Modified Bielschowsky and immunocytochemical studies on cerebellar plaques in Alzheimer's disease.

Senile plaques (SP) in the cerebellum of 23 cases of Alzheimer's disease (AD), three with widespread amyloid angiopathy, were studied with a modified Bielschowsky stain and immunocytochemical methods using antibodies to a beta-amyloid synthetic peptide (beta ASP), phosphorylated neurofilament proteins, ubiquitin, tau protein, and glial fibrillary acidic protein (GFAP). The four subtypes of SP (diffuse plaques, compact plaques, perivascular plaques, and subpial fibrillar deposits) that were observed with the modified Bielschowsky stain were also stained with antibodies to beta ASP. Many cerebellar SP contained ubiquitin-positive granular elements resembling dystrophic neurites. In contrast to neuritic elements in cerebral SP in AD, ubiquitin-positive elements in cerebellar SP were not labeled with antibodies to phosphorylated neurofilament or tau proteins. Various degrees of glial reaction were observed in all subtypes of SP except diffuse plaques. The absence of phosphorylated neurofilament and tau epitopes in neuritic elements in cerebellar SP is not surprising since paired helical filaments have not been seen in the cerebellum. Nevertheless, our results suggest that cerebellar SP are frequently associated with dystrophic neurites.     

Neurochemical diversity of dystrophic neurites in the early and late stages of Alzheimer's disease

We examined the neurochemical and morphological diversity of abnormal neurites associated with beta-amyloid plaque formation in the early and late stages of Alzheimer's disease. Preclinical Alzheimer's disease was characterised by the presence of abnormal neurites containing either neurofilament or chromogranin A immunoreactivity. All clustered dystrophic neurites in these cases were associated with beta-amyloid plaques. Neurofilament immunoreactive dystrophic neurites in preclinical Alzheimer's disease could be further subclassified into bulb- and ring-like structures, and these abnormal neurites contained both phosphorylated and dephosphorylated neurofilament epitopes. Dystrophic neurites in Alzheimer's disease could be subdivided into predominantly neurofilament, tau, or chromogranin A immunolabeled forms. Some neurofilament immunoreactive neurites had a core region labeled for tau. The neurofilaments of the dystrophic neurites in Alzheimer's disease had the same complement of phosphorylation- and dephosphorylation-dependent epitopes as observed in preclinical cases. Therefore, an abnormal accumulation of variably phosphorylated neurofilaments represent the earliest cytoskeletal alteration associated with dystrophic neurite formation. Furthermore, these data indicate that dystrophic neurites may "mature" through neurofilament-abundant forms to the neurites containing the profoundly altered filaments labeled for tau. The precise morphological and neurochemical changes associated with dystrophic neurite formation suggests that beta-amyloid plaques are causing physical damage to surrounding axons. The resultant axonal sprouting and profound cytoskeletal alterations would follow the chronic stimulation of the stereotypical reaction to such physical trauma.     

Cotton wool plaques in non-familial late-onset Alzheimer disease.

Cotton wool plaques (CWP) are large, ball-like plaques lacking dense amyloid cores that displace adjacent structures. They were first described in a Finnish kindred with early-onset Alzheimer disease (AD) with spastic paraparesis due to a presenilin-1 delta9 mutation. We describe a case of sporadic late-onset AD with numerous neocortical CWP as well as severe amyloid angiopathy and marked leukoencephalopathy, compared with 16 cases of late-onset AD with similar degrees of amyloid angiopathy and leukoencephalopathy. The cases were studied with histologic methods and with single and double immunostaining for beta-amyloid (Abeta), paired helical filaments-tau (PHF-tau), neurofilament (NF), glial fibrillary acidic protein (GFAP), HLA-DR, and amyloid precursor protein (APP). We found that CWP were well-circumscribed amyloid deposits infiltrated by ramified microglia and surrounded by dystrophic neurites that were immunopositive for APP, but only weakly for NF and PHF-tau. Abeta1-12 was diffuse throughout the CWP, while Abeta37-42 was peripherally located and Abeta20-40 more centrally located. Two of the 16 late-onset AD cases also had CWP, but they were also admixed with diffuse plaques and plaques with dense amyloid cores. Pyramidal tract degeneration was not a consistent finding or a prominent feature in any case. The results suggest that CWP are not specific for early-onset familial AD with spastic paraparesis.     

