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4. Free water corrected diffusion tensor imaging discriminates between good and poor outcomes of comatose patients after cardiac arrest.

Author

Keijzer, H.M., Duering, M., Pasternak, O., Meijer, F.J.A., Verhulst, M.M.L.H., Tonino, B.A.R., Blans, M.J., Hoedemaekers, C.W.E., Klijn, C.J.M., Hofmeijer, J., Keijzer, H.M., Duering, M., Pasternak, O., Meijer, F.J.A., Verhulst, M.M.L.H., Tonino, B.A.R., Blans, M.J., Hoedemaekers, C.W.E., Klijn, C.J.M., and Hofmeijer, J.

Abstract

Item does not contain fulltext, OBJECTIVES: Approximately 50% of comatose patients after cardiac arrest never regain consciousness. Cerebral ischaemia may lead to cytotoxic and/or vasogenic oedema, which can be detected by diffusion tensor imaging (DTI). Here, we evaluate the potential value of free water corrected mean diffusivity (MD) and fractional anisotropy (FA) based on DTI, for the prediction of neurological recovery of comatose patients after cardiac arrest. METHODS: A total of 50 patients after cardiac arrest were included in this prospective cohort study in two Dutch hospitals. DTI was obtained 2-4 days after cardiac arrest. Outcome was assessed at 6 months, dichotomised as poor (cerebral performance category 3-5; n = 20) or good (n = 30) neurological outcome. We calculated the whole brain mean MD and FA and compared between patients with good and poor outcomes. In addition, we compared a preliminary prediction model based on clinical parameters with or without the addition of MD and FA. RESULTS: We found significant differences between patients with good and poor outcome of mean MD (good: 726 [702-740] × 10(-6) mm(2)/s vs. poor: 663 [575-736] × 10(-6) mm(2)/s; p = 0.01) and mean FA (0.30 ± 0.03 vs. 0.28 ± 0.03; p = 0.03). An exploratory prediction model combining clinical parameters, MD and FA increased the sensitivity for reliable prediction of poor outcome from 60 to 85%, compared to the model containing clinical parameters only, but confidence intervals are overlapping. CONCLUSIONS: Free water-corrected MD and FA discriminate between patients with good and poor outcomes after cardiac arrest and hold the potential to add to multimodal outcome prediction. KEY POINTS: • Whole brain mean MD and FA differ between patients with good and poor outcome after cardiac arrest. • Free water-corrected MD can better discriminate between patients with good and poor outcome than uncorrected MD. • A combination of free water-corrected MD (sensitive to grey matter abnormalities) and FA (sensitive to wh

Published
2023

5. Disentangling the effects of Alzheimer's and small vessel disease on white matter fibre tracts.

Author

Dewenter, A., Jacob, M.A., Cai, M., Gesierich, B., Hager, P., Kopczak, A., Biel, D., Ewers, M., Tuladhar, A.M., Leeuw, F.E. de, Dichgans, M., Franzmeier, N., Duering, M., Dewenter, A., Jacob, M.A., Cai, M., Gesierich, B., Hager, P., Kopczak, A., Biel, D., Ewers, M., Tuladhar, A.M., Leeuw, F.E. de, Dichgans, M., Franzmeier, N., and Duering, M.

