Your search keyword '"Simon-Vermot, Lee"' showing total 2 results

1. Correspondence Between Resting-State and Episodic Memory-Task Related Networks in Elderly Subjects

Author

Simon-Vermot, Lee, Taylor, Alexander N W, Ewers, Michael, Araque Caballero, Miguel À, Franzmeier, Nicolai, Bürger, Katharina, Catak, Cihan, Janowitz, Daniel, Kambeitz-Ilankovic, Lana M, Ertl-Wagner, Birgit, and Duering, Marco

Subjects

connectivity, brain activation, network, ddc:610, episodic memory, resting-state fMRI, Neuroscience, Original Research

Abstract

Resting-state fMRI studies demonstrated temporally synchronous fluctuations in brain activity among ensembles of brain regions, suggesting the existence of intrinsic functional networks. A spatial match between some of the resting-state networks and regional brain activation during cognitive tasks has been noted, suggesting that resting-state networks support particular cognitive abilities. However, the spatial match and predictive value of any resting-state network and regional brain activation during episodic memory is only poorly understood. In order to address this research gap, we obtained fMRI acquired both during rest and a face-name association task in 38 healthy elderly subjects. In separate independent component analyses, networks of correlated brain activity during rest or the episodic memory task were identified. For the independent components identified for task-based fMRI, the design matrix of successful encoding or retrieval trials was regressed against the time course of each of the component to identify significantly activated networks. Spatial regression was used to assess the match of resting-state networks against those related to successful memory encoding or retrieval. We found that resting-state networks covering the medial temporal, middle temporal, and frontal areas showed increased activity during successful encoding. Resting-state networks located within posterior brain regions showed increased activity during successful recognition. However, the level of resting-state network connectivity was not predictive of the task-related activity in these networks. These results suggest that a circumscribed number of functional networks detectable during rest become engaged during successful episodic memory. However, higher intrinsic connectivity at rest may not translate into higher network expression during episodic memory.

Published

2018

2. Resting-State Connectivity of the Left Frontal Cortex to the Default Mode and Dorsal Attention Network Supports Reserve in Mild Cognitive Impairment.

Author

Franzmeier, Nicolai, Gõttler, Jens, Grimmer, Timo, Drzezga, Alexander, Áraque-Caballero, Miguel A., Simon-Vermot, Lee, Taylor, Alexander N. W., Burger, Katharina, Catak, Cihan, Janowitz, Daniel, Muller, Claudia, Duering, Marco, Sorg, Christian, and Ewers, Michael

Subjects

MILD cognitive impairment, ALZHEIMER'S disease diagnosis, PREFRONTAL cortex, NEUROLOGICAL disorders, CINGULATE cortex, DIAGNOSIS

Abstract

Reserve refers to the phenomenon of relatively preserved cognition in disproportion to the extent of neuropathology, e.g., in Alzheimer's disease. A putative functional neural substrate underlying reserve is global functional connectivity of the left lateral frontal cortex (LFC, Brodmann Area 6/44). Resting-state fMRI-assessed global LFC- connectivity is associated with protective factors (education) and better maintenance of memory in mild cognitive impairment (MCI). Since the LFC is a hub of the fronto- parietal control network that regulates the activity of other networks, the question arises whether LFC-connectivity to specific networks rather than the whole-brain may underlie reserve. We assessed resting-state fMRI in 24 MCI and 16 healthy controls (HC) and in an independent validation sample (23 MCI/32 HC). Seed-based LFC-connectivity to seven major resting-state networks (i.e., fronto-parietal, limbic, dorsal-attention, somatomotor, default-mode, ventral-attention, visual) was computed, reserve was quantified as residualized memory performance after accounting for age and hippocampal atrophy. In both samples of MCI, LFC-activity was anti-correlated with the default-mode network (DMN), but positively correlated with the dorsal-attention network (DAN). Greater education predicted stronger LFC-DMN-connectivity (anti-correlation) and LFC-DAN-connectivity. Stronger LFC-DMN and LFC-DAN-connectivity each predicted higher reserve, consistently in both MCI samples. No associations were detected for LFC-connectivity to other networks. These novel results extend our previous findings on global functional connectivity of the LFC, showing that LFC- connectivity specifically to the DAN and DMN, two core memory networks, enhances reserve in the memory domain in MCI. [ABSTRACT FROM AUTHOR]

Published

2017