although in a small number of animals. Iodine deficiency associated with carcinogenic agents and chemical mutagens will result in a higher incidence of thyroid malignancy. Inadequate low iodine intake will result in increased TSH stimulation, increased thyroid cell responsiveness to TSH, increased thyroid cell EGF-induced proliferation, decreased TGFb 1 production and increased angiogenesis, all phenomena related to promotion of tumor growth. Epidemiological studies associating iodine intake and thyroid cancer led to controversial and conflicting results. There is no doubt that introduction of universal iodine prophylaxis in population previously in chronic iodine-deficiency leads to a changing pattern of more prevalent papillary thyroid cancer and declining of follicular thyroid cancer. Also anaplastic thyroid cancer is practically not seen after years of iodine supplementation. Iodine excess has also been indicated as a possible nutritional factor in the prevalence of differentiated thyroid cancer in Iceland, Hawaii and, more recently, in China. In conclusion: available evidence from animal experiments, epidemiological studies and iodine prophylaxis has demonstrated a shift towards a rise in papillary carcinoma, but no clear relationship between overall thyroid cancer incidence and iodine intake.

Keywords: Iodine; Thyroid cancer; Iodine deficiency; Iodine excess; Carcinogenic agents; Environmental effect


RESUMO

O iodo é essencial para a síntese de hormônios tireóideos e tanto a deficiência crônica deste halogeno como o excesso nutricional de iodo levam a hiperplasia e hipertrofia dos elementos foliculares (por excesso de TSH). Esse fenômeno pode se associar a maior risco de câncer de tireóide, especialmente no sexo feminino. Estudos experimentais documentam indução de câncer de tireóide após prolongado excesso circulante de TSH, o qual induz aumento da proliferação celular medida por fator de crescimento epidermal (EGF), decréscimo de síntese de fator de transformação do crescimento (TGFb 1) e aumento da angiogenese. Estudos epidemiológicos entre nutrição de iodo e câncer de tireóide são conflitantes. É, todavia, aceito que a correção de prévia deficiência de iodo com aporte nutricional adequado deste halogeno leva à maior prevalência de carcinoma papilífero (e decréscimo de carcinoma folicular). Em alguns países, o excesso de iodo foi apontado como causa aparente de maior prevalência de câncer de tireóide. Em conclusão: não existe uma relação causa-efeito entre iodo nutricional e prevalência de câncer de tireóide, e outros fatores intervenientes ambientais devem ser considerados.

Descritores: Iodo nutricional; Câncer de tireóide; Deficiência de iodo; Excesso de iodo; Agentes carcinogênicos; Efeito ambiental


 

 

THYROID CARCINOMA IS THE MOST commonly encountered endocrine malignancy (1). Its incidence among all ages rose steadily in different countries in the last 10 years, whereas its mortality rates dropped (2). The declining mortality rates are largely due to early diagnosis and effective therapy applied at an early tumor stage when it is most amenable to surgery and 131I therapy. Those tumors have a marked variability in aggressiveness from highly differentiated papillary carcinomas with a good prognosis, if found and treated early, to undifferentiated anaplastic cancers occurring mainly in older people and with a poor prognosis (3).

Iodine is a trace element that is essential in the synthesis of thyroid hormones. Both chronic iodine deficiency and chronically high iodine intake have been associated with the development of goiter (i.e., hypertrophy and hyperplasia of the thyroid cells) and attributed to excessive secretion of TSH by the pituitary. In turn, goiter has been associated with thyroid cancer risk, particularly in women (4).

A clear relationship between iodine supply to the population and thyroid cancer incidence has not been proven and is still debated (3). In general, chronic iodine deficiency and residence in an endemic goiter area are associated with an increased risk of follicular histological type of cancer, whereas chronically high iodine intake may increase the risk of the more common papillary histological type of thyroid cancer.

This outline summarizes available data from animal experiments, epidemiological studies and from the introduction of iodine prophylaxis on the possible association between iodine deficiency and the development of differentiated thyroid carcinoma.