Abstract

Item does not contain fulltext, Alzheimer's disease and cerebral small vessel disease are the two leading causes of cognitive decline and dementia and coexist in most memory clinic patients. White matter damage as assessed by diffusion MRI is a key feature in both Alzheimer's and cerebral small vessel disease. However, disease-specific biomarkers of white matter alterations are missing. Recent advances in diffusion MRI operating on the fixel level (fibre population within a voxel) promise to advance our understanding of disease-related white matter alterations. Fixel-based analysis allows derivation of measures of both white matter microstructure, measured by fibre density, and macrostructure, measured by fibre-bundle cross-section. Here, we evaluated the capacity of these state-of-the-art fixel metrics to disentangle the effects of cerebral small vessel disease and Alzheimer's disease on white matter integrity. We included three independent samples (total n = 387) covering genetically defined cerebral small vessel disease and age-matched controls, the full spectrum of biomarker-confirmed Alzheimer's disease including amyloid- and tau-PET negative controls and a validation sample with presumed mixed pathology. In this cross-sectional analysis, we performed group comparisons between patients and controls and assessed associations between fixel metrics within main white matter tracts and imaging hallmarks of cerebral small vessel disease (white matter hyperintensity volume, lacune and cerebral microbleed count) and Alzheimer's disease (amyloid- and tau-PET), age and a measure of neurodegeneration (brain volume). Our results showed that (i) fibre density was reduced in genetically defined cerebral small vessel disease and strongly associated with cerebral small vessel disease imaging hallmarks; (ii) fibre-bundle cross-section was mainly associated with brain volume; and (iii) both fibre density and fibre-bundle cross-section were reduced in the presence of amyloid, but not further exacerbated by abno

Published
2023

6. The global burden of cerebral small vessel disease in low- and middle-income countries: A systematic review and meta-analysis.

Author

Lam, B.Y.K., Cai, Y., Akinyemi, R., Biessels, G.J., Brink, H. van den, Chen, C, Cheung, C.W., Chow, K.N., Chung, H.K.H., Duering, M., Fu, S.T., Gustafson, D., Hilal, S., Hui, V.M.H., Kalaria, R., Kim, S., Lam, M.L.M., Leeuw, F.E. de, Li, A.S.M., Markus, H.S., Marseglia, A., Zheng, H., O'Brien, J., Pantoni, L., Sachdev, P.S., Smith, E.E., Wardlaw, J., Mok, V.C.T., Lam, B.Y.K., Cai, Y., Akinyemi, R., Biessels, G.J., Brink, H. van den, Chen, C, Cheung, C.W., Chow, K.N., Chung, H.K.H., Duering, M., Fu, S.T., Gustafson, D., Hilal, S., Hui, V.M.H., Kalaria, R., Kim, S., Lam, M.L.M., Leeuw, F.E. de, Li, A.S.M., Markus, H.S., Marseglia, A., Zheng, H., O'Brien, J., Pantoni, L., Sachdev, P.S., Smith, E.E., Wardlaw, J., and Mok, V.C.T.

Abstract

01 januari 2023, Item does not contain fulltext, BACKGROUND: Cerebral small vessel disease (cSVD) is a major cause of stroke and dementia. Previous studies on the prevalence of cSVD are mostly based on single geographically defined cohorts in high-income countries. Studies investigating the prevalence of cSVD in low- and middle-income countries (LMICs) are expanding but have not been systematically assessed. AIM: This study aims to systematically review the prevalence of cSVD in LMICs. RESULTS: Articles were searched from the Ovid MEDLINE and EMBASE databases from 1 January 2000 to 31 March 2022, without language restrictions. Title/abstract screening, full-text review, and data extraction were performed by two to seven independent reviewers. The prevalence of cSVD and study sample size were extracted by pre-defined world regions and health status. The Risk of Bias for Non-randomized Studies tool was used. The protocol was registered on PROSPERO (CRD42022311133). A meta-analysis of proportion was performed to assess the prevalence of different magnetic resonance imaging markers of cSVD, and a meta-regression was performed to investigate associations between cSVD prevalence and type of study, age, and male: female ratio. Of 2743 studies identified, 42 studies spanning 12 global regions were included in the systematic review. Most of the identified studies were from China (n = 23). The median prevalence of moderate-to-severe white matter hyperintensities (WMHs) was 20.5%, 40.5%, and 58.4% in the community, stroke, and dementia groups, respectively. The median prevalence of lacunes was 0.8% and 33.5% in the community and stroke groups. The median prevalence of cerebral microbleeds (CMBs) was 10.7% and 22.4% in the community and stroke groups. The median prevalence of moderate-to-severe perivascular spaces was 25.0% in the community. Meta-regression analyses showed that the weighted median age (51.4 ± 0.0 years old; range: 36.3-80.2) was a significant predictor of the prevalence of moderate-to-severe WMH and lacunes

