Description

Cognitive decline is a major cause of disability in older adults, and vascular pathologies play a critical role in the genesis of age-related cognitive impairment. Despite advances in understanding the pathophysiology of vascular cognitive impairment (VCI), effective interventions remain scarce. Neurovascular coupling (NVC), the physiological process that adjusts local cerebral blood flow to neuronal activity, is essential for maintaining optimal brain function. According to our preclinical and clinical studies, along with accumulating evidence from other research groups, dysregulation of NVC is increasingly recognized as a key contributor to age-related cognitive decline, highlighting an urgent need for targeted therapeutic strategies.

Transcranial photobiomodulation (tPBM) has emerged as a promising, non-invasive technique with the potential to enhance both neuronal and vascular health. tPBM delivers near-infrared light to cortical areas, stimulating mitochondrial activity, reducing oxidative stress, and improving cerebral hemodynamics. There is increasing evidence that tPBM, which uses red and infrared light with specific wavelengths, confers benefit in various neurological, cardiovascular, and cerebrovascular disorders. However, the underlying neurophysiological changes need to be clarified in human studies, and there are further patient populations who would benefit from a tPBM-based intervention. Optical imaging devices, such as near-infrared spectroscopy (NIRS), offer a means to evaluate tPBM-related changes in brain oxygenation and hemodynamics in an out-of-lab environment, which would significantly improve the feasibility of trials focusing on the effects of tPBM on cerebrovascular health. The practical advantages of tPBM lie in its documented safe application, simplicity of use, affordability, and the potential for home-based interventions.

Recent studies have demonstrated a strong association between cognitive performance and NVC responses in healthy older adults and in patients with mild cognitive impairment. Neuronal activity-induced vasodilation is largely mediated by nitric oxide (NO), whose dissociation from cytochrome c oxidase (CCO) and thus bioavailability is promoted by tPBM. It has also been shown that tPBM confers anti-inflammatory effects in the brain, which is relevant given the heightened inflammatory processes in older adult,s implicating aging-induced neuroinflammation. However, limited clinical evidence exists on the impact of tPBM on NVC, particularly in aging individuals. Moreover, existing research focuses on cognitive benefits rather than neurophysiological or hemodynamic changes, with minimal integration of these outcomes. Addressing this gap, this proposal aims to leverage advanced multimodal neuroimaging techniques to investigate the age-specific tPBM-improvements in NVC and its association with the effects on cognitive function.

Preclinical and early clinical studies suggest that tPBM enhances microvascular perfusion and tissue oxygenation, while simultaneously reducing neuroinflammation and oxidative stress. These dual effects underscore its potential as a multifaceted tool for promoting neural and vascular recovery. To date, evaluations of tPBM in various populations have shown it to be a safe intervention with transient and mild headache as the most common and considerable adverse effect induced by the sessions. Its non-pharmacological nature and compatibility with existing treatments further support its use as an innovative approach for cognitive rehabilitation.

The significance of this project lies in its potential to develop a novel, non-invasive intervention for cognitive impairment in aging populations and also in its ability to elucidate the underlying mechanisms of NVC modulation by tPBM. Findings from this research will provide critical insights into the dual neural and vascular effects of tPBM, laying the groundwork for future combination therapies to address age-related cognitive decline.