 

EXPERIMENTAL INDUCTION OF THYROID TUMORS

Thyroid neoplasia may be induced by exposure of experimental animals to a variety of treatment regimens, exogenous chemicals or physical agents.

Tumor induction by elevation of TSH

It has been recognized for some time that neoplasms induced in experimental animals by a number of treatments result in thyroid gland dysfunction, more frequently hypothyroidism.

Among the thyroid cancer-causing factors inducing a hypothyroid state are iodine deficiency (5,6) and subtotal thyroidectomy (7). In addition, thyroid tumors can result from the transplantation of TSH-secreting pituitary tumors (7-9). The one factor common to each of these conditions is that they all lead to increased production of TSH and prolonged stimulation of the thyroid gland by continuously elevated serum TSH. In the first two conditions, elevated TSH results from chronic stimulation of the pituitary in response to a deficiency in the circulating levels of thyroid hormone. It is worth mention note that nothing has been administered to these animals. Therefore the tumors developed in the absence of factors that are normally present in the animals (i.e., iodine and thyroid gland mass). It should rightfully be pointed out, however, that the animals were under chronic stress due to deficiency of thyroid hormone. In the third case, excess TSH comes from the transplanted pituitary tumor. Thus, irrespective of the cause, it appears that prolonged stimulation of the thyroid pituitary that results in release of elevated levels of TSH by the thyrotrophs may lead to thyroid gland neoplasia (10).

Tumor induction by low iodine intake

The hypothesis of an association between iodine intake and the risk for thyroid cancer is based on the results of studies in experimental animals, which showed that animals on an iodine-restricted diet were more likely to develop cancer (6,11). On this basis, overstimulation by thyroid-stimulating hormone (TSH) was considered to play a major role in tumorigenesis. At variance, recent studies have shown, however, that the serum levels of TSH are in fact lower in individuals with mild-moderate iodine deficiency (12).

In golden hamsters submitted to long-term low-iodine diet, it has been experimentally shown hyperplasia, then nodular goiter and, eventually, in a small percentage of animals, carcinomas. The spontaneous malignancies reported in the iodine-deficient animals were follicular adenocarcinomas; 18% of females, but no thyroid lesions were found in males after a 70-week iodine-deficient diet. (11).

C3H/Hey strain-mice where placed in low-iodine diet to induce benign and malignant thyroid tumors. After one year of this nutritional condition, follicular adenomas developed in 60% and follicular carcinomas became manifest in 10% of the animals (6).

Male Sprague-Dawley (Han:SPRD) rats submitted to chronic iodine deficiency induced by a long-term iodine intake of approximately 10% of the normal iodine dietary supply developed follicular hypertrophy and subsequently follicular cell hyperplasia and thyroid hypertrophy (13). Iodine supplementation to approximately 16 times the normal concentration lead to hyperplasia of follicular cells, organ hypertrophy and a massive increased proliferation rate. Interestingly, the high proliferation rates did not induce any malignant changes. The risk that a benign thyroid tumor may develop after iodine deficiency or excess is 2- to 3-fold higher than in controls. It was suggested that under the experimental conditions both long-term iodine deficiency and excess are insufficient to stimulate carcinogenesis, whereas benign tumors, detectable in approximately 90% of the animals after 110 weeks of treatment, were clearly more frequently found as compared to the control group with normal iodine supply. It seems that previous studies contradict these data (5,14).

Iodine-deficient Fisher rats were shown to develop chromosomal abnormalities (aneuploidy) of some heterogeneous thyroid cell population. These cells may have acquired neoplastic characteristics, for when such a cell population is transplanted, a neoplastic tumor is produced (15).

Studies with combination of tumor-inducing factors

Several investigations have indicated that combined treatment regimens are associated with thyroid carcinogenetic responses in excess of that produced by either single treatment alone.

A few direct acting exogenous chemical compounds have been identified that produce thyroid tumors that do not appear to influence the thyroid-pituitary status, as these compounds did not increase thyroid weights unrelated to tumor development or cause a persistent elevation of serum TSH levels (16). Two of them are N-nitrosomethylurea (NMU) and N-bis(2-hydroxypropyl)-nitrosamine (DHPN), classified as genotoxic, since involves direct carcinogenic effects at the DNA level in follicular cells.