Phosphorylated tau in neuritic plaques of APP<Superscript>sw</Superscript>/Tau<Superscript>vlw</Superscript> transgenic mice and Alzheimer disease

We have previously reported that double-transgenic APP(SW)/Tau(VLW) mice show enhanced amyloid deposition, stronger tau hyperphosphorylation, increased sarkosyl tau polymers, and wider tau filaments when compared to simple mutant models. To validate these transgenic mice as models of Alzheimer disease pathology, in the present study we analyze tau phosphorylation at 12E8 and AT-8 epitopes in amyloid plaques. In APP(SW) mice, phospho-tau in plaque-associated neurites suggests a local direct effect of plaque-amyloid (and/or APP(SW)) on tau phosphorylation. In vitro, attempts to identify which kinases are induced by fibrillar amyloid reveal to Protein Kinase C as responsible for phosphorylation at the 12E8 epitope. Tau(VLW) mice, without plaques, show increased tau phosphorylation at the 12E8 epitope, particularly in pyramidal neurons. APP(SW)/Tau(VLW) mice show earlier and stronger 12E8 tau phosphorylation. Ultrastructurally, the same two types of neurites are found in plaques from APP(SW)/Tau(VLW) and Alzheimer disease (AD) brains: (a) dystrophic giant neurites filled with degenerating organelles and/or phospho-tau-positive filaments and (b) non-dystrophic phospho-tau-positive small punctiform neurites. Both types of plaque-associated neurites are AT-8 positive in APP(SW)/Tau(VLW) mice and AD, but 12E8-positive dystrophic neurites are only detected in AD. We conclude that the simultaneous presence of human mutated Tau(VLW) and plaque-amyloid (and/or APP(SW)) potentiates and anticipates tau phosphorylation at the 12E8 epitope, intensifying pyramidal neuron immunostaining and tau filament formation in this double-transgenic model. Thus, the APP(SW)/Tau(VLW) mouse is a useful model to study neuritic plaques, since they reproduce most of the characteristics that these structures have in AD.     

Presenile Alzheimer dementia characterized by amyloid angiopathy and large amyloid core type senile plaques in the APP 692Ala→Gly mutation

Mutations at codons 717 and 670/671 in the amyloid precursor protein (APP) are rare genetic causes of familial Alzheimer’s disease (AD). A mutation at codon 693 of APP has also been described as the genetic defect in hereditary cerebral hemorrhage with amyloidosis of the Dutch type (HCHWA-D). We have reported a APP692Ala→Gly (Flemish) mutation as a cause of intracerebral hemorrhage and presenile dementia diagnosed as probable AD in a Dutch family. We now describe the post-mortem examination of two demented patients with the APP692 mutation. The neuropathological findings support the diagnosis of AD. Leptomeningial and parenchymal vessels showed extensive deposition of Aβ amyloid protein. Numerous senile plaques consisted of large Aβ amyloid cores, often measuring more than 30 μm in diameter and were surrounded by a fine meshwork of dystrophic neurites. In addition, there were a large number of paired helical filaments in pyramidal neurons and dystrophic neurites. Our findings show that the APP692 mutation leads to morphological abnormalities that are similar to AD, but the morphology of senile plaques is clearly distinct from that described in sporadic and chromosome 14-linked AD patients, in patients with APP717 mutations causing familial, presenile AD and in patients with the APP693 mutation causing HCHWA-D. Received: 11 August 1997 / Revised, accepted: 9 February 1998     

Hyperphosphorylated tau and paired helical filament-like structures in the brains of mice carrying mutant amyloid precursor protein and mutant presenilin-1 transgenes