Published
2023

7. Cerebral Small Vessel Disease Progression Increases Risk of Incident Parkinsonism.

Author

Jacob, M.A., Cai, M., Bergkamp, M.I., Darweesh, S.K.L., Gelissen, L.M.Y., Marques, J.P., Norris, D.G., Duering, M., Esselink, R.A.J., Tuladhar, A.M., Leeuw, F.E. de, Jacob, M.A., Cai, M., Bergkamp, M.I., Darweesh, S.K.L., Gelissen, L.M.Y., Marques, J.P., Norris, D.G., Duering, M., Esselink, R.A.J., Tuladhar, A.M., and Leeuw, F.E. de

Abstract

01 juni 2023, Contains fulltext : 293219.pdf (Publisher’s version ) (Open Access), OBJECTIVE: Cerebral small vessel disease (SVD) is associated with motor impairments and parkinsonian signs cross-sectionally, however, there are little longitudinal data on whether SVD increases risk of incident parkinsonism itself. We investigated the relation between baseline SVD severity as well as SVD progression, and incident parkinsonism over a follow-up of 14 years. METHODS: This study included 503 participants with SVD, and without parkinsonism at baseline, from the RUN DMC prospective cohort study. Baseline inclusion was performed in 2006 and follow-up took place in 2011, 2015, and 2020, including magnetic resonance imaging (MRI) and motor assessments. Parkinsonism was diagnosed according to the UK Brain Bank criteria, and stratified into vascular parkinsonism (VaP) and idiopathic Parkinson's disease (IPD). Linear mixed-effect models were constructed to estimate individual rate changes of MRI-characteristics. RESULTS: Follow-up for incident parkinsonism was near-complete (99%). In total, 51 (10.2%) participants developed parkinsonism (33 VaP, 17 IPD, and 1 progressive supranuclear palsy). Patients with incident VaP had higher SVD burden compared with patients with IPD. Higher baseline white matter hyperintensities (hazard ratio [HR] = 1.46 per 1-SD increase, 95% confidence interval [CI] = 1.21-1.78), peak width of skeletonized mean diffusivity (HR = 1.66 per 1-SD increase, 95% CI = 1.34-2.05), and presence of lacunes (HR = 1.84, 95% CI = 0.99-3.42) were associated with increased risk of all-cause parkinsonism. Incident lacunes were associated with incident VaP (HR = 4.64, 95% CI = 1.32-16.32). INTERPRETATION: Both baseline SVD severity and SVD progression are independently associated with long-term parkinsonism. Our findings indicate a causal role of SVD in parkinsonism. Future studies are needed to examine the underlying pathophysiology of this relation. ANN NEUROL 2023;93:1130-1141.

Published
2023

8. Integrated intravoxel incoherent motion tensor and diffusion tensor brain MRI in a single fast acquisition.

Author

Dietrich, O., Cai, M., Tuladhar, A.M., Jacob, M.A., Drenthen, G.S., Jansen, J.F., Marques, J.P., Topalis, J., Ingrisch, M., Ricke, J., Leeuw, H.F. de, Duering, M., Backes, W.H., Dietrich, O., Cai, M., Tuladhar, A.M., Jacob, M.A., Drenthen, G.S., Jansen, J.F., Marques, J.P., Topalis, J., Ingrisch, M., Ricke, J., Leeuw, H.F. de, Duering, M., and Backes, W.H.

