International Scholarly Research Network
ISRN Oncology
Volume 2011, Article ID 708343, 5 pages
doi:10.5402/2011/708343

Clinical Study

Does Radioiodine Therapy in Patients with
Differentiated Thyroid Cancer Increase the Frequency of
Another Malignant Neoplasm?

Renata Midori Hirosawa,1 Monica Marivo,1 Juliana de Moura Leite Luengo,1

Jose Vicente Tagliarini,2 Emanuel Cellice Castilho,2 Mariangela de Alencar Marques,3

Yoshio Kiy,4 Marilia Martins Silveira Marone,5 Liciana Vaz de Arruda Silveira,6

and Glaucia Maria Ferreira da Silva Mazeto1

1 Departamento de Clinica Medica, Faculdade de Medicina (FMB), UNESP, Rubiao Junior s/n, Botucatu,
18618-000 São Paulo, Brazil

2 Departamento de Oftalmologia e Otorrinolaringologia, Faculdade de Medicina (FMB), UNESP, Rubiao Junior s/n, Botucatu,
18618-000 São Paulo, Brazil

3 Departamento de Patologia, Faculdade de Medicina (FMB), UNESP, Rubiao Junior s/n, Botucatu, 18618-000 São Paulo, Brazil
4 Servico de Medicina Nuclear, Faculdade de Medicina (FMB), UNESP, Rubiao Junior s/n, Botucatu, 18618-000 São Paulo, Brazil
5 Servico de Medicina Nuclear, Santa Casa de Sao Paulo, Rua Cesario Mota Junior, 112 ,Vila Buarque,
01221-020 São Paulo, Brazil

6 Departamento de Bioestatistica, Instituto de Biociencias, UNESP, Rubiao Junior s/n, Botucatu, 18618-000 São Paulo, Brazil

Correspondence should be addressed to Renata Midori Hirosawa, rmhirosawa@yahoo.com.br

Received 7 June 2011; Accepted 30 June 2011

Academic Editor: J. E. Tyczynski

Copyright © 2011 Renata Midori Hirosawa et al. This is an open access article distributed under the Creative Commons
Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is
properly cited.

Objectives. To compare the frequency of another primary malignancy in patients with differentiated thyroid carcinoma (DTC) who
received radioiodine therapy or not (131I). Material and Methods. 168 cases of DTC patients were retrospectively evaluated as to the
frequency of another neoplasia by comparing patients with and without it, taking into account clinical, laboratory, and therapeutic
parameters. Results. Another primary malignancy occurred in 8.9% of patients. Of these, 53.3% showed the malignancy before 131I
and 46.7% after it. By comparing both groups, the age at the moment of diagnosis of another neoplasia was 46.1 ± 20.2 years for
the group before 131I therapy and of 69.4 ± 11.4 years for the group after it (P = 0.02). Of the 148 patients treated with 131I, 4.7%
developed another malignancy. The latter were older (61 ± 17 years) than those who did not show another cancer type (44.1 ±
14.2 years) (P < 0.05). Conclusion. The frequency of another neoplasia found after 131I was similar to that found before 131I.

1. Introduction

Differentiated thyroid carcinomas (DTC) are the most fre-
quent malignant endocrine neoplasias [1, 2], and when
properly treated, they show good prognosis and similar life
expectancy to that of the general population [3].

Total thyroidectomy followed by radioiodine ablation
(131I), associated with TSH suppression therapy with
levothyroxine, is the initial treatment recommended for the
majority of patients [4, 5].

Thyroid ablation by 131I fosters the followup of patients
with DTC since it increases serum thyroglobulin specificity
as a tumor marker. It also fosters early metastasis detection
by means of whole-body scanning (WBS) after an uptake
[6].

