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Erschienen in: BMC Cancer 1/2014

Open Access 01.12.2014 | Research article

Biomarkers of thyroid function and autoimmunity for predicting high-risk groups of thyroid cancer: a nested case–control study

verfasst von: Young Ae Cho, Sun-Young Kong, Aesun Shin, Jeonghee Lee, Eun Kyung Lee, You Jin Lee, Jeongseon Kim

Erschienen in: BMC Cancer | Ausgabe 1/2014

Abstract

Background

A remarkable increase in the number of thyroid cancer cases has been reported in recent years; however, the markers to predict high-risk groups have not been fully established.

Methods

We conducted a case–control study (257 cases and 257 controls) that was nested in the Cancer Screenee Cohort Study between August 2002 and December 2010; the mean follow-up time for this study was 3.1 ± 2.2 years. The levels of total triiodothyronine (TT3), free thyroxine (FT4), thyroid-stimulating hormone (TSH), thyroglobulin (Tg), anti-thyroperoxidase antibody (TPOAb), and anti-thyroglobulin antibody (TgAb) were measured using samples with pre-diagnostic status. Logistic regression models were used to examine the association between thyroid function/autoimmunity and thyroid cancer risk.

Results

When the markers were categorized by the tertile distributions of the control group, the highest tertile of FT4 (OR = 1.73, 95% CI = 1.11 - 2.69) and the middle tertile of TSH (OR = 1.77, 95% CI = 1.14 - 2.74) were associated with an increased risk of thyroid cancer by multivariate analyses. In addition, an elevated risk for thyroid cancer was found in subjects with TPOAb levels above 30 IU/mL (OR = 8.47, 95% CI = 5.39 - 13.33 for 30–60 IU/mL and OR = 4.48, 95% CI = 2.59 - 7.76 for ≥60 IU/mL). Stratified analyses indicated that some of these associations differed by sex, BMI, smoking status, and the duration of follow-up.

Conclusions

This study demonstrated that the levels of biomarkers of thyroid function/autoimmunity, particularly the presence of TPOAb, might be used as diagnostic markers for predicting thyroid cancer risk. Our findings suggest that careful monitoring of thyroid biomarkers may be helpful for identifying Korean populations at high-risk for thyroid cancer.
Hinweise

Electronic supplementary material

The online version of this article (doi:10.​1186/​1471-2407-14-873) contains supplementary material, which is available to authorized users.
Young Ae Cho, Sun-Young Kong contributed equally to this work.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

YAC carried out the statistical analysis and interpretation of the data and drafted the manuscript. SK participated in interpretation of the data and manuscript preparation. AS participated in the study design, data acquisition, and quality control of the data. JL participated in the study design and quality control of the data. EKL and YJL participated in interpretation of the data. JK contributed to the study concept and design, data acquisition, and quality control of the data. All authors participated in the revision of the manuscript and approved the final version.
Abkürzungen
BMI
Body mass index
CIs
Confidence intervals
CSCS
Cancer screenee cohort study
ELCLIA
Electrochemiluminescence immunoassay
FT4
Free thyroxine
KCCR
The Korea central cancer registry
ORs
Odds ratios
Tg
Thyroglobulin
TgAb
Anti-thyroglobulin
TPOAb
Anti-thyroperoxidase
TSH
Thyroid-stimulating hormone
TSHR-Abs
TSH receptor-stimulating antibodies
TT3
Triiodothyronine.

