Vascular basement membrane alterations and ß-amyloid accumulations in an animal model of cerebral small vessel disease.

Non-amyloid cerebral small vessel disease (CSVD) and cerebral amyloid angiopathy (CAA) may be interrelated through the damaged basement membranes (BMs) and extracellular matrix changes of small vessels, resulting in a failure of ß-amyloid (Aß) transport and degradation. We analyzed BM changes and the pattern of deposition of Aß in the walls of blood vessels in spontaneously hypertensive stroke-prone rats (SHRSP), a non-transgenic CSVD model. In 45 SHRSP and 38 Wistar rats aged 18 to 32 weeks: (i) the percentage area immunostained for vascular collagen IV and laminin was quantified; (ii) the capillary BM thickness as well as endothelial and pericyte pathological changes were analysed using transmission electron microscopy (TEM); and (iii) the presence of vascular Aß was assessed. Compared with controls, SHRSP exhibited a significantly higher percentage area immunostained with collagen IV in the striatum and thalamus. SHRSP also revealed an age-dependent increase of the capillary BM thickness and of endothelial vacuoles (caveolae) within subcortical regions. Endogenous Aß deposits in the walls of small blood vessels were observed in the cortex (with the highest incidence found within fronto-parietal areas), striatum, thalamus and hippocampus. Vascular ß-amyloid accumulations were frequently detected at sites of small vessel wall damage. Our data demonstrate changes in the expression of collagen IV and of the ultrastructure of BMs in the small vessels of SHRSP. Alterations are accompanied by vascular deposits of endogenous Aß. Impaired ß-amyloid clearance along perivascular and endothelial pathways and failure of extracellular Aß degradation may be the key mechanisms connecting non-amyloid CSVD and CAA.

Common Impact of Chronic Kidney Disease and Brain Microhemorrhages on Cerebral Aß Pathology in SHRSP.

While chronic kidney disease seems to be an independent risk factor for cognitive decline, its impact on cerebral amyloid-ß (Aß) depositions, one hallmark of Alzheimer's Disease (AD) pathology, has not been investigated. Utilizing 80 male nontransgenic spontaneously hypertensive stroke prone rats (SHRSP) at various ages (12 to 44 weeks), tubulointerstitial renal damage, prevalence of cerebral microhemorrhages and Aß accumulations were quantified. Using age-adjusted general linear models we investigated the main and interaction effects of renal damage and cerebral microhemorrhages on cerebral Aß load. In addition, using post mortem human brain tissue of 16 stroke patients we examined the co-localization of perivascular Aß deposits and small vessel wall damage. Statistical models revealed an age-independent main effect of tubulointerstitial kidney damage on brain Aß accumulations, which was reinforced by the consecutive presence of cerebral microhemorrhages. Moreover, cerebral microhemorrhages independently predicted brain Aß burden in SHRSP. In up to 69% of all human cases perivascular Aß deposits were detected in the direct vicinity of small vessel wall damage. Our results support the associations between vascular pathology and Aß deposition, and demonstrate a relationship between chronic kidney disease and cerebral Aß pathology. Hence, our data suggest that prevention of chronic renal damage may reduce cerebral Aß pathology.

Intravital imaging in spontaneously hypertensive stroke-prone rats-a pilot study.

BACKGROUND: There is growing evidence that endothelial failure and subsequent blood brain barrier (BBB) breakdown initiate cerebral small vessel disease (CSVD) pathology. In spontaneously hypertensive stroke-prone rats (SHRSP) endothelial damage is indicated by intraluminal accumulations of erythrocytes (erythrocyte thrombi) that are not observed with current magnetic resonance imaging techniques. Two-photon microscopy (2 PM) offers the potential for real-time direct detection of the small vasculature. Thus, within this pilot study we investigated the sensitivity of 2 PM to detect erythrocyte thrombi expressing initiating CSVD phenomena in vivo. METHODS: Eight SHRSP and 13 Wistar controls were used for in vivo imaging and subsequent histology with haematoxylin-eosin (HE). For 2 PM, cerebral blood vessels were labeled by fluorescent Dextran (70 kDa) applied intraorbitally. The correlation between vascular erythrocyte thrombi observed by 2 PM and HE-staining was assessed. Artificial surgical damage and parenchymal Dextran distribution were analyzed postmortem. RESULTS: Dextran was distributed within the small vessel walls and co-localized with IgG.Artificial surgical damage was comparable between SHRSP and Wistar controls and mainly affected the small vasculature. In fewer than 20% of animals there was correlation between erythrocyte thrombi as observed with 2 PM and histologically with HE. CONCLUSIONS: Contrary to our initial expectations, there was little agreement between intravital 2 PM imaging and histology for the detection of erythrocyte thrombi. Two-photon microscopy is a valuable technique that complements but does not replace the value of conventional histology.

Impact of N-Acetylcysteine on cerebral amyloid-ß plaques and kidney damage in spontaneously hypertensive stroke-prone rats.

