Cerebral Microbleeds: Imaging and Clinical Significance

Haller, Sven; Vernooij, Meike W.; Kuijer, Joost P.A.; Larsson, Elna-Marie; Jäger, Hans Rolf; Barkhof, Frederik

doi:10.1148/radiol.2018170803

Cited by 231 publications

(184 citation statements)

References 103 publications

Supporting

Mentioning

174

Contrasting

Unclassified

Order By: Relevance

“…8 As expected, MBs were more easily detected with higher magnetic strength and SWI. 9 The distribution and extent of microbleeds we describe may be distinct for severe HACE. Microbleeds reported in other conditions are usually far fewer in number, in different distributions, and lack the fine black pepper appearance.…”

Section: Microbleedsmentioning

confidence: 75%

“…Microbleeds reported in other conditions are usually far fewer in number, in different distributions, and lack the fine black pepper appearance. 9 Previous studies using SWI in subjects after high altitude exposure support this view. Eleven of 13 climbers with a history of HACE demonstrated residual MBs, with only severe cases or those with HAPE showing the extensive distribution similar to that in our patients.…”

Section: Microbleedsmentioning

confidence: 88%

See 1 more Smart Citation

Acute and Evolving MRI of High-Altitude Cerebral Edema: Microbleeds, Edema, and Pathophysiology

Hackett

Yarnell

Weiland

et al. 2019

AJNR Am J Neuroradiol

View full text Add to dashboard Cite

MR imaging of high-altitude cerebral edema shows reversible WM edema, especially in the corpus callosum and subcortical WM. Recent studies have revealed hemosiderin deposition in WM long after high-altitude cerebral edema has resolved, providing a high-altitude cerebral edema "footprint." We wished to determine whether these microbleeds are present acutely and also describe the evolution of all MR imaging findings. In 8 patients with severe high-altitude cerebral edema, we obtained 26 studies: 18 with 3T and 8 with 1.5T scanners, during the acute stage, recovery, and follow-up in 7 patients and acutely in 1 patient. Imaging confirmed reversible cytotoxic and vasogenic WM edema that unexpectedly worsened the first week during clinical improvement before resolving. The 3T SWI, but not 1.5T imaging, showed extensive microbleeds extending beyond areas of edema seen acutely, which persisted and with time coalesced. These findings support cytotoxic and vasogenic edema leading to capillary failure/leakage in the pathophysiology of high-altitude cerebral edema and provide imaging correlation to the clinical course.ABBREVIATIONS: HACE ϭ high-altitude cerebral edema; HAPE ϭ high-altitude pulmonary edema; MB ϭ microbleed

show abstract

Section: Microbleedsmentioning

confidence: 75%

Section: Microbleedsmentioning

confidence: 88%

Acute and Evolving MRI of High-Altitude Cerebral Edema: Microbleeds, Edema, and Pathophysiology

Hackett

Yarnell

Weiland

et al. 2019

AJNR Am J Neuroradiol

View full text Add to dashboard Cite

show abstract

“…The detection rate of cortical microinfarcts was also improved considerably by imaging at 7 T in comparison to 3 T, which was confirmed histologically through subsequent serial sectioning. Therefore, technical limitations, such as field strength, image resolution, pulsesequence parameters and MRI-histological matching were considered to be the major sources for obtaining false negative results [15,25,47,49]. However, our analyses with a field strength of 11.7 T now showed that there is also some variability in the histopathological features of cortical cerebral microinfarcts, including not only their size and shape, the cortical layer in which they occur, thinning, and cavitation, but also the degree of iron accumulation, which influenced MRI signals and the detectability of microinfarcts in this study.…”

Section: Discussionmentioning

confidence: 99%

“…Rupture or occlusion of these arterioles could be caused by CAA or atherosclerosis of leptomeningeal vessels and their arteriolar branches that supply the cerebral cortex [31,43]. Other causes of cortical cerebral microinfarcts include thrombotic microembolisms originating from the heart (e.g., endocarditis) or plaques in cerebral arteries, lipid microembolisms following major surgeries, hereditary forms of small vessel disease such as CADASIL, leukoencephalopathy, and radiation therapy [11,25].…”

Section: Discussionmentioning

confidence: 99%

Histological correlates of postmortem ultra-high-resolution single-section MRI in cortical cerebral microinfarcts

