of work: As part of our program of research on early markers of Alzheimers disease, we are performing serial magnetic resonance imaging (MRI), including measures of vascular changes, positron emission tomography (PET), and neuropsychological assessments in participants from the Baltimore Longitudinal Study of Aging (BLSA) to investigate the neurobiological basis of memory change and cognitive impairment. These evaluations allow us to examine changes in brain structure and function which may be early preclinical predictors of cognitive change and impairment, including Alzheimer's disease (AD). We continue longitudinal testing of older participants and evaluation of new participants, including MRI and neuropsychological assessments of participants younger than 55 years old. For a subsample aged 55 and older, we perform PET measurements of cerebral blood flow, followed by a PET scan using 11-C-Pittsburgh Compound B (PiB) to measure in vivo amyloid deposition. Over the last year we initiated Tau PET (AV-1451) studies of BLSA participants receiving PET amyloid scans. Our progress includes continued acquisition of new neuroimaging assessments and continued analysis of existing data and methods development. We use neuroimaging tools to investigate modulators of cognitive and brain changes, including sex differences in cognitive and brain aging, genetic, metabolic, and inflammatory risk factors, and the effects of sex steroid and other hormones. An understanding of these brain-behavior associations and early detection of accelerated brain changes during the preclinical or asymptomatic stage of disease will be critical in identifying individuals likely to benefit from interventions if a successful treatment for prevention or delaying onset of disease is available. We have published a number of papers describing results from the BLSA neuroimaging study: Longitudinal Change in ABeta and Relation with APOE Genotype. In our PET-PiB amyloid imaging investigations, we continue to highlight the importance of individuals with intermediate amyloid levels that would be considered PiB negative in many binary classification schemes. In our initial longitudinal studies, we pointed out that rates of longitudinal change in PET-PiB retention were a function of baseline levels. We noted that once an individual reached a study-defined threshold, that individual was likely to show longitudinal increases over time. Individuals at intermediate levels, i.e., just above our study-defined threshold, were those in the earliest stages of the development of ABeta neuropathology, a time when a future treatment might be most effective. As our sample sizes and follow-up have increased, it is clear that some individuals maintain no or negligible amyloid burden with advancing age while others cross a threshold and demonstrate steady increases in ABeta over time. In a recent publication, we characterized the spatial progression of PiB retention over time (Bilgel et al 2016). In an important advance (Bilgel et al, 2016), we developed an approach for using longitudinal PET-PiB data to estimate the age at onset of amyloid accumulation on an individual basis, providing an index for each individual that can be used as a dependent outcome to assess factors that may modify age at onset of amyloid accumulation. We applied this approach to demonstrate that APOE e4 positive individuals were 3 times more likely to reach the PiB change point, and on average e4+ individuals began accumulating ABeta 13.3 years earlier than e4- individuals. We believe this approach will be extremely useful in gauging the efficacy of future treatment interventions to delay amyloid accumulation in high-risk samples. Sphingolipids and White Matter Integrity. We have continued our collaboration with Dr. Michelle Mielke to characterize factors related to age-associated changes in sphingolipids, including specific ceramide and sphingomyelin chain lengths. More recently, we used diffusion tensor imaging (DTI) to demonstrate that peripheral sphingolipids are associated with variation in white matter (WM) microstructure in older adults (Gonzalez et al., 2016). We found that elevations in some ceramide species (C20:0, C22:0, C22:1, and C24:1) were associated with lower fractional isotropy (FA) in multiple WM regions, including total cerebral WM, anterior corona radiata, and the cingulum of the cingulate gyrus. Higher sphingomyelins (C18:1 and C20:1) were associated with lower FA in regions such as the anterior corona radiata and body of the corpus callosum. These findings suggest that plasma sphingolipids are associated with variation in white matter microstructure in older adults. Sleep Duration and Cortical Thinning. We continued collaborative studies with Dr. Adam Spira on the relation between sleep patterns and brain aging. In a recent report (Spira et al., 2016), we examined self-reported sleep duration in relation to rates of