Background

Thyroid cancer is the most frequent cancer among endocrine tumors, and its incidence has been greatly increasing in many countries [1]. In particular, the incidence of thyroid cancer in Korea has increased rapidly and has become one of the highest in the world [2]. Although the increased incidence rate of thyroid cancer is partly attributed to the increased detection of subclinical cancer resulting from advanced diagnostic technologies [3], studies have reported a true increase in thyroid cancer incidence due to changes in lifestyle or environmental factors (e.g., iodine intake, exposure to radiation) [4, 5].
Recently, an effort has been made to predict the risk of thyroid cancer using the markers of thyroid function/autoimmunity [69]. Although the findings were inconsistent, several studies found biomarkers that predicted thyroid cancer. Some studies have reported that higher levels of thyroid-stimulating hormone (TSH) are associated with an increased risk of thyroid malignancy [6, 7], possibly because of its role in affecting thyroid cell differentiation and proliferation or in stimulating angiogenesis [10]. Other studies have suggested that thyroid autoantibodies could be used as predictors of thyroid cancer risk based on the association between thyroid autoimmune disease and thyroid cancer [9]. However, most studies have investigated these associations retrospectively, which has the potential for selection and referral biases.
In this study, we aimed to investigate whether blood markers representing thyroid function and autoimmunity could predict thyroid malignancy. We designed a nested case–control study, which was affected little by bias, to validate blood markers for thyroid malignancy.

Methods

Study population

We conducted a nested case–control study on participants in the ongoing Cancer Screenee Cohort Study (CSCS) between August 2002 and December 2010, which had a mean time of follow-up of 3.1 ± 2.2 years. The CSCS is a prospective cohort study consisting of participants of the Cancer Screening Program at the National Cancer Center in South Korea. Participants were aged 30 years or older, underwent health-screening examinations, and were screened for selected cancers. All of the participants were asked to complete a self-administered questionnaire at the baseline evaluation. The data collected in the baseline evaluation included socio-demographic characteristics, personal and family medical history, lifestyle factors, and reproductive factors. A total of 22,085 subjects provided written informed consent and provided a blood sample for study participation.

Ascertainment of cases and selection of controls

Potential cases diagnosed with thyroid cancer (ICD10 code C73) were ascertained by linkage to the Korea Central Cancer Registry (KCCR) database, which was used to identify the incidence of cancer in Korea. Among 258 thyroid cancer patients, 257 patients were selected after excluding those who were dead. Among the potential controls (n = 21,827) who were not diagnosed with thyroid cancer, 3,740 participants were excluded because of the following reasons: death, missing questionnaire data, history of other cancers, any thyroid disease, thyroid surgery, or thyroid-related medicine. For each case, one control among the remaining 18,807 participants who was matched by entry age (same age) and sex was selected. In total, 257 incident cases and 257 controls were used for the final biomarker analysis (Figure 1). The participants were followed up from the date of blood collection until December 31, 2010. The study procedure was approved by the institutional review board of the National Cancer Center (NCCNCS 13–698).

Laboratory procedures

Blood samples were collected at the baseline evaluation and stored at -80°C until analysis. The serum concentrations of the following six biomarkers were measured for both cases and controls: total triiodothyronine (TT3), thyroid-stimulating hormone (TSH), free thyroxine (FT4), thyroglobulin (Tg), anti-thyroglobulin antibody (TgAb), and anti-thyroperoxidase antibody (TPOAb). We selected these biomarkers of thyroid function/autoimmunity based on their associations with thyroid cancer that had been reported in previous studies [69, 11].
The serum concentrations of TT3, TSH, Tg, FT4, TgAb, and TPOAb were measured using an electrochemiluminescence immunoassay (ELCLIA; Molecular Analytics E170, Roche kit, Roche, Mannheim, Germany), which had reference (normal) ranges of 0.82 - 2.0 ng/mL for TT3, 0.27 - 4.20 μIU/mL for TSH, 0.93 - 1.70 ng/dL for FT4, and 1.4 - 78.0 ng/mL for Tg. TgAb was defined as negative if ≤115.0 IU/mL, and TPOAb was defined as negative if ≤34.0 IU/mL. The detection limits were 20 IU/mL for TgAb and 30 IU/mL for TPOAb.