Senile plaques composed mainly of beta-amyloid (Abeta) and neurofibrillary tangles principally composed of hyperphosphorylated tau are the major pathological features of Alzheimer's disease (AD). Despite the fact that increased expression of amyloid precursor protein (APP) and presenilin-1 (PS1) transgenes in mice lead to increased Abeta deposition in plaquelike structures in the brain, little is known about the nature and distribution of tau in these mice. Therefore the relationship between Abeta and hyperphosphorylated tau was investigated in mice carrying mutant APP and mutant PS1 transgenes using both light (LM) and electron microscopy (EM) with immunocytochemistry. LM immunocytochemistry revealed cerebral Abeta deposits to be present from 8 weeks of age, whereas hyperphosphorylated tau was not detected until 24 weeks of age, when it appeared as punctate deposits in close association with the Abeta deposits in the cortex and hippocampus. However, dystrophic neurites were not as heavily immunolabeled as they are in AD brain. EM revealed that aggregations of straight filaments (10-12 nm wide) were present in some cellular processes at the periphery of Abeta plaques in 8-month-old APP/PS1 mice. In one such mouse, single filaments and paired filaments showing a helical configuration (50-55 nm half-period, 25 nm max. width) were present in a dark, atrophic hippocampal neuron. Immunogold labeling of APP/PS1 mouse brain revealed hyperphosphorylated tau epitopes in some dystrophic neurites from 24 weeks of age that were similar to those present in AD. These results suggest that hyperphosphorylated tau appears in APP/PS1 mouse brain after the onset of Abeta deposition and although it is associated with Abeta deposits, its distribution is not identical to that in AD.     

Ubiquitin immunoelectron microscopy of dystrophic neurites in cerebellar senile plaques of Alzheimer's disease

Summary Senile plaques are present in the cerebellum of most Alzheimer patients. They are composed of beta-amyloid deposits lacking neurites detectable with immunocytochemistry for neurofilament, tau and paired helical filament proteins. Recent studies, however, have shown that cerebellar plaques usually contain round structures that are reactive with ubiquitin antibodies. In this immunoelectron microscopic study, the nature of these structures is explored. Ubiquitin-positive structures in cerebellar senile plaques were composed of degenerating neurites that contained membranous and vesicular dense bodies, but no paired helical filaments. A minority of the neurites contained finely granular material. Thus, cerebellar plaques are associated with neuritic degeneration, and the neurites in cerebellar plaques resemble dystrophic neurites in senile plaques of non-demented elderly subjects and subjects with non-Alzheimer dementias. They differ from some of the neurites in senile plaques in the neocortex in Alzheimer's disease by the absence of paired helical filaments. These results suggest that the same mechanisms involved in the generation of dystrophic neurites in pathological aging are involved in generating dystrophic neurites in the cerebellum in Alzheimer's discase.Supported by NIH grant: AG06803 and AG1136     

Intracellular mechanisms of amyloid accumulation and pathogenesis in Alzheimer’s disease

Cell-culture studies have revealed some of the fundamental features of the interaction of amyloid Abeta with cells and the mechanism of amyloid accumulation and pathogenesis in vitro. A(beta)1-42, the longer isoform of amyloid that is preferentially concentrated in senile plaque (SP) amyloid deposits in Alzheimer's disease (AD), is resistant to degradation and accumulates as insoluble aggregates in late endosomes or lysosomes. Once these aggregates have nucleated inside the cell, they grow by the addition of aberrantly folded APP and amyloidgenic fragments of APP, that would otherwise be degraded, onto the amyloid lattice in a fashion analogous to prion replication. This accumulation of heterogeneous aggregated APP fragments and Abeta appears to mimic the pathophysiologyof dystrophic neurites, where the same spectrum of components has been identified by immunohistochemistry. In the brain, this residue appears to be released into the extracellular space, possibly by a partially apoptotic mechanism that is restricted to the distal compartments of the neuron. Ultimately, this insoluble residue may be further digested to the protease-resistant A(beta)n-42 core, perhaps by microglia, where it accumulates as senile plaques. Thus, the dystrophic neurites are likely to be the source of the immediate precursors of amyloid in the senile plaques. This is the opposite of the commonly held view that extracellular accumulation of amyloid induces dystrophic neurites. Many of the key pathological events of AD may also be directly related to the intracellular accumulation of this insoluble amyloid. The aggregated, intracellular amyloid induces the production of reactive oxygen species (ROS) and lipid peroxidation products and ultimately results in the leakage of the lysosomal membrane. The breakdown of the lysosomal membrane may be a key pathogenic event, leading to the release of heparan sulfate and lysosomal hydrolases into the cytosol. Together, these observations provide the novel view that amyloid deposits and some of the early events of amyloid pathogenesis initiate randomly within single cells in AD. This pathogenic mechanism can explain some of the more enigmatic features of Alzheimer's pathogenesis, like the focal nature of amyloid plaques, the relationship between amyloid, dystrophic neurites and neurofibrillary-tangle pathology, and the miscompartmentalization of extracellular and cytosolic components observed in AD brain.     