Abstract

01 juli 2023, Contains fulltext : 293781.pdf (Publisher’s version ) (Open Access), The acquisition of intravoxel incoherent motion (IVIM) data and diffusion tensor imaging (DTI) data from the brain can be integrated into a single measurement, which offers the possibility to determine orientation-dependent (tensorial) perfusion parameters in addition to established IVIM and DTI parameters. The purpose of this study was to evaluate the feasibility of such a protocol with a clinically feasible scan time below 6 min and to use a model-selection approach to find a set of DTI and IVIM tensor parameters that most adequately describes the acquired data. Diffusion-weighted images of the brain were acquired at 3 T in 20 elderly participants with cerebral small vessel disease using a multiband echoplanar imaging sequence with 15 b-values between 0 and 1000 s/mm(2) and six non-collinear diffusion gradient directions for each b-value. Seven different IVIM-diffusion models with 4 to 14 parameters were implemented, which modeled diffusion and pseudo-diffusion as scalar or tensor quantities. The models were compared with respect to their fitting performance based on the goodness of fit (sum of squared fit residuals, chi(2) ) and their Akaike weights (calculated from the corrected Akaike information criterion). Lowest chi(2) values were found using the model with the largest number of model parameters. However, significantly highest Akaike weights indicating the most appropriate models for the acquired data were found with a nine-parameter IVIM-DTI model (with isotropic perfusion modeling) in normal-appearing white matter (NAWM), and with an 11-parameter model (IVIM-DTI with additional pseudo-diffusion anisotropy) in white matter with hyperintensities (WMH) and in gray matter (GM). The latter model allowed for the additional calculation of the fractional anisotropy of the pseudo-diffusion tensor (with a median value of 0.45 in NAWM, 0.23 in WMH, and 0.36 in GM), which is not accessible with the usually performed IVIM acquisitions based on three orthogonal diffusio

Published
2023

9. Neuroimaging standards for research into small vessel disease-advances since 2013.

Author

Duering, M., Biessels, G.J., Brodtmann, A., Chen, C, Cordonnier, C., Leeuw, F.E. de, Debette, S., Frayne, R., Jouvent, E., Rost, N.S., Telgte, A. ter, Al-Shahi Salman, R., Backes, W.H., Bae, H.J., Brown, R., Chabriat, H., Luca, A. De, DeCarli, C., Dewenter, A., Doubal, F.N., Ewers, M., Field, T.S., Ganesh, A., Greenberg, S., Helmer, K.G., Hilal, S., Jochems, A.C.C., Jokinen, H., Kuijf, H., Lam, B.Y.K., Lebenberg, J., MacIntosh, B.J., Maillard, P., Mok, V.C.T., Pantoni, L., Rudilosso, S., Satizabal, C.L., Schirmer, M.D., Schmidt, R., Smith, C., Staals, J., Thrippleton, M.J., Veluw, S.J. van, Vemuri, P., Wang, Yilong, Werring, D., Zedde, M., Akinyemi, R.O., Brutto, O.H. Del, Markus, H.S., Zhu, Y.C., Smith, E.E., Dichgans, M., Wardlaw, J.M., Duering, M., Biessels, G.J., Brodtmann, A., Chen, C, Cordonnier, C., Leeuw, F.E. de, Debette, S., Frayne, R., Jouvent, E., Rost, N.S., Telgte, A. ter, Al-Shahi Salman, R., Backes, W.H., Bae, H.J., Brown, R., Chabriat, H., Luca, A. De, DeCarli, C., Dewenter, A., Doubal, F.N., Ewers, M., Field, T.S., Ganesh, A., Greenberg, S., Helmer, K.G., Hilal, S., Jochems, A.C.C., Jokinen, H., Kuijf, H., Lam, B.Y.K., Lebenberg, J., MacIntosh, B.J., Maillard, P., Mok, V.C.T., Pantoni, L., Rudilosso, S., Satizabal, C.L., Schirmer, M.D., Schmidt, R., Smith, C., Staals, J., Thrippleton, M.J., Veluw, S.J. van, Vemuri, P., Wang, Yilong, Werring, D., Zedde, M., Akinyemi, R.O., Brutto, O.H. Del, Markus, H.S., Zhu, Y.C., Smith, E.E., Dichgans, M., and Wardlaw, J.M.

