Fate of melatonin orally administered in preterm newborns: Antioxidant performance and basis for neuroprotection

Preterm infants cannot counteract excessive reactive oxygen species (ROS) production due to preterm birth, leading to an excess of lipid peroxidation with malondialdehyde (MDA) production, capable of contributing to brain damage. Melatonin (ME), an endogenous brain hormone, and its metabolites, act...

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Veröffentlicht in:Journal of pineal research 2024-01, Vol.76 (1), p.e12932-n/a
Hauptverfasser: Garofoli, Francesca, Franco, Valentina, Accorsi, Patrizia, Albertini, Riccardo, Angelini, Micol, Asteggiano, Carlo, Aversa, Salvatore, Ballante, Elena, Borgatti, Renato, Cabini, Raffaella F., Caporali, Camilla, Chiapparini, Luisa, Cociglio, Sara, Fazzi, Elisa, Longo, Stefania, Malerba, Laura, Materia, Valeria, Mazzocchi, Laura, Naboni, Cecilia, Palmisani, Michela, Pichiecchio, Anna, Pinelli, Lorenzo, Pisoni, Camilla, Preda, Lorenzo, Riboli, Alice, Risso, Francesco M., Rizzo, Vittoria, Rognone, Elisa, Simoncelli, Anna M., Villani, Paola, Tzialla, Chryssoula, Ghirardello, Stefano, Orcesi, Simona
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Zusammenfassung:Preterm infants cannot counteract excessive reactive oxygen species (ROS) production due to preterm birth, leading to an excess of lipid peroxidation with malondialdehyde (MDA) production, capable of contributing to brain damage. Melatonin (ME), an endogenous brain hormone, and its metabolites, act as a free radical scavenger against ROS. Unfortunately, preterms have an impaired antioxidant system, resulting in the inability to produce and release ME. This prospective, multicenter, parallel groups, randomized, double‐blind, placebo‐controlled trial aimed to assess: (i) the endogenous production of ME in very preterm infants (gestational age ≤ 29 + 6 WE, 28 infants in the ME and 26 in the placebo group); (ii) the exogenous hormone availability and its metabolization to the main metabolite, 6‐OH‐ME after 15 days of ME oral treatment; (iii) difference of MDA plasma concentration, as peroxidation marker, after treatment. Blood was collected before the first administration (T1) and after 15 days of administration (T2). ME and 6‐OH‐ME were detected by liquid chromatography tandem mass spectrometry, MDA was measured by liquid chromatograph with fluorescence detection. ME and 6‐OH‐ME were not detectable in the placebo group at any study time‐point. ME was absent in the active group at T1. In contrast, after oral administration, ME and 6‐OH‐ME resulted highly detectable and the difference between concentrations T2 versus T1 was statistically significant, as well as the difference between treated and placebo groups at T2. MDA levels seemed stable during the 15 days of treatment in both groups. Nevertheless, a trend in the percentage of neonates with reduced MDA concentration at T2/T1 was 48.1% in the ME group versus 38.5% in the placebo group. We demonstrated that very preterm infants are not able to produce endogenous detectable plasma levels of ME during their first days of life. Still, following ME oral administration, appreciable amounts of ME and 6‐OH‐ME were available. The trend of MDA reduction in the active group requires further clinical trials to fix the dosage, the length of ME therapy and to identify more appropriate indexes to demonstrate, at biological and clinical levels, the antioxidant activity and consequent neuroprotectant potential of ME in very preterm newborns.
ISSN:0742-3098
1600-079X
DOI:10.1111/jpi.12932