Cerebral circulation involves the transport of blood oxygen and nutrients, waste removal, and nutrient metabolism. Maintaining a stable supply of cerebral blood flow depends on vascular autoregulation and vasoreactivity in the cerebral circulatory system. Past studies have indicated that neurovascular coupling occurs to assemble the energy demands of brain nerve activation, regulate blood vessel dilation, and increase cerebral blood flow to transport oxygen and glucose. Earlier studies have indicated that in order to meet the energy needs of the brain during neural activation, the regulation of blood vessel expansion and local brain blood flow increase to transport oxygen and glucose is called the neural vascular coupling mechanism. When the neural vascular coupling mechanism is impaired, it can lead to insufficient blood flow in the terminal small blood vessels of the brain circulation, which may cause damage to local brain nerves, leading to cognitive decline, small vessel disease, and even stroke. Therefore, for exploring the mechanism of brain aging and early detection and intervention of age-related neurological diseases, how to develop reliable brain blood flow-related biomarkers using non-invasive neuroimaging techniques to provide individual brain neurovascular health information is crucial. The purpose of this dissertation was to develop techniques for observing the blood flow changes of individual brain regions, including (1) using a near-infrared spectrometer with high time resolution to measure and explore the brain's hemodynamics dynamic change when elderly individuals perform cognitive tests; (2) using functional magnetic resonance imaging with a high spatial resolution to extract the relevant parameters of arterial and venous transit time, to examine changes in blood flow of cerebral small vessel disease and its relationship with disease severity. In Aim 1, to investigate whether age caused individual neurovascular changes, we used near-infrared spectroscopy to measure the concentration change of hemoglobin in the frontal lobe region of young and elderly populations. According to the results of this study, the younger group performed significantly better than the elderly group on the cognitive test in terms of test completion and reaction speed. In addition, the younger group had a lower error rate during the trial. During the cognitive test, the blood oxygen concentration of the elderly group was lower than that of the younger group. The trend of oxyhemoglobin concentrations was slowly and steadily rising. In Aim 2, for examining the potential association between microvascular lesions and cerebral blood flow changes, we used resting-state functional magnetic resonance imaging to extract systematic low-frequency oscillation signals and further applied cross-correlation analysis to estimate the individual vascular relevant parameters (arterial and venous transit time) in healthy aging and cerebral small vessel disease populations. The result revealed that the transit time increased with age. In addition, after controlling this age effect, there still was a significant positive correlation between the transit time and white matter lesions volume. Furthermore, compared to the healthy elderly group, the transit time was longer in the cerebral small vessel disease group, and the alteration showed the dose-effect increasing tread with the disease severity. In summary, this dissertation utilized near-infrared spectroscopy and functional magnetic resonance imaging, two non-invasive neuroimaging measurement techniques with complementary information in temporal and spatial dimensions, to establish oxygen concentration and cerebral brain flow indices that reflected individual cognitive performance in the aging process and validated the clinical feasibility in cerebral small vessel disease. Therefore, based on these study results, we provided multiple measurement techniques that reflected individual neurovascular healthy and might serve as potential biomarkers for neurological and vascular-related diseases in the future.