Abstract

01 juli 2023, Item does not contain fulltext, Cerebral small vessel disease (SVD) is common during ageing and can present as stroke, cognitive decline, neurobehavioural symptoms, or functional impairment. SVD frequently coexists with neurodegenerative disease, and can exacerbate cognitive and other symptoms and affect activities of daily living. Standards for Reporting Vascular Changes on Neuroimaging 1 (STRIVE-1) categorised and standardised the diverse features of SVD that are visible on structural MRI. Since then, new information on these established SVD markers and novel MRI sequences and imaging features have emerged. As the effect of combined SVD imaging features becomes clearer, a key role for quantitative imaging biomarkers to determine sub-visible tissue damage, subtle abnormalities visible at high-field strength MRI, and lesion-symptom patterns, is also apparent. Together with rapidly emerging machine learning methods, these metrics can more comprehensively capture the effect of SVD on the brain than the structural MRI features alone and serve as intermediary outcomes in clinical trials and future routine practice. Using a similar approach to that adopted in STRIVE-1, we updated the guidance on neuroimaging of vascular changes in studies of ageing and neurodegeneration to create STRIVE-2.

Published
2023

10. Blood-brain barrier leakage hotspots collocating with brain lesions due to sporadic and monogenic small vessel disease.

Author

Rudilosso, S., Stringer, M.S., Thrippleton, M., Chappell, F., Blair, G.W., Jaime Garcia, D., Doubal, F., Hamilton, I., Janssen, E., Kopczak, A., Ingrisch, M., Kerkhofs, D., Backes, W.H., Staals, J., Duering, M., Dichgans, M., Wardlaw, J.M., Rudilosso, S., Stringer, M.S., Thrippleton, M., Chappell, F., Blair, G.W., Jaime Garcia, D., Doubal, F., Hamilton, I., Janssen, E., Kopczak, A., Ingrisch, M., Kerkhofs, D., Backes, W.H., Staals, J., Duering, M., Dichgans, M., and Wardlaw, J.M.

Abstract

01 september 2023, Item does not contain fulltext, Blood-brain barrier (BBB) is known to be impaired in cerebral small vessel disease (SVD), and is measurable by dynamic-contrast enhancement (DCE)-MRI. In a cohort of 69 patients (42 sporadic, 27 monogenic SVD), who underwent 3T MRI, including DCE and cerebrovascular reactivity (CVR) sequences, we assessed the relationship of BBB-leakage hotspots to SVD lesions (lacunes, white matter hyperintensities (WMH), and microbleeds). We defined as hotspots the regions with permeability surface area product highest decile on DCE-derived maps within the white matter. We assessed factors associated with the presence and number of hotspots corresponding to SVD lesions in multivariable regression models adjusted for age, WMH volume, number of lacunes, and SVD type. We identified hotspots at lacune edges in 29/46 (63%) patients with lacunes, within WMH in 26/60 (43%) and at the WMH edges in 34/60 (57%) patients with WMH, and microbleed edges in 4/11 (36%) patients with microbleeds. In adjusted analysis, lower WMH-CVR was associated with presence and number of hotspots at lacune edges, and higher WMH volume with hotspots within WMH and at WMH edges, independently of the SVD type. In conclusion, SVD lesions frequently collocate with high BBB-leakage in patients with sporadic and monogenic forms of SVD.