Recent studies have reported increased risk for devel-
oping a second cancer after radioiodine therapy [7–9]. On
the other hand, some authors have suggested that patients
with DTC per se show increased incidence of neoplasias
that are unrelated to 131I therapy, thus suggesting another



2 ISRN Oncology

common etiology and/or genetic mechanism rather than a
causal relationship [10, 11].

Hence, the present study aimed at evaluating the fre-
quency of another primary malignancy, in addition to DTC,
and its temporal relation to 131I, in patients assisted at a
specialized outpatient unit of a university hospital.

2. Material and Methods

The medical records of 168 patients with DTC who initiated
followup at the Thyroid Neoplasia Outpatient Unit of the
Botucatu School of Medicine, UNESP from 1970 to 2008
were retrospectively evaluated.

The following data were obtained: gender, age, age at
the time of thyroidectomy, DTC histological type, follow-up
period, radioiodine therapy performance, accumulated dose
of 131I, presence of a second malignancy, age at its diagnosis,
temporal relationship between the diagnosis of the second
malignancy and 131I dose, and the second type of malignancy
presented.

Of the 168 patients, eight were not submitted to 131I, and
12 did not have information about the total 131I dose. Thus,
the number of patients effectively treated with radioiodine
was 148. They were classified into two groups (with and
without another neoplasia after 131I use) and then compared
in relation to gender, age at thyroidectomy, histological type
of DTC, follow-up period, accumulated dose of 131I, age at
the diagnosis of another malignancy, and the second type of
malignancy presented.

The patients who developed another neoplasia were
also classified into two groups: the first group showed a
second malignancy before the 131I dose and the second group
showed it after the 131I dose. Such two groups were also
compared with respect to the abovementioned parameters.

2.1. Statistical Analysis. Excel sheets (Microsoft Corporation,
EUA) and the Statistical Analysis System (SAS) software
package, version 9.2, were used for statistical analysis. Results
were expressed in terms of frequencies, mean ± standard
deviation, or median (minimum and maximum values).
Clinical, laboratory, and development data were compared
by using the most appropriate statistical tests to each case.
Student’s t-test for independent samples, the Chi-square test,
and Fisher’s exact test were utilized. Logistic regression, from
which the odds ratio was obtained, and generalized linear
models, with gamma error and a log-link function, were also
fitted. 95% confidence intervals and a 5% level of significance
(P < 0.05) were used.

3. Results

The patients’ general, clinical, epidemiological, and thera-
peutic characteristics, are shown in Table 1. Fifteen patients
(8.9%) showed another neoplasia in addition to DTC. Of
these, eight (53.3%) did not receive 131I or showed the second
malignancy before 131I use, and seven (46.6%) showed it
after 131I therapy. By comparing these two groups, age at the
diagnosis of the second neoplasia was smaller for patients
who developed it before 131I than in the group in which

Table 1: Clinical, epidemiological, and therapeutic characteristics
of 168 patients with differentiated thyroid carcinoma (DTC).

Clinical, epidemiological, and therapeutic characteristics

Females n (%) Female: 142 (84.7)

Age∗ (years) 45.15 ± 15.32

Follow-up period∗∗ (months) 77.5 (1; 468)

Papilliferous carcinoma n (%) 137 (81.5)

Radioiodine therapy n (%) 160 (95.2)

Radioiodine dose∗∗ (mCi) 200 (30; 870)

Another neoplasia n (%) 15 (8.93)
∗

mean ± standard deviation; ∗∗median (minimum value; maximum
value).

another malignancy was observed after radioiodine therapy
(P = 0.02). No significant differences were observed with
respect to gender, age at thyroidectomy, follow-up period, or
histological type of DTC between the two groups (Table 2).

The neoplasias diagnosed before and after 131I therapy
are specified in Table 3.

Of the 148 patients who received a known accumulated
dose of 131I, seven (4.7%) developed a second malignancy
after treatment. The median time between 131I therapy
and diagnosis of second malignancy was 60 months, with
minimum of 6 months and maximum of 275 months. Age at
thyroidectomy was greater in the group of individuals who
developed another malignancy than in those who did not
show it (P = 0.006). No statistically significant differences
were observed with respect to gender, follow-up period,
accumulated 131I dose, or histological type of DTC between
the two groups (Table 4).

