8:10 1425–1432X Nie, Y Xu and et al. Fat distribution and thyroid 
hormones

RESEARCH

Trunk fat and leg fat in relation to free 
triiodothyronine in euthyroid 
postmenopausal women
Xiaomin Nie*, Yiting Xu*, Xiaojing Ma, Yun Shen, Yufei Wang and Yuqian Bao

Department of Endocrinology and Metabolism, Shanghai Jiao Tong University Affiliated Sixth People’s Hospital; Shanghai Clinical Center for Diabetes; 
Shanghai Key Clinical Center for Metabolic Disease; Shanghai Diabetes Institute; Shanghai Key Laboratory of Diabetes Mellitus, Shanghai, China

Correspondence should be addressed to X Ma or Y Bao: maxiaojing@sjtu.edu.cn or yqbao@sjtu.edu.cn

*(X Nie and Y Xu contributed equally to this work)

Abstract

Background: A high level of free triiodothyronine (FT3) within the reference range may 
be a potential metabolic risk marker. However, the relationship between different fat 
depots and FT3 has remained unclear.
Objective: We aimed to explore the relationships between segmental fat distribution and 
FT3 in euthyroid middle-aged and elderly men and postmenopausal women.
Methods: A total of 891 subjects (394 men and 497 women) were enrolled. A bioelectrical 
impedance analyzer was used to measure total, trunk, arm and leg fat mass (FM) and 
fat percentage (fat%). The leg fat mass to trunk fat mass ratio (LTR) was calculated to 
evaluate the relative distribution of leg fat compared with that of trunk fat. Thyroid 
hormones were measured by electrochemical luminescence immunoassay.
Results: FT3 in men did not change significantly with increases in LTR quartiles, while FT3 
in women decreased significantly (P for trend = 0.004). In multivariate linear regression 
analysis, multiple metabolic and cardiovascular risk factors were adjusted. The LTR was 
negatively related to FT3 in women (P < 0.05). After further mutual adjustment for trunk 
fat and leg fat parameters, trunk FM and fat% were positively related to FT3, while leg FM 
and fat% were negatively related to FT3 in women (all P < 0.05).
Conclusions: In euthyroid postmenopausal women, trunk fat was positively correlated with 
FT3, whereas leg fat was negatively correlated with FT3. Our findings supported that a high 
level of FT3 within the reference range was related to adverse fat distribution.

Introduction

Obesity is the key pathogenic factor of type 2 diabetes 
and cardiovascular disease (1). The disease risk associated 
with obesity is related not only to fat content but also 
to fat distribution. Abdominal obesity characterized by 
an ‘apple-shape’ significantly increases the risk of type 
2 diabetes and cardiovascular disease (2). In contrast to 
that, a ‘pear-shape’ with most fat accumulating in the 
lower body is found to have metabolic and cardiovascular 
protective effects (3).

Free triiodothyronine (FT3) is the bioactive form of 
thyroxines. FT3 regulates basal metabolic rate, promotes 
fat decomposition and acts on the cardiovascular system 
through adrenergic signaling (4). Previous studies have 
found that a high level of FT3 within the reference range 
was positively related to BMI and waist circumference 
(5, 6). Non-alcoholic fatty liver disease (NAFLD) is one 
of the most common complications of obesity. In recent 
years, some studies found that a high level of FT3 within 

-19-0394

Key Words

 f trunk fat

 f leg fat

 f trunk fat mass to leg fat 
mass ratio

 f free triiodothyronine

Endocrine Connections
(2019) 8, 1425–1432

ID: 19-0394
8 10

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the reference range was related to the risk of NAFLD and 
multiple adverse metabolic and cardiovascular risk factors 
(5, 7, 8), which suggests that a high level of FT3 within the 
reference range may be a potential adverse metabolic risk 
marker. The middle-aged and elderly population is at high 
risk of metabolic and cardiovascular disease; thus, it is 
meaningful to explore the associations between different 
fat depots and FT3 in this age group.

