89 research outputs found
Influence of thickening of the inner skull table on intracranial volume measurement in older people
INTRODUCTION: It is generally assumed that intracranial volume (ICV) remains constant after peaking in early adulthood. Thus ICV is used as a âproxyâ for original brain size when trying to estimate brain atrophy in older people in neuroimaging studies. However, physiological changes in the skull, such as thickening of the frontal inner table, are relatively common in older age and will reduce ICV. The potential influence that inner table skull thickening may have on ICV measurement in old age has yet to be investigated. METHODS: We selected 60 (31 males, 29 females) representative older adults aged 71.1â74.3 years from a community-dwelling ageing cohort, the Lothian Birth Cohort 1936. A semi-automatically derived current ICV measurement obtained from high resolution T1-weighted volume scans was compared to the estimated original ICV by excluding inner skull table thickening using expert manual image processing. RESULTS: Inner table skull thickening reduced ICV from an estimated original 1480.0 ml to a current 1409.1 ml, a median decrease of 7.3% (Z = â 6.334; p < 0.001), and this reduction was more prominent in women than men (median decrease 114.6 vs. 101.9 ml respectively). This led to potential significant underestimations of brain atrophy in this sample by 5.3% (p < 0.001) and obscured potential gender differences. CONCLUSIONS: The effects of skull thickening are important to consider when conducting research in ageing, as they can obscure gender differences and result in underestimation of brain atrophy. Research into reliable methods of determining the estimated original ICV is required for research into brain ageing
Metric to quantify white matter damage on brain magnetic resonance images
PURPOSE: Quantitative assessment of white matter hyperintensities (WMH) on structural Magnetic Resonance Imaging (MRI) is challenging. It is important to harmonise results from different software tools considering not only the volume but also the signal intensity. Here we propose and evaluate a metric of white matter (WM) damage that addresses this need. METHODS: We obtained WMH and normal-appearing white matter (NAWM) volumes from brain structural MRI from community dwelling older individuals and stroke patients enrolled in three different studies, using two automatic methods followed by manual editing by two to four observers blind to each other. We calculated the average intensity values on brain structural fluid-attenuation inversion recovery (FLAIR) MRI for the NAWM and WMH. The white matter damage metric is calculated as the proportion of WMH in brain tissue weighted by the relative image contrast of the WMH-to-NAWM. The new metric was evaluated using tissue microstructure parameters and visual ratings of small vessel disease burden and WMH: Fazekas score for WMH burden and Prins scale for WMH change. RESULTS: The correlation between the WM damage metric and the visual rating scores (Spearman Ï > =0.74, p  =0.72, p < 0.0001). The repeatability of the WM damage metric was better than WM volume (average median difference between measurements 3.26% (IQR 2.76%) and 5.88% (IQR 5.32%) respectively). The follow-up WM damage was highly related to total Prins score even when adjusted for baseline WM damage (ANCOVA, p < 0.0001), which was not always the case for WMH volume, as total Prins was highly associated with the change in the intense WMH volume (p = 0.0079, increase of 4.42 ml per unit change in total Prins, 95%CI [1.17 7.67]), but not with the change in less-intense, subtle WMH, which determined the volumetric change. CONCLUSION: The new metric is practical and simple to calculate. It is robust to variations in image processing methods and scanning protocols, and sensitive to subtle and severe white matter damage
Integrity of normal-appearing white matter: influence of age, visible lesion burden and hypertension in patients with small vessel disease
White matter hyperintensities accumulate with age and occur in patients with stroke, but their pathogenesis is poorly understood. We measured multiple magnetic resonance imaging biomarkers of tissue integrity in normal-appearing white matter and white matter hyperintensities in patients with mild stroke, to improve understanding of white matter hyperintensities origins. We classified white matter into white matter hyperintensities and normal-appearing white matter and measured fractional anisotropy, mean diffusivity, water content (T1-relaxation time) and bloodâbrain barrier leakage (signal enhancement slope from dynamic contrast-enhanced magnetic resonance imaging). We studied the effects of age, white matter hyperintensities burden (Fazekas score) and vascular risk factors on each biomarker, in normal-appearing white matter and white matter hyperintensities, and performed receiver-operator characteristic curve analysis. Amongst 204 patients (34.3â90.9 years), all biomarkers differed between normal-appearing white matter and white matter hyperintensities (Pâ<â0.001). In normal-appearing white matter and white matter hyperintensities, mean diffusivity and T1 increased with age (Pâ<â0.001), all biomarkers varied with white matter hyperintensities burden (Pâ<â0.001; Pâ=â0.02 signal enhancement slope), but only signal enhancement slope increased with hypertension (Pâ=â0.028). Fractional anisotropy showed complex age-white matter hyperintensities-tissue interactions; enhancement slope showed white matter hyperintensities-tissue interactions. Mean diffusivity distinguished white matter hyperintensities from normal-appearing white matter best at all ages. Bloodâbrain barrier leakage increases with hypertension and white matter hyperintensities burden at all ages in normal-appearing white matter and white matter hyperintensities, whereas water mobility and content increase as tissue damage accrues, suggesting that bloodâbrain barrier leakage mediates small vessel disease-related brain damage
White matter hyperintensity reduction and outcomes after minor stroke
Objective: To assess factors associated with white matter hyperintensity (WMH) change in a large cohort after observing obvious WMH shrinkage 1 year after minor stroke in several participants in a longitudinal study.