Non-genotoxic agents, as iodine, may alter the negative feedback system of the thyroid-pituitary hypothalamus axis, leading to TSH increase and its prolonged stimulation of follicular epithelium (17) as already mentioned.

The thyroid combined treatment studies are consistent with the concepts of initiation-promotion. The genotoxic agent might permanently alter the thyroid cell so that its accentuated growth under a goitrogenic stimulus would result in neoplasms (6).

Rats previously treated with NMU and then placed on an iodine-deficient diet, had increased incidence of thyroid follicular cell carcinomas (90%) in comparison to 10% of rats exposed to iodine deficiency alone. On the other hand, about 20% of the rats developed follicular carcinomas when treated with the same carcinogen, but in normal conditions for iodine nutrition. These observations indicated that the iodine-deficient diet is a potent promoter of thyroid tumors initiated by NMU and also a carcinogen by itself (18). Moreover, the results suggested that the non-genotoxic component, i.e., elevation of TSH, plays a key role in the development of thyroid lesions (19).

In another study, F344 rats were given the chemical mutagen DHPN and supplemented with various amounts of potassium iodide in drinking water to generate conditions that extended to chronic iodine deficiency to severe iodine excess. In DHPN-treated rats, both conditions significantly increased thyroid follicular tumorigenesis. In DHPN-untreated rats, iodine deficiency produced diffuse thyroid hyperplasia, together with a decrease in serum thyroxine and an increase in serum TSH. On the other hand, iodine excess produced colloid goiter, together with normal serum T4 and slightly decreased TSH. Under influence of DHPN there was a rapid rise in tumor incidence with increasingly low levels of dietary iodine. Interestingly, in this study there was a slight rise in tumor incidence at high iodide levels. These effects were directly proportional to the severity of iodine deficiency or extent of iodine excess and suggest that each condition has a different thyroid tumor promotion mechanism (20) (figure 1).

 

 

In rats, iodine deficiency is much more effective as a tumor promoter as compared to its carcinogenic effect, suggesting that a similar relationship may exist in human populations. However, it should be emphasized that data from animal studies in relation to thyroid tumors may not be extended to human thyroid. In the former, thyroid tumors can be reproduced precisely and studied exactly, but the relevance of these tumors to human lesions is doubtful since they show a pattern of morphology and behavior that is strictly different from human tumors.

 

CELL BIOLOGY OF THYROID CARCINOGENESIS

Thyroid carcinogenesis is a multi-stage phenomenon and is considered to involve basically an oncogene mutation, response to growth factors and the clonality of the neoplastic tissue architecture (21). All conditions that favor prolonged stimulation of cell proliferation are apt to facilitate pre-malignant transformation. The increased number of cell division gives to protooncogenes an enhanced probability to be activated and to oncosuppressor genes to be damaged (22).

The characteristic feature of malignancy is an increased growth rate of the cell, and the development of a tumor can be thought of as a series of steps, each marked by the growth of a clone with higher growth rate than the rest of the lesion. Moreover, the importance of post-mutagen growth in the thyroid is well shown by two observations: a) there is a great increase in incidence of rodent thyroid tumors if TSH is elevated by goitrogen treatment or by a low-iodide diet after mutagen administration, as DHPN or NMU, and b) thyroid carcinogenesis is abolished if suppressive thyroxine treatment or hypophysectomy is used immediately after mutagen exposure preventing any TSH-induced growth (23,24).

Unlike many other highly specialized cells, thyroid cells are not irreversibly terminally differentiated. When they proliferate in response to certain growth signals they temporarily lose the ability to concentrate iodide and to synthesize thyroglobulin. Certain unregulated growth signals associated with malignant transformation may contribute to the loss of differentiated thyroid function. The thyroid cell turns over, on average, no more than five times through adulthood (25). Turnover increases in early infancy and adolescence (25,26). Because of the homogeneity of the growth potential of follicular cells (27), a fraction of these follicular cells in adults would likely turnover much more than five times. It is assumed that cycles of cell division may be more frequent in benign or malignant tumors (27,28), although evidence from human tumors does not always support this notion (29).