BMI and waist circumference are simple indexes 
to evaluate obesity, but cannot be used to reflect the 
distribution of different fat depots. Segmental fat depots 
(trunk, arm and leg) measured by segmental bioelectrical 
impedance analysis (sBIA) are highly consistent with 
those measured by dual energy X-ray absorptiometry 
(9). sBIA can accurately evaluate body fat content with 
simple operation and lightweight size. None of the 
previous studies have focused on associations between 
segmental fat distribution and FT3. In the present study, 
we aimed to explore the relationship between segmental 
fat distribution and FT3 in euthyroid middle-aged and 
elderly men and postmenopausal women. Trunk fat 
and leg fat were found to have an inverse relationship 
with metabolic and cardiovascular disease in previous 
studies (3, 10, 11). The relationship between arm fat 
and cardiovascular metabolic risk was nonsignificant 
or weak (12, 13). Thus, we calculated the leg FM to 
trunk FM ratio (LTR) to study the relationship between 
a tendency of fat to accumulate in the legs rather than 
trunk and FT3.

Materials and methods

Study population

Men and postmenopausal women aged 50 years or older 
were recruited from Shanghai communities from October 
2015 to July 2016. Postmenopausal status was defined as at 
least 1 year of amenorrhea in the absence of other medical 
conditions (14). The methods of population recruitment 
and data collection were described in our previous 
study (15). All participants provided informed consent 
and received questionnaires, a physical examination, 
laboratory tests and segmental fat measurements. The 
exclusion criteria included a history of thyroid disease with 
thyroxine supplement or anti-thyroid therapy; abnormal 
thyroid function; a history of diabetes or cardiovascular 
disease; moderate-to-severe anemia; malignancy or 
an intracranial mass lesion; severe kidney or liver 
dysfunction; acute infection; hypoalbuminemia; taking 

lipid-lowering drugs, hypotensive drugs, weight-loss pills, 
glucocorticoids, sex hormones, amiodarone or lithium. 
The study was approved by the Ethics Committee of the 
Shanghai Jiao Tong University Affiliated Sixth People’s 
Hospital and was carried out following the guidelines of 
the 1964 Declaration of Helsinki.

Anthropometric and biochemical assessments

Height, body weight and blood pressure were measured 
according to standard methods, which were described 
in our previous study (15). BMI was equal to the body 
weight (kg) divided by the height squared (m2). Systolic 
blood pressure (SBP) and diastolic blood pressure (DBP) 
were determined by the mean blood pressure from three 
measurements taken at 3-min intervals.

All subjects underwent a 75-g oral glucose tolerance 
test in the morning after an overnight fast of 10 h. The 
measurements of fasting plasma glucose (FPG), 2-h 
plasma glucose (2 h PG), glycated hemoglobin A1c 
(HbA1c), fasting insulin (FINS), triglyceride (TG), total 
cholesterol (TC), high-density lipoprotein cholesterol 
(HDL-c), and low-density lipoprotein cholesterol (LDL-c)  
were performed according to methods described in 
our previous study (15). Estradiol (E2) was detected by 
chemiluminescent microparticle immunoassays on an 
Architect i2000SR analyzer (Abbott GmbH & Co. KG). 
The level of insulin resistance was evaluated by the 
homeostasis model assessment of insulin resistance 
(HOMA-IR) with the following formula: HOMA-IR = FINS 
(mU/L) × FPG (mmol/L)/22.5 (16).

A Cobas e601 analyzer (Roche Diagnostics GmbH) 
was used to measure FT3, free thyroxine (FT4) and 
thyroid-stimulating hormone (TSH). The reference 
range and intra- and interassay coefficients for FT3 were  
3.10–6.80 pmol/L, <7.0 and <8.0%, respectively; for 
FT4, they were 12.00–22.00 pmol/L, <5.0 and <7.0%, 
respectively; and for TSH, they were 0.27–4.20 mIU/L, 
<3.0 and <8.0%, respectively.

Measurement of segmental fat distribution

An automatic bioelectrical impedance analyzer (TBF-418B;  
Tanita Corp., Tokyo, Japan) was used to measure total, 
trunk, arm and leg fat mass (FM) and fat percentage 
(fat%) according to a previously described method (15). 
To evaluate the tendency of fat accumulation in the legs 
rather than the trunk, the LTR was calculated as leg FM 
(kg) divided by trunk FM (kg).