Statistical methods

The general characteristics of the study participants and the risk factors for thyroid cancer were compared using t-tests for continuous variables and chi-square tests for categorical variables. To evaluate the association between serum biomarkers and thyroid cancer risk, serum levels of TT3, FT4, TSH, and Tg were categorized into three groups based on those of the control group. The antibody titers for TgAb and TPOAb were also categorized into tertiles: the lowest tertile (under detection limit; 20 IU/mL for TgAb and 30 IU/mL for TPOAb), the middle tertile (over detection limit - < 60 IU/mL), and the highest tertile (>60 IU/mL). Then, we performed unconditional and conditional logistic regressions and calculated odds ratios (ORs) and 95% confidence intervals (CIs) using univariate and multivariate analyses. The lowest levels of each biomarker were used as references. The multivariate unconditional logistic regression models were adjusted for age, sex, body mass index (BMI) (<23, 23 - < 25, and ≥25 kg/m2), and cigarette smoking (nonsmoker, former smoker, and current smoker). To analyze the association between Tg levels and cancer risk, we excluded subjects who were positive for TgAb because the presence of TgAb hampers the usefulness of serum Tg as a tumor marker [12]. To explore potential modifying factors, analyses stratified according to sex, BMI (<23 and ≥23 kg/m2), and smoking status (nonsmoker and former/current smoker) were conducted; these factors showed different distributions between cases and controls in this study and have been reported to affect thyroid cancer risk [13, 14]. We also conducted an analysis stratified by the duration of follow-up. To examine the role of TPOAb in the association between thyroid cancer risk and other biomarkers, we also conducted analyses stratified by the presence of TPOAb. Because unconditional regression produced more stable results for the different subanalyses [15], only the results from the unconditional analyses are presented in the tables. We verified that both the conditional and unconditional approaches gave approximately the same results for the entire dataset.
All statistical analyses were performed using SAS 9.1 software (SAS Institute Inc., Cary, NC). A two-sided P-value of less than 0.05 was regarded as statistically significant.

Results

This study included 257 cases and 257 controls, of whom 70% were women and 30% were men. We examined the differences in the general characteristics of the study subjects according to thyroid cancer status (Table 1). The mean age for cases and controls was 49.4 ± 8.9 years. The cases were more likely to have a higher BMI than the controls (P = 0.019); however, no differences with respect to other variables were observed between the cases and controls.
Table 1
General characteristics of the study subjects
 
Controls (n = 257)
Cases (n = 257)
P-value
Age (years), means
49.4 ± 8.9
49.4 ± 8.9
0.994
BMI (kg/m2)
   
  <23
125(48.6)
95(37.0)
0.019
  23 - <25
68(26.5)
75(29.2)
 
  ≥ 25
64(24.9)
87(33.9)
 
Family history of cancer (yes)a
93(41.0)
108(46.4)
0.245
Family history of thyroid cancer (yes)a
5(2.2)
6(2.6)
0.794
Educational level
   
  Elementary school or less
21(8.8)
23(9.8)
0.774
  Middle school
19(7.9)
16(6.8)
 
  High school
95(39.6)
84(35.9)
 
  College or more
105(43.8)
115(47.4)
 
Monthly household incomeb
   
  <200
35(16.6)
24(11.8)
0.102
  200 - <400
56(26.5)
72(35.3)
 
  >400
120(56.9)
108(52.9)
 
Marital status
   
  Married
218(90.8)
215(90.0)
0.480
  Unmarried
8(3.3)
5(2.1)
 
  Divorced/Widowed
14(5.8)
19(8.0)
 
Smoking status
   
  Nonsmoker
147(64.8)
158(69.3)
0.215
  Former smoker
33(14.5)
37(16.3)
 
  Current smoker
47(20.7)
33(14.5)
 
Alcohol consumption
   
  Nondrinker
87(36.4)
100(41.5)
0.208
  Former drinker
7(2.9)
12(5.0)
 
  Current drinker
145(60.7)
129(53.5)
 
Age at menarche (years)c
   
  ≤13
35(22.0)
31(20.5)
0.680
  14
34(21.4)
34(22.5)
 
  15
37(23.3)
28(18.5)
 
  ≥16
53(33.3)
58(38.4)
 
Menopause (yes)c
83(47.7)
79(43.9)
0.472
Age at menopause (years)c
   
  <46
16(21.1)
12(17.7)
0.185
  46 - <49
14(18.4)
8(11.8)
 
  49 - <52
14(18.4)
23(33.8)
 
  ≥52
32(42.1)
25(36.8)
 
Type of menopausec
   
  Natural
57(71.3)
51(64.6)
0.366
  Surgery, Other
23(28.8)
28(35.4)
 
