Childhood growth-restriction can lead to lasting developmental changes, increasing susceptibility to chronic diseases and neurodegenerative conditions in adulthood. High-intensity interval training (H Show more
Childhood growth-restriction can lead to lasting developmental changes, increasing susceptibility to chronic diseases and neurodegenerative conditions in adulthood. High-intensity interval training (HIIT) elevates brain-derived neurotrophic factor (Bdnf) levels more effectively than moderate intensity continuous exercise, supporting neuroplasticity. Building on these findings, this study aimed to determine whether HIIT could enhance neuroplasticity-related protein expression in the brains of PNGR mice. FVB mouse pups born to normal-protein and low-protein-fed dams were cross-fostered at postnatal day (PN) 1 to establish two groups: postnatally growth-restricted mice (PNGR) and control mice (CON). At PN 21, all pups were weaned onto a normal protein diet and assigned to either a high-intensity interval training group (TRD) or a sedentary group (SED). At PN 45, a maximal exercise performance test was conducted to determine HIIT intensities. Based on these results, mice performed treadmill HIIT 5 days per week for 4 weeks, with alternating intervals of 8 minutes at 85% and 2 minutes at 50% of maximal exercise capacity, totaling 60 minutes per session. At PN 73, all mice were euthanized, and cerebrum tissue was collected for western blot analysis of Bdnf, Tropomyosin receptor kinase B (TrkB), Growth-associated protein 43 (Gap-43), and synaptophysin protein expression. Despite significant body mass reductions observed in both CON and PNGR groups following HIIT, neuroplasticity-related protein expression did not increase in PNGR mice. The PNGR group exhibited consistently lower TrkB and reduced Bdnf and Gap-43 levels compared to CON mice, indicating a limited neuroplastic response to exercise. Contrary to expectations, HIIT did not elevate neuroplasticity markers in PNGR mice, highlighting the lasting impact of early-life growth restriction on brain plasticity and suggesting the need for alternative interventions. Show less
This study aims to investigate the radioprotective effects of melatonin (MEL) against oxidative damage that may be caused by flattening filter (FF) and flattening filter-free (FFF) beam in the cerebru Show more
This study aims to investigate the radioprotective effects of melatonin (MEL) against oxidative damage that may be caused by flattening filter (FF) and flattening filter-free (FFF) beam in the cerebrum and cerebellum of rat using various genetic markers. Forty female Wistar albino rats were randomly assigned to five groups. The control group received no intervention. The FF group received a single 16 Gy fraction at 600 MU/min. The FF+MEL group received the same FF protocol, preceded by melatonin (50 mg/kg, intraperitoneal) administered 15 min before irradiation. The FFF group received a single dose of 16 Gy at 2,400 MU/min. The FFF+MEL group received the same FFF protocol with melatonin administered as above. After treatment, cerebrum and cerebellum tissues were harvested, and mRNA expression levels of BDNF, CREB, BAX, BCL2 and IL6 were measured. Both FF and FFF radiotherapy treatments significantly increased BDNF, CREB, IL6, and BAX gene expression in cerebrum and cerebellum tissues, while decreasing BCL2 levels (P < 0.05). Melatonin treatment increased BDNF and CREB expression, significantly attenuated radiation-induced increases in IL6 and BAX, and partially reversed the decrease in BCL2 (P < 0.05). The increase in the BAX/BCL2 ratio after radiotherapy was significantly attenuated by melatonin treatment. Overall, FFF irradiation induced a stronger oxidative, inflammatory, and pro-apoptotic response than FF, whereas melatonin exhibited potent neuroprotective and anti-apoptotic effects. In conclusion, MEL demonstrates potential as a protective agent for healthy tissues during irradiations, owing to its antiapoptotic, anti-inflammatory, and neurotrophic properties. Show less