Approach to the dementia research

Main causes of dementia in the elderly are vascular dementia and Alzheimer's dementia. Vascular dementia is related to both amounts and localization of lesions. Recently incidence of diffuse vascular leukoencephalopathy (Binswanger type, leukoaraiosis) and amyloid angiopathy are increasing. In Alzheimer's protein chemistry of amyloid (beta protein, A4 protein) revealed its precursor APP and its gene (chromosome 21), which produces protease inhibitor in the brain of Alzheimer and Down's brains. APP is considered as an membrane protein (receptor) and appears abundantly in the cerebral cortex. Immunohistochemical study showed that beta protein is observed also in normal aged brain. On the other hand, tau protein (main component of Alzheimer's neurofibrillary tangle, PHF) appeared as abnormal sprouting of neurites in Alzheimer's brain. The latter may related to dementia and neural death. In Alzheimer's dementia, several neurotransmitters, including acetylcholine, are reduced in the brain and related structural changes are observed. Recently olfactory bulb and mucosal changes are remarked as one of pathogenesis of this disease. Delayed neuronal death is a new phenomenon of nerve cell death of vascular origin and should be studied in human vascular dementia.     

Sporadic cerebral amyloid angiopathy presenting with dementia and prominent capillary beta-amyloid deposition: a case report]

We report a sporadic case of unusual cerebral amyloid angiopathy (CAA) with prominent capillary involvement. A 67-year-old doctor developed gait disturbance, resting tremor and rigidity. He was diagnosed to have Parkinson's disease, for which the treatment with levodopa was effective. Four years later he began to exhibit progressive cognitive decline and behavioral abnormalities consisting of hallucination and agitation. Subsequently, his condition steadily worsened and became bedridden with severe dementia, and he died eight years after the disease onset. During the clinical course, there had been no episode of stroke. Postmortem examinations revealed the typical pathology of Parkinson's disease with frequent cortical Lewy bodies in the amygdala. The most striking pathological feature of this patient was widespread CAA where prominent beta-amyloid (A beta) deposition was observed in the capillaries of the neocortex, most pronouncedly in the occipital lobe, as well as leptomeningeal and cerebral medium-sized and small vessels. Further, perivascular plaques were found in half of the amyloid-laden capillaries. Tau-positive dystrophic neurites were only sparsely detectable within a few perivascular plaques. Despite the severe A beta pathology, there was no microaneurysmal dilatation, fibrinoid necrosis or vascular occlusion. There was only one small ischemic lesion in the brain. The cerebral white matter was unremarkable. Senile plaques of neuritic type and neurofibrillary tangles were mostly limited to the hippocampal regions and, to a lesser degree, in the amygdaloid nucleus, which did not meet the neuropathological criteria of Alzheimer's disease. On the gene analyses, his apolipoprotein E (ApoE) genotyping was verified to be heterozygous epsilon 3/epsilon 4, and no mutation was seen in exons 16 and 17 of the amyloid precursor protein gene. Severe A beta capillary angiopathy as seen in our patient is exceptional in sporadic CAA. Further, A beta angiopathy of this patient was notable in the absence of an associated cerebrovascular disease despite prominent A beta deposition in the vessel walls. Regarding the development of his severe dementia, the limbic pathology of Lewy body disease might be one of the potential causes, but A beta angiopathy appears more likely because of its severity. We speculate that widespread A beta deposition disregulates the blood-brain barrier of the capillaries leading to a disturbance of the microcirculation throughout the cerebral cortex without obvious ischemic disintegration of the neuropil. We should take into consideration that A beta angiopathy can present as progressive dementia without cerebrovascular disease.     

Characterization of amyloid deposition in the APPswe/PS1dE9 mouse model of Alzheimer disease

Transgenic mice carrying disease-linked forms of genes associated with Alzheimer disease often demonstrate deposition of the beta-amyloid as senile plaques and cerebral amyloid angiopathy. We have characterized the natural history of beta-amyloid deposition in APPswe/PS1dE9 mice, a particularly aggressive transgenic mouse model generated with mutant transgenes for APP (APPswe: KM594/5NL) and PS1 (dE9: deletion of exon 9). Ex vivo histochemistry showed Abeta deposition by 4 months with a progressive increase in plaque number up to 12 months and a similar increase of Abeta levels. In vivo multiphoton microscopy at weekly intervals showed increasing beta-amyloid deposition as CAA and plaques. Although first appearing at an early age, CAA progressed at a significantly slower rate than in the Tg2576 mice. The consistent and early onset of beta-amyloid accumulation in the APPswe/PS1dE9 model confirms its utility for studies of biochemical and pathological mechanisms underlying beta-amyloid deposition, as well as exploring new therapeutic treatments.     