Postmenopausal hormone use (ever)c
28(36.8)
20(30.8)
0.448
Parity (yes)c
157(96.3)
159(98.2)
0.315
a First-degree relative.
bUnit is 10,000 Korean won.
cOnly in women.
Table 2 presents the association between the biomarkers of thyroid function/autoimmunity and thyroid cancer risk. When the markers were categorized by the tertile distributions of the control group, the highest tertile of FT4 (OR = 1.73, 95% CI = 1.11 - 2.69) showed an increased risk of thyroid cancer, while the middle tertile of TSH (OR = 1.77, 95% CI = 1.14 - 2.74) was associated with thyroid cancer risk. In addition, TPOAb levels greater than 30 IU/mL (OR = 8.47, 95% CI = 5.39 - 13.33 for 30 - < 60 IU/mL and OR = 4.48, 95% CI = 2.59 - 7.76 for ≥60 IU/mL) were strongly associated with risk of thyroid cancer when compared with those whose TPOAb levels were less than 30 IU/mL.
Table 2
The association between the biomarkers of thyroid function/autoimmunity and thyroid cancer risk
 
Controls (n = 257)
Cases (n = 257)
Crude OR (95% CI)
Adjusted OR (95% CI)c
TT3 (ng/mL)
    
  <1.2
88(34.2)
79(30.7)
1.0(ref)
1.0(ref)
  1.2 - <1.4
104(40.5)
109(42.4)
1.17(0.78 - 1.75)
1.18(0.78 - 1.79)
  ≥1.4
65(25.3)
69(26.9)
1.18(0.75 - 1.86)
1.21(0.75 - 1.94)
FT4 (ng/dL)
    
  <1.25
85(33.1)
68(26.5)
1.0(ref)
1.0(ref)
  1.25 - <1.39
85(33.1)
75(29.2)
1.10(0.71 - 1.72)
1.05(0.66 - 1.65)
  ≥1.39
87(33.9)
114(44.4)
1.64(1.07 - 2.57)*
1.73(1.11 - 2.69)*
TSH (μIU/mL)
    
  <1.36
84(33.1)
59(23.2)
1.0(ref)
1.0(ref)
  1.36 - <2.5
86(33.9)
111(43.7)
1.81(1.18 - 2.79)*
1.77(1.14 - 2.74)*
  ≥2.5
84(33.1)
84(33.1)
1.40(0.90 - 2.19)
1.37(0.87 - 2.16)
Tg (ng/mL)a
    
  0 - <3.9
77(33.8)
67(29.7)
1.0(ref)
1.0(ref)
  3.9 - <7
74(32.5)
64(28.3)
0.98(0.61 - 1.56)
0.97(0.60 - 1.55)
  ≥7
77(33.8)
95(42.0)
1.40(0.90 - 2.17)
1.40(0.89 - 2.19)
TgAb (IU/mL)b
    
  <20
212(82.5)
203(79.0)
1.0(ref)
1.0(ref)
  20 - <60
17(6.6)
25(9.7)
1.54(0.81 - 2.93)
1.58(0.82 - 3.06)
  ≥60
28(10.9)
29(11.3)
1.08(0.62 - 1.88)
1.13(0.64 - 2.00)
TPOAb (IU/mL)b
    
