Regional Cortical Thickness Predicts Top Cognitive Performance in the Elderly

Dominguez, Elena; Stark, Shauna M.; Ren, Yueqi; Corrada, María M.; Kawas, Claudia H.; Stark, Craig E.L.

doi:10.3389/fnagi.2021.751375

Cited by 9 publications

(17 citation statements)

References 33 publications

(29 reference statements)

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“…The brain is known to undergo significant changes during the lifespan. Studies of brain volume, white and gray matter tissue volume (Fan et al, 2019; Fjell and Walhovd, 2010; Hedman et al, 2012; Lebel et al, 2012; Pfefferbaum et al, 1992; Scahill et al, 2003; Steffener, 2021), cortical thickness (Dominguez et al, 2021; Frangou et al, 2022; Habeck et al, 2020; Hou et al, 2021), microstructure measures (Beck et al, 2021; Fan et al, 2019; Lebel et al, 2012; Storsve et al, 2016), and myelination (Grydeland et al, 2019) have described patterns of neuroanatomical variation that provide insight into the biological sequelae of development and aging. For example, well characterized waves of brain growth occur, with gray matter volume increasing until middle childhood (~ 6 years), followed by volume decreases from young adulthood and into late adulthood, while white matter reaches peak volume in adulthood (20-40 years), again leveling off and decreasing into late adulthood, with both tissues experiencing accelerated atrophy during late adulthood (Bethlehem et al, 2022; Hedman et al, 2012; Lebel et al, 2012; Scahill et al, 2003).…”

Section: Discussionmentioning

confidence: 99%

“…For example, features such as SWM volume or thickness of the SWM sheet below the cortex have not been characterized. Unlike the cortical thickness and cortical volume metrics that have been thoroughly investigated, are easily quantified using standard toolsets (Destrieux et al, 2010; Fischl, 2012), and have proven strong associations with cognition, aging, and disease (Dickie et al, 2020; Dominguez et al, 2021; Fjell and Walhovd, 2010; Frangou et al, 2022; Gao et al, 2018; Habeck et al, 2020; Hou et al, 2021; Mattsson et al, 2018; Meyer et al, 2019; Racine et al, 2018; Roe et al, 2021; Steffener, 2021; Storsve et al, 2016; Tustison et al, 2019; Vogt et al, 2019), SWM thickness and SWM volume have not been investigated or quantified. Towards this end, we study three high-quality datasets that span the human lifespan (ages 5-100, N=2421 subjects), and implement advances and innovations in SWM tractography.…”

Section: Introductionmentioning

confidence: 99%

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Superficial white matter across the lifespan: volume, thickness, change, and relationship with cortical features

Schilling

Archer

Rheault

et al. 2022

Preprint

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Superficial white matter (SWM) represents a significantly understudied part of the human brain, despite comprising a large portion of brain volume and making up a majority of cortical structural connections. Using multiple, high-quality, datasets with large sample sizes (N=2421, age range 5-100) in combination with methodological advances in tractography, we quantified features of SWM volume and thickness across the brain and across the lifespan. We address four questions: (1) How does U-fiber volume change with age? (2) What does U-fiber thickness look like across the brain? (3) How does SWM thickness change with age? (4) Are there relationships between SWM thickness and cortical features? Our main findings are that (1) SWM volume shows unique volumetric trajectories with age that are distinct from gray matter and other white matter trajectories; (2) SWM thickness varies across the brain, with patterns robust across individuals and across the population at the region-level and vertex-level; (3) SWM shows nonlinear changes across the lifespan that vary across regions; and (4) SWM thickness is associated with cortical thickness and curvature. For the first time, we show that SWM volume follows a similar trend as overall white matter volume, peaking at a similar time in adolescence, leveling off throughout adulthood, and decreasing with age thereafter. Notably, the relative fraction of total brain volume of SWM continuously increases with age, and consequently takes up a larger proportion of total white matter volume, unlike the other tissue types that decrease with respect to total brain volume. This study represents the first characterization of SWM features across the lifespan and provides the background for characterizing normal aging and insight into the mechanisms associated with SWM development and decline.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Superficial white matter across the lifespan: volume, thickness, change, and relationship with cortical features

Schilling

Archer

Rheault

et al. 2022

Preprint

View full text Add to dashboard Cite

show abstract

“…More females were included in cognitively high-performing than control cohorts in six of these studies 11,18,19,28,49,53 while education levels were significantly higher in six cognitively high performing cohorts compared with controls. [11][12][13]15,28,49 Rates of hypertension and diabetes were higher in the cognitively average than the super-ageing cohort in one study but not significantly so. 43 [64][65][66] Processing speed has been shown to decline from the third decade of life while memory performance may begin to decline in the 50s and executive function especially after age 70 but more complex reasoning capabilities beginning around age 45.…”

Section: Methodological Quality Of the Included Studiesmentioning

confidence: 99%

“…One study selected performers in the top 20th percentile on a memory composite score 45 and one study those in the 50th percentile for episodic memory and executive function. 28 Most studies relied on cross-sectional assessment of cognition with only nine requiring maintenance of exceptional performance over time and one study further characterising participants by stable, worsened or improved performance at follow up. 14 Baran et al required 'supernormals' to maintain a positive mean slope of executive function and episodic memory performance over a 5-year period.…”

Section: Summary Of Included Studiesmentioning

confidence: 99%

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Defining exceptional cognition in older adults: A systematic review of cognitive super‐ageing

Powell,

Page,

et al. 2023

Int J Geriat Psychiatry

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ObjectiveA consistent approach to defining cognitive super‐ageing is needed to increase the value of research insights that may be gained from studying this population including ageing well and preventing and treating neurodegenerative conditions. This review aims to evaluate the existing definitions of ‘super‐ageing’ with a focus on cognition.MethodsA systematic literature search was conducted across PubMed, Embase, Web of Science, Scopus, PsycINFO and Google Scholar from inception to 24 July 2023.ResultsOf 44 English language studies that defined super‐ageing from a cognitive perspective in older adults (60–97 years), most (n = 33) were based on preserved verbal episodic memory performance comparable to that of younger adult in age range 16–65 years. Eleven studies defined super‐agers as the top cognitive performers for their age group based upon standard deviations or percentiles above the population mean. Only nine studies included longitudinal cognitive performance in their definitions.ConclusionsEquivalent cognitive abilities to younger adults, exceptional cognition for age and a lack of cognitive deterioration over time are all meaningful constructs and may provide different insights into cognitive ageing. Using these criteria in combination or individually to define super‐agers, with a clear rationale for which elements have been selected, could be fit for purpose depending on the research question. However, major discrepancies including the age range of super‐agers and comparator groups and the choice of cognitive domains assessed should be addressed to reach some consensus in the field.

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Superficial white matter across development, young adulthood, and aging: volume, thickness, and relationship with cortical features

et al. 2023

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Regional Cortical Thickness Predicts Top Cognitive Performance in the Elderly

Cited by 9 publications

References 33 publications

Superficial white matter across the lifespan: volume, thickness, change, and relationship with cortical features

Superficial white matter across the lifespan: volume, thickness, change, and relationship with cortical features

Defining exceptional cognition in older adults: A systematic review of cognitive super‐ageing

Superficial white matter across development, young adulthood, and aging: volume, thickness, and relationship with cortical features

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