Amyloid-first and Neurodegeneration-first Profiles Characterize Incident Amyloid PET Positivity

Overview

Journal Neurology

Specialty Neurology

Date 2013 Oct 18

PMID 24132377

Citations 114

Authors

Clifford R Jack Jr

Heather J Wiste

Stephen D Weigand

David S Knopman

Val Lowe

Prashanthi Vemuri

Michelle M Mielke

David T Jones

Matthew L Senjem

Jeffrey L Gunter

Brian E Gregg

Vernon S Pankratz

Ronald C Petersen

Affiliations

Soon will be listed here.

Abstract

Objective: To estimate the incidence of and to characterize cognitive and imaging findings associated with incident amyloid PET positivity.

Methods: Cognitively normal (CN) participants in the Mayo Clinic Study of Aging who had 2 or more serial imaging assessments, which included amyloid PET, FDG-PET, and MRI at each time point, were eligible for analysis (n = 207). Twelve subjects with Alzheimer disease dementia were included for comparison.

Results: Of the 123 CN participants who were amyloid-negative at baseline, 26 met criteria for incident amyloid PET positivity. Compared to the 69 subjects who remained stable amyloid-negative, on average these 26 did not differ on any imaging, demographic, or cognitive variables except amyloid PET (by definition) and task-free functional connectivity, which at baseline was greater in the incident amyloid-positive group. Eleven of the 26 incident amyloid-positive subjects had abnormal hippocampal volume, FDG-PET, or both at baseline.

Conclusions: The incidence of amyloid PET positivity is approximately 13% per year among CN participants over age 70 sampled from a population-based cohort. In 15/26 (58%), incident amyloid positivity occurred prior to abnormalities in FDG-PET and hippocampal volume. However, 11/26 (42%) incident amyloid-positive subjects had evidence of neurodegeneration prior to incident amyloid positivity. These 11 could be subjects with combinations of preexisting non-Alzheimer pathophysiologies and tau-mediated neurodegeneration who newly entered the amyloid pathway. Our findings suggest that both "amyloid-first" and "neurodegeneration-first" biomarker profile pathways to preclinical AD exist.

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