An understanding of the factors involved in normal human thyroid cell growth, differentiation, and signaling is an essential prelude to understanding aberrations related to thyroid cell transformation. Unfortunately, the picture is incomplete due to the variability among species of factors that sustain thyroid proliferation and the pathways used (30). Growth factors also play a key role, along with TSH, in the complex regulation of thyroid cell proliferation, but there are few data yet to explain how these trophic factors interact with the cell cycle to stimulate or inhibit cell division in the thyroid.

A variety of mechanisms cooperate to determine thyroid cell stimulation to proliferate in conditions of chronic iodine deficiency (31).

Increased TSH stimulation

Thyrotropin, through activation of its receptor, has been shown to stimulate more than one signal transduction pathway in the regulation of both growth and differentiated function. Each pathway may be related to specific cellular events. The main effector of TSH on proliferation and differentiation in a variety of species, humans and rats included, is the cAMP signal transduction pathway, that is, the cascade involving activation of adenylate cyclase resulting in cAMP generation (33).

Evidence concerning the mitogenic role of TSH for thyroid cells in vivo has been further consolidated over recent years. Studies from various laboratories using tritiated thymidine labeling, metaphase arrest techniques for mitotic index, or immunohistochemical decoration of statin (a non-proliferation-specific nuclear antigen identifying quiescent Go-phase cells) show that TSH stimulates, in a dose- and time-dependent way, the recruitment of noncycling Go cells into the cycling compartment, as well as entry into S-phase and the entry of G2 cells into mitosis (32).

Recent work has indicated that the normal rodent (and human) thyroid may have an intrinsic heterogeneity in the follicular cell population regarding the capacity for proliferative response to TSH. One hypothesis suggests that there are a few subsets of stemlike follicular cells with a high growth potential compared to the majority of the population and that this trait is stable and heritable (34). According to this model, the clones of cells with extensive proliferative potential are the origin of the adenomas that develop under conditions of chronic TSH stimulation (35).

As proposed by Studer et al. (27), the above intrinsic stem cell clone model reconciles earlier kinetic observations (36,37) that hyperstimulated thyroid attains a plateau phase of growth or state of "desensitization", with the vast majority of follicular cells becoming refractory to the mitogenic effects of increased TSH levels before the emergence of adenomas. In this model, chronic TSH stimulation would select preexisting thyrocyte clones with the greatest proliferative potential and thus with the greater risk of neoplastic transformation. An alternative model for explaining the self-limited nature of hyperthyroidism and the development of hormone-responsive tumors in the chronically stimulated rat thyroid proposes that clones of cells escape from the desensitization mechanism through mutational events and natural selection, leading ultimately to tumor formation (19). Both models agree that thyroid carcinogenesis involves rare subsets of cells responsive to continued TSH stimulation but differ concerning the origin of follicular cell heterogeneity. Additional support for the intrinsic subset concept and/or the controlling influence of TSH on the development of selected clones of thyroid follicular cells comes from other studies on cell proliferation (33) and from those using transplantation methodology (38).

The impaired synthesis of thyroid hormones, due to the iodine shortage, will result in (subclinical) hypothyroidism and increased TSH secretion. TSH induces human thyroid cell growth at a higher concentration than is necessary for induction of differentiated function (39).

Increased thyroid cell responsiveness to TSH

Iodine deficient thyroid cells will have an increased content of the two major intracellular messengers for the TSH signaling pathways, cAMP and Ca++ (39). Under this condition, the thyroid cell is sensitized to TSH stimulation, which elicit responses that are inappropriately high for a given stimulation.

There is evidence that iodine is a major mediator of thyroid autoregulation, involving numerous inhibitory actions (41). One of these is a decrease in cAMP formation in response to TSH, resulting in an inhibition of all cAMP-mediated stimulatory effects of TSH on the thyroid. Excess iodide therefore exerts a negative control on different thyroid parameters, inhibiting iodide uptake and organification, protein and RNA biosynthesis, hormone secretion, as well as paracrine mitogenic activity on endothelial cells and fibroblasts (42).