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Statistical analysis

The normality of the distribution of variables was evaluated 
by the Kolmogorov–Smirnov test. Normally distributed 
variables are expressed as the mean ± standard deviation. 
Variables with a skewed distribution are expressed as the 
median (interquartile range). For normally distributed 
variables, one-way ANOVA was used for trend analysis. 
For skewed variables, the Kruskal–Wallis H-test was used 
for trend analysis. Partial correlation analysis was used to 
explore the age- and BMI-adjusted relationships between 
fat parameters and thyroid hormones. Multivariate linear 
regression analysis was used to explore the relationship 
between segmental fat parameters and thyroid hormones. 
Considering close correlations among segmental fat 
parameters, multicollinearity was analyzed for each linear 
regression model. A variance inflation factor > 10 indicated 
serious multicollinearity. SPSS version 22.0 (SPSS, Inc.) 
statistical software was used for all data analyses. A two-
tailed P value <0.05 was considered statistically significant.

Results

Clinical characteristics of the study participants

The study included 891 subjects with an age range of 
50–81 years (mean age 61 ± 5 years). There were 394 men 
and 497 postmenopausal women. The medians of BMI, 
total FM and total fat% were 23.0 (21.2–25.1) kg/m2, 
16.0 (12.2–20.1) kg, and 25.9 (20.0–32.3)%, respectively. 
The medians of FT3, FT4 and TSH were 4.93 (4.60–5.29) 
pmol/L, 16.55 (15.31–17.71) pmol/L and 2.17 (1.55–2.87) 
mIU/L, respectively.

Both men and women were divided into four groups 
according to LTR quartiles: Q1 < 0.58, Q2 0.58–0.63,  
Q3 0.64–0.73 and Q4 > 0.73 for men; and Q1 < 0.64,  
Q2 0.64–0.70, Q3 0.71–0.80 and Q4 > 0.80 for women 
(Table 1). In men, age, BMI, total FM, total fat%, DBP, 
FPG, FINS, HOMA-IR and E2 decreased significantly 
with increasing LTR quartiles (all P for trend < 0.05). 
In women, BMI, total FM, total fat%, SBP, FPG, HbA1c, 
FINS, HOMA-IR, TG and E2 decreased significantly with 
increasing LTR quartiles (all P for trend < 0.05). In both 
genders, HDL-c significantly increased with increasing 
LTR quartiles (all P for trend < 0.05).

Changes of thyroid hormones in LTR quartiles

In men, FT3, FT4 and TSH did not significantly change 
with increasing LTR quartiles (all P > 0.05). In women,  

only FT3 significantly decreased with increasing LTR 
quartiles. The medians of FT3 from the Q1 to the Q4 
group of LTR quartiles were 4.84 (4.56–5.19) pmol/L, 
4.78 (4.48–5.15) pmol/L, 4.74 (4.52–5.03) pmol/L and 
4.64 (4.34–4.93) pmol/L (P for trend = 0.004). In women, 
FT4 and TSH did not change significantly with increasing 
LTR quartiles (all P > 0.05, Fig. 1).

Partial correlation analysis of segmental fat 
parameters and thyroid hormones

In men and women, trunk FM was 7.5 (5.5–9.9) kg  
and 9.9 (7.4–12.1) kg, trunk fat% was 21.0 (16.5–25.3)% 
and 30.9 (25.8–35.1)%, arm FM was 1.0 (0.8–1.2) kg and  
1.4 (1.2–1.9) kg, arm fat% was 1.5 (1.3–1.7)% 
and 2.6 (2.1–3.1)%, leg FM was 4.8 (3.8–5.9) kg and 
6.8 (5.8–8.0) kg, leg fat% was 7.0 (6.1–8.0)% and  
11.9 (11.1–12.8)%, and the LTR was 0.63 (0.58–0.73)  
and 0.70 (0.64–0.80), respectively.

Age and BMI were adjusted in the partial correlation 
analysis. In men, none of the fat parameters were related to 
FT3 (all P > 0.05). In women, total FM (r = 0.098, P = 0.030), 
total fat% (r = 0.138, P = 0.002), trunk FM (r = 0.124, 
P = 0.006) and trunk fat% (r = 0.132, P = 0.003) were 
positively related to FT3, while the LTR was negatively 
related to FT3 (r = −0.147, P = 0.001) (Fig. 2). In women, 
leg FM, leg fat%, arm FM and arm fat% were not related 
to FT3 (all P > 0.05). None of the segmental fat parameters 
were related to FT4 or TSH in both men and women (all 
P > 0.05).

