Spontaneous upper limb monoplegia secondary to probable cerebral amyloid angiopathy

Alzheimer's disease is the largest unmet medical need in neurology. Current drugs improve symptoms, but do not have profound disease-modifying effects. However, in recent years, several approaches aimed at inhibiting disease progression have advanced to clinical trials. Among these, strategies targeting the production and clearance of the amyloid-beta peptide - a cardinal feature of Alzheimer's disease that is thought to be important in disease pathogenesis - are the most advanced. Approaches aimed at modulating the abnormal aggregation of tau filaments (another key feature of the disease), and those targeting metabolic dysfunction, are also being evaluated in the clinic. This article discusses recent progress with each of these strategies, with a focus on anti-amyloid strategies, highlighting the lessons learned and the challenges that remain.

Recent epidemiological and clinico-pathologic data suggest overlaps between Alzheimer disease (AD) and cerebrovascular lesions that may magnify the effect of mild AD pathology and promote progression of cognitive decline or even may precede neuronal damage and dementia. Vascular pathology in the aging brain and in AD includes: 1. cerebral amyloid angiopathy (CAA) with an incidence of 82-98% often associated with ApoE epsilon 2 and causing a) cerebral mass hemorrhages (around 70%, mainly in the frontal and parietal lobes), b) multiple or recurrent microhemorrhages (15%), and c) ischemic (micro-)infarcts or lacunes (around 20%). The frequency of these lesions increases with the severity of CAA and shows no correlation with that of senile amyloid plaques. CAA, significantly more frequent in patients with cerebral hemorrhages or infarcts than in aged controls, is an important risk factor for cerebrovascular lesions in AD. 2. Microvascular changes with decreased density and structural abnormalities causing regional metabolic and blood-brain barrier dysfunctions with ensuing neuronal damage. In large autopsy series of demented aged subjects, around 80% show Alzheimer type pathology, 20-40% with additional, often minor vascular lesions, 7-10% "pure" vascular dementia, and 3-5% "mixed" dementia (combination of AD and vascular encephalopathy). AD cases with additional minor cerebrovascular lesions have significantly more frequent histories of hypertension or infarcts than "pure" AD patients. Vascular lesions in AD include cortical microinfarcts, subcortical lacunes, white matter lesions / leukoencephalopathy, small hemorrhages and corticosubcortical infarcts, while in mixed type dementia multiple larger or hemispheral infarcts are more frequent. Small infarcts in AD patients have no essential impact on global cognitive decline which mainly depends on the severity of Alzheimer pathology, but in early stage of AD they may influence and promote the development of dementia. Recent studies showed lower density of plaques and tangles in brains with cerebrovascular lesions, and similar severity of dementia was related to fewer AD lesions in brains with than in those without small vascular lesions. Further studies will help to elucidate the risk factors and impact of cerebrovascular lesions on the development and progression of dementia in AD.

Cerebral atherosclerosis (AS), small vessel disease (SVD), and cerebral amyloid angiopathy (CAA) are the most prevalent arterial disorders in the aged brain. Pathogenetically, AS and SVD share similar mechanisms: plasma protein leakage into the vessel wall, accumulation of lipid-containing macrophages, and fibrosis of the vessel wall. CAA, on the other hand, is characterized by the deposition of the amyloid β-protein in the vessel wall. Despite these differences between CAA, AS and SVD, apolipoprotein E (apoE) is involved in all three disorders. Such a pathogenetic link may explain the correlations between AS, SVD, CAA, and Alzheimer’s disease in the brains of elderly individuals reported in the literature. In addition, AS, SVD, and CAA can lead to tissue lesions such as hemorrhage and infarction. Moreover, intracerebral SVD leads to plasma protein leakage into the damaged vessel wall and into the perivascular space resulting in a blood–brain barrier (BBB) dysfunction. This SVD-related BBB dysfunction is considered to cause white matter lesions (WMLs) and lacunar infarcts. In this review, we demonstrate the relationship between AS, SVD, and CAA as well as their contribution to the development of vascular tissue lesions and we emphasize an important role for apoE in the pathogenesis of vessel disorders and vascular tissue lesions as well as for BBB dysfunction on WML and lacunar infarct development.