Graves' disease (GD) is the most common cause

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Thyroid peroxidase antibody positivity and triiodothyronine levels are associated with pediatric Graves' ophthalmopathy Jung Hyun Lee, So Hyun Park, Dae Gyun Koh, Byung Kyu Suh Gyeonggi-do, Korea Background: Graves' ophthalmopathy (GO) occurs commonly in children with Graves' disease (GD). However, there are limited studies on the clinical manifestations and thyroid autoantibodies in pediatric GO. The aim of this study was to investigate the prevalence and risk factors of GO in childhood GD. Methods: Clinical and biochemical data from children and adolescents with GD were retrospectively reviewed. Eighty patients under 19 years of age were included in the present study. We compared the clinical and biochemical differences between patients with and without GO. Results: Thirty-nine percent of the patients had GO, and 81% of the GO patients were females. Of these, two patients showed unilateral GO. Triiodothyronine (T3) levels were higher in GO patients than in those without GO. Anti-thyroglobulin antibody and thyroid stimulating hormone receptor antibody titers were not significantly different between the two groups. Anti-thyroid peroxidase antibody (TPO Ab) positivity was 68% in the patients with GO and only 47% in the patients without GO. In multivariate regression analysis, high T3 levels and TPO Ab positivity were related to the presence of GO. Conclusion: In children and adolescents with GD, TPO Ab positivity and high T3 levels could act as predictive factors for the presence of GO. World J Pediatr 2014;10(2):155-159 Author Affiliations: Department of Pediatrics, the Catholic University of Korea, St. Vincent's Hospital, 93-6, Ji-dong, Paldal-gu, Suwon-si, Gyeonggi-do, Republic of Korea (Lee JH, Park SH, Koh DG); Department of Pediatrics, the Catholic University of Korea, Seoul St. Mary's Hospital, 222 Banpo-daero, Seocho-gu, Seoul, Republic of Korea (Suh BK) Corresponding Author: So Hyun Park, Department of Pediatrics, The Catholic University of Korea, St. Vincent Hospital, 93-6, Ji-dong, Paldalgu, Suwon-si, Gyeonggi-do, Republic of Korea (Tel:+82 31 249 8312; Fax: +82 257 9111; Email: nicedoc@catholic.ac.kr) doi: 10.1007/s12519-014-0476-y Children's Hospital, Zhejiang University School of Medicine, China and Springer-Verlag Berlin Heidelberg 2014. All rights reserved. Key words: Graves' disease; Graves' ophthalmopathy; pediatrics; thyroid peroxidase antibody; triiodothyronine Introduction Graves' disease (GD) is the most common cause of thyrotoxicosis in the pediatric population. Affected children suffer from abnormal physical growth, impaired school performance, and complain of cosmetic problems characterized by ocular manifestations, so-called Graves' ophthalmopathy (GO). According to a recent study, [1] GO occurs in 33% of the children and adolescents with GD. In adults, GO is characterized by increased retrobulbar tissue, enlargement of the extraocular muscles, and elevation of intraocular pressure, leading to eyelid swelling, proptosis, and even loss of vision. [1,2] GO is less severe in children, with the predominant eye manifestations being exophthalmos and involvement of the soft tissues; eye muscles and optic function are infrequently affected. [2-5] Nevertheless, GO can still significantly impair the quality of life of affected children. For instance, prominent exophthalmos can be very stressful to adolescents who are conscious of their appearance. Furthermore, severe GO can have life-long effects on the quality of life of the patients. [6] GO often develops concomitantly with hyperthyroidism, but it could precede or follow hyperthyroidism. GO is usually bilateral, but it can be asymmetric or unilateral. [7] Case series report that even in the absence of clinical manifestations, imaging studies could reveal subtle orbital changes in most GD patients. Common ocular symptoms, including diplopia and symptoms related to corneal exposure, such as photophobia, tearing, grittiness, and pain, may interfere with daily activities. [7] Bartley et al [8] indicated that the incidences of eyelid retraction, exophthalmos, extraocular muscle dysfunction, ocular pain, and lacrimation were 91%, 62%, 43%, 30%, and 23%, respectively. Studies [9,10] on GO pathogenesis in adults have revealed an association 155