Multivariate linear regression analysis for 
thyroid hormones

Multivariate linear regression analysis was used to explore 
the relationships between segmental fat parameters 
and thyroid hormones in women (Table 2). In model 1,  
age, HOMA-IR, DBP, LDL-c and E2 were adjusted. 
Only LTR was negatively related to FT3 (standardized 
β = −0.116, P < 0.05), while total fat and other segmental 
fat parameters were not related to FT3 (all P > 0.05). None 
of the segmental fat parameters were related to FT4 or TSH 
(all P > 0.05).

Considering a significant and negative relationship 
between LTR and FT3, trunk fat and leg fat might be 
confounding factors of one another. Thus, we further 
created model 2. In model 2, all confounding factors 
involved in model 1 were included. In addition, leg FM 
and trunk FM were mutually adjusted, and leg fat% and 
trunk fat% were mutually adjusted. Trunk FM and trunk 

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fat% were both positively related to FT3 (standardized 
β = 0.303 and 0.218, respectively, all P < 0.05). Leg FM and 
leg fat% were both negatively related to FT3 (standardized 
β = −0.285 and −0.195, respectively, all P < 0.05).

Discussion

In the present study, we found that trunk fat accumulation 
was related to increased FT3 in euthyroid postmenopausal 
women, while increased leg fat accumulation was related 
to decreased FT3. These relationships were independent 

of multiple metabolic and cardiovascular risk factors. In 
men, none of the fat parameters were related to thyroid 
hormones.

Obesity is closely related to FT3. Previous studies have 
found that BMI and waist circumference were positively 
related to FT3 in the euthyroid population (5, 6). A 
Mendelian randomization study indicated that higher 
BMI or FM played a causal role in increasing FT3 levels (17). 
Simple obesity indexes, such as BMI have been widely used 
in these studies. There have been few studies of associations 
between precisely-measured fat distribution and FT3. 
Lambrinoudaki et  al. measured abdominal subcutaneous 

Table 1 Clinical characteristics of subjects.

