부산대학교 도서관

Introduction: Vascular cognitive impairment (VCI) describes a full spectrum of cognitive deficits caused by underlying cerebral vascular alterations, regardless of the specific mechanisms involved. Several factors such as ageing, stroke, hypertension and cerebral hypoperfusion are associated with an increased risk of developing VCI. Vascular dementia (VaD) is the second most common cause of dementia after Alzheimer's disease (AD). It is now recognised that considerable overlaps exist between the features of VaD and AD. Key pathological and neuroimaging features including cerebral amyloid angiopathy (CAA), white matter lesions (WML), microinfarcts and microbleeds are evident in both VaD and AD. Furthermore, brain infarction has been reported to influence the presence and severity of clinical expressions such as cognitive performance of AD, suggesting a common pathophysiological mechanism that contributes to the development of cognitive deficits. However, gaps remain in understanding the exact mechanisms by which vascular risk factors contribute to cognitive decline and neurodegenerative processes leading to dementia. Given the importance of blood supply to the brain for maintaining its structural and functional integrity, it has been proposed that vascular risk factors may affect the cerebral haemodynamic and alter the vascular function resulting in damages to the brain. These changes may involve altered neurovascular coupling that is a critical mechanism for regulating the dynamic changes of local cerebral circulation. Further, impaired vascular function, amyloid-β (Aβ) accumulation in the cerebral vasculature and disrupted neurovascular unit are found in VCI. The glymphatic pathway, a clearance route for removing soluble waste from the brain to periphery, has been proposed to play a role in the pathogenesis of VCI. Mounting evidence has suggested that cerebral hypoperfusion, by large vessel occlusion and stenosis, is emerging as a major contributor to cognitive impairment. This has led to the development of mouse models of bilateral common carotid stenosis (BCAS), a model narrowing both common carotid arteries by placing microcoils. The BCAS model has been reported to produce many features of VCI, including white matter damage, microglial activation, gliovascular disruption, increased oxidative stress (by increased NADPH oxidase 2 (NOX2) levels) as well as memory impairment. To investigate whether there is an interaction between cerebral hypoperfusion and microvascular Aβ accumulation, a mixed model that demonstrates both microvascular amyloid (Tg-SwDI mouse model) and BCAS has been developed. In this thesis, it is hypothesized that the complex interaction of Aβ and BCAS leads to cognitive impairment via an impaired glymphatic function in addition to perfusion deficits that promote vascular related lesions and neurodegenerative changes. Second to this, given clear links between NOX2, hypoperfusion and amyloid accumulation, it was further hypothesised that NOX2 is a central mechanism leading to VCI. Methods Mice were given BCAS surgery to mimic cerebral hypoperfusion for a period of 3 months. In vivo laser speckle imaging was performed to evaluate the changes in cortical blood flow. This was followed by additional CBF measurements using arterial spin labelling (ASL)-based magnetic resonance imaging (MRI), which gave a non-invasive access to CBF information in the cerebral cortex, hippocampus and thalamus. Neurovascular coupling was assessed by performing whisker stimulation. Barnes maze was used to assess the spatial learning and memory function at 3 months following BCAS or sham surgery. For the examination of glymphatic function, in vivo intracisternal injection and ex vivo imaging of CSF fluorescent tracers were performed. Histological assessment and immunohistochemistry were used to examine vascular related pathology, Aβ burden, astrogliosis and basement membrane changes following BCAS. Results Part 1: To examine the effect of BCAS on cerebral perfusion deficits, glymphatic function and cognition in Tg-SwDI mice compared to wild-type mice. The first studies in the thesis sought to examine the effect of BCAS and microvascular amyloid on the extent of cerebral perfusion deficits and cognitive impairment. The first step was to validate whether the BCAS model has an effect on cerebral perfusion. Cortical cerebral blood flow (CBF) was examined by laser speckle imaging. This revealed sustained reductions of CBF at 24 hours, 1 and 3 months following the establishment of BCAS (p < 0.001) but no effect of the microvascular Aβ was found to affect cortical perfusion (p > 0.05). To further explore the CBF changes in other brain regions following BCAS, Arterial spin labelling (ASL), a technique widely used in clinical imaging, was performed. A significant effect of BCAS was confirmed in the dorsolateral cortex and hippocampus (p < 0.001, respectively) but no genotype effect of the microvascular Aβ or any interaction was found (p > 0.05, respectively). In order to investigate whether long-term carotid stenosis has a further effect on cognitive function in the experimental animals, assessment of Barnes maze demonstrated that BCAS mice spent longer escape latency than the sham mice in both wild-type and Tg-SwDI animals (p < 0.05, respectively) indicating visuo-spatial learning was significantly impaired at 3 months following BCAS. To determine the effect of BCAS and Aβ on long-term memory, a probe test was taken to examine whether mice remember the previous training target after a period of time. This test revealed that all groups spent a significantly higher percentage of time than chance (25%). Exclusively in wild-type BCAS mice, the percentage of time spent in the target quadrant was significantly lower than by chance (p < 0.05). In addition, there was no significant effect of BCAS or Aβ on the percentage of time spent in the correct quadrant (p > 0.05, respectively). These results suggested long-term memory was not impaired in BCAS and the presence of amyloid. Further to enhance the detection of spatial learning and memory impairment, reversal trials were taken to evaluate the ability of experimental animals to learn a new location. Compared to wild-type mice that still learned the new tests showing significantly improved performance over time (p < 0.05), both the Tg-SwDI sham and BCAS mice no longer learned the task (p > 0.05). The long-term memory tested in reversal tests showed impairment in both wildtype and Tg-SwDI BCAS as well as in the presence of amyloid after increasing the difficulties in reversal probe tests. The results indicated the only mice from wild-type sham (37.40 ± 12.63) (p < 0.05) spent a significantly higher percentage of time by 12.40 (95%CI, 1.84 to 22.96) than by chance, t(7)=2.8, p=0.027 and a significantly higher percentage of time than Tg-SwDI BCAS mice (p < 0.05) with all the other groups spending a lower percentage of time than chance (wild-type BCAS: 27.57 ± 11.12%, Tg-SwDI sham: 20.36 ± 15.50%, Tg-SwDI BCAS: 26.79 ± 16.79%). To further explore the potential mechanisms by which BCAS causes cognitive impairment, the glymphatic entry was further assessed. This revealed that the global influx of CSF tracers was different across the anatomical levels (p < 0.001) but unaltered post-BCAS in wild-type and Tg-SwDI mice (p > 0.05, respectively). To explore whether BCAS influences CSF glymphatic influx, ex vivo images of the CSF tracer influx in the dorsolateral cortex (DL CTX) and hippocampus (CA1-DG molecular layer) on the D-3 tracer were measured. The results showed in both regions, altered CSF influx was found in the BCAS and Tg-SwDI mice due to the main effect of BCAS (p=0.037 and p=0.011, DL CTX and CA-DG regions respectively) but not Aβ (p > 0.05, respectively). Taken together, these first studies support the original hypothesis that BCAS causes cognitive impairment via reduced cerebral perfusion and impaired glymphatic function. However, there was no exacerbation of these effects in Tg-SwDI mice.