World Journal of Pediatrics between thyroid stimulating hormone receptor antibodies (TSHR Ab) and the occurrence and severity of GO. GO is more prevalent in female patients, whereas severe GO is more common in male patients. [11] Some studies [12] showed that patients treated with radioactive iodine were more prone to GO than those treated with antithyroid drugs. Few studies [2,13,14] have focused on the clinical and laboratory factors that affect the pathogenesis of GO in children. The present study aimed to identify the predictive factors associated with GO in children in comparing the clinical features of GD patients with and without GO. Methods Patients This study included all GD patients who were diagnosed at age 18 or younger and were followed up for more than one year at St. Vincent Hospital of the Catholic University of Korea, Suwon, South Korea from January 2000 to December 2012. A total of 80 patients (17 boys and 63 girls) met these criteria. Diagnostic criteria for GD were defined as low serum thyroid stimulating hormone (TSH) levels with high serum triiodothyronine (T3) and free thyroxin (ft4) levels and positivity for serum TSHR Ab. The diagnosis of GO was according to Vision, Inflammation, Strabismus, and Appearance (VISA) classification [15] based on the presence of clinically apparent symptoms and signs of disease, including visual acuity loss, eyelid edema, eyelid retraction, exophthalmos, diplopia, photophobia, tearing grittiness, ocular pain, lacrimation and impaired motility due to ocular myopathy. Exophthalmos is diagnosed by measurement with a Hertel exophthalmometer also according to the VISA classification. However, there are no diagnostic criteria for young children with exophthalmos, children less than 10 years of age were diagnosed with exophthalmos by description of the patients and their parents, and confirmed by one ophthalmologist. Orbital imaging with the use of computed tomography (CT) was warranted to GD patients in whom ophthalmopathy is unilateral. The findings of orbital imaging in patients with GO included enlargement of the extraocular muscles, an increase in intraorbital fat tissue, or both. [16] This study complied with the recommendations of the Declaration of Helsinki and was approved by the Institutional Review Board of the St. Vincent Hospital of the Catholic University of Korea. Laboratory methods The levels of serum T3, ft4, and TSH were measured by a chemiluminescent microparticle immunoassay using an Architect i2000 analyzer (Abbott, Abbott Park, IL, USA). The levels of serum anti-thyroid peroxidase antibody (TPO Ab) and anti-thyroglobulin antibody (Tg Ab) were measured by a chemiluminescent immunometric assay using an Immulite 200 analyzer (Siemens Healthcare Diagnostic Products Ltd., Llanberis, Gwynedd, UK). TSHR Ab levels, considered to reflect thyrotropin binding inhibitory immunoglobulin (TBII) levels, were measured by an electrochemiluminescence immunoassay using a Cobase 411 analyzer (Roche Diagnostics GmbH, Mannheim, Germany). Reference values were as follows: T3, 0.58-1.9 ng/ml; ft4, 0.7-1.79 ng/dl; TSH, 0.35-4.95 μiu/ml; TPO Ab, <30 IU/mL; Tg Ab, <40 IU/mL; and TSHR Ab, <1.75 IU/L. Statistical analysis Statistical analyses were performed using SPSS for Windows (version 12.0, SPSS Inc., Chicago, IL, USA). Continuous variables were expressed as the mean±standard deviation of values. Student's t test and the Mann-Whitney U test were used for the analysis of continuous data and the chi-square test or Fisher's exact test was used for the analysis of categorical variables. Multivariate logistic regression analysis was performed to investigate the odds ratios (OR) and 95% confidence interval (CI) of clinical predictors among several parameters associated