Methods: We recruited participants with minor ischemic stroke and performed clinical assessments and brain MRI. At 1 year, we assessed recurrent cerebrovascular events and dependency and repeated the MRI. We assessed change in WMH volume from baseline to 1 year (normalized to percent intracranial volume [ICV]) and associations with baseline variables, clinical outcomes, and imaging parameters using multivariable analysis of covariance, model of changes, and multinomial logistic regression.
Results: Among 190 participants (mean age 65.3 years, range 34.3â96.9 years, 112 [59%] male), WMH decreased in 71 participants by 1 year. At baseline, participants whose WMH decreased had similar WMH volumes but higher blood pressure (p = 0.0064) compared with participants whose WMH increased. At 1 year, participants with WMH decrease (expressed as percent ICV) had larger reductions in blood pressure (ÎČ = 0.0053, 95% confidence interval [CI] 0.00099â0.0097 fewer WMH per 1âmm Hg decrease, p = 0.017) and in mean diffusivity in normal-appearing white matter (ÎČ = 0.075, 95% CI 0.0025â0.15 fewer WMH per 1-unit mean diffusivity decrease, p = 0.043) than participants with WMH increase; those with WMH increase experienced more recurrent cerebrovascular events (32%, vs 16% with WMH decrease, ÎČ = 0.27, 95% CI 0.047â0.50 more WMH per event, p = 0.018).
Conclusions: Some WMH may regress after minor stroke, with potentially better clinical and brain tissue outcomes. The role of risk factor control requires verification. Interstitial fluid alterations may account for some WMH reversibility, offering potential intervention targets
Topological relationships between perivascular spaces and progression of white matter hyperintensities:A pilot study in a sample of the Lothian Birth Cohort 1936
Enlarged perivascular spaces (PVS) and white matter hyperintensities (WMH) are features of cerebral small vessel disease which can be seen in brain magnetic resonance imaging (MRI). Given the associations and proposed mechanistic link between PVS and WMH, they are hypothesized to also have topological proximity. However, this and the influence of their spatial proximity on WMH progression are unknown. We analyzed longitudinal MRI data from 29 out of 32 participants (mean age at baseline = 71.9 years) in a longitudinal study of cognitive aging, from three waves of data collection at 3-year intervals, alongside semi-automatic segmentation masks for PVS and WMH, to assess relationships. The majority of deep WMH clusters were found adjacent to or enclosing PVS (wavesâ1: 77%; 2: 76%; 3: 69%), especially in frontal, parietal, and temporal regions. Of the WMH clusters in the deep white matter that increased between waves, most increased around PVS (wavesâ1â2: 73%; 2â3: 72%). Formal statistical comparisons of severity of each of these two SVD markers yielded no associations between deep WMH progression and PVS proximity. These findings may suggest some deep WMH clusters may form and grow around PVS, possibly reflecting the consequences of impaired interstitial fluid drainage via PVS. The utility of these relationships as predictors of WMH progression remains unclear
Blood-brain barrier failure as a core mechanism in cerebral small vessel disease and dementia: evidence from a cohort study
Introduction: Small vessel disease (SVD) is a common contributor to dementia. Subtle blood-brain
barrier (BBB) leakage may be important in SVD-induced brain damage.
Methods: We assessed imaging, clinical variables, and cognition in patients with mild (i.e., nondisabling)
ischemic lacunar or cortical stroke. We analyzed BBB leakage, interstitial fluid, and white
matter integrity using multimodal tissue-specific spatial analysis around white matter hyperintensities
(WMH). We assessed predictors of 1 year cognition, recurrent stroke, and dependency.