Amyloid beta-protein precursor accumulates in dystrophic neurites of senile plaques in Alzheimer-type dementia

We raised two rabbit antisera against synthetic peptides corresponding to the carboxyl- and amino-terminal regions of the predicted amyloid beta-protein precursor (APP). Both antisera recognized the same 106-135 kDa proteins of human brain extract by immunoblot analysis. Immunocytochemical studies showed that these antisera both reacted with the same dystrophic neurites within the senile plaques of Alzheimer brains. These results indicated that APP accumulated in the dystrophic neurites of the senile plaques.     

Expression of APP in the early stage of brain damage.

We immunocytochemically studied the expression of various epitopes of amyloid beta/A4 protein precursor (APP) after brain damage by kainic acid injection. After 3 h, APP695 rapidly accumulated in dystrophic neurites near the damaged site. After 3 days, APP with Kunitz-type protease inhibitor domain was expressed in reactive astrocytes in the lesion and ipsilateral hippocampus. APP rapidly accumulated in dystrophic neurites, and different types of APP were expressed in different cell types in the damaged brain.     

Thrombolysis induces cerebral hemorrhage in a mouse model of cerebral amyloid angiopathy

We studied the impact of cerebral amyloid angiopathy on tissue plasminogen activator-induced cerebral hemorrhages in APP23 transgenic mice. Results show that the intravenous administration of tissue plasminogen activator in APP23 mice leads to an increase in cerebral amyloid angiopathy-associated microhemorrhages and can provoke parenchymal and subarachnoidal hematomas. We conclude that cerebral amyloid angiopathy is a risk factor for cerebral hemorrhage caused by tissue plasminogen activator administration in mice and stress the need for more comprehensive studies of the relation between cerebral amyloid angiopathy and tissue plasminogen activator-induced cerebral hemorrhages in elderly and Alzheimer's disease patients.     

Modified Bielschowsky stain and immunohistochemical studies on striatal plaques in Alzheimer's disease

Summary The nature of senile plaques (SP) in the striatum in 14 cases of Alzheimer's disease (AD) was investigated with the modified Bielschowsky stain and immunohistochemistry using antibodies to a amyloid synthetic peptide, ubiquitin, tau protein, and paired helical filaments (PHF). Striatal SP, composed of amyloid deposits with or without neuritic elements, were demonstrated in all AD cases examined. Compact and perivascular amyloid deposits were concentrated in the ventral striatum, including the nucleus accumbens. Many diffuse amyloid deposis in the ventral striatum contained ubiquitin-positive granular elements, presumably representing dystrophic neurites, whereas most of those in the dorsal striatum did not have such elements. On the other hand, most compact amyloid deposits in both ventral and dorsal striatum had ubiquitin immunoreactivity. Dystrophic neurites with tau or PHF immunoreactivity were detected particularly around compact amyloid deposits. Our results indicate that the ventral striatum, which is closely affiliated with the limbic system, is frequently affected by amyloid deposits with dystrophic neurites, and suggest that the ventral striatum is particularly vulnerable to AD. Furthermore, our results suggest that amyloid deposits, especially compact deposits, may induce dystrophic neurites.Supported by NIH grant: AG06803 and AG4145     

Novel amyloid precursor protein mutation in an Iowa family with dementia and severe cerebral amyloid angiopathy.

Several mutations in the amyloid precursor protein (APP) gene have been found to associate with pathologic deposition of the beta-amyloid peptide (Abeta) in neuritic plaques or in the walls of cerebral vessels. We report a mutation at a novel site in APP in a three-generation Iowa family with autosomal dominant dementia beginning in the sixth or seventh decade of life. The proband and an affected brother had progressive aphasic dementia, leukoencephalopathy, and occipital calcifications. Neuropathological examination of the proband revealed severe cerebral amyloid angiopathy, widespread neurofibrillary tangles, and unusually extensive distribution of Abeta40 in plaques. The affected brothers shared a missense mutation in APP, resulting in substitution of asparagine for aspartic acid at position 694. This site corresponds to residue 23 of Abeta, thus differing from familial Alzheimer's disease mutations, which occur outside the Abeta sequence. Restriction enzyme analysis of DNA from 94 unrelated patients with sporadic cerebral amyloid angiopathy-related hemorrhage found no other instances of this mutation. These results suggest a novel site within Abeta that may promote its deposition and toxicity.     