  <30
192(74.1)
77(30.0)
1.0(ref)
1.0(ref)
  30 - <60
38(14.8)
131(51.0)
8.60(5.49 - 13.45)*
8.47(5.39 - 13.33)*
  ≥60
27(10.5)
49(19.1)
4.53(2.64 - 7.76)*
4.48(2.59 - 7.76)*
Abbreviations: CI, Confidence interval; OR, Odds ratio; TT3, Total triiodothyronine; FT4, Free thyroxine; TSH, Thyroid-stimulating hormone; Tg, Thyroglobulin; TgAb, Anti-thyroglobulin antibody; TPOAb, Anti-thyroperoxidase antibody.
aAnalyzed only for TgAb-negative subjects; bThe detection limits used were 20 IU/mL for TgAb and 30 IU/mL for TPOAb; cAdjusted for age, sex, BMI, and smoking.
* P <0.05.
The associations of some markers with thyroid cancer risk appeared to be different when the data were stratified by sex, BMI, smoking status, or the duration of follow-up (Table 3). The association between FT4 levels and thyroid cancer risk was only significant among women or those with a BMI <23 kg/m2. The elevated risk for the middle tertile of TSH was only significant among men, those with a BMI ≥23 kg/m2, or former/current smokers. The levels of TT3, FT4, and TSH were associated with thyroid cancer risk only when the duration of follow-up was shorter than 3 years. However, in all of the analyses, the presence of TPOAb strongly elevated the risk of thyroid cancer. Additionally, we examined whether other known risk factors showed different distributions according to the presence of TPOAb, but no differences were observed (Additional file 1: Table S1).
Table 3
The association between thyroid function/autoimmunity biomarkers and thyroid cancer risk, stratified by sex, BMI, smoking status, and the duration of follow-up a
 
Sex
BMI (kg/m2)
Smoking
Follow-up duration
 
Men
Women
<23
≥23
Non-smoker
Former/Current smoker
< 3 years
≥3 years
Controls/Cases
77/77
180/180
125/95
132/162
147/158
80/70
97/171
160/86
TT3 (ng/mL)
        
  <1.2
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
  1.2 - <1.4
1.66(0.68 - 4.04)
1.08(0.67 - 1.75)
1.16(0.63 - 2.15)
1.18(0.67 - 2.08)
0.92(0.55 - 1.54)
2.07(0.85 - 5.02)
1.81(1.03 - 3.20)*
0.93(0.47 - 1.83)
  ≥1.4
1.56(0.61 - 4.00)
1.22(0.69 - 2.14)
0.93(0.43 - 2.00)
1.50(0.81 - 2.78)
0.80(0.43 - 1.51)
1.97(0.80 - 4.89)
2.51(1.21 - 5.22)*
1.10(0.53 - 2.25)
FT4 (ng/dL)
        
  <1.25
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
  1.25 - <1.39
0.65(0.23 - 1.80)
1.19(0.71 - 2.00)
1.37(0.62 - 2.89)
0.91(0.51 - 1.64)
0.82(0.46 - 1.46)
1.05(0.42 - 2.66)
1.58(0.84 - 2.97)
0.73(0.36 - 1.46)
  ≥1.39
1.44(0.53 - 3.88)
1.76(1.06 - 2.92)*
2.52(1.28 - 4.96)*
1.43(0.78 - 2.60)
1.46(0.83 - 2.56)
1.85(0.77 - 4.41)
3.01(1.57 - 5.77)*
1.10(0.57 - 2.10)
TSH (μIU/mL)
        
  <1.36
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
  1.36 - <2.5
2.31(1.06 - 5.02)*
1.58(0.92 - 2.72)
1.16(0.59 - 2.29)
2.31(1.30 - 4.13)*
1.71(0.95 - 3.09)
2.44(1.14 - 5.24)*
2.07(1.11 - 3.88)*
1.57(0.80 - 3.06)
  ≥2.5
1.97(0.76 - 5.08)
1.16(0.68 - 1.97)
0.96(0.49 - 1.89)
1.82(0.98 - 3.37)
1.23(0.68 - 2.22)
1.33(0.53 - 3.38)
1.36(0.72 - 2.59)
1.41(0.70 - 2.83)
Tg (ng/mL)b
        
  0 - <3.9
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
  3.9 - <7
1.09(0.46 - 2.57)
0.93(0.52 - 1.66)
1.09(0.52 - 2.30)
0.95(0.52 - 1.77)
0.77(0.41 - 1.43)
1.16(0.48 - 2.79)
1.75(0.87 - 3.52)
0.65(0.32 - 1.33)
  ≥7
2.98(1.23 - 7.17)*
1.08(0.63 - 1.83)
1.09(0.55 - 2.14)
1.89(1.02 - 3.49)*
0.98(0.55 - 1.75)
2.52(1.05 - 6.03)*
1.80(0.96 - 3.36)
1.06(0.54 - 2.10)
TgAb (IU/mL)c
        