Published
2023

13. Framework for Clinical Trials in Cerebral Small Vessel Disease (FINESSE): A Review

Author

Markus, H.S., Flier, W.M. van der, Smith, E.E., Bath, P., Biessels, G.J., Briceno, E., Brodtman, A., Chabriat, H., Chen, C, Leeuw, F.E. de, Egle, M., Ganesh, A., Georgakis, M.K., Gottesman, R.F., Kwon, S., Launer, L., Mok, V., O'Brien, J., Ottenhoff, L., Pendlebury, S., Richard, E., Sachdev, P., Schmidt, R., Springer, M., Tiedt, S., Wardlaw, J.M., Verdelho, A., Webb, A., Werring, D., Duering, M., Levine, D., Dichgans, M., Markus, H.S., Flier, W.M. van der, Smith, E.E., Bath, P., Biessels, G.J., Briceno, E., Brodtman, A., Chabriat, H., Chen, C, Leeuw, F.E. de, Egle, M., Ganesh, A., Georgakis, M.K., Gottesman, R.F., Kwon, S., Launer, L., Mok, V., O'Brien, J., Ottenhoff, L., Pendlebury, S., Richard, E., Sachdev, P., Schmidt, R., Springer, M., Tiedt, S., Wardlaw, J.M., Verdelho, A., Webb, A., Werring, D., Duering, M., Levine, D., and Dichgans, M.

Abstract

Item does not contain fulltext, IMPORTANCE: Cerebral small vessel disease (SVD) causes a quarter of strokes and is the most common pathology underlying vascular cognitive impairment and dementia. An important step to developing new treatments is better trial methodology. Disease mechanisms in SVD differ from other stroke etiologies; therefore, treatments need to be evaluated in cohorts in which SVD has been well characterized. Furthermore, SVD itself can be caused by a number of different pathologies, the most common of which are arteriosclerosis and cerebral amyloid angiopathy. To date, there have been few sufficiently powered high-quality randomized clinical trials in SVD, and inconsistent trial methodology has made interpretation of some findings difficult. OBSERVATIONS: To address these issues and develop guidelines for optimizing design of clinical trials in SVD, the Framework for Clinical Trials in Cerebral Small Vessel Disease (FINESSE) was created under the auspices of the International Society of Vascular Behavioral and Cognitive Disorders. Experts in relevant aspects of SVD trial methodology were convened, and a structured Delphi consensus process was used to develop recommendations. Areas in which recommendations were developed included optimal choice of study populations, choice of clinical end points, use of brain imaging as a surrogate outcome measure, use of circulating biomarkers for participant selection and as surrogate markers, novel trial designs, and prioritization of therapeutic agents using genetic data via Mendelian randomization. CONCLUSIONS AND RELEVANCE: The FINESSE provides recommendations for trial design in SVD for which there are currently few effective treatments. However, new insights into understanding disease pathogenesis, particularly from recent genetic studies, provide novel pathways that could be therapeutically targeted. In addition, whether other currently available cardiovascular interventions are specifically effective in SVD, as opposed to other subtypes

Published
2022

14. Systematic validation of structural brain networks in cerebral small vessel disease

Author

Dewenter, A., Gesierich, B., Telgte, A. ter, Wiegertjes, K., Cai, M., Jacob, M.A., Marques, J.P., Norris, D.G., Franzmeier, N., Leeuw, F.E. de, Tuladhar, A.M., Duering, M., Dewenter, A., Gesierich, B., Telgte, A. ter, Wiegertjes, K., Cai, M., Jacob, M.A., Marques, J.P., Norris, D.G., Franzmeier, N., Leeuw, F.E. de, Tuladhar, A.M., and Duering, M.

Abstract

Contains fulltext : 252107.pdf (Publisher’s version ) (Open Access), Cerebral small vessel disease (SVD) is considered a disconnection syndrome, which can be quantified using structural brain network analysis obtained from diffusion MRI. Network analysis is a demanding analysis approach and the added benefit over simpler diffusion MRI analysis is largely unexplored in SVD. In this pre-registered study, we assessed the clinical and technical validity of network analysis in two non-overlapping samples of SVD patients from the RUN DMC study (n = 52 for exploration and longitudinal analysis and n = 105 for validation). We compared two connectome pipelines utilizing single-shell or multi-shell diffusion MRI, while also systematically comparing different node and edge definitions. For clinical validation, we assessed the added benefit of network analysis in explaining processing speed and in detecting short-term disease progression. For technical validation, we determined test-retest repeatability.Our findings in clinical validation show that structural brain networks provide only a small added benefit over simpler global white matter diffusion metrics and do not capture short-term disease progression. Test-retest reliability was excellent for most brain networks. Our findings question the added value of brain network analysis in clinical applications in SVD and highlight the utility of simpler diffusion MRI based markers.