Most of these actions appear to be mediated by an intracellular organified iodine intermediate of unknown identity. Various derivatives of arachidonic acid have been proposed as this putative regulator(s), including the iodinated eicosanoid, delta-iodolactone (42).

The iodolactone growth inhibitory mechanism, which is decreased in iodine-deficient thyroid cells, is believed to occur via inhibition of the specific EGF-dependent production of IP3, a signal transducer that modulates thyroid cell proliferation (43). However, this compound had no effect on TSH-mediated cAMP formation in porcine follicles (43). Considered to be a more likely candidate is 2-iodohexadecanal (44), a major iodolipid formed in horse thyroid when incubated with iodide (45), but which is also detectable in the thyroid of other species, including humans and rats.

Increased thyroid cell EGF-induced proliferation

Growth factors also play a key role, along with TSH, in the complex regulation of thyroid cell proliferation, but there are few data yet to explain how these trophic factors interact with the cell cycle to stimulate or inhibit cell division in the thyroid.

These autocrine/paracrine regulators of thyroid growth, with potent mitogenic activity for thyroid cells demonstrable in vitro, include epidermal growth factor (EGF) and basic fibroblast growth factor (bFGF). EGF is synthesized within the thyroid gland and induces proliferation in thyroid cells from a wide range of species at the expense of dedifferentiation and loss of specialized thyroid-specific function (46). Over expression of EGF and GF-receptor in RNAS were detected in dyshormonogenetic goiters that were under constant and prolonged endogenous TSH stimulation (47). Basic FGF (fibroblast growth factor) is present in human thyroid tissue (48) and there are stores of FGF in the basement membrane of follicles in normal adult rat thyroid (49). Moreover, bFGF expression increases during thyroid hyperplasia in rodents (50).

EGF has been shown to stimulate the growth and invasion of differentiated human thyroid cancer cells in culture and in nude mice (51). In some tissue culture systems TSH does not stimulate thyroid cell growth unless other growth factors as EGF are present (52). EGF binding in thyroid neoplasms is also somewhat higher than in normal thyroid tissue from the same patients (53).

Decreased TGFb production

Transforming growth factor b1 (TGFb1) is a putative negative regulator of thyroid growth, as studies in normal cell systems have shown it to inhibit thyrocyte proliferation, including that mediated by TSH (54). Although the actual role of TGFb1 in the thyroid is not known, cell culture and rodent investigations suggest that it is a limiting autocrine influence on thyroid cell hyperplasia, cancer growth and invasion (55). In one study, TGFb1 was detected in approximately 50% of human thyroid carcinomas, but not in adenomas, with a striking correlation being observed between the dual presence of TGFb1 expression and arginine substitution at codon 61 of the H-ras oncogene (56). Lazzereschi et al. (57) demonstrated a significant reduction of TGFb receptor type II mRNA and protein expression in thyroid carcinomas but found no reduction in thyroid adenomas. These studies suggest that escape from the growth inhibitory effect of TGFb1 may play an important role in the progression of human thyroid cancer.

Iodine increases the thyroid production of TGFb1 (58), a process that is related to iodine organification. Iodine deficiency, therefore, may result in a decrease of thyroid cell growth negative regulation.

Increased angiogenesis

Iodine deficiency causes thyroid enlargement (goiter), which is characterized also by formation of new vessels. The factors regulating angiogenesis in thyroid are not yet well established. Many of the factors elaborated by the thyroid, e.g., IGF-I (59) and FGF (60), also act in vivo on endothelial cells to induce neovascularization (59) and to enhance adhesion molecule synthesis to support thyroid growth. Data from animal thyroid tissue support the hypothesis that capillary growth during thyroid enlargement occurs, at least in part, as a result of a parenchymal-stromal (epithelial-mesenchymal) paracrine interaction mediated by specific endotheliotropic (angiogenic) factors released by follicular epithelial cells (62). FGF is also a potent thyroid cell mitogen (63). In agreement, serum vascular endothelial growth factor (VEGF) is significantly elevated in patients with metastatic differentiated thyroid cancer but not in those with poorly differentiated thyroid cancer metastases (64). Furthermore, in hypothyroid subjects, serum VEGF levels correlate with TSH values (65).

