Insulin-like growth factor-1 (IGF-1) elicits a variety of effects on the regulation of oxidative stress, a topic that remains shrouded in controversy. This intricate regulation plays a pivotal role in the aging process and its associated diseases. Notably, it centers around the challenge posed by endogenous antioxidant defenses, which often struggle to counteract free radicals-induced damage to various neural cell macromolecules. The interplay between IGF-1 and oxidative stress holds significant implications. Both factors are intertwined in the context of degenerative and inflammatory disruptions within the central nervous system (CNS), giving rise to dysfunctions in neurons and glial cells. These dysfunctions encompass detrimental outcomes such as excitotoxicity, neuronal attrition, and axonal impairment, all of which are closely related to behavioral irregularities. However, the complexities of IGF-1’s impact remain a topic of debate. Divergent research findings present IGF-1 as both an antioxidative agent and a catalyst to produce reactive oxygen species (ROS) in various neuropathologies. This diversity of outcomes has contributed to the ongoing controversy in the field. The present theoretical review undertakes a comprehensive vision, shedding light on the role of IGF-1 as a regulator within the mechanistic framework of oxidative stress responses. This regulatory role serves as the basis for the emergence of progressive neurodegenerative and neuroinflammatory conditions. Particularly compelling is the exploration of IGF-1 as a potential target for promising therapeutic interventions in this domain. However, the review also highlights significant limitations, including the considerations to work with this factor and the need for further research to clarify IGF-1’s role. Future perspectives should focus on refining our understanding of IGF-1’s mechanisms and exploring its therapeutic potential in more detail.
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