4. Discussion

The association of radioiodine therapy with the development
of a second neoplasia in patients with DTC has been
controversial. In our service, the frequency of other primary
neoplasias was 8.9%, which is an apparently high percentage
when taking into account that the estimated incidence of
malignant neoplasias for the general population in São Paulo
state for the years 2010 and 2011 is approximately 313 per
year for every 100,000 inhabitants [12].

Increased risk for a second neoplasia in patients with
DTC has been reported. Sandeep et al. analyzed over 39,000
patients with thyroid carcinoma and observed 30% risk
increase for developing a second malignancy as compared to
the general population. Additionally, greater occurrence of
thyroid cancer in patients with other types of neoplasias has
been found [8].

In the present study, it was observed that, of the patients
showing another neoplasia, similar percentages had (46.6%)
or had not (53.3%) received a therapeutic dose of 131I before
the other neoplasm. These findings are in agreement with
those reported by Bhattacharyya et al., who observed that
the use of radioiodine did not increase risk for developing
a second neoplasia by evaluating over 29,000 patients with
DTC [11]. Similarly, Verkooijen et al. observed that the
increased incidence of a second neoplasia was not related



ISRN Oncology 3

Table 2: Clinical and epidemiological characteristics of 15 patients with differentiated thyroid carcinoma and another malignancy.

Clinical and epidemiological characteristic
Another malignancy

P
Postiodine
N = 7

(46.66%)

Preiodine
N = 8

(53.33%)

Males N (%) 4 (57.14) 3 (37.5) 0.6193

Age at thyroidectomy (years)∗ 61 ± 17 51 ± 13.7 0.2295

Follow-up period (months)∗∗ 75 (48; 336) 56.5 (20; 60) 0.1505

Age at diagnosis of a second neoplasia∗ (years) 69.4 ± 11.4 46.1 ± 20.2 0.0187

Classic nonpapilliferous histological type N (%) 3 (42.85) 2 (25) 0.6084
∗

mean ± standard deviation; ∗∗median (minimum value; maximum value).

Table 3: Types of other neoplasias diagnosed in 15 patients with
differentiated thyroid carcinoma.

PRE 131I POST 131I

2 breast adenocarcinomas
2 skin spinocellular
carcinomas

1 chronic myeloid leukemia 1 prostate adenocarcinoma

1 lymphoma 1 colon adenocarcinoma

1 rectal adenocarcinoma
1 endometrial
adenocarcinoma

1 Palatal spinocellular
carcinoma

1 rectal carcinoma

1 testicular seminoma 1 lung carcinoma

1 endometrial
adenocarcinoma

to 131I therapy, thus suggesting the nonexistence of a causal
relationship between the two events [10].

Other studies, however, have shown increased risk for
a second malignancy related to radioiodine therapy. In a
prospective study on 6,841 European patients with DTC,
Rubino et al. reported 27% risk for developing a second neo-
plasia, which is a significant increase in relation to the general
population in the studied countries [7]. Those authors
also observed increased risk for both solid tumors and
leukemia, according to the accumulated dose of radioiodine
administered. In 2008, Brown et al. published a prospective
study that followed over 30,000 American patients with
DTC for approximately 103 months and also reported
significantly increased risk for a second neoplasia. Such risk
changed according to age at diagnosis and radioactive iodine
use [9]. A recent meta-analysis published in 2009 studied
over 16,000 American and European patients and found
increased risk for developing a second neoplasia in patients
receiving 131I therapy. Such risk was particularly higher for
the development of leukemia and linearly associated with the
accumulated radioiodine dose. However, previous exposure
to 131I therapy was not related to increased risk for neoplasias
in the breast, central nervous system, colon, rectum, kidneys,
or stomach of patients with DTC as compared to the general
population [13].

