Abstract
Oxygen free radicals have been implicated in brain damage after neonatal asphyxia. In the early phase of asphyxia/reoxygenation, changes in antioxidant enzyme activity play a pivotal role in switching on and off the cascade of events that can kill the neurons. Hypoxia/ischemia (H/I) forces the brain to activate endogenous mechanisms (e.g., antioxidant enzymes) to compensate for the lost or broken neural circuits. It is important to evaluate therapies to enhance the self-protective capacity of the brain. In animal models, decreased body temperature during neonatal asphyxia has been shown to increase cerebral antioxidant capacity. However, in preterm or severely asphyxiated newborns this therapy, rather than beneficial seems to be harmful. Thus, seeking new therapeutic approaches to prevent anoxia-induced complications is crucial. Pharmacotherapy with deferoxamine (DFO) is commonly recognized as a beneficial regimen for H/I insult. DFO, via iron chelation, reduces oxidative stress. It also assures an optimal antioxidant protection minimizing depletion of the antioxidant enzymes as well as low molecular antioxidants. In the present review, some aspects of recently acquired insight into the therapeutic effects of hypothermia and DFO in promoting neuronal survival after H/I are discussed.
Highlights
Neurons have endogenous cellular systems to counteract neuronal damage [1]
In this review we focus on therapeutic hypothermia and DFO treatment in enhancing endogenous neuroprotective processes involved in the regulation of redox status under neonatal H/I conditions
Current knowledge allows us to conclude that endogenous neuroprotectants can determine the extent of hypoxia/ischemia induced brain injury
Summary
Neurons have endogenous cellular systems to counteract neuronal damage [1]. Some of them prevent cell death and others allow functional recovery after injury. The disruption of oxidant/antioxidant balance of the oxidation processes leads to oxidative stress resulting in neuronal damage This was proven both in animal models [26,27,65] and in babies suffering from birth asphyxia [81,94]. The developing brain is prone to damage caused by ROS and RNS This is related to several factors, including high demand of the brain for oxygen; high concentration of oxidizing polyunsaturated fatty acids in the brain tissue which constitute the main ingredient of phospholipids with low antioxidant defense; high concentration of metals catalysing ROS generation; and a large proportion of sensitive immature cells [95]. Yan [98] postulates that redox modification of certain proteins, when induced purposely by approaches that trigger positive (weak) oxidative stress, can serve as a cellular defense mechanism that protects against ischemic injury
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