Results: In 201 patients, median age 67 (range 34â97), BBB leakage, and interstitial fluid were
higher in WMH than normal-appearing white matter; leakage in normal-appearing white matter
increased with proximity to WMH (P , .0001), with WMH severity (P 5 .033), age (P 5 .03),
and hypertension (P , .0001). BBB leakage in WMH predicted declining cognition at 1 year.
Discussion: BBB leakage increases in normal-appearing white matter with WMH and predicts worsening
cognition. Interventions to reduce BBB leakage may prevent SVD-associated dementia
Progression of white matter disease and cortical thinning are not related in older community-dwelling subjects
Background and Purposeâ
We assessed cross-sectional and longitudinal relationships between whole brain white matter hyperintensity (WMH) volume and regional cortical thickness.
Methodsâ
We measured WMH volume and regional cortical thickness on magnetic resonance imaging at â73 and â76 years in 351 community-dwelling subjects from the Lothian Birth Cohort 1936. We used multiple linear regression to calculate cross-sectional and longitudinal associations between regional cortical thickness and WMH volume controlling for age, sex, Mini Mental State Examination, education, intelligence quotient at age 11, and vascular risk factors.
Resultsâ
We found cross-sectional associations between WMH volume and cortical thickness within and surrounding the Sylvian fissure at 73 and 76 years (rho=â0.276, Q=0.004). However, we found no significant longitudinal associations between (1) baseline WMH volume and change in cortical thickness; (2) baseline cortical thickness and change in WMH volume; or (3) change in WMH volume and change in cortical thickness.
Conclusionsâ
Our results show that WMH volume and cortical thinning both worsen with age and are associated cross-sectionally within and surrounding the Sylvian fissure. However, changes in WMH volume and cortical thinning from 73 to 76 years are not associated longitudinally in these relatively healthy older subjects. The underlying cause(s) of WMH growth and cortical thinning have yet to be fully determined
Magnetic Resonance Imaging Tissue Signatures Associated With White Matter Changes Due to Sporadic Cerebral Small Vessel Disease Indicate That White Matter Hyperintensities Can Regress
Background White matter hyperintensities (WMHs) might regress and progress contemporaneously, but we know little about underlying mechanisms. We examined WMH change and underlying quantitative magnetic resonance imaging tissue measures over 1âyear in patients with minor ischemic stroke with sporadic cerebral small vessel disease. Methods and Results We defined areas of stable normalâappearing white matter, stable WMHs, progressing and regressing WMHs based on baseline and 1âyear brain magnetic resonance imaging. In these areas we assessed tissue characteristics with quantitative T1, fractional anisotropy (FA), mean diffusivity (MD), and neurite orientation dispersion and density imaging (baseline only). We compared tissue signatures crossâsectionally between areas, and longitudinally within each area. WMH change masks were available for N=197. Participants' mean age was 65.61âyears (SD, 11.10), 59% had a lacunar infarct, and 68% were men. FA and MD were available for N=195, quantitative T1 for N=182, and neurite orientation dispersion and density imaging for N=174. Crossâsectionally, all 4 tissue classes differed for FA, MD, T1, and Neurite Density Index. Longitudinally, in regressing WMHs, FA increased with little change in MD and T1 (difference estimate, 0.011 [95% CI, 0.006â0.017]; â0.002 [95% CI, â0.008 to 0.003] and â0.003 [95% CI, â0.009 to 0.004]); in progressing and stable WMHs, FA decreased (â0.022 [95% CI, â0.027 to â0.017] and â0.009 [95% CI, â0.011 to â0.006]), whereas MD and T1 increased (progressing WMHs, 0.057 [95% CI, 0.050â0.063], 0.058 [95% CI, 0.050 â0.066]; stable WMHs, 0.054 [95% CI, 0.045â0.063], 0.049 [95% CI, 0.039â0.058]); and in stable normalâappearing white matter, MD increased (0.004 [95% CI, 0.003â0.005]), whereas FA and T1 slightly decreased and increased (â0.002 [95% CI, â0.004 to â0.000] and 0.005 [95% CI, 0.001â0.009]). Conclusions Quantitative magnetic resonance imaging shows that WMHs that regress have less abnormal microstructure at baseline than stable WMHs and follow trajectories indicating tissue improvement compared with stable and progressing WMHs
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