The differences in the findings from different studies may
be related to a number of factors, among which are the

particular characteristics of the studied populations. Some
factors, such as genetic profile and environmental character-
istics, certainly influence the prevalence of different types of
cancer. The role played by genetic heredity has been particu-
larly studied. Several loci have recently been associated with
some types of cancer and reported to increase their risk [14].
A study conducted on 9.6 million people found a greater
association with hereditary factors in cancers in the thyroid
(53%), endocrine system (25%), testis (23%), breasts (20%),
and melanoma (20%). However, other types of cancers, such
as those in the nervous system, colon, rectum, non-Hodgkin
lymphoma, and lungs, showed only slight agreement [15]. In
general, the specific role played by each gene locus in malig-
nancy induction seems to be relatively small [14]. The phe-
nomenon of incomplete alleles of cancer susceptibility and
environmental exposure could be responsible for these find-
ings. Hence, depending on the environment, an individual
with high genetic risk for developing a neoplasia may never
show it, while another individual at low risk could eventually
develop it [16, 17]. Among environmental factors, the pos-
sible influence of disruptors is noteworthy. Exposure to such
elements seems to play an important role in the occurrence of
certain cancer types [18]. The group of molecules identified
as disruptors is heterogeneous and includes synthetic prod-
ucts such as industrial solvents/lubricants and their byprod-
ucts [polychlorinated biphenyls (PCBs), polybrominated
biphenyls (PBBs), dioxins], plastics [bisphenol A (BPA)],
plasticizers (phthalates), pesticides [methoxychlor, chlor-
pyrifos, dichlorodiphenyltrichloroethane (DDT)], fungi-
cides (vinclozolin), and pharmaceutical agents [diethylstilbe-
strol (DES)]. Natural compounds present in humans as well
as animal foods (e.g., phytoestrogens, including genistein
and coumestrol) can also work as disruptors [19, 20].
Depending on age and exposure time, studies show that
some disruptors can change mechanisms that regulate cell
proliferation and tissue organization patterns, and such
alterations may also be associated with the development of
neoplastic lesions. Disruptors, such as DDT, BPA, DES, seem
to be associated with breast and prostate cancer [21–26].

In addition to the aforementioned factors, which affect
the general population, we could question how much nutri-
tional habits and iodine sufficiency influence the occurrence
of other neoplasias, specifically in patients with DTD treated
by 131I. The uptake of iodine by the thyroid tissue is mediated



4 ISRN Oncology

Table 4: Clinical, epidemiological, and therapeutic characteristics of 148 patients with differentiated thyroid carcinoma who received a
therapeutic dose of radioactive iodine and showed another postiodine malignancy or not.

Clinical and epidemiological data
Another postradioactive iodine malignancy

Odds ratio IC 95% P
Yes

N = 7
(4.7%)

No
N = 141
(95.3%)

Males N (%) 4 (57.1) 21 (14.9) 0.123 0.015–1.026 0.0528

Age at thyroidectomy (years)∗ 61± 17 44.08± 14.2 1.133 1.036–1.239 0.0061

Follow-up period (months)∗∗ 75 (48; 336) 74 (9; 468) 1.013 1.000–1.026 0.0514

Accumulated dose of 131I (mCi)∗∗ 175 (100; 300) 200 (30; 870) 0.994 0.985–1.002 0.1375

Classic nonpapilliferous histological type N (%) 3 (42.8) 59 (41.8) 2.350 0.311–17.742 0.4073
∗

mean ± standard deviation; ∗∗median (minimum value; maximum value).