Parameters
LTR quartiles

P for trendQ1 Q2 Q3 Q4
Men
 n 98 99 99 98 –
 Age (years) 63 (58–67) 62 (57–66) 61 (56–65) 59 (56–65) 0.026
 BMI (kg/m2) 23.9 (22.4–25.5) 24.4 (22.2–26.3) 23.5 (22.2–25.0) 22.0 (19.5–23.4) <0.001
 Total FM (kg) 16.0 (12.9–18.7) 15.4 (12.6–18.8) 13.0 (11.0–15.3) 8.7 (6.3–11.4) <0.001
 Total fat% 23.1 (20.0–25.3) 21.8 (19.5–24.0) 18.7 (17.0–20.9) 13.9 (10.9–16.4) <0.001
 SBP (mmHg) 135 (122–148) 134 (122–145) 132 (123–144) 130 (119–141) 0.301
 DBP (mmHg) 80 (74–88) 81 (74–87) 80 (74–86) 77 (71–82) 0.020
 FPG (mmol/L) 5.7 (5.4–6.2) 5.7 (5.4–6.0) 5.8 (5.5–6.3) 5.6 (5.3–6.1) 0.044
 2 h PG (mmol/L) 7.5 (5.8–9.7) 7.4 (5.9–8.8) 7.2 (5.8–8.3) 7.1 (5.7–8.7) 0.548
 HbA1c (%) 5.7 (5.4–6.0) 5.6 (5.4–5.9) 5.6 (5.4–5.9) 5.6 (5.4–5.8) 0.614
 FINS (mU/L) 8.8 (6.3–11.7) 7.6 (5.8–11.5) 8.3 (5.5–12.0) 6.5 (4.7–9.1) 0.001
 HOMA-IR 2.2 (1.5–3.5) 2.0 (1.4–3.1) 2.1 (1.4–3.4) 1.6 (1.1–2.4) 0.001
 TC (mmol/L) 5.3 ± 0.9 5.1 ± 0.9 5.2 ± 0.9 5.0 ± 0.8 0.102
 TG (mmol/L) 1.6 (1.2–2.3) 1.4 (1.0–2.3) 1.5 (1.0–2.2) 1.2 (0.9–2.0) 0.105
 HDL-c (mmol/L) 1.3 (1.1–1.5) 1.2 (1.1–1.4) 1.3 (1.1–1.4) 1.4 (1.1–1.6) 0.018
 LDL-c (mmol/L) 3.3 ± 0.7 3.2 ± 0.8 3.2 ± 0.7 3.0 ± 0.7 0.051
 E2 (pmol/L) 99.1 (80.8–125.7) 113.8 (91.8–128.5) 95.5 (84.4–110.1) 99.1 (80.8–121.2) 0.009
Women
 n 124 126 123 124 –
 Age (years) 60 (57–63) 61 (56–65) 61 (57–64) 60 (57–63) 0.355
 BMI (kg/m2) 25.0 (23.1–27.0) 23.4 (22.0–25.1) 22.5 (21.0–24.4) 20.2 (18.7–21.5) <0.001
 Total FM (kg) 23.0 (20.0–27.0) 19.6 (17.5–22.9) 17.0 (14.9–20.0) 12.4 (10.7–14.5) <0.001
 Total fat% 36.5 (34.1–39.0) 32.7 (30.9–35.5) 30.4 (28.3–33.4) 24.8 (22.1–26.7) <0.001
 SBP (mmHg) 127 (115–140) 128 (118–140) 125 (116–137) 121 (110–132) 0.002
 DBP (mmHg) 76 (71–83) 76 (70–81) 74 (68–82) 73 (68–80) 0.080
 FPG (mmol/L) 5.8 (5.5–6.2) 5.7 (5.4–6.2) 5.7 (5.4–6.0) 5.5 (5.1–6.0) <0.001
 2hPG (mmol/L) 7.1 (6.1–9.2) 7.1 (5.6–9.0) 7.2 (6.1–8.5) 6.8 (5.6–8.1) 0.274
 HbA1c (%) 5.7 (5.5–6.1) 5.8 (5.6–6.0) 5.7 (5.5–6.0) 5.6 (5.4–5.9) 0.049
 FINS (mU/L) 11.3 (8.5–14.3) 10.2 (7.3–14.1) 8.3 (6.8–10.5) 6.3 (4.8–7.7) <0.001
 HOMA-IR 2.8 (2.2–3.9) 2.6 (1.8–3.8) 2.1 (1.7–2.7) 1.6 (1.2–2.0) <0.001
 TC (mmol/L) 5.7 ± 0.9 5.9 ± 1.0 5.6 ± 0.9 5.8 ± 1.0 0.974
 TG (mmol/L) 1.4 (1.0–1.9) 1.4 (1.0–2.0) 1.3 (0.9–1.7) 1.0 (0.8–1.4) <0.001
 HDL-c (mmol/L) 1.4 (1.2–1.7) 1.4 (1.3–1.7) 1.6 (1.3–1.7) 1.8 (1.5–2.0) <0.001
 LDL-c (mmol/L) 3.6 ± 0.8 3.6 ± 0.9 3.4 ± 0.8 3.4 ± 0.9 0.073
 E2 (pmol/L) 36.7 (18.4–47.7) 38.5 (18.4–47.7) 18.4 (18.4–44.1) 18.4 (18.4–40.4) 0.002

Data were means ± standard deviation or medians (interquartile range). Q1 < 0.58, Q2 0.58–0.63, Q3 0.64–0.73 and Q4 > 0.73 for men; Q1 < 0.64, Q2 
0.64–0.70, Q3 0.71–0.80 and Q4 > 0.80 for women.
2 h PG, 2-h plasma glucose; BMI, body mass index; DBP, diastolic blood pressure; fat%, fat percentage; E2, estradiol; FINS, fasting insulin; FM, fat mass; 
FPG, fasting plasma glucose; HbA1c, glycated hemoglobin A1c; HDL-c, high-density lipoprotein cholesterol; HOMA-IR, homeostasis model assessment-
insulin resistance; LDL-c, low-density lipoprotein cholesterol; LTR, leg fat mass to trunk fat mass ratio; SBP, systolic blood pressure; TC, total cholesterol; 
TG, triglyceride.

