Your search keyword '"Mizuno, Akiko"' showing total 3 results

1. Functional Asymmetry During Working Memory and Its Association with Markers of Alzheimer's Disease in Cognitively Normal Older Adults.

Author

Li, Jinghang, Mountz, Elizabeth J., Mizuno, Akiko, Shah, Ashti M., Weinstein, Andrea, Cohen, Ann D., Klunk, William E., Snitz, Beth E., Aizenstein, Howard J., and Karim, Helmet T.

Subjects

ALZHEIMER'S disease, OLDER people, SHORT-term memory, FUNCTIONAL magnetic resonance imaging, COGNITIVE testing

Abstract

Background: Amyloid-β (Aβ) deposits asymmetrically early in Alzheimer's disease (AD). This process is variable and has been associated with asymmetric hypometabolism. Objective: We investigated whether neural asymmetry during working memory and executive function processing was associated with AD genetic risk and markers of AD as well as other brain neuropathology biomarkers, cognitive function, and cognitive reserve in cognitively normal older adults. Methods: We analyzed data from 77 cognitively healthy, older adults who completed functional magnetic resonance imaging, positron emission tomography, and cognitive testing. We identified regions of significant activation and asymmetry during the Digital Symbol Substitution Task (DSST). We examined associations between regions with significant hemispheric asymmetry (directional and absolute) and global cerebral Aβ, cerebral glucose metabolism, white matter hyperintensities, APOE ɛ4 allele status, DSST reaction time, age, sex, education, and cognitive function. Results: Asymmetry was not associated with several factors including cognitive function, Aβ, and white matter hyperintensities. The presence of at least one ɛ4 APOE allele in participants was associated with less asymmetric activation in the angular gyrus (right dominant activation). Greater education was associated with less asymmetric activation in mediodorsal thalamus (left dominant activation). Conclusions: Genetic risk of AD was associated with lower asymmetry in angular gyrus activation, while greater education was associated with lower asymmetry in mediodorsal thalamus activation. Changes in asymmetry may reflect components of compensation or cognitive reserve. Asymmetric neural recruitment during working memory may be related to maintenance of cognitive function in cognitively normal older adults. [ABSTRACT FROM AUTHOR]

Published

2023

2. An Effect of Education on Memory-Encoding Activation in Subjective Cognitive Decline.

Author

Mizuno, Akiko, Karim, Helmet T., Ly, Maria J., Cohen, Ann D., Lopresti, Brian J., Mathis, Chester A., Klunk, William E., Aizenstein, Howard J., and Snitz, Beth E.

Subjects

*MIND-wandering, *SYMPTOMS, *ALZHEIMER'S disease

Abstract

Background: Subjective cognitive decline (SCD) may be an early manifestation of pre-clinical Alzheimer's disease. Elevated amyloid-β (Aβ) is a correlate of SCD symptoms in some individuals. The underlying neural correlates of SCD symptoms and their association with Aβ is unknown. SCD is a heterogeneous condition, and cognitive reserve may explain individual differences in its neural correlates.Objective: We investigated the association between brain activation during memory encoding and SCD symptoms, as well as with Aβ, among older individuals. We also tested the moderating role of education (an index of cognitive reserve) on the associations.Methods: We measured brain activation during the "face-name" memory-encoding fMRI task and Aβ deposition with Pittsburgh Compound-B (PiB)-PET among cognitively normal older individuals (n = 63, mean age 73.1 ± 7.4 years). We tested associations between activation and SCD symptoms by self-report measures, Aβ, and interactions with education.Results: Activation was not directly associated with SCD symptoms or Aβ. However, education moderated the association between activation and SCD symptoms in the executive control network, salience network, and subcortical regions. Greater SCD symptoms were associated with greater activation in those with higher education, but with lower activation in those with lower education.Conclusion: SCD symptoms were associated with different patterns of brain activation in the extended memory system depending on level of cognitive reserve. Greater SCD symptoms may represent a saturation of neural compensation in individuals with greater cognitive reserve, while it may reflect diminishing neural resources in individuals with lower cognitive reserve. [ABSTRACT FROM AUTHOR]

Published

2021

3. Improving brain age prediction models: incorporation of amyloid status in Alzheimer's disease.

Author

Ly, Maria, Yu, Gary Z., Karim, Helmet T., Muppidi, Nishita R., Mizuno, Akiko, Klunk, William E., and Aizenstein, Howard J.

Subjects

*ALZHEIMER'S disease, *PREDICTION models, *AGE, *AGE differences, *COGNITIVE training

Abstract

Brain age prediction is a machine learning method that estimates an individual's chronological age from their neuroimaging scans. Brain age indicates whether an individual's brain appears "older" than age-matched healthy peers, suggesting that they may have experienced a higher cumulative exposure to brain insults or were more impacted by those pathological insults. However, contemporary brain age models include older participants with amyloid pathology in their training sets and thus may be confounded when studying Alzheimer's disease (AD). We showed that amyloid status is a critical feature for brain age prediction models. We trained a model on T1-weighted MRI images participants without amyloid pathology. MRI data were processed to estimate gray matter density voxel-wise, which were then used to predict chronological age. Our model performed accurately comparable to previous models. Notably, we demonstrated more significant differences between AD diagnostic groups than other models. In addition, our model was able to delineate significant differences in brain age relative to chronological age between cognitively normal individuals with and without amyloid. Incorporation of amyloid status in brain age prediction models ultimately improves the utility of brain age as a biomarker for AD. • Brain age may serve as a promising, individualized biomarker of brain health. • Current brain age models may be confounded by amyloid pathology in training sets. • We have shown that amyloid status is a critical feature for brain age models. • Our model accurately predicted brain age in the training and independent test sets. • We demonstrated significant differences in brain age between AD diagnostic groups. [ABSTRACT FROM AUTHOR]

Published

2020