by sodium-iodide symporter (NIS), cloned in 1996 [27].
Although it is classic in the thyroid, NIS is also found
in several other tissues that capture iodine, such as the
stomach, salivary glands, lactating breasts, thymus, nasal
mucosa, lachrymal glands, and placenta [28–30]. While
the NIS-mediated uptake of radioiodine by normal or
neoplastic thyroid cells depends, among other factors, on
the concentration of organified intracellular iodine [31], the
interferents affecting the uptake of that element in other
organs are not yet known. Since the induction of malignancy
by radioactive iodine must occur through exposure of tissues
to that radiopharmaceutical, the effect of iodine sufficiency
or deficiency on the uptake of 131I in nonthyroid tissues is
questionable. Hence, we may be able to hypothesize that
different populations with diverse genetic and environmental
characteristics and different iodine sufficiency could respond
differently to radioactive iodine with respect to the induction
of another neoplasia.

In this study, the studied characteristics (gender, follow-
up period, histological type, age at diagnosis of another
neoplasia) showed no statistical differences when comparing
the group that developed a second malignancy before 131I
use and the group that developed another neoplasia after 131I
therapy. The only parameter showing significance was age at
diagnosis of another neoplasia.

When comparing the patients who underwent radioio-
dine therapy but did not develop a second neoplasia (141)
to those who were also submitted to 131I and later developed
another malignancy (7), again no differences were found for
the following studied parameters: gender, follow-up period,
histological type, and accumulated 131I dose. Additionally,
the median accumulated 131I dose in patients who did not
develop a second neoplasia (200 mCi) was even higher in
relation to those showing another malignancy (175 mCi).
The only parameter that showed statistically significant
differences was age at thyroidectomy, thus suggesting that
older patients at the time of surgery could be at increased
risk for developing a second malignancy. The causes for
this finding remain to be clarified. With respect to other
primary malignancies found, no predominance of any
specific neoplasia was observed.

Our study showed limitations, such as its retrospective
character and a short follow-up period (approximately

6.5 years). Moreover, we did not do an active screening of
other cancers, considering the retrospective nature of the
study, such a procedure impractical to monitor all patients
with differentiated thyroid cancer, which would burden
our health system. Nevertheless, our findings, as previously
described in other studies, can suggest that, at least in certain
populations, the occurrence of another malignancy after 131I
does not have a causal relationship with such treatment.
Hence, patients with DTC could have increased incidence
of a second neoplasia which is not related to 131I therapy,
thus more probably suggesting a common etiology and/or a
genetic mechanism rather than a causal relationship between
the two tumors.

Conflict of Interests

The authors declare that there is no conflict of interests.

References

[1] Canadian Cancer Society. National Cancer Institute of
Canada. Statistics Canada. Public Health Agency of Canada,
“Canadian Cancer Statistics,” 2008, http://www.cancer.org/.

[2] American Cancer Society, “Cancer Facts and Figures,” 2008,
http://www.cancer.org/.

[3] M. Sant, T. Aareleid, F. Berrino et al., “EUROCARE-3:
survival of cancer patients diagnosed 1990–1994—results and
commentary,” Annals of Oncology, vol. 14, supplement 5, pp.
61–118, 2003.

[4] D. R. Blankenship, E. Chin, and D. J. Terris, “Contemporary
management of thyroid cancer,” American Journal of Otolaryn-
gology, vol. 26, no. 4, pp. 249–260, 2005.

[5] “Thyroid cancer clinical practice guidelines in oncology,”
Journal of the National Comprehensive Cancer Network, vol. 3,
p. 404, 2005.

[6] P. W. Souza do Rosário, A. L. Barroso, L. L. Rezende et
al., “Post I-131 therapy scanning in patients with thyroid
carcinoma metastases: an unnecessary cost or a relevant
contribution?” Clinical Nuclear Medicine, vol. 29, no. 12, pp.
795–798, 2004.

[7] C. Rubino, F. de Vathaire, M. E. Dottorini et al., “Second
primary malignancies in thyroid cancer patients,” British
Journal of Cancer, vol. 89, no. 9, pp. 1638–1644, 2003.