Thus, the proposed mechanisms implicating growth factors associating low iodine intake to thyroid carcinogenesis can be summarized as follows:

• Increased TSH stimulation: low T4 synthesis associated to higher TSH secretion will promote follicular cell proliferation

• Thyroid cell responsiveness to TSH: is increased in iodine deficient thyroid cell (increased Ca++ and cAMP pathways)

• Increased thyroid cells EGF-induced proliferation: decreased intracellular organified iodine intermediate (iodolactone or 2-iodohexadecanal) will result in EGF-induced cell proliferation

• Decreased TGFb production: thyroid cell proliferation is inhibited by TGFb. Iodine deficiency will result in a decrease of growth negative regulation

• Increased angiogenesis: may promote tumor growth.

 

EPIDEMIOLOGICAL STUDIES, RELATIONSHIP BETWEEN IODINE INTAKE AND THYROID CANCER HISTOTYPES

Thyroid carcinoma is an infrequent tumor with geographic variation in its prevalence. Papillary carcinoma accounts for 85–90% of differentiated thyroid cancers in iodide-sufficient countries (66), while the remaining epithelial thyroid cell tumors are predominantly follicular carcinomas. Anaplastic carcinoma, whose incidence has been decreasing, often arises from preexisting well-differentiated (usually follicular) carcinoma (67).

Epidemiologists search for clues to causes of disease and to factors that increase an individual’s risk of disease (risk factors) by examining descriptive data or designing analytic studies. Descriptive data consist of morbidity, mortality or incidence rates of diseases in population groups. Incidence rates (newly diagnosed cases in a population over a given time period) reveal patterns of disease by age, race, sex, ethnic group and geographic localization. Those rates and their changes over time identify high-risk groups and provide indirect evidence for causes of disease. Analytical epidemiology consists of case control, often termed retrospective and cohort or prospective studies. These studies permit greater control of confounding factors and an opportunity to link exposure and response information in individuals. Thus, evidence for causes of disease is more direct.

Numerous studies have been carried out in the populations of distinct geographical areas known to have different iodine intake and in the same area, before and after changes in population iodine intake, in order to evaluate the discrepancies in the prevalence of thyroid cancer. Most of them, however, are considered to be biased by either ethnic differences in the studies populations and also by environmental factors, other than iodine deficiency, that may also influence thyroid tumorigenesis, like exposure to radiation, goitrogens or diet. The distinct procedures used by the investigators for both surveying cancer and evaluating iodine deficiency may also have affected the results obtained.

The epidemiologic approach to investigating whether goiter leads to thyroid cancer in humans is based in the following procedures:

1. examine descriptive data

2. compare the thyroid cancer rates between endemic goiter areas and goiter-free areas

3. examine time trends for thyroid cancer after prophylactic measures (iodine supplementation) reduce endemic goiter frequency in a given area, and

4. evaluate whether goitrous individuals have a greater risk of thyroid cancer or whether thyroid cancer cases have a more frequent history of hyperplasia and nodules than controls.

Clinically evident thyroid nodules and benign goiters occur frequently in iodine-deficient areas. A population-based study carried out in Sicily in two adjacent areas with different iodine intake but similar ethnic and life-style characteristics, first surveyed cold thyroid nodules and then using fine needle aspiration and cytology which percentage of cancer occurred among the cold nodules in two populations (68). This study indicated that the risk of thyroid cancer is increased (relative risk = 1.4) in the population living in the iodine deficient area.

The relationship of thyroid cancer to endemic goiter is widely accepted (69,70). In agreement, it was found a geographical correlation between endemic areas for goiter and thyroid cancer. A higher incidence of thyroid cancer was found in England, Wales and Switzerland in areas with endemic goiter (70,71). However, no association was found in the United States between goitrous and non-goitrous areas (72). Another study performed in Nordic countries as Finland, Iceland, Norway and Sweden over periods ranging from 1 to 14 years found no association between the presence of endemic goiter and the risk of follicular carcinoma. Further, there was a marked negative association between endemic goiter and the risk of papillary carcinoma (73).