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fat and preperitoneal fat through ultrasonography in 
194 euthyroid postmenopausal women. They found 
that FT3 was positively associated with subcutaneous 
fat and preperitoneal fat (18). sBIA directly measures 
the bioelectrical impedance of the trunk, arms and legs. 
Subsequently, FM and fat% of different fat depots can 
be calculated based on the bioelectrical impedance. The 
segmental fat distribution measured by sBIA was highly 
consistent with that measured by dual energy X-ray 
absorptiometry (r ≥ 0.95, P < 0.001) (9). Our findings in 
trunk fat were in consistent with Lambrinoudaki`s results. 
However, we further found a significant and negative 
relationship between FT3 and leg fat, while arm fat was 
not related to thyroid hormones. Moreover, our study 
found that there were no relationships between segmental 
fat distribution and thyroid hormones in men.

In this study, the LTR was calculated to reflect a 
tendency of fat accumulating in the legs rather than the 
trunk. In one previous study, Gavi et al. also calculated the 
limb fat to trunk fat ratio. Limb fat specifically referred 
to leg fat in their study. They found that the limb fat to 
trunk fat ratio was negatively related to insulin resistance 

and TG and positively related to HDL-c in a middle-aged 
and elderly population (19). The middle-aged and elderly 
population, especially postmenopausal women, is at 
high risk of metabolic and cardiovascular diseases (20). 
In our study, we also chose this high-risk population as 
study subjects. We found that the LTR was negatively 
related to FT3 in postmenopausal women. The correlation 
coefficient of total FM related to FT3 was weaker than 
that of trunk FM related to FT3 in the partial correlation 
analysis, and a negative relationship was found between 
the LTR and FT3. Thus, we conjectured that leg fat and 
trunk fat might be confounding factors of one another. 
In the multivariate linear regression analysis, trunk fat 
and leg fat parameters were mutually adjusted. We found 
that trunk fat parameters were positively related to FT3 
and that leg fat parameters were negatively related to 
FT3. The result suggested that leg fat might alleviate the 
adverse effect between trunk fat and increased FT3. A sex 
difference existed in the relationship between segmental 
fat distribution and FT3 in our study, which might because 
women had a greater propensity to store fat in the lower 
body driven by the effects of sex hormones (21, 22, 23).

Figure 1
Thyroid hormones with LTR quartiles. FT3 decreased significantly as LTR quartiles increased in women (P for trend = 0.004), but this trend was not 
significant in men. FT4 and TSH were not significantly changed as LTR quartiles increased in both men and women.

Figure 2
Partial correlation analysis of total FM, trunk FM, LTR and FT3 in women. Age and BMI were adjusted.

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Because FT3 promotes adipose decomposition and 
increases the basal metabolic rate (4), a high level of FT3 
in the obese population was considered a compensatory 
effect under the condition of energy surplus according to 
the conventional view (6). However, in recent years, some 
studies found that a high level of FT3 within the reference 
range is related to an increased risk of NAFLD (7, 8). In 
the Lifelines cohort study, the risk of NAFLD increased 
1.34-fold for each 1 standard deviation increase in FT3 
in the euthyroid population (7). In a euthyroid Chinese 
population, a high level of FT3 was an independent 
predictive factor of NAFLD (8). Roef et al. found that FT3 
was positively related to multiple adverse metabolic and 
cardiovascular risk factors in a euthyroid middle-aged 
population (5). Although there is still a lack of evidence 
from prospective studies, a high level of FT3 within  
the reference range may be a potential adverse  
metabolic marker.

