Biomarkers.

Background: The association between [F]Flortaucipir (FTP) and [F]MK6240, two commonly used tau-PET tracers in Alzheimer's disease (AD), varies due to distinct binding properties and off-target signal regions. Our study aims to elucidate the biological factors influencing this association and evaluate the applicability of a common equation across different on-target regions.

Method: 113 individuals from the HEAD dataset (11 young, 58 cognitively unimpaired elderly, and 44 cognitively impaired) underwent [F]MK6240, [F]FTP and Aβ-PET scans.

Biomarkers.

Background: Tau-PET tracers allow for in vivo Braak staging of individuals in the Alzheimer's disease (AD) continuum. The impact of tracers' characteristics for Braak staging using tau-PET remains unclear. Therefore, we performed a head-to-head comparison of Braak staging using first- and second-generation tau-PET tracers.

Biomarkers.

Background: The Knight Alzheimer Research Imaging (KARI) dataset, a compilation of data from projects conducted at Washington University in St. Louis, represents a comprehensive effort to advance our understanding of Alzheimer disease (AD) through multimodal data collection. The overarching goal is to characterize normal aging and disease progression to contribute insights into the biological changes preceding AD symptom onset.

Biomarkers.

Background: There is a strong link between tau and progression of Alzheimer's disease (AD), necessitating an understanding of tau spreading mechanisms. Prior research, predominantly in typical AD, suggested that tau propagates from epicenters (regions with earliest tau) to functionally connected regions. However, given the constrained spatial heterogeneity of tau in typical AD, validating this connectivity-based tau spreading model in AD variants with distinct tau deposition patterns is crucial.

Biomarkers.

Background: Autosomal dominant Alzheimer disease (ADAD) is characterized by genetic mutations affecting the beta-amyloid (Aβ) pathway. However, vascular and immune factors play important roles which are not completely understood. Understanding the function of the neurovascular unit (NVU) comprised of neurons, glial cells, and vasculature, at different disease stages appears ideal to developing and evaluating therapeutics.