The search for a similar relationship between the occurrence of malignant thyroid tumors and iodine intake has been controversial and with conflicting results.

The overall incidence of thyroid carcinoma is generally considered without influence from the iodine intake in a given population (3), although a study from two regions in Italy has recently demonstrated a two-fold increase in thyroid cancer incidence in an iodine-deficient area compared to an iodine-sufficient one (68). Contrary to this, some of the highest incidence rates of thyroid cancer are found in Iceland (74) and Hawaii (75) (table 1), both known to have long-standing high iodine intake, although exposure to volcanic activity (where the natural radiation is higher and radiation is known to increase the development of thyroid carcinomas) has been suggested as an explanation for the high incidence in these islands.

 

 

Very recently, another study compared the thyroid cancer incidence by morphological subtypes in the eastern (with mild iodine deficiency) and western (with moderate iodine deficiency) Denmark, in the period of 1973– 1997. No regional difference was found in the overall incidence of follicular or papillary thyroid cancer (76).

Overall the above data indicate that:

• nutritional iodine intake and incidence of cancer remains a controversial issue

• there is a weak evidence that low iodine intake would increase the temporal incidence of thyroid malignancy in a given population

• high iodine intake, however, is also associated with an increased incidence of thyroid cancer (other environmental factors may be present).

Differences in iodine intake also affect the distribution of morphological subtypes of thyroid cancer, although the findings are also equivocal.

It has been hypothesized that iodine deficiency causes a high incidence of follicular tumors and that iodine supplementation shifts the distribution towards papillary tumors, as observed in Switzerland (70), Germany (77) and in Austria (78) (figure 1).

A study in Tasmania during a period when iodine intake changed from sufficient to deficient (1978–1998) showed a similar trend, although this followed a period of iodine supplementation, which complicates the interpretation (79) (table 2).

 

 

In a Swedish study, papillary thyroid cancer was commoner in iodine-rich areas, and follicular cancer was more common in iodine-depleted areas. After an iodine supplementation program, the incidence of papillary cancer rose and that of follicular cancer fell, but these trends were the same in both areas, and thus unrelated to the supplementation program (80). These inconsistencies in the results of these studies might be explained by different causation patterns for the different histological subtypes. In line with this argument, a case control study in Sweden of 484 cases of thyroid cancers during 1980–1992 (80) showed that the length of residence in an iodine-deficient area where goiter had been endemic was most strongly associated with an increased risk of thyroid follicular cancer (RR = 1.3–1.5). Moreover, for papillary cancer, an increased risk (RR) to 2.5 was observed only for women exposed to iodine-deficiency during puberty (81). Overall there remains a general view that no convincing evidence has yet emerged to link environmental thyroid cancer with areas of iodine deficiency (82-84). In a recent study on the effect of iodine intake on thyroid diseases in China, three representative communities, respectively with deficient iodine intake (A), normal iodine intake (B) and excessive iodine intake (C), were surveyed for thyroid diseases in a period of five years. No cases of thyroid cancer were identified in areas A and B but, at baseline, 10 patients with thyroid cancer were identified in the area C (excessive iodine intake). Moreover 13 new cases of thyroid cancer were diagnosed in this area C but none were found in the two other regions (A, B). Although this study has some limitations, it points to the fact that excessive iodine intake may be linked to a higher prevalence of thyroid cancer as compared to populations with low or adequate Iodine nutrition (85). More recently, Camargo et al. (86) studied urinary excretion of iodine, thyroid function tests, thyroid antibodies and sonographic characteristics of 829 inhabitants of a suburban area of great São Paulo city. This population had been on excessive iodine intake (59.5% excreted more than 300 µg Iodine/L of urine) for six years (1998–2003). Although there was an increase in prevalence of autoimmune thyroiditis (17.9%), 18 nodules (2.18%) were considered suspicious for malignancy (none have yet been submitted to surgery). In order to reach a conclusion about excessive intake and thyroid cancer it would be necessary to follow-up subjects with nodules form this population for at least two more years and to obtain histological evidence (after surgery) for suspicious nodules.