Trunk fat and leg fat have exhibited inverse 
relationships with type 2 diabetes, cardiovascular disease 
and multiple metabolic and cardiovascular risk factors 
(3, 10, 11, 24, 25). There are large discrepancies between 
trunk fat and leg fat in the uptake and release of free fatty 
acids (26). Trunk fat is more sensitive to lipolysis stimulus. 
Leg fat has a lower lipolysis rate and is the ‘storage 
pool’ of circulating ectopic lipids. Leg fat can stabilize 
free fatty acids that are released by trunk fat and thus 
decrease lipotoxicity (21). Trunk fat and leg fat also differ 
in the release of adipokines and inflammatory factors  

(11, 27, 28); however, few studies have explored the 
relationships between adipokines and FT3. Further 
research is needed to clarify the mechanisms underlying 
the correlations between trunk fat, leg fat and FT3.

Our study has some limitations. First, the study 
subjects were middle-aged and elderly; thus, the 
results may not be generalizable to other age groups.  
Second, the present study did not fully consider some 
information such as luteinizing hormone, follicle-
stimulating hormone and selective estrogen receptor 
modulators. Third, due to the nature of the cross-sectional 
study, causality cannot be deduced. Further prospective 
studies are needed to elucidate the causal relationship 
between segmental fat distribution and FT3.

Conclusions

In euthyroid postmenopausal women, trunk fat is 
positively related to FT3, while leg fat is negatively 
related to FT3. Our findings supported that a high level 
of FT3 within the reference range was related to adverse 
fat distribution. Further studies are needed to clarify the 
causality and underlying mechanisms.

Declaration of interest
The authors declare that there is no conflict of interest that could be 
perceived as prejudicing the impartiality of the research reported.

Table 2 Multivariate linear regression for thyroid hormones in women.

Independent variables FT3 FT4 TSH

Model 1
 Total Fat mass 0.021 (0.402) 0.021 (0.407) −0.037 (−0.693)

Fat% 0.050 (0.976) −0.003 (−0.063) −0.053 (−1.019)
 Trunk Fat mass 0.042 (0.818) 0.031 (0.597) −0.041 (−0.783)

Fat% 0.056 (1.111) −0.005 (−0.102) −0.050 (−0.968)
 Arm Fat mass −0.003 (−0.063) 0.008 (0.160) −0.022 (−0.428)

Fat% 0.004 (0.069) −0.019 (−0.376) −0.025 (−0.489)
 Leg Fat mass −0.019 (−0.382) 0.003 (0.050) −0.030 (−0.572)

Fat% −0.026 (−0.530) −0.048 (−0.970) −0.032 (−0.634)
 Leg fat mass to trunk fat mass ratio −0.116 (−2.464)a −0.032 (−0.667) 0.073 (1.505)
Model 2
 Trunk Fat mass 0.303 (2.628)b 0.146 (1.244) −0.072 (−0.609)

fat% 0.218 (2.582)a 0.097 (1.130) −0.067 (−0.768)
 Leg Fat mass −0.285 (−2.525)a −0.126 (−1.092) 0.034 (0.291)

fat% −0.195 (−2.388)a −0.124 (−1.486) 0.020 (0.236)

Data were expressed as standardized β (t). aP < 0.05, bP < 0.01.
Model 1 was adjusted for age, homeostasis model assessment-insulin resistance, diastolic blood pressure, low-density lipoprotein cholesterol and 
estradiol.
In model 2, all confounding factors included in model 1 were adjusted, in addition that trunk fat mass was adjusted for leg fat mass, trunk fat% was 
adjusted for leg fat%, leg fat mass was adjusted for trunk fat mass, leg fat% was adjusted for trunk fat%.
fat%, fat percentage; FT3, free triiodothyronine; FT4, free thyroxine; TSH, thyroid-stimulating hormone.

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International License.

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X Nie, Y Xu and et al. Fat distribution and thyroid 
hormones

14318:10

Funding
This work was supported by the National Key R&D Program of China 
(2016YFA0502003).

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Received in final form 16 September 2019
Accepted 26 September 2019
Accepted Preprint published online 26 September 2019

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	Abstract
	Introduction
	Materials and methods
	Study population
	Anthropometric and biochemical assessments
	Measurement of segmental fat distribution
	Statistical analysis

	Results
	Clinical characteristics of the study participants
	Changes of thyroid hormones in LTR quartiles
	Partial correlation analysis of segmental fat parameters and thyroid hormones
	Multivariate linear regression analysis for thyroid hormones

	Discussion
	Conclusions
	Declaration of interest
	Funding
	References