BACKGROUND: Cerebral small vessel disease (CSVD) in spontaneously hypertensive stroke prone rats (SHRSP) is accompanied by parenchymal amyloid-ß (Aß) deposition in the brain and by hypertensive nephropathy with tubulointerstitial damage. N-acetylcysteine (NAC) promotes blood-brain barrier (BBB) breakdown in SHRSP and may thus accelerate the failure of vascular and perivascular clearance of Aß. OBJECTIVE: In this study, we test the hypothesis that treatment with NAC increases the cerebral Aß load and improves renal damage in the SHRSP model. METHODS: A total of 46 SHRSP (ages 18-44 weeks) were treated daily with NAC (12 mg/kg body weight) and 74 no-treated age-matched SHRSP served as controls. The prevalence of parenchymal Aß load, IgG positive small vessels, and small perivascular bleeds was assessed in different brain regions. Tubulointerstitial kidney damage was assessed through a) the presence of erythrocytes in peritubular capillaries and b) tubular protein cylinders. RESULTS: SHRSP treated with NAC had an age-dependent increase of BBB breakdown (assessed by the presence of IgG positive small vessels) and small perivascular bleeds, mainly in the cortex. NAC significantly increased the Aß plaque load in the cortex while the number of parenchymal amyloid deposits in the remaining brain areas including basal ganglia, hippocampus, thalamus, and corpus callosum were unchanged. There were no significant treatment effects on tubulointerstitial kidney damage. CONCLUSION: The impact of NAC on cerebral cortical plaque load increase may result from the vascular pathology of SHRSP that accompanies BBB breakdown, leading to the failure of amyloid clearance mechanisms. It remains to be seen whether in humans chronic NAC intake may increase amyloid load in the aging human brain and dementia.

Interplay between age, cerebral small vessel disease, parenchymal amyloid-ß, and tau pathology: longitudinal studies in hypertensive stroke-prone rats.

BACKGROUND: Accumulation of amyloid-ß (Aß) and hyperphosphorylated tau (ptau) accompany cerebral small vessel disease (CSVD) in the aging brain and in Alzheimer's disease. CSVD is characterized by a heterogeneous spectrum of histopathological features possibly initiated by an endothelial dysfunction and blood-brain barrier (BBB) breakdown. OBJECTIVE: We test the hypothesis that characteristic features of CSVD are associated with the accumulation of Aß and ptau in non-transgenic spontaneously hypertensive stroke-prone rats (SHRSP). METHODS: Amyloid-ß protein precursor (AßPP) and tau were investigated by western blotting (n = 12 SHRSP, age 20 weeks). Lectin staining and plasma protein immunocytochemistry for BBB examination were performed in 38 SHRSP (age 12-44 weeks) and Aß (n = 29) and ptau (n = 17) immunocytochemistry in 20-44 week-old SHRSP. We assessed the correlation between extracellular amyloid deposits and features of CSVD (n = 135, 12-44 weeks). RESULTS: In 20 week-old SHRSP, cortical AßPP expression was significantly increased compared to Wistar controls but tau levels were unchanged. At ages of 20-44 weeks, SHRSP exhibited an age-dependent increase in extracellular Aß. Ptau was observed in 26-44 week-old SHRSP. Distinct features of CSVD pathology developed from the age of 12 weeks on. CONCLUSION: We demonstrate that in a hypertensive rat model that displays features of CSVD from 12 weeks, there is an age-dependent extracellular deposition of Aß observed from 20 weeks onwards, increased AßPP expression at 20 weeks and ptau accumulation from 26 weeks on. This study suggests that CSVD associated with hypertension results in an age-related failure of Aß clearance, increase in AßPP expression, and intraneuronal tau hyperphosphorylation.

Early microvascular dysfunction in cerebral small vessel disease is not detectable on 3.0 Tesla magnetic resonance imaging: a longitudinal study in spontaneously hypertensive stroke-prone rats.

BACKGROUND: Human cerebral small vessel disease (CSVD) has distinct histopathologic and imaging findings in its advanced stages. In spontaneously hypertensive stroke-prone rats (SHRSP), a well-established animal model of CSVD, we recently demonstrated that cerebral microangiopathy is initiated by early microvascular dysfunction leading to the breakdown of the blood-brain barrier and an activated coagulatory state resulting in capillary and arteriolar erythrocyte accumulations (stases). In the present study, we investigated whether initial microvascular dysfunction and other stages of the pathologic CSVD cascade can be detected by serial magnetic resonance imaging (MRI). FINDINGS: Fourteen SHRSP and three control (Wistar) rats (aged 26-44 weeks) were investigated biweekly by 3.0 Tesla (3 T) MRI. After perfusion, brains were stained with hematoxylin-eosin and histology was correlated with MRI data. Three SHRSP developed terminal CSVD stages including cortical, hippocampal, and striatal infarcts and macrohemorrhages, which could be detected consistently by MRI. Corresponding histology showed small vessel thromboses and increased numbers of small perivascular bleeds in the infarcted areas. However, 3 T MRI failed to visualize intravascular erythrocyte accumulations, even in those brain regions with the highest densities of affected vessels and the largest vessels affected by stases, as well as failing to detect small perivascular bleeds. CONCLUSION: Serial MRI at a field strength of 3 T failed to detect the initial microvascular dysfunction and subsequent small perivascular bleeds in SHRSP; only terminal stages of cerebral microangiopathy were reliably detected. Further investigations at higher magnetic field strengths (7 T) using blood- and flow-sensitive sequences are currently underway.