  <20
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
  20 - <60
1.77(0.31 - 10.20)
1.56(0.77 - 3.19)
1.92(0.77 - 4.79)
1.27(0.50 - 3.26)
1.54(0.71 - 3.33)
1.33(0.28 - 6.26)
1.25(0.55 - 2.83)
1.17(0.35 - 3.89)
  ≥60
0.25(0.03 - 2.22)
1.31(0.71 - 2.41)
1.16(0.49 - 2.77)
1.11(0.52 - 2.37)
1.14(0.53 - 2.47)
1.07(0.30 - 3.79)
1.67(0.71 - 3.92)
0.77(0.32 - 1.87)
TPOAb (IU/mL)c
        
  <30
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
1.0(ref)
  30 - <60
5.59(2.57 - 12.16)*
10.67(6.03 - 18.88)*
8.77(4.30 - 17.86)*
8.40(4.62 - 15.24)*
10.96(5.85 - 20.53)*
4.97(2.31 - 10.69)*
6.10(3.10 - 11.67)*
14.75(2.36 - 29.56)*
  ≥60
3.89(1.05 - 14.41)*
4.60(2.50 - 8.46)*
4.43(1.95 - 10.04)*
4.41(2.10 - 9.26)*
3.52(1.78 - 6.96)*
6.35(1.80 - 22.41)*
4.54(2.10 - 9.84)*
4.32(1.77 - 10.52)*
Abbreviations: BMI, Body mass index; CI, Confidence interval; OR, Odds ratio; TT3, Total triiodothyronine; FT4, Free thyroxine; TSH, Thyroid-stimulating hormone; Tg, thyroglobulin; TgAb, Anti-thyroglobulin antibody; TPOAb, Anti-thyroperoxidase antibody.
aData were analyzed using multivariate logistic regression models which were adjusted for age, sex, BMI, and smoking; bAnalyzed only for TgAb-negative subjects; cThe detection limits used were 20 IU/mL for TgAb and 30 IU/mL for TPOAb.
* P <0.05.
Finally, we examined the role of TPOAb in the association between the other biomarkers (TT3, FT4, TSH, Tg, and TgAb) and thyroid cancer risk (Table 4). The association between FT4 and thyroid cancer risk was stronger among those with TPOAb levels <30 IU/mL (OR = 2.12, 95% CI = 1.06 - 4.24).
Table 4
The association between thyroid function/autoimmunity biomarkers and thyroid cancer risk, stratified by the presence of TPOAb
 
TPOAb (IU/mL)
 
<30
≥30
 
Controls/cases
Adjusted OR (95% CI)c
Controls/cases
Adjusted OR (95% CI)c
TT3 (ng/mL)
    
  <1.2
67/29
1.0(ref)
21/50
1.0(ref)
  1.2 - <1.4
74/32
1.03(0.55 - 1.91)
30/77
1.05(0.53 - 2.07)
  ≥1.4
51/16
0.71(0.34 - 1.49)
14/53
1.71(0.76 - 3.85)
FT4 (ng/dL)
    
  <1.25
66/18
1.0(ref)
19/50
1.0(ref)
  1.25 - <1.39
62/21
1.14(0.55 - 2.40)
23/54
0.87(0.42 - 1.80)
  ≥1.39
64/38
2.12(1.06 - 4.24)*
23/76
1.37(0.66 - 2.83)
TSH (μIU/mL)
    
  <1.36
66/16
1.0(ref)
18/43
1.0(ref)
  1.36 - <2.5
63/32
2.00(1.00 - 4.01)*
23/79
1.48(0.73 - 3.00)
  ≥2.5
63/28
1.82(0.89 - 3.72)
21/56
1.14(0.54 - 2.40)
Tg (ng/mL)a
    
  0 - <3.9
58/22
1.0(ref)
19/45
1.0(ref)
  3.9 - <7
59/18
0.70(0.34 - 1.44)
15/46
1.28(0.57 - 2.86)
  ≥7
63/32
1.21(0.63 - 2.32)
14/63
1.95(0.87 - 4.38)
TgAb (U/mL)b
    