ISRN Oncology 5

[8] T. C. Sandeep, M. W. J. Strachan, R. M. Reynolds et al.,
“Second primary cancers in thyroid cancer patients: a
multinational record linkage study,” Journal of Clinical
Endocrinology and Metabolism, vol. 91, no. 5, pp. 1819–1825,
2006.

[9] A. P. Brown, J. Chen, Y. J. Hitchcock, A. Szabo, D. C. Shrieve,
and J. D. Tward, “The risk of second primary malignancies up
to three decades after the treatment of differentiated thyroid
cancer,” Journal of Clinical Endocrinology and Metabolism, vol.
93, no. 2, pp. 504–515, 2008.

[10] R. B. T. Verkooijen, J. W. A. Smit, J. A. Romijn, and M. P. M.
Stokkel, “The incidence of second primary tumors in thyroid
cancer patients is increased, but not related to treatment of
thyroid cancer,” European Journal of Endocrinology, vol. 155,
no. 6, pp. 801–806, 2006.

[11] N. Bhattacharyya and W. Chien, “Risk of second primary
malignancy after radioactive iodine treatment for differen-
tiated thyroid carcinoma,” Annals of Otology, Rhinology and
Laryngology, vol. 115, no. 8, pp. 607–610, 2006.

[12] Instituto Nacional de Câncer, “Estimativa 2010: incidência
de câncer no Brasil,” http://www.inca.gov.br/estimativa/2010/
index.asp?link=conteudo view.asp&ID=3.

[13] A. M. Sawka, L. Thabane, L. Parlea et al., “Second primary
malignancy risk after radioactive iodine treatment for thyroid
cancer: a systematic review and meta-analysis,” Thyroid, vol.
19, no. 5, pp. 451–457, 2009.

[14] A. Galvan, J. P. A. Ioannidis, and T. A. Dragani, “Beyond
genome-wide association studies: genetic heterogeneity and
individual predisposition to cancer,” Trends in Genetics, vol.
26, no. 3, pp. 132–141, 2010.

[15] K. Czene, P. Lichtenstein, and K. Hemminki, “Environmental
and heritable causes of cancer among 9.6 million individuals
in the Swedish Family-Cancer Database,” International Journal
of Cancer, vol. 99, no. 2, pp. 260–266, 2002.

[16] P. Lichtenstein, N. V. Holm, P. K. Verkasalo et al., “Envi-
ronmental and heritable factors in the causation of cancer:
analyses of cohorts of twins from Sweden, Denmark, and
Finland,” The New England Journal of Medicine, vol. 343, no.
2, pp. 78–85, 2000.

[17] J. P. Ioannidis, E. Y. Loy, R. Poulton, and K. S. Chia, “Research-
ing genetic versus nongenetic determinants of disease: a
comparison and proposed unification,” Science Translational
Medicine, vol. 1, no. 7, pp. 7–ps8, 2009.

[18] E. Diamanti-Kandarakis, J. P. Bourguignon, L. C. Giudice
et al., “Endocrine-disrupting chemicals: an endocrine society
scientific statement,” Endocrine Reviews, vol. 30, no. 4, pp.
293–342, 2009.

[19] G. G. J. M. Kuiper, J. G. Lemmen, B. Carlsson et al.,
“Interaction of estrogenic chemicals and phytoestrogens with
estrogen receptor β,” Endocrinology, vol. 139, no. 10, pp. 4252–
4263, 1998.

[20] S. M. Dickerson and A. C. Gore, “Estrogenic environmental
endocrine-disrupting chemical effects on reproductive neu-
roendocrine function and dysfunction across the life cycle,”
Reviews in Endocrine and Metabolic Disorders, vol. 8, no. 2, pp.
143–159, 2007.

[21] J. R. Palmer, E. E. Hatch, C. L. Rosenberg et al., “Risk
of breast cancer in women exposed to diethylstilbestrol in
utero: preliminary results (United States),” Cancer Causes and
Control, vol. 13, no. 8, pp. 753–758, 2002.