There is also some further evidence that has come from studies in areas with previous iodine deficiency before and after iodine prophylaxis, that the incidence rates of the type of thyroid carcinoma may be changing. In one such study from an area in Argentina (82), the ratio of papillary to follicular carcinomas rose from 1.7:1 to 3.1:1 (table 3).

 

 

Another study demonstrated that the histopathological types of thyroid cancer are different in iodine deficient areas and iodine sufficient ones (83).

A striking difference in the relative prevalence in the thyroid cancer histotypes was also observed in the two adjacent areas of Sicily (68) with different iodine intake (table 4) indicating that even moderate iodine deficiency is associated with an increased frequency of more aggressive histopathological types of thyroid cancer. However, it should be emphasized that the long-standing program of supplementation of food items with iodine in Sweden has not affected thyroid cancer trends in iodine-deficient or iodine-rich areas (80).

 

 

 

 

An alternative explanation for the observed increase in the number of papillary cancers could be the introduction and wider use of more modern and precise examination equipment through the years, as the reversal of iodine deficiency coincides with the dissemination of better techniques in the health system, including thyroid scintigraphy, ultrasound and fine-needle biopsy. Furthermore, in areas without iodine deficiency, and hence less goiter, patients are more likely to notice a slight change in their thyroid gland and visit their doctor for examination (3). Autopsy studies support the possibility of a pool of slowly growing, undiagnosed papillary thyroid tumors (84).

The importance of accurate histological typing in cancer epidemiology cannot be overemphasized, and great caution is needed in comparison of different types of thyroid tumors in different populations if not evidenced by the same pathologist. The reproducibility of the WHO classification has been questioned and a considerable observer variation has been reported, particularly as regards to follicular and mixed papillary-follicular cancers (87). Differences in the detection and inclusion of occult thyroid cancers in the studies could also play a role in the observed cancer incidences. Finally, it should be noted that a concomitant selenium deficiency in iodine-deficient areas has not been taken into account, since selenium (Se) deficiency in itself has recently been associated with an increased incidence of thyroid carcinoma, based on converging data from epidemiological and clinical studies (88). Other studies, however, failed to find links between Se and thyroid carcinogenesis (89). To our knowledge, up to now there are no reliable experimental data that supports the plausibility of Se as a risk factor in thyroid cancer.

All of the above reservations are probably reasons why comparison of thyroid carcinoma epidemiology in different populations and geographic areas are so difficult to perform and interpret, and why no specific solutions to the questions concerning environmental influence of iodine intake have been provided, despite a large number of studies over many years.

Thus, regarding iodine prophylaxis and variations on thyroid cancer incidence, the data indicate that:

• After iodine prophylaxis it has been demonstrated a clear relationship between increased iodine nutrition and elevation of the PTC/FTC ratio

• This has occurred even in modest increases in iodine urinary excretion

• A decrease in prevalence of anaplastic thyroid cancer was also observed in most areas.

 

CONCLUSION

Available evidence from animal experiments, epidemiological studies and from the introduction of iodine prophylaxis has demonstrated a relationship between iodine intake and the types of thyroid carcinoma, while no clear evidence exists for a relationship between the overall cancer incidence and iodine intake. All the studies are in general hampered by difficulty in comparing populations since many factors have to be considered other than the iodine intake, such as ethnicity, other dietary factors (e.g., selenium), histological examination and radiation. Knowledge of all these factors has an influence also on the diagnostic work-up and management of patients in each population.

 

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Address for correspondence:
Meyer Knobel
Thyroid Unit, Division of Endocrinology and Metabolism
Hospital das Clínicas, University of São Paulo Medical School
Av. Dr. Enéas Carvalho de Aguiar 155, 8 A, bl 3, PAMB
05403-900 São Paulo, SP
Fax: (11) 3069-7970
E-mail: meyer.knobel@hcnet.usp.br

Recebido em 12/12/06
Aceito em 16/12/06