  <20
170/69
1.0(ref)
42/134
1.0(ref)
  ≥20
22/8
0.95(0.40 - 2.26)
23/46
0.59(0.31 - 1.14)
Abbreviations: CI, Confidence interval; OR, Odds ratio; TT3, Total triiodothyronine; FT4, Free thyroxine; TSH, Thyroid-stimulating hormone; Tg, Thyroglobulin; TgAb, Anti-thyroglobulin antibody; TPOAb, Anti-thyroperoxidase antibody.
aAnalyzed only for TgAb-negative subjects; bThe detection limits used were 20 IU/mL for TgAb, and we combined these groups into two groups because of the small sample sizes; cAdjusted for age, sex, BMI, and smoking.
* P <0.05.

Discussion

This study prospectively investigated the association between biomarkers of thyroid function/autoimmunity and thyroid cancer risk and found that differences in the levels of thyroid biomarkers, particularly TPOAb, could predict the incidence of thyroid cancer.
Several studies have examined the association between thyroid function and thyroid cancer risk [68, 16, 17]. A large population-based cohort study from Taiwan [8] has investigated the incidence of cancer in patients with hyperthyroidism and found that patients with hyperthyroidism were at an increased risk for thyroid cancer. This group also reported that the duration of hyperthyroidism was related to increased risk of thyroid cancer. In the present study, the levels of thyroid hormones were normal in most of the study participants. However, relatively higher levels of FT4 showed a positive association with thyroid cancer risk. Because the association between thyroid hormones and thyroid cancer risk has not been sufficiently studied, the underlying mechanisms still remain unclear. Pellegriti et al. reported that circulating TSH receptor-stimulating antibodies (TSHR-Abs) were present in all patients with Graves’ disease [18], implying an association between TSHR-Abs and elevated levels of thyroid hormones. TSHR-Abs are known to stimulate the same intracellular signal pathways as TSH, which has mitogenic and antiapoptotic effects on thyroid follicular cells and thus may play a role in thyroid cancer initiation [19].
The positive association between TSH levels and thyroid cancer risk has been reported in some studies [6, 7, 16, 17], implying that high TSH levels may play a key role in the initiation of thyroid carcinogenesis. TSH has a proliferative effect on thyroid cell growth that is most likely mediated by TSH receptors on tumor cells [17]. However, some studies did not find an association between TSH levels and thyroid cancer risk [20]. Our study demonstrated that the highest tertile of TSH levels did not show any association with thyroid cancer, but the medium tertile of TSH levels seemed to slightly increase thyroid cancer risk.
Tg is produced by normal thyroid tissue and neoplastic follicular cells; therefore, serum Tg measurements can be used as specific and sensitive tumor markers of differentiated thyroid cancer in clinical practice [21]. The level of serum Tg is known to aid in the detection of residual, recurrent, or metastatic disease rather than in determining the incidence of thyroid cancer [22], but the role of Tg in the initiation of thyroid cancer remains unclear. However, this study has found that Tg is positively associated with thyroid cancer risk only among lean people, men, or smokers.
A high prevalence of thyroid cancer in those with autoimmune thyroid diseases [2325] and systemic autoimmune diseases [26] may imply the possible association between thyroid autoimmunity and cancer risk. Kim et al.[24] found an elevated risk of papillary thyroid cancer in Korean patients with Hashimoto’s thyroiditis with elevated levels of TPOAb. Antonelli et al. [26] reported the higher prevalence of papillary thyroid cancer in systemic lupus erythematosus patients, particularly in patients with thyroid autoimmunity. The results of these studies suggest that the risk of thyroid cancer is strongly associated with elevated levels of TPOAb. TPO is a membrane protein that catalyzes thyroid hormone synthesis; thus, the presence of TPOAb in the blood may reflect an alteration in the immune system and lymphocytic infiltration in the thyroid [27]. TPOAb may destroy thyroid tissue as well as cytokines produced by infiltrating inflammatory cells, which may contribute to inflammation-induced carcinogenesis [25, 28, 29]. Furthermore, the presence of TPOAb could be associated with thyroid function. In a study using the NHANES III survey from the United States, Hollowell et al. reported an association between TPOAb and overt thyroid dysfunction [30]. We also observed that the presence of TPOAb may affect the association between FT4 levels and the risk of thyroid cancer.
Several factors may modify the association between thyroid abnormalities/thyroid autoimmunity and thyroid cancer risk. First, the effect of FT4 and TSH on thyroid cancer risk was affected by obesity status in the present study. In addition, previous studies have reported a positive association between obesity and thyroid cancer [4, 14]. It has also been proposed that obesity may affect the secretion of certain hormones such as insulin and sex steroids, which may act on the thyroid to stimulate cell proliferation and suppress apoptosis [31]. Second, this study also found that the levels of TSH and Tg were associated with thyroid cancer risk only among smokers. Smoking is known to have a negative association with the risk of thyroid cancer [13, 32], possibly by exerting anti-estrogenic effects or by affecting the immune system through nicotinic anti-inflammatory pathways [3335]. Additionally, smoking is known to decrease the levels of TSH and the positivity of thyroid autoantibodies [36], which were reported to be positively associated with thyroid cancer risk. Third, the association of these biomarkers with thyroid cancer was different in men and women. The higher levels of TPOAb in women and the higher prevalence of smokers in men may partly explain the observed differences in the incidence of thyroid cancer based on sex [32]. A negative association between TPOAb and smoking was also reported [37].
The present study has strengths in its study design in terms of ascertaining thyroid cancer patients within a prospective cohort. This study design allowed for determining the potential role of pre-diagnostic serum levels of biomarkers on thyroid cancer risk. In addition, the controls were derived from the same cohort as the cases; thus, the potential selection bias that can occur with a conventional case–control study was minimized. However, the findings from the present study should be interpreted with caution because of several limitations. First, the duration of follow-up in this study was relatively short. However, the association between thyroid cancer and the levels of TPOAb was not modified by duration of follow-up in this study. Second, we lacked detailed information on the specifics of the thyroid cancer, e.g., tumor stage and histological type, because case ascertainment was performed by data linkage with the cancer registry; therefore, we could not include these variables in our analyses. Third, the sample size was relatively small, especially for a stratified analysis. Finally, the study population consisted of participants in a cancer-screening program; thus, these individuals may pay more attention to their health status and may not be representative of the general Korean population.