Published
2022

15. Prediction of dementia using diffusion tensor MRI measures: the OPTIMAL collaboration

Author

Egle, M., Hilal, S., Tuladhar, A.M., Pirpamer, L., Hofer, E., Duering, M., Wason, J., Morris, R.G.M., Dichgans, M., Schmidt, R., Tozer, D., Chen, C, Leeuw, F.E. de, Markus, H.S., Egle, M., Hilal, S., Tuladhar, A.M., Pirpamer, L., Hofer, E., Duering, M., Wason, J., Morris, R.G.M., Dichgans, M., Schmidt, R., Tozer, D., Chen, C, Leeuw, F.E. de, and Markus, H.S.

Abstract

Item does not contain fulltext, OBJECTIVES: It has been suggested that diffusion tensor imaging (DTI) measures sensitive to white matter (WM) damage may predict future dementia risk not only in cerebral small vessel disease (SVD), but also in mild cognitive impairment. To determine whether DTI measures were associated with cognition cross-sectionally and predicted future dementia risk across the full range of SVD severity, we established the International OPtimising mulTImodal MRI markers for use as surrogate markers in trials of Vascular Cognitive Impairment due to cerebrAl small vesseL disease collaboration which included six cohorts. METHODS: Among the six cohorts, prospective data with dementia incidences were available for three cohorts. The associations between six different DTI measures and cognition or dementia conversion were tested. The additional contribution to prediction of other MRI markers of SVD was also determined. RESULTS: The DTI measure mean diffusivity (MD) median correlated with cognition in all cohorts, demonstrating the contribution of WM damage to cognition. Adding MD median significantly improved the model fit compared to the clinical risk model alone and further increased in all single-centre SVD cohorts when adding conventional MRI measures. Baseline MD median predicted dementia conversion. In a study with severe SVD (SCANS) change in MD median also predicted dementia conversion. The area under the curve was best when employing a multimodal MRI model using both DTI measures and other MRI measures. CONCLUSIONS: Our results support a central role for WM alterations in dementia pathogenesis in all cohorts. DTI measures such as MD median may be a useful clinical risk predictor. The contribution of other MRI markers varied according to disease severity.

Published
2022

16. Spatial Relation Between White Matter Hyperintensities and Incident Lacunes of Presumed Vascular Origin: A 14-Year Follow-Up Study

Author

Yi, F., Cai, M., Jacob, M.A., Marques, J.P., Norris, D.G., Duering, M., Tuladhar, A.M., Leeuw, F.E. de, Yi, F., Cai, M., Jacob, M.A., Marques, J.P., Norris, D.G., Duering, M., Tuladhar, A.M., and Leeuw, F.E. de

