Variations in melatonin levels in preterm and term human breast milk during the first month after delivery

Melatonin (N-acetyl-5-methoxytryptamine), an endogenously produced indoleamine, is secreted by the pineal gland and mainly present in external secretions, such as serum, saliva and breast milk^1–3. Melatonin has a wide range of biological functions, including antioxidation, anti-inflammatory, anti-apoptosis, and immunomodulatory, as well as adjustment of sleep and circadian rhythm^4–6. Importantly, clinical trials have demonstrated that roles of melatonin in the prevention of neonatal sepsis and children’s sleep disturbances^7,8.

Melatonin in human milk exhibits a pronounced circadian rhythm, reaching high levels at night but undetectable amounts during the day². This may suggest that the melatonin fluctuation in breast milk indicates the time of day to infants. Some studies have attributed longer sleep time in breastfed infants compared with that in formula-fed infants to melatonin in breast milk, as no melatonin is detected in formula⁹. Being a normal component and a multifunctional protein in human milk, melatonin may significantly contribute to better growth, development and long-term outcomes in infants, which are associated with breastfeeding. A few studies have shown that concentrations of melatonin in human milk vary widely^2,9–12. But no data is available on the human milk melatonin (HMM) level at different lactation stages. In this study, we identified HMM levels and explored the effects of gestation and lactation stages.

The present study characterized the melatonin level in preterm milk and term milk across different lactation stages. Understanding the levels and variations of HMM could contribute to the body of research that supports the importance of breastfeeding for infant nourishment and development.

In this study, for the first time, we demonstrated that melatonin has a clear circadian rhythm in both preterm and term breast milk across lactation stages. The current work identified that the peak melatonin level in breast milk was 23.49 pg/ml on average, which is comparable to previous data^2,11. The peak HMM level accounts an average of 35% of the maternal serum concentration, which also shares a similar circadian rhythm². That suggests HMM is likely derived from blood and the 24-hour HMM profile mimicked the melatonin levels changes in the blood¹³. HMM productions were relatively low during daytime hours, elevating at night, and then peaking at around 03:00, while artificial formulas do not contain melatonin^9,14. Newborns have low serum melatonin levels due to an inadequacy of self-produced, which increase progressively up to the 3rd month of age when a characteristic circadian rhythm is first detectable¹⁴. HMM plays an important role in newborn synchronization with the mother’s rhythm¹⁵ and is responsible for longer sleep time in breastfed infants than that in formula-fed infants^9,16. Some authors suggested that mothers should nurse with dimmer light or even lights off at night to avoid HMM reductions, which could disturb infant sleep patterns¹⁷. By the same token, differentiating milk pumped during the day from milk pumped during darkness has also been suggested for women that pump milk for their infants^11,18.

In addition, we also found that HMM concentration changed dynamically during lactation in preterm or term breast milk. The peak HMM level was highest in colostrum, and then in transitional milk, and in mature milk, decreasing considerably during the first month after delivery. Honorio et al.¹⁰ found that higher colostrum melatonin levels at night appear to increase the phagocytic activity of colostral cells against bacteria. However, melatonin was shown to increase superoxide production and bactericidal activity of colostral phagocytes from normoglycemic women, but not from hyperglycemic women. This may suggest that the antioxidant effect of melatonin on the functional activity of colostral phagocytes decreased in diabetic women. However, limited data are available concerning the melatonin in the transitional and mature milk.

Compared with term milk, the preterm milk had a higher peak concentration of melatonin in every tested lactation stage, which may benefit for premature infants during the first few weeks after birth when they are especially vulnerable. Indeed, being a potential neuroprotective agent, melatonin was found to reduce brain injury and its long-lasting consequences after hypoxia-ischemia^19–25 and oxidative damage in immature rat brains²⁶. Furthermore, melatonin supplementation was also found to improve both lipopolysaccharide-induced neonatal inflammation and related brain injury in rats²⁷, and the inflammatory reaction and cell death were reduced in the white matter of preterm and near-term fetal sheep following umbilical cord occlusion^28,29. In view of undetectable plasma melatonin level before 31 weeks gestation age, an interesting proposed use of melatonin as a drug is to treat perinatal ischemic brain injuries³⁰.

Our study had several limitations. There could be a selection bias. We attempted to diminish that by randomly approaching the mothers and explain the goal of the research only after they have agreed to cooperate. In addition, almost none of the mothers refused to participate. The small cohort size of preterm breast milk represented another limitation within our study. In the future, we plan to extend the breastfeeding period or divide the gestation ages into early preterm, middle preterm, and near term for more detailed research. Notwithstanding these limitations, this work offers valuable insight into the effects of preterm and lactation stage on HMM level, which provides an opportunity to develop hypotheses for future studies to evaluate how the HMM content was modulated on the basis of maternal and/ or infant factors.

This variability in HMM levels might reflect the different needs of different infants during the first few weeks of life. Our data might help to inform models to design tailored supplementation strategies of melatonin in nurseries and after home discharge. In fact, detection of HMM levels in specific mothers and during specific periods of lactation might reveal tailored melatonin supplementation for the infant according to the present maternal milk levels.

This study has shown that melatonin has a clear circadian rhythm in both preterm and term breast milk across varying lactation stages. The peak HMM level was highest in colostrum, and then in transitional milk, and in mature milk, decreasing considerably during the first month after birth. Compared with term milk, the preterm milk had a higher peak concentration of melatonin, especially in the colostrum, which may benefit premature infants during early life when they are extremely vulnerable.