Age‐related regional brain T2‐relaxation changes in healthy adults

Kumar, Rajesh; Delshad, Sean; Woo, Mary A.; Macey, Paul M.; Harper, Ronald M.

doi:10.1002/jmri.22831

Cited by 45 publications

(49 citation statements)

References 28 publications

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“…The metabolite concentrations determined in this study agree in general with those reported by using single voxel spectroscopy (SVS), with NAA being the largest component in cerebrum and tCr the largest component in cerebellum, while the Cho concentration is the smallest in both regions 14, 15 , though in this study the measurements were obtained in multiple regions using only a single MRSI acquisition. The T2 and T2′ values found in this study are also comparable with those previously published, with T2′ being shortest in supratentorial deep gray matter, and T2 longest in cerebellum 6, 16 . With combined wbMRSI and qMRI measurements this study determined for the first time simultaneously the age-related metabolite concentrations and tissue transverse relaxation times at multiple supratentorial and infratentorial structures in healthy human brain, which has the potential to provide a reference basis for future studies to identify pathological alterations in patients.…”

Section: Discussionsupporting

confidence: 92%

Detection of Normal Aging Effects on Human Brain Metabolite Concentrations and Microstructure with Whole-Brain MR Spectroscopic Imaging and Quantitative MR Imaging

Eylers

Maudsley

Bronzlik

et al. 2015

AJNR Am J Neuroradiol

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Background and purpose Whole brain 1H-MR spectroscopic imaging (wbMRSI) was used in combination with quantitative MRI (qMRI) to study the effects of normal aging on healthy human brain metabolites and microstructure. Materials and Methods Sixty healthy volunteers aged 21 to 70 years were studied. Brain maps of the metabolites NAA, Cr, and Cho, and the tissue irreversible and reversible transverse relaxation times, T2 and T2′, were derived from the datasets. The relative metabolite concentrations [NAA], [tCr] and [Cho] as well as the values of relaxation times were measured with ROIs placed within frontal and parietal WM, centrum semiovale (CSO), splenium of the corpus callosum (SCC), hand motor area (HK), occipital GM, putamen, thalamus, pons ventral/dorsal (BSv/BSd), cerebellar white matter (CbWM) and posterior lobe (CbGM). Linear regression analysis and Pearson’s correlation tests were used to analyze the data. Results Aging resulted in decreased [NAA] in occipital GM, putamen, SCC, and BSv, and decreased [tCr] in BSd and putamen. [Cho] did not change significantly in selected brain regions. T2 increased in CbWM and decreased in SCC with aging, while the T2′ decreased in the occipital GM, HK, putamen, and increased in the SCC. Correlations were found between [NAA] and T2′ in occipital GM and putamen and between [tCr] and T2′ in the putamen. Conclusion The effects of normal aging on brain metabolites and microstructure are regional dependent. Correlations between both processes are evident in the gray matter. The obtained data could be used as references for future studies on patients.

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Section: Discussionsupporting

confidence: 92%

Detection of Normal Aging Effects on Human Brain Metabolite Concentrations and Microstructure with Whole-Brain MR Spectroscopic Imaging and Quantitative MR Imaging

Eylers

Maudsley

Bronzlik

et al. 2015

AJNR Am J Neuroradiol

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“…An important task for further research is to disentangle to what degree common mechanisms may be responsible for brain maturation in childhood and degenerative changes in aging (Nikolaev et al, 2009; Wines-Samuelson and Shen 2005), and to what degree distinct processes are causing the observed macrostructural changes. Longitudinal studies should utilize multimodal and multidimensional data to explore the relationships between morphometric measures, water diffusivity and signal intensity and tissue contrast in development and aging (Brown and Jernigan In press; Groves et al, 2012; Kumar et al, 2012; Salat et al, 2009; Westlye et al, 2010a; Westlye et al, 2009), as this could indirectly inform us on the underlying specific biological processes that give rise to the imaging effects. Intriguingly, a recent cross-sectional study (Brown et al, 2012)found that different imaging modalities contribute most strongly to predicting age over the course of development, indicating a dynamic cascade of changes with different features dominating at different points.…”

Section: Discussionmentioning

confidence: 99%

Brain development and aging: Overlapping and unique patterns of change

et al. 2013

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Early-life development is characterized by dramatic changes, impacting lifespan function more than changes inany other period. Developmental origins of neurocognitive late-life functions are acknowledged, but detailed longitudinal magnetic resonance imaging studies of brain maturation and direct comparisons with aging are lacking. To these aims, a novel method was used to measure longitudinal volume changes in development (n = 85, 8–22 years) and aging (n = 142, 60–91 years). Developmental reductions exceeded 1% annually in much of cortex, more than double that seen in aging, with a posterior-to-anterior gradient. Cortical reductions were greater than subcortical during development, while the opposite held in aging. The pattern of lateral cortical changes was similar across development and aging, but the pronounced medial temporal reduction in aging was not precast in development. Converging patterns of change in adolescents and elderly, particularly in medial prefrontal areas, suggest that late developed cortices are especially vulnerable to atrophy in aging. A key question in future research will be to disentangle the neurobiological underpinnings for the differences and the similarities between brain changes in development and aging.

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“…T 2 * information can provide a useful proxy for examining changes in baseline BOLD signals, and interpreting the related BOLD-CVR signal with age. However, intrinsic, tissues T 2 values can also vary due to age-related physical changes (Siemonsen et al, 2008;Kumar et al, 2012). Separating hemodynamic/oxygenation state from intrinsic tissue properties will remain challenging as both extravascular T 2 ′and T 2 values are affected by the blood oxygenation level, especially around small vessels (Siero et al, 2013).…”

Section: Caveats and Future Considerationsmentioning

confidence: 99%