with the presence of GO. P values less than 0.05 were considered statistically significant. Results Clinical characteristics of patients with GD The medical records of 98 patients who met the eligibility criteria were retrospectively reviewed. Eighteen of these patients were excluded from the study, as they were referred to our clinic in the middle of their treatment or had incomplete medical records. Thus, a total of 80 patients (17 boys and 63 girls) who were newly diagnosed and were followed up for more than 12 months at St. Vincent Hospital were included in the study. The mean age of the patients was 12.2±3.5 years (range, 2-18 years). Of the 80 patients, 31 (39%) had GO (Table 2). Most of the patients had cardiac manifestations (73%), goitre (65%), and weight loss (60%). Symptoms present in a minority of patients included restlessness, enuresis, and diarrhea; one patient showed weight gain (Table 1). Table 1 illustrates the clinical manifestations of GD in all patients. Orbit CT scan was performed in 2 patients with unilateral GO and revealed rectus muscle hypertrophy rather than lipid hyperplasia. All patients were non-smokers. The patients with GO had exophthalmos and eyelid 156

Table 1. Clinical manifestations of patients with Graves' disease Clinical manifestations n (%) Cardiac manifestations 58 (73) Goiter 52 (65) Weight loss 48 (60) Heat intolerance 45 (56) Ophthalmopathy 31 (39) Restlessness 25 (31) Enuresis 3 (4) Diarrhea 3 (4) Hyperglycemia 1 (1) Weight gain 1 (1) Total 80 (100) Table 2. Comparison of clinical and laboratory findings between patients with Graves' ophthalmopathy and without Graves' ophthalmopathy Parameters GO Without GO P value Age at diagnosis (y) 11.29±3.60 12.76±3.27 0.523 Sex, n (%) Male (n=17) 6 (19%) 11 (22%) 0.787 Female (n=63) 25 (81%) 38 (78%) Goiter, n (%) Present 23 (74%) 29 (59%) 0.230 Absent 8 (26%) 20 (41%) Weight loss, n (%) Present 25 (81%) 23 (47%) 0.005 Absent 6 (19%) 26 (53%) Cardiac manifestations, n (%) Present 24 (77%) 34 (69%) 0.608 Absent 7 (23%) 15 (31%) Heat intolerance, n (%) Present 19 (61%) 26 (53%) 0.643 Absent 12 (39%) 22 (47%) TPO Ab, n (%) Present 21 (68%) 22 (45%) 0.066 Absent 10 (32%) 27 (55%) TPO Ab titer (IU/mL) 328.08±399.18 277.53±420.00 0.518 Follow-up 381.30±382.23 416.83±440.13 0.791 Tg Ab, n (%) Present 16 (52%) 26 (53%) 1.000 Absent 15 (48%) 23 (47%) TBII titer (IU/L) 32.470±38.850 19.500±21.470 0.142 T3 (ng/ml) 5.401±2.457 4.158±1.969 0.006 ft4 (ng/dl) 3.726±1.298 3.291±1.398 0.537 TSH (μiu/ml) 0.002±0.005 0.025±0.127 0.067 Total (n=80) 31 (39%) 49 (61%) GO: Graves' ophthalmopathy; TPO Ab: anti-thyroid peroxidase antibody; Tg Ab: anti-thyroglobulin antibody; TBII: thyrotropin binding inhibitory immunoglobulin; T3: triidothyronine; ft4: free thyroxine; TSH: thyroid stimulating hormone. Table 3. Factors associated with Graves' ophthalmopathy Parameters Odds ratio 95% CI P value Age 0.916 0.794-1.056 0.226 Sex 0.954 0.287-3.177 0.939 T3 (ng/ml) 1.291 1.046-1.593 0.017 ft4 (ng/dl) 1.267 0.905-1.774 0.168 TPO Ab 2.577 1.007-6.599 0.048 Tg Ab 1.060 0.431-2.608 0.899 TBII (IU/L) 1.017 0.997-1.036 0.095 CI: confidence interval; T3: triidothyronine; ft4: free thyroxine; TPO Ab: anti-thyroid peroxidase antibody; Tg Ab: anti-thyroglobulin antibody; TBII: thyrotropin binding inhibitory immunoglobulin. retraction, and one patient with bilateral exophthalmos had conjunctival injection. Only one patient with unilateral GO had diplopia and underwent medical treatment in the ophthalmologic department. Clinical profiles of GD patients with and without GO The patients were divided into two groups: GD patients with GO in the group 1 and GD patients without GO in the group 2. The mean ages of patients in the groups 1 and 2 were 11.29±3.60 and 12.76±3.27 years, respectively. The proportion of female patients was slightly higher in the group 1 (81% vs. 78%). Goitre was present in 74% of the patients in the group 1 and 59% of the patients in the group 2. The proportion of patients showing weight loss in the group 1 was significantly higher than that