Yilmazer-Hanke

Mayer

Müller³

et al. 2020

acta neuropathol commun

View full text Add to dashboard Cite

The identification of cerebral microinfarctions with magnetic resonance imaging (MRI) and histological methods remains challenging in aging and dementia. Here, we matched pathological changes in the microvasculature of cortical cerebral microinfarcts to MRI signals using single 100 μm-thick histological sections scanned with ultra-highresolution 11.7 T MRI. Histologically, microinfarcts were located in superficial or deep cortical layers or transcortically, compatible with the pattern of layer-specific arteriolar blood supply of the cerebral cortex. Contrary to acute microinfarcts, at chronic stages the core region of microinfarcts showed pallor with extracellular accumulation of lipofuscin and depletion of neurons, a dense meshwork of collagen 4-positive microvessels with numerous string vessels, CD68-positive macrophages and glial fibrillary acidic protein (GFAP)-positive astrocytes. In MRI scans, cortical microinfarcts at chronic stages, called chronic cortical microinfarcts here, gave hypointense signals in T1-weighted and hyperintense signals in T2-weighted images when thinning of the tissue and cavitation and/or prominent iron accumulation were present. Iron accumulation in chronic microinfarcts, histologically verified with Prussian blue staining, also produced strong hypointense T2*-weighted signals. In summary, the microinfarct core was occupied by a dense microvascular meshwork with string vessels, which was invaded by macrophages and astroglia and contained various degrees of iron accumulation. While postmortem ultra-high-resolution single-section imaging improved MRI-histological matching and the structural characterization of chronic cortical cerebral microinfarcts, miniscule microinfarcts without thinning or iron accumulation could not be detected with certainty in the MRI scans. Moreover, string vessels at the infarct margin indicate disturbances in the microcirculation in and around microinfarcts, which might be exploitable in the diagnostics of cortical cerebral microinfarcts with MRI in vivo.

show abstract

“…Today, in radiological routine, physiological ageing assessment consists in mostly 4 tasks, such as (i) categorical assessment of atrophy (eg : medial temporal lobe atrophy score (MTA), aiming to distinguish normal to pathologic atrophy (Gaillard s. d.)), (ii) assessment of ventricles dilatation (the task consists in identifying atrophy to hydrocephalus), (iii) assessment of White Matter Hyperintensities (WMH) on MRI T2 sequences (this tasks consists in firstly identifying the leukoaraiosis pattern vs other WHM patterns (for eg : inflammatory, such as in multiple sclerosis), and secondly grading level of leukoaraiosis with Fazekas scale (Fazekas et al 1987)), and (iv) detect, count, and assess spatial distribution of cerebral microbleeds (CMBs), in order to distinct normal ageing in the brain to the main differential diagnostics : high cardiovascular risk (deep spatial repartition CMBs are associated with small vessel disease due to hypertension) versus Amyloid angiopathy (superficial, lobar distribution of CMBs) ; for a recent review see (Haller et al 2018). Schematically, 3 MRI sequences are used for this 4 tasks : T1 weighted MRI for grey matter and CSF, T2 weighted (FLAIR sequence) for white matter (and CSF), T2* or SW for CMBs assessments.…”

Section: Brain Ageing In Radiologymentioning

confidence: 99%

Brain age prediction of healthy subjects on anatomic MRI with deep learning: going beyond with an "explainable AI" mindset

Hérent¹,

Jégou²,

Wainrib³

et al. 2018

Preprint

View full text Add to dashboard Cite

Objectives: Define a clinically usable preprocessing pipeline for MRI data. Predict brain age using various machine learning and deep learning algorithms. Define Caveat against common machine learning traps. Data and Methods: We used 1597 open-access T1 weighted MRI from 24 hospitals. Preprocessing consisted in applying: N4 bias field correction, registration to MNI152 space, white and grey stripe intensity normalization, skull stripping and brain tissue segmentation. Prediction of brain age was done with growing complexity of data input (histograms, grey matter from segmented MRI, raw data) and models for training (linear models, non linear model such as gradient boosting over decision trees, and 2D and 3D convolutional neural networks). Work on interpretability consisted in (i) proceeding on basic data visualization like correlations maps between age and voxels value, and generating (ii) weights maps of simpler models, (iii) heatmap from CNNs model with occlusion method. Results: Processing time seemed feasible in a radiological workflow: 5 min for one 3D T1 MRI. We found a significant correlation between age and gray matter volume with a correlation r = -0.74. Our best model obtained a mean absolute error of 3.60 years, with fine tuned convolution neural network (CNN) pretrained on ImageNet. We carefully analyzed and interpreted the center effect. Our work on interpretability on simpler models permitted to observe heterogeneity of prediction depending on brain regions known for being involved in ageing (grey matter, ventricles). Occlusion method of CNN showed the importance of Insula and deep grey matter (thalami, caudate nuclei) in predictions. Conclusions: Predicting the brain age using deep learning could be a standardized metric usable in daily neuroradiological reports. An explainable algorithm gives more confidence and acceptability for its use in practice. More clinical studies using this new quantitative biomarker in neurological diseases will show how to use it at its best.

show abstract

Cerebral Microbleeds: Imaging and Clinical Significance

Cited by 231 publications

References 103 publications

Acute and Evolving MRI of High-Altitude Cerebral Edema: Microbleeds, Edema, and Pathophysiology

Acute and Evolving MRI of High-Altitude Cerebral Edema: Microbleeds, Edema, and Pathophysiology

Histological correlates of postmortem ultra-high-resolution single-section MRI in cortical cerebral microinfarcts

Brain age prediction of healthy subjects on anatomic MRI with deep learning: going beyond with an "explainable AI" mindset

Contact Info

Product

Resources

About