The Effects of Age, Memory Performance, and Callosal Integrity on the Neural Correlates of Successful Associative Encoding

Chastelaine, Marianne de; Wang, Tracy H.; Minton, Brian; Muftuler, L. Tugan; Rugg, Michael D.

doi:10.1093/cercor/bhq294

Cited by 124 publications

(179 citation statements)

References 40 publications

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“…In addition, more activation in old adults can sometimes be associated with poorer, not better, performance 54 . Recent studies have reported greater activity in the PFC during memory encoding 55 or retrieval 56 in older adults, both of which were correlated with poorer memory. Similarly, higher activity in a distributed set of regions, including PFC and parietal cortex, in old adults compared to young adults 57,58 was found to be correlated with slower and more variable reaction times on a set of visual tasks.…”

Section: Compensation In the Older Brainmentioning

confidence: 97%

“…In some cases, over-recruitment of brain areas may reflect a greater demand on neural resources or less efficient use of them, and may or may not be related specifically to individual differences in behavior. One explanation for this is the 'partial compensation hypothesis' 55 , whereby over-recruitment of the right PFC during memory encoding may aid old adults in carrying out the encoding task because of less effective use of the left PFC, which would normally carry out this task 21,59,60 . However, this additional right PFC activity during encoding cannot compensate for a reduction in encoding effectiveness of the left PFC, and so does not provide a benefit for subsequent memory of the encoded items.…”

Section: Compensation In the Older Brainmentioning

confidence: 99%

“…A longitudinal study 135 showed that both hippocampal volume and integrity of white matter in the corpus callosum were reduced in older adults and correlated with declining memory performance. Some studies 49,55 have found that age differences in activation within PFC were mediated by white matter integrity, such that more intact white matter was related to more activation, but others have failed to find this effect 94,136 . Despite this inconsistency in results, the use of DTI to assess white matter integrity holds considerable promise for the study of cognitive aging, particularly as the integrity of specific tracts has been shown to be related to speed of performance in older adults 137 or to accuracy of performance [138][139][140] .…”

Section: Brain Structurementioning

confidence: 99%

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The cognitive neuroscience of ageing

2012

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PrefaceThe availability of neuroimaging technology has spurred a marked increase in the human cognitive neuroscience literature, including the study of cognitive aging. Although there is a growing consensus that the aging brain retains considerable plasticity of function, currently measured primarily by means of functional magnetic resonance imaging, it is less clear how age differences in brain activity relate to cognitive performance. The field also is hampered by the complexity of the aging process itself and the large number of factors that are influenced by age. In this review, current trends and unresolved issues in the cognitive neuroscience of aging are discussed.

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Section: Compensation In the Older Brainmentioning

confidence: 97%

Section: Compensation In the Older Brainmentioning

confidence: 99%

Section: Brain Structurementioning

confidence: 99%

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The cognitive neuroscience of ageing

2012

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“…For example, a number of experiments have focused on brain activity during encoding of items that are remembered successfully, the so-called subsequent memory effect, and shown differences between younger and older adults indicating that successful encoding is supported by somewhat different brain areas (Cansino et al, 2010;de Chastelaine et al, 2011;Dennis et al, 2007;Duverne et al, 2009;Gutchess et al, 2005;Morcom et al, 2003). Similarly, a number of studies examining brain activity for successful recognition have reported differences between young and older adults in both frontal and parietal cortex (e.g., Daselaar et al, 2006;Duarte et al, 2008;Giovanello and Schacter, 2012;Kalpouzos et al, 2012;Morcom et al, 2007;Rajah et al, 2010;Spaniol and Grady, 2012).…”

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confidence: 99%

Age differences in brain activity related to unsuccessful declarative memory retrieval

2015

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Although memory recall is known to be reduced with normal aging, little is known about the patterns of brain activity that accompany these recall failures. By assessing faulty memory, we can identify the brain regions engaged during retrieval attempts in the absence of successful memory and determine the impact of aging on this functional activity. We used functional magnetic resonance imaging to examine age differences in brain activity associated with memory failure in three memory retrieval tasks: autobiographical (AM), episodic (EM) and semantic (SM). Compared to successful memory retrieval, both age groups showed more activity when they failed to recall a memory in regions consistent with the salience network (SLN), a brain network also associated with non-memory errors. Both groups also showed strong functional coupling among SLN regions during incorrect trials and in intrinsic patterns of functional connectivity. In comparison to young adults, older adults demonstrated (1) less activity within the SLN during unsuccessful AM trials; (2) weaker intrinsic functional connectivity between SLN nodes and dorsolateral prefrontal cortex; and (3) less differentiation of SLN functional connectivity during incorrect trials across memory conditions. These results suggest that the SLN is engaged during recall failures, as it is for non-memory errors, which may be because errors in general have particular salience for adapting behavior. In older adults, the dedifferentiation of functional connectivity within the SLN across memory conditions and the reduction of functional coupling between it and prefrontal cortex may indicate poorer internetwork communication and less flexible use of cognitive control processes, either while retrieval is attempted or when monitoring takes place after retrieval has failed. Keywords fMRI; aging; episodic memory; salience network; frontal lobe IntroductionA number of studies have provided extensive evidence of the neural circuitry that supports memory retrieval (e.g., Cabeza and Nyberg, 2000;Spaniol et al., 2009 CIHR Author Manuscript CIHR Author Manuscript CIHR Author Manuscript2008), as well as evidence of how aging influences this circuitry (e.g., Cabeza et al., 2005;Grady, 2012;Rajah and D'Esposito, 2005). However, most research has investigated how the brain supports successful memory performance (Addis and McAndrews, 2006;Brewer et al., 1998;Morcom et al., 2003;Wagner et al., 1998), and limited attention has been paid to brain networks involved in faulty memory retrieval, most notably faulty long-term memory recall. A number of processes may be engaged during recall, including goal setting, memory search, accessing (hopefully correct) stored memories, and evaluating retrieval success (Henson et al., 1999;Moscovitch, 1992;Rugg et al., 2002). The assessment of faulty memory retrieval can be used to identify brain regions whose activity reflects processes engaged when retrieval fails. Such processes can include cognitive control processes involved regardless of retrieval succes...

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“…A dominant observation of age-related over-recruitment is the bilateral activation of homologous prefrontal regions in older adults on tasks where their younger counterparts show unilateral activation pattern. Specifically, whereas young adults typically engage left lateralized frontal activity for tasks that involve verbal working memory, semantic processing, and recognition memory, older adults tend to show preserved left frontal activity with additional contralateral recruitment in the homologous site of the right hemisphere that is not observed in young adults ( Figure 4; Cabeza et al, 1997;de Chastelaine et al, 2011;Daselaar et al, 2003;Duverne et al, 2009;Leshikar et al, 2010;Madden et al, 1999;Reuter-Lorenz et al, 2000;Schneider-Garces et al, 2010). Similarly, older adults engage both right and left prefrontal activity during tasks in which younger adults engage only right lateralized prefrontal activity, such as in tasks associated with face processing, spatial working memory, non-verbal spatial judgment, and episodic recall (Cabeza et al, 1997;Grady et al, 1995;Reuter-Lorenz et al, 2000).…”

Section: Increased Neural Effort Involved In Cognitive Processingmentioning

confidence: 99%