in the group 2 (81% vs. 47%, P=0.005). Clinical manifestations such as heat intolerance or cardiac symptoms were not significantly different between the two groups (Table 2). Biochemical profiles of GD subjects with and without GO The serum levels of T3, ft4, TSH, TPO Ab, Tg Ab, and TBII were measured in all participating patients (Table 2). The mean serum T3 level was 5.40±2.46 ng/ ml in the group 1, which was significantly higher than that in the group 2 (P=0.006). Otherwise, there was no significant difference in the mean serum levels of ft4 and TSH between the two groups. TPO Ab was present in 68% of the patients in the group 1 and only 47% of the patients in the group 2 (P=0.066). Tg Ab was present in 52% and 53% of the patients in groups 1 and 2 respectively, with no significant difference. The TBII titre was higher in the group 1 (32.47±38.85 μiu/ml) than in the group 2 (19.50±21.47 μiu/ml), although the difference was not statistically significant. Follow-up titres of TPO Ab at euthyroid state after a treatment in the group 1 were not significantly different from those at initial diagnosis. These findings were also found in the group 2 (277.53±420.00 IU/mL vs. 416.83±440.13 IU/mL, P=0.212). There were no significant differences between GO patients with TPO Ab and without TPO Ab in terms of orbital symptoms and signs. The two patients with conjunctival injection and diplopia were negative for TPO Ab. Logistic regression analysis of clinical and biochemical profiles associated with GO Table 3 summarizes the associations between biological factors and GO in children. Using multivariate logistic regression analysis, we found significant association between the presence of GO and the serum levels of T3 (P<0.05; OR=1.291; 95% CI=1.046-1.593) and TPO Ab positivity (P<0.05; OR=2.577; 95% CI=1.007-157

World Journal of Pediatrics 6.599) in children with GD (Table 3). TBII levels were not significantly associated with the presence of GO. Age and sex were not significantly related to GO. Discussion In this study, we found that high levels of T3 and TPO Ab positivity were associated with the presence of GO in childhood GD. High T3 levels suggest the severity of hyperthyroidism that could directly cause GO in childhood GD. In this study, weight loss was significantly different between the two groups. This finding could reaffirm that GD severity is closely associated with the development of GO. Using logistic regression analysis, we identified that the positivity of TPO Ab was independently related to the presence of GO. However, TPO Ab titers were not significantly different between the two groups although the titers were slightly high in the GO group. Also, follow-up TPO Ab titers after acquiring euthyroid state were not significantly different compared to the initial titers. The role of TPO Ab in autoimmune thyroid disease remains controversial. Previous studies [17-21] showed TPO Ab in the serum of adult patients with GO. Wright-Pascoe et al [19] proposed that the presence of both TPO Ab and Tg Ab was correlated with the incidence of adulthood GO. Hence, TPO Ab is considered to cause inflammatory destruction of thyroid cells and induce the release of thyroid hormone into the blood stream during the early phase of destruction. In contrast, two different studies [20,21] demonstrated that TPO Ab negativity was associated with an increased risk of GO in adults. These studies assessed both adult and adolescent patients, in contrast to our study, which was limited to pediatric patients with GD. The interaction of genetic and environmental factors plays a key role in GD. [22] Smoking is a wellknown environmental risk factor for the development and aggravation of GO, and passive smoking is now being considered an important cause of GO in children. [1] Krassas et al [1] identified that a higher proportion of children below 10 years old develop GO in countries with a higher prevalence of smoking (25%). Countries with a lower prevalence of smoking also have a lower incidence of GO in children aged less than 10 years (19%). [1] Because of the retrospective nature of this study, although our study patients were not active smokers, we were unable to assess the effect, if any, of passive smoking on the presence of GO. In our study, we found that GD pediatric patients with GO had a higher titre of TSHR Abs (TBII) than those without GO, although this difference was not statistically significant. Many reports [9,10,14] have shown that TBII is related to the presence and severity of GO. Recently two methods are used to measure TSHR antibody levels. The TBII assay measures the levels of immunoglobulins that inhibit binding of TSH to TSHR: as such, this assay measures the levels of both thyroidstimulating immunoglobulins (TSIs) and thyroidblocking immunoglobulins (TBIs) that target the TSH receptor. [23] The second method is a bioassay that can distinguish between TSI and TBI through their effects on cyclic AMP production. [24] It was reported that TSIs are more significantly associated with GO than TBII. [9] However, in our study, we did not distinguish between TSIs and TBIs. In the present study, the prevalence of GO (39%) in GD patients was similar to that reported previously, ranging from 25% to 50%. [16,25-28] In the previous studies, there was female predominance in GO patients, with a girl to boy ratio of 4:1. However, other reports suggested that the female to male ratio is likely to be 2:1, and men with GD appear to have a more severe form of GO. [11] Compared to its severity in adults, GO in children is milder, and most children could improve after becoming euthyroid. Although the exact mechanisms involved in the spontaneous resolution of GO in children have not been established, physiologic decompression caused by increased orbital volume due to childhood somatic growth is thought to be involved in the process, especially in patients diagnosed at a prepubertal age. [12] Therefore, a wait-and-see policy is the recommended treatment for GO in children. [2] However, if GO is present or worsening even after the patient shows normal results in thyroid tests, steroid treatment may be recommended. [2] In the present study, orbital symptoms did not improve in two girls after they acquired an euthyroid state. One was diagnosed at 14 years of age with severe unilateral GO and diplopia and treated with steroids by an ophthalmologist. The other, diagnosed at 10 years of age, had bilateral exophthalmos and lid retraction without other symptoms. She was therefore followed up closely. This study has limitations. It has a small number of patients and is of cross-sectional nature. Moreover, we only evaluated the clinical parameters of GD patients. In conclusion, the present study suggests that the positivity of TPO Ab could act as a predictive factor for the presence of GO in children although clinical and radiologic evidences are lacking for its diagnosis. Funding: None. Ethical approval: This study was approved by the data inspectorate of Korea and by the regional committee for medical research ethics. 158

Competing interest: No benefits in any form have been received or will be received from any commercial party related directly or indirectly to the subject of this article. Contributors: LJH wrote the main body of the article under the supervision of PSH. KDG and SBK provided advice on medical aspects. References 1 Krassas GE, Segni M, Wiersinga WM. Childhood Graves' ophthalmopathy: results of a European questionnaire study. Eur J Endocrinol 2005;153:515-521. 2 Krassas GE, Gogakos A. Thyroid-associated ophthalmopathy in juvenile Graves' disease--clinical, endocrine and therapeutic aspects. J Pediatr Endocrinol Metab 2006;19:1193-1206. 3 Uretsky SH, Kennerdell JS, Gutai JP. Graves' ophthalmopathy in childhood and adolescence. Arch Ophthalmol 1980;98:1963-1964. 4 Chan W, Wong GW, Fan DS, Cheng AC, Lam DS, Ng JS. Ophthalmopathy in childhood Graves' disease. Br J Ophthalmol 2002;86:740-742. 5 Prummel MF, Bakker A, Wiersinga WM, Baldeschi L, Mourits MP, Kendall-Taylor P, et al. 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