cortical thinning in 122 BLSA participants, using data with a mean of 7.6 1.5-T MRI scans and mean follow-up from initial scan of 8.0 y. We observed nonlinear associations between sleep duration and cortical thinning in some regions. Among cognitively normal older adults, sleep durations of < 7 h and > 7 h were associated with increases in rates of subsequent frontotemporal gray matter atrophy. These studies will be expanded, using objective sleep measures to investigate mechanisms linking sleep duration to gray matter loss. Motor Function and Brain Integrity. With Drs. Stephanie Studenski, Luigi Ferrucci and Teresa Tian, we examined the relation between variation in motor function and changes in white matter and gray matter integrity, measured by DTI. We found that higher levels of average MD, associated with reduced gray matter integrity, were significantly associated with higher lap time variability, based on individual trajectories over ten 40-m laps (Tian et al, 2016). These findings suggest that lower gray matter integrity in some brain areas may underlie greater lap time variability in nondemented older adults. In a second study (Tian et al 2016), we examined the effect of age on the associations of regional microstructural white matter integrity with walking variability and speed, independent of macrostructural white matter lesion volume. While macrostructural white matter lesion burden predicts more variable and slower walking in older adults, we found that microstructural white matter disruption was independently associated with more variable and slower fast-paced walking only in the young-old. Thus, disruptions in white matter integrity may contribute to abnormal gait early in the aging process. Methodological Developments. We have continued to optimize our approach for MRI volumetric analysis. In a major methodological advance, we collaborated with Christos Davatzikos on the development of the MUSE, MUlti-atlas region Segmentation utilizing Ensembles of registration algorithms and parameters, pipeline for volumetric MRI analysis. We validated this approach and applied it to cross-sectional data across a studies, including BLSA (Doshi et al, 2016). We demonstrated aging trajectories from infancy to late adulthood in a number of regional volumes. In addition, we applied the approach to longitudinal SPGR MRI data showing longitudinal trajectories of brain aging. In the next phase, we are validating this approach for application to longitudinal MRI data acquired on different scanners with different pulse sequences.

Agency
National Institute of Health (NIH)
Institute
National Institute on Aging (NIA)
Type
Investigator-Initiated Intramural Research Projects (ZIA)
Project #
1ZIAAG000191-20
Application #
9351925
Study Section
Project Start
Project End
Budget Start
Budget End
Support Year
20
Fiscal Year
2016
Total Cost
Indirect Cost
Name
Aging
Department
Type
DUNS #
City
State
Country
Zip Code
Bilgel, Murat; An, Yang; Helphrey, Jessica et al. (2018) Effects of amyloid pathology and neurodegeneration on cognitive change in cognitively normal adults. Brain :
Knopman, David S; Haeberlein, Samantha Budd; Carrillo, Maria C et al. (2018) The National Institute on Aging and the Alzheimer's Association Research Framework for Alzheimer's disease: Perspectives from the Research Roundtable. Alzheimers Dement 14:563-575
Warren, Kristen N; Beason-Held, Lori L; Carlson, Olga et al. (2018) Elevated Markers of Inflammation Are Associated With Longitudinal Changes in Brain Function in Older Adults. J Gerontol A Biol Sci Med Sci 73:770-778
Eavani, Harini; Habes, Mohamad; Satterthwaite, Theodore D et al. (2018) Heterogeneity of structural and functional imaging patterns of advanced brain aging revealed via machine learning methods. Neurobiol Aging 71:41-50
Habes, Mohamad; Sotiras, Aristeidis; Erus, Guray et al. (2018) White matter lesions: Spatial heterogeneity, links to risk factors, cognition, genetics, and atrophy. Neurology 91:e964-e975
Wong, Dean F; Comley, Robert A; Kuwabara, Hiroto et al. (2018) Characterization of 3 Novel Tau Radiopharmaceuticals, 11C-RO-963, 11C-RO-643, and 18F-RO-948, in Healthy Controls and in Alzheimer Subjects. J Nucl Med 59:1869-1876
Bermudez, Camilo; Plassard, Andrew J; Davis, Taylor L et al. (2018) Learning Implicit Brain MRI Manifolds with Deep Learning. Proc SPIE Int Soc Opt Eng 10574:
Kamil, Rebecca J; Jacob, Athira; Ratnanather, John Tilak et al. (2018) Vestibular Function and Hippocampal Volume in the Baltimore Longitudinal Study of Aging (BLSA). Otol Neurotol 39:765-771
Gomez, Gabriela; Beason-Held, Lori L; Bilgel, Murat et al. (2018) Metabolic Syndrome and Amyloid Accumulation in the Aging Brain. J Alzheimers Dis 65:629-639
Tian, Qu; Bair, Woei-Nan; Resnick, Susan M et al. (2018) ?-amyloid deposition is associated with gait variability in usual aging. Gait Posture 61:346-352

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