Exploring Hypoxia-Induced Neuroprotection Mechanisms in Post-Stroke Recovery.

Stroke recovery is a multifaceted process influenced by various neuroprotective mechanisms that support long-term rehabilitation. Recent studies on hypoxia-induced neuroprotection have shown promising potential in enhancing stroke recovery through adaptive cellular responses. Hypoxic conditioning in techniques of passive intermittent hypoxic exposures (IHE) or intermittent hypoxic-hyperoxic exposures (IHHE), which alternates between low and normal/high oxygen levels, is emerging as a novel complementary therapy that may improve post-stroke outcomes by promoting neuroprotection, neurogenesis, and vascular remodeling. This review aims to explore the therapeutic implications of IHE/IHHE as a novel complementary therapy to mitigate post-stroke exacerbations and enhance recovery through various physiological and molecular mechanisms. A comprehensive literature search was conducted using public databases such as PubMed, Scopus, Relemed, the National Library of Medicine, and Google Scholar. The search focused on studies related to hypoxia training, neuroprotection, stroke recovery, and IHE/IHHE. The review synthesizes current findings on the pathophysiological insights and therapeutic potential of intermittent hypoxic conditioning in stroke rehabilitation. The review highlights several key areas where IHE/IHHE shows adaptive responses involving hypoxia-inducible factor (HIF) signaling, reactive oxygen species (ROS) regulation, and mitochondrial energetics, contributing to enhanced neuroprotection and tissue recovery. Angiogenesis and vascular remodeling: IHE/IHHE promotes angiogenesis and improves cerebral blood flow, facilitating vascular remodeling and improved perfusion in damaged brain areas. Neurogenesis: IHE/IHHE enhances neurogenesis, aiding in brain repair and functional recovery by promoting neuronal survival and regeneration. Cognitive and motor function: IHE/IHHE has been shown to improve cognitive performance and motor function in post-stroke patients, as well as in elderly individuals with mild cognitive impairment. Cardioprotection: IHE/IHHE reduces cardiovascular risk factors, such as hypertension and inflammation, and has been shown to enhance cardiac function in patients with ischemic heart disease. Integrative rehabilitation: Incorporating IHE/IHHE into post-stroke rehabilitation programs may enhance physical and cognitive outcomes, supporting a holistic approach to recovery. Hypoxic conditioning in modes of IHE/IHHE represents a promising complementary therapy for stroke recovery, leveraging adaptive responses to hypoxia and hyperoxia to promote neuroprotection, neurogenesis, and vascular remodeling. Further research is needed to optimize IHHE protocols, understand their long-term effects, and integrate them effectively into clinical practice. This review benefits physicians, molecular biologists, and neurologists and describes the potential of IHE/IHHE in enhancing stroke rehabilitation outcomes, and highlights the need for well-controlled clinical trials to validate its efficacy and safety.