View clinical trials related to Plaque, Amyloid.
Filter by:This is a randomized, double-blind, placebo-controlled, parallel group study. The use of placebo is appropriate to minimize bias related to treatment expectations of the subject, study partner, and site investigator, as well as to changes in the relationship between the subject and study partner that might occur with the initiation of treatment and expectation of improvement in motor symptoms or cognition. Changes in subject/study partner interactions can impact subject mood and might introduce biases that cannot be quantified. The double-blind use of placebo will also prevent bias in the clinical and scientific assessments.
The purpose of this study is to assess the safety, tolerability, immunogenicity and pharmacodynamic effects of ACI-24.060 in subjects with prodromal Alzheimer's disease and in non-demented adults with Down syndrome.
This study is based on the hypothesis that MRI could make it possible to non-invasively detect these amyloid deposits at the level of the wrist using parametric sequences known as T1 mapping, in the form of an extension of T1 in the wrists. areas where amyloid deposits are found in the wrist.
According to the most popular pathophysiological models of Alzheimer's disease, the amyloid hypothesis, amyloid deposition is the causative event triggering a chain of other downstream events which finally lead to Alzheimer's disease and dementia. In mouse models of Alzheimer's disease, 40 Hz multi-sensory (auditory and visual) stimulation was able to reduce the number and size of amyloid plaques throughout cortex and improve cognitive performance. The primary objective of this study is to assess whether an intervention consisting of 40 Hz multi-sensory (auditory and visual) stimulation is able to reduce the amyloid load in non-demented amyloid-positive individuals. As secondary objectives, the investigators will assess whether such intervention is able to: - improve the brain electrical activity, - improve or slow down the worsening of Alzheimer's blood-based biomarkers, - improve or slow down the worsening of cognition.
Stroke can lead to signficiant neurological deficits, and about one-third of stroke patients will be diagnosed of vascular mild cognitive impairment or post-stroke dementia. Post-stroke dementia includes all types of dementia that happen after stroke, irrespective of their cause, and vascular dementia (VaD), degenerative dementia (especially Alzheimer's disease), or mixed dementia (dementia as a result of the coexistence of vascular lesions of the brain and neurodegenerative lesions) are the most common causes of post-stroke dementia. However, it is difficult to determine to what extent cognitive impairment may be attributable to stroke versus concomitant Alzheimer disease. With the advent of PET imaging technique, we are able to conduct a multi-modal neuroimaging study to explore the composite influence of vascular injury, amyloid plaque and Tau protein the the cognitive performance after stroke.
Amyloid plaques and tau protein are the landmarks of neurodegeneration in Alzheimer's disease (AD). On the other hand, it is reported that cerebral ischemia may induce amyloid plaques and tau protein accumulation. However, it was difficult to in vivo disentangle the complex and dynamic interactions between AD pathophysiology and cerebral vascular injury in the development of post-stroke cognitive impairment in the past. With the advent of novel radiotracers specific to cerebral amyloid plaques and tau protein, we aim to conduct a prospective multimodal neuroimaging cohort study to investigate the contribution of vascular injury, amyloid plaques and tau protein to stroke recovery and post-stroke cognitive impairment.
Background and objects Amyloid plaques and tau protein are the landmarks of neurodegeneration in Alzheimer's disease (AD). On the other hand, it is reported that cerebral ischemia may induce amyloid plaques and tau protein accumulation. However, it was difficult to in vivo disentangle the complex and dynamic interactions between AD pathophysiology and cerebral vascular injury during the post-stroke cognitive impairment development in the past. With the advent of novel radiotracers specific to cerebral amyloid plaques and tau protein, we aim to conduct a prospective multimodal neuroimaging cohort study to investigate the contribution of vascular injury, amyloid plaque and tau protein to cognitive impairment. Subjects and methods The prospective project plans to recruit patients with vascular cognitive impairment (VCI) (Group A, n=80), Alzheimer's disease/mild cognitive impairment (MCI) (Group B, n = 120), fronto-temporal dementia (FTD) (Group C, n =30), and progressive supranuclear palsy (PSP) (Group E, n = 80). In addition, another 30 healthy people will be recruited as the control group (Group D, n=30). [18F]AV45 and [18F]MNI-958(PMPBB3) PET will be done for imaging cerebral amyloid plaque and tau protein distribution, brain MRI for obtaining structural and functional information, and neuropsychological tests for cognitive performance. Cognitive evaluation will be repeated 18 months after recruitment. In addition, APOE genotyping will be performed as well. By obtaining the neuroimaging information, such as severity of white matter change and infarction, cortical and hippocampal atrophy, and SUVRs of [18F]AV-45 and [18F]MNI-958(PMPBB3) PET, the study will be able to investigate the composite influence of cerebrovascular disease and neurodegenerative pathology on the trajectory of cognitive impairment. Group comparisons will be performed using the Chi-square test, independent t test, Mann-Whitney U test, ANOVA test, and multiple linear regression, where appropriate. Anticipation In this project, we will be able to explore the distribution patterns of amyloid plaque and tau protein among dementia patients with different etiologies, and also evaluate their influence on cognition
Accumulating evidence indicates that inflammation is prominent both in the blood and central nervous system (CNS) of Alzheimer's disease (AD) patients. These data suggest that systemic inflammation plays a crucial role in the cause and effects of AD neuropathology. Capitalizing on the experience from a previous clinical trial with thalidomide, here, the investigators hypothesize that modulating both systemic and CNS inflammation via the pleiotropic immunomodulator lenalidomide is a putative therapeutic intervention for AD if administered at a proper time window during the course of the disease.
Although being classified as a rare disease, cardiac amyloidosis constitutes an increasing cause of heart failure, which is often overlooked and thus poorly managed. Amyloidosis involves deposits of light chain immunoglobulins in the immunoglobulin light chain amyloidosis (AL) type, but it may also be of a hereditary type in mutated transthyretin amyloidosis (ATTRm) or of a senile type in wildtype transthyretin forms (ATTRwt). Myocardial biopsy remains a gold standard for definitive diagnosis but it is a traumatic technique which only provides information on a limited number of sampled sites. Useful but not fully specific signs of cardiac amyloidosis may also be provided by Magnetic Resonance Imaging or MRI (delayed retention imaging) and echocardiography (longitudinal strain pattern). Notwithstanding the above, relatively specific markers of amyloid plaques are now available in Positron Emission Tomography (PET). These markers are primarily fluorinated tracers which have been developed for the diagnosis of Alzheimer's disease. Two of these have already been the subject of feasibility studies in the setting of cardiac amyloidosis diagnosis, on a maximum of 10 amyloidosis patients but with very favorable results. The hypothesis is that one of these two tracers, Florbetaben labelled with Fluorine-18-Florbetaben (18F-Florbetaben) used in the study, has sufficiently strong and prolonged binding kinetics at the level of the amyloid plaques to allow: (i) achieving whole-body PET recordings and thus, (ii) identifying not only cardiac amyloidosis but also extracardiac binding sites, particularly those readily accessible to biopsy sampling. This hypothesis has been strengthened by a recent case report illustrating the ability of whole-body florbetaben-PET to image not only cardiac but also extra-cardiac sites of amyloid deposits (Clin Nucl Med. 2017;42(1):50-3).
The purpose of this study is based on the Flutemetamol-PET senile plaque imaging to investigate the peripheral blood biochemical and brain MRI imaging biomarkers and to research completely independent intellectual property rights neuropsychological test tool for the MCI due to AD. At the same time, the investigators will study the efficacy and safety of early treatment of MCI due to AD by Huperzine A in 52 weeks.