Description

Aging is considered a major risk factor for the development of various cardio- and cerebrovascular related diseases, with vascular endothelial dysfunction representing one of the earliest vascular complications. Age-related cerebrovascular endothelial dysfunction contributes to a progressive decrease in cerebral blood flow, which is associated with lower measures of cognitive function, including information-processing speed, executive function, and global cognition in older adults. Similar to aging, type 2 diabetes mellitus (T2DM) also negatively impacts vascular endothelial function. There is a large body of evidence that clearly demonstrates there is an interplay between aging and T2DM and that the presence of both risk factors together promotes greater endothelial dysfunction than that of either condition alone. In this context, certain measures of cerebral blood flow are reduced to a greater extent in older individuals with T2DM compared to those without. Moreover, the exaggerated cerebral perfusion deficits frequently observed among older adults with T2DM are linked to cognitive decrements. To this point, the rate of cognitive decline due to aging is increased 1.5 to 2.0-fold in individuals with T2DM. Taken together, older adults with T2DM are at greater risk for developing dementia and Alzheimer's disease when compared age-matched controls.

Exploration of non-pharmacological therapies for the improvement of cerebrovascular health and cognition have become more common over the past decade. Intermittent hypoxia (IH) is a therapeutic intervention that combines multiple, brief (~1-10 minutes) episodes of moderate hypoxia, interspersed with episodes of normoxia. In preclinical and human studies, repeated bouts of IH improve measures of respiratory, autonomic, cardio-, and cerebrovascular health. The investigators previously demonstrated that cerebral blood flow is increased with each episode of hypoxia and a single session of IH improves nitic oxide (NO) mediated endothelial function in the internal carotid artery (ICA; major supplier of overall brain blood flow) of young adults. While cerebral blood flow is also augmented during a single session of IH in older adults, the magnitude of change appears to be less, which might suggest older adults with and without T2DM may need repeated sessions of IH for improvements in cerebrovascular health to occur. The investigator's central hypothesis is that experimental use of IH will effectively and progressively improve cerebrovascular health and cognition in older adults with T2DM. Specifically, the investigators will evaluate the interplay between aging and T2DM and how it influences cerebral endothelial function as well as the cerebrovascular responses to IH (Aim 1) and test the effectiveness of IH training for the improvement of cerebrovascular health in older adults living with diabetes (Aim 2). Collectively, the proposed studies will provide 1) novel understanding of cerebrovascular function in older adults with and without T2DM, and 2) important insight into the therapeutic potential of IH for improving cerebrovascular health and cognition in older adults living with T2DM.