Conclusions

We found that the levels of biomarkers of thyroid function and autoimmunity could provide additional information for predicting thyroid malignancy. Particularly, the presence of TPOAb seems to be a strong predictor of thyroid cancer. Interestingly, most participants who showed positive associations between these biomarkers and thyroid cancer risk were in the normal ranges of these markers and may not have had any symptoms of thyroid disease. Therefore, we cautiously suggest that careful monitoring of these biomarkers, even within the normal range, may be helpful for identifying those at high risk for thyroid cancer and for enhancing the likelihood of early detection in Koreans.

Acknowledgements

This research was supported by a grant from National Research Foundation of Korea (NRF-2012R1A1A2044332). The study sponsor had no role in the study design, in the collection analysis and interpretation of the data, in the writing of the manuscript, or in the decision to submit the manuscript for publication.
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made.
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Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

YAC carried out the statistical analysis and interpretation of the data and drafted the manuscript. SK participated in interpretation of the data and manuscript preparation. AS participated in the study design, data acquisition, and quality control of the data. JL participated in the study design and quality control of the data. EKL and YJL participated in interpretation of the data. JK contributed to the study concept and design, data acquisition, and quality control of the data. All authors participated in the revision of the manuscript and approved the final version.
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Metadaten
Titel
Biomarkers of thyroid function and autoimmunity for predicting high-risk groups of thyroid cancer: a nested case–control study
verfasst von
Young Ae Cho
Sun-Young Kong
Aesun Shin
Jeonghee Lee
Eun Kyung Lee
You Jin Lee
Jeongseon Kim
Publikationsdatum
01.12.2014
Verlag
BioMed Central
Erschienen in
BMC Cancer / Ausgabe 1/2014
Elektronische ISSN: 1471-2407
DOI
https://doi.org/10.1186/1471-2407-14-873

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