The widespread alteration of neurites in Alzheimer's disease may be unrelated to amyloid deposition

The structural changes of Alzheimer's disease (AD) include a widespread alteration of neuronal cell processes in addition to senile plaques and neurofibrillary tangles. Since the antigenic characteristics of these abnormal neurites are similar to those of the abnormal neurites associated with the senile plaques, the question has been raised as to whether the widespread neuritic alteration is secondary to the deposition of amyloid. To answer this question, we examined brains from 2 subjects with a longer-lasting form of subacute sclerosing panencephalitis (SSPE) characterized by the presence of numerous neurofibrillary tangles but no senile plaques, 3 subjects with AD, and 2 age-matched controls. Light and electron immunocytochemical analyses revealed that abnormal neurites are present diffusely in SSPE cerebral cortex in the absence of amyloid deposits. These abnormal neurites were qualitatively identical to the widespread abnormal neurites of AD. The abnormal neurites, in contrast to the neurites of control brains, immunoreacted with antibodies to tau and ubiquitin. These distinctive antigenic features were due to the presence in these abnormal neurites of straight filaments, 14 to 16 nm in diameter, mixed with a few paired helical filaments. The spatial distribution of the widespread neuritic alteration correlated with that of neurofibrillary tangles in both conditions, but not with that of senile plaques in AD. The present findings demonstrate that a diffuse alteration of neurites similar to that present in AD takes place independently of the deposition of amyloid in SSPE, and they are consistent with the hypothesis that in AD, also, this alteration is not secondary to the deposition of amyloid.(ABSTRACT TRUNCATED AT 250 WORDS)     

Beta-amyloid plaques induce neuritic dystrophy of nitric oxide-producing neurons in a transgenic mouse model of Alzheimer's disease

A causative role for nitric oxide has been postulated in a number of neurodegenerative diseases. Using histochemical and immunohistochemical methods, we examined the effect of beta-amyloid plaques on nitric oxide-producing cells in transgenic mice which overexpress a mutant human amyloid precursor protein (APP). In 14-month-old animals, nitric oxide synthase (NOS)-positive dystrophic neurites were observed frequently in the cerebral cortex and hippocampus of all of 16 plaque-bearing transgenic animals and in none of 16 wild-type animals. Double labeling of NOS and beta-amyloid revealed that 90% of beta-amyloid plaques were associated with NOS-containing dystrophic neurites. In 7-month-old animals, beta-amyloid plaques were very rare, but those present were frequently associated with NOS-positive neuritic dystrophy. We conclude that beta-amyloid plaques induce neuritic dystrophy in cortical neurons containing NOS in this model of AD, and hypothesize that this finding may be relevant to the mechanism of beta-amyloid neurotoxicity in human AD.     

Cerebrospinal fluid amyloid β40 is decreased in cerebral amyloid angiopathy

Cerebral amyloid angiopathy is caused by deposition of the amyloid β protein in the cerebral vasculature. In analogy to previous observations in Alzheimer disease, we hypothesized that analysis of amyloid β₄₀ and β₄₂ proteins in the cerebrospinal fluid might serve as a molecular biomarker. We observed strongly decreased cerebrospinal fluid amyloid β₄₀ (p < 0.01 vs controls or Alzheimer disease) and amyloid β₄₂ concentrations (p < 0.001 vs controls and p < 0.05 vs Alzheimer disease) in cerebral amyloid angiopathy patients. The combination of amyloid β₄₂ and total tau discriminated cerebral amyloid angiopathy from controls, with an area under the receiver operator curve of 0.98. Our data are consistent with neuropathological evidence that amyloid β₄₀ as well as amyloid β₄₂ protein are selectively trapped in the cerebral vasculature from interstitial fluid drainage pathways that otherwise transport amyloid β proteins toward the cerebrospinal fluid. Ann Neurol 2009;66:245–249