This study examined the relations between maternal serum leptin and thyroid hormone levels in the third trimester and TSH levels of the newborn measured from capillary blood samples; and found a positive correlation between newborn TSH levels and maternal leptin levels. To the best of our knowledge, this study is the first to focus on the relation between third trimester maternal leptin levels and thyroid function of the newborn.
T3 and T4 circulating in the fetus are of maternal origin during the first trimester; whereas, developing fetal thyroid gland increasingly contributes to the levels of these thyroid hormones from the beginning of the second trimester. Thyroid hormones have crucial roles in healthy fetal growth and development [13]. Several environmental factors may effect the thyroid function of the mother and the newborn [14]. Iodine deficiency[15], maternal thyroid hormones[5], low birth weight infants[16], pregnancy duration, maternal weight gain during pregnancy[8], high BMI, and lifetime smoking behavior[7] are among the known factors associated with subclinical hypothyroidism in the newborn. One of the well-established cause of subclinical hypothyroidism during infancy is iodine deficiency such that World Health Organization (WHO) recommended the use of percentage of newborns with a TSH > 5 U/L as a marker for population iodine deficiency [17]. The Turkish Newborn Screening Program recommends spot TSH levels of 5.5µIU/L as a threshold for the detection of congenital hypothyroidism [12] [15]. Leptin levels were significantly higher in mothers of the newborns whose TSH levels were higher than > 5.5 µIU/ml. Our results showed that increased maternal leptin levels could influence newborn TSH levels, which can be one of the main reasons for subclinical hypothyroidism in the newborn.
Leptin has modulatory roles in critical processes such as invasion, proliferation, protein synthesis, and placental cell apoptosis during early pregnancy[18]. In later stages of a healthy pregnancy, it is required to increase nutrient availability and regulate fetal growth. However, elevated leptin concentrations may represent a state of leptin resistance, which may be due to reduced bioactivity or reduced sensitivity at hypothalamic level[19]. On the other hand, leptin overproduction by placenta is associated with diabetes mellitus[20], hypertension[21], high BMI[7], and weight gain during pregnancy[8],[22]. Diabetes, obesity, and inflammation seem to be associated with the development of peripheral leptin resistance, which causes impaired leptin signaling in the brain [19]. Therefore, it is very crucial to understand both the physiological and pathological effects of increased leptin levels during pregnancy on the mother and the newborn. In the present study, third trimester leptin levels were positively correlated with BMI and maternal weight. These results are consistent with the findings of Sattar et al.[23], who found a positive correlation between BMI and third trimester leptin levels. An increase in leptin levels is expected during pregnancy due to fat tissue accumulation [23].
Additionally, Shaarawy et al. reported a positive correlation between weight gain and BMI as well as third trimester leptin levels in pregnant women [24]. However, in contrast with our findings, they failed to find a significant difference between pregnant women with high and normal BMI in terms of leptin levels. The results of that study supports the suggestion that leptin release is mainly placenta based during pregnancy[25].
Increased weight gain during pregnancy results in higher fetal weight gain[26]. Although leptin levels known to increase with increasing fat tissue, we were not able to find a correlation between maternal leptin levels and birthweight of the newborn. Similarly, Serapio et al. found no correlation between maternal leptin levels and birthweight[27]. However, Manderson et al. found a correlation between birthweight and cord leptin levels [28]. On the other hand, Stefaniak et al. found an association between birthweight and cord leptin levels, but not between birthweight and maternal leptin levels[29]. These studies support that cord leptin may increase fetal adipose tissue.
Various factors such as autoimmunity, fertility, hormones like estrogen, gender, insulin resistance, and high BMI affect the relationship between thyroid function and leptin[30]. The relation between leptin levels and thyroid function has been examined in many studies. This study found inverse relations between fT4/fT3 and leptin levels measured in the third trimester. However, we could not find correlations between maternal TSH hormone levels, levels of anti-TG and TPO, and leptin hormone. Pop et al. recently examined the adverse effects of high BMI during pregnancy on thyroid function. In that study, pregnant women who gained much weight were found to have higher TSH levels and lower FT4 levels in comparison to pregnant women with a healthy weight increase. In their study, they speculated that the excessive leptin released from fat tissue might have affected thyroid function of the pregnant women [22]. Our results are in line with that study.
In the study by Iacobellis et al., a positive correlation was found between TSH and leptin levels adjusted for BMI in euthyroid obese women [31]. On the contrary, Betry C. et al. showed an association between leptin and TSH levels independent of BMI in healthy individuals [32]. There were conflicting results from several studies; some researchers showed a negative correlation whereas others could not show a significant modulatory role for leptin on thyroid function.
In our study, median leptin level was 19 µg/L (range, 1.5–46) in the third trimester, which is similar to the distribution of leptin levels in the study by Okdemir et.al. In their study, the median of leptin level was 7.32 µg/L (range, 1.00–33.19) and 12.54 µg/L (range, 1.07–45.75) in pregnant women with healthy and excess weight gain, respectively[33]. On the other hand, Mazaki-Yovi’s research found higher leptin levels at the third trimester: 30.2 µg/L (range, 16.9–43.5) [34]. These suggest that BMI and weight gain, as well as ethnicity, may affect leptin levels.
To the best of our knowledge, this is the first study revealing that maternal leptin levels may be corraleted with maternal thyroid functions and increased newborn TSH levels and subclinical hypothyroidism. This study has limitations, it was a cross-sectional study in which maternal blood was obtained only in the third trimester, and pregnancies were not regularly followed up. Thyroid functions, leptin levels and weight gain during the first, and second trimesters were not analysed. Larger prospective studies are warranted to elucidate the clinical relevance of these findings.