[22] J. R. Palmer, L. A. Wise, E. E. Hatch et al., “Prenatal
diethylstilbestrol exposure and risk of breast cancer,” Cancer
Epidemiology Biomarkers and Prevention, vol. 15, no. 8, pp.
1509–1514, 2006.

[23] M. Durando, L. Kass, J. Piva et al., “Prenatal bisphenol A
exposure induces preneoplastic lesions in the mammary gland
in Wistar rats,” Environmental Health Perspectives, vol. 115, no.
1, pp. 80–86, 2007.

[24] S. G. Driscoll and S. H. Taylor, “Effects of prenatal maternal
estrogen on the male urogenital system,” Obstetrics and
Gynecology, vol. 56, no. 5, pp. 537–542, 1980.

[25] R. A. Keri, S. M. Ho, P. A. Hunt, K. E. Knudsen, A. M. Soto, and
G. S. Prins, “An evaluation of evidence for the carcinogenic
activity of bisphenol A,” Reproductive Toxicology, vol. 24, no.
2, pp. 240–252, 2007.

[26] P. Cocco and J. Benichou, “Mortality from cancer of the
male reproductive tract and environmental exposure to the
anti-androgen p,p’-dichlorodiphenyldichloroethylene in the
United States,” Oncology, vol. 55, no. 4, pp. 334–339, 1998.

[27] P. A. Smanik, Q. Liu, T. L. Furminger et al., “Cloning
of the human sodium iodide symporter,” Biochemical and
Biophysical Research Communications, vol. 226, no. 2, pp. 339–
345, 1996.

[28] A. de la Vieja, O. Dohan, O. Levy, and N. Carrasco, “Molecular
analysis of the sodium/iodide symporter: impact on thyroid
and extrathyroid pathophysiology,” Physiological Reviews, vol.
80, no. 3, pp. 1083–1105, 2000.

[29] L. S. Zuckier, O. Dohan, Y. Li, C. J. Chang, N. Carrasco, and E.
Dadachova, “Kinetics of perrhenate uptake and comparative
biodistribution of perrhenate, pertechnetate, and iodide by
NaI symporter-expressing tissues in vivo,” The Journal of
Nuclear Medicine, vol. 45, no. 3, pp. 500–507, 2004.

[30] D. H. Y. Shen, R. T. Kloos, E. L. Mazzaferri, and S. M. Jhiang,
“Sodium iodide symporter in health and disease,” Thyroid, vol.
11, no. 5, pp. 415–425, 2001.

[31] D. P. Carvalho and A. C. F. Ferreira, “The importance of
sodium/iodide symporter (NIS) for thyroid cancer manage-
ment,” Arquivos Brasileiros de Endocrinologia e Metabologia,
vol. 51, no. 5, pp. 672–682, 2007.



Submit your manuscripts at
http://www.hindawi.com

Stem Cells
International

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

MEDIATORS
INFLAMMATION

of

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

Behavioural 
Neurology

Endocrinology
International Journal of

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

Disease Markers

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

BioMed 
Research International

Oncology
Journal of

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

Oxidative Medicine and 
Cellular Longevity

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

PPAR Research

The Scientific 
World Journal
Hindawi Publishing Corporation 
http://www.hindawi.com Volume 2014

Immunology Research
Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

Journal of

Obesity
Journal of

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

 Computational and  
Mathematical Methods 
in Medicine

Ophthalmology
Journal of

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

Diabetes Research
Journal of

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

Research and Treatment
AIDS

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

Gastroenterology 
Research and Practice

Hindawi Publishing Corporation
http://www.hindawi.com Volume 2014

Parkinson’s 
Disease

Evidence-Based 
Complementary and 
Alternative Medicine

Volume 2014
Hindawi Publishing Corporation
http://www.hindawi.com