Abstract

Item does not contain fulltext, BACKGROUND: The underlying mechanisms of incident lacunes regarding their spatial distribution remain largely unknown. We investigated the spatial distribution pattern and MRI predictors of incident lacunes in relation to white matter hyperintensity (WMH) over 14 years follow-up in sporadic small vessel disease. METHODS: Five hundred three participants from the ongoing prospective single-center Radboud University Nijmegen Diffusion Tensor and Magnetic resonance Cohort (RUN DMC) were recruited with baseline assessment in 2006 and follow ups in 2011, 2015, and 2020. Three hundred eighty-two participants who underwent at least 2 available brain MRI scans were included. Incident lacunes were systematically identified, and the spatial relationship between incident lacunes located in subcortical white matter and WMH were determined using a visual rating scale. Adjusted multiple logistic regression and linear mixed-effect regression models were used to assess the association between baseline small vessel disease markers, WMH progression, and incident lacunes. Participants with atrial fibrillation were excluded in multivariable analysis. RESULTS: Eighty incident lacunes were identified in 43 patients (mean age 66.5±8.2 years, 37.2% women) during a mean follow-up time of 11.2±3.3 years (incidence rate 10.0/1000 person-year). Sixty percent of incident lacunes were in the white matter, of which 48.9% showed no contact with preexisting WMH. Baseline WMH volume (odds ratio=2.5 [95% CI, 1.6-4.2]) predicted incident lacunes after adjustment for age, sex, and vascular risk factors. WMH progression was associated with incident lacunes independent of age, sex, baseline WMH volume, and vascular risk factors (odds ratio, 3.2 [95% CI, 1.5-6.9]). Baseline WMH volume and progression rate were higher in participants with incident lacunes in contact with preexisting WMH. No difference in vascular risk factors was observed regarding location or relation with preexisting WMH. CONCLUSIONS: The

Published
2022

22. The BDNFVal66Met SNP modulates the association between beta-amyloid and hippocampal disconnection in Alzheimer’s disease

Author

Franzmeier, N, Ren, J, Damm, A, Monté-Rubio, G, Boada, M, Ruiz, A, Ramirez, A, Jessen, F, Düzel, E, Rodríguez Gómez, O, Benzinger, T, Goate, A, Karch, CM, Fagan, AM, McDade, E, Buerger, K, Levin, J, Duering, M, Dichgans, M, Suárez-Calvet, M, Haass, C, Gordon, BA, Lim, YY, Masters, CL, Janowitz, D, Catak, C, Wolfsgruber, S, Wagner, M, Milz, E, Moreno-Grau, S, Teipel, S, Grothe, MJ, Kilimann, I, Rossor, M, Fox, N, Laske, C, Chhatwal, J, Falkai, P, Perneczky, R, Lee, JH, Spottke, A, Boecker, H, Brosseron, F, Fliessbach, K, Heneka, MT, Nestor, P, Peters, O, Fuentes, M, Menne, F, Priller, J, Spruth, EJ, Franke, C, Schneider, A, Westerteicher, C, Speck, O, Wiltfang, J, Bartels, C, Araque Caballero, MÁ, Metzger, C, Bittner, D, Salloway, S, Danek, A, Hassenstab, J, Yakushev, I, Schofield, PR, Morris, JC, Bateman, RJ, Ewers, M, Franzmeier, N, Ren, J, Damm, A, Monté-Rubio, G, Boada, M, Ruiz, A, Ramirez, A, Jessen, F, Düzel, E, Rodríguez Gómez, O, Benzinger, T, Goate, A, Karch, CM, Fagan, AM, McDade, E, Buerger, K, Levin, J, Duering, M, Dichgans, M, Suárez-Calvet, M, Haass, C, Gordon, BA, Lim, YY, Masters, CL, Janowitz, D, Catak, C, Wolfsgruber, S, Wagner, M, Milz, E, Moreno-Grau, S, Teipel, S, Grothe, MJ, Kilimann, I, Rossor, M, Fox, N, Laske, C, Chhatwal, J, Falkai, P, Perneczky, R, Lee, JH, Spottke, A, Boecker, H, Brosseron, F, Fliessbach, K, Heneka, MT, Nestor, P, Peters, O, Fuentes, M, Menne, F, Priller, J, Spruth, EJ, Franke, C, Schneider, A, Westerteicher, C, Speck, O, Wiltfang, J, Bartels, C, Araque Caballero, MÁ, Metzger, C, Bittner, D, Salloway, S, Danek, A, Hassenstab, J, Yakushev, I, Schofield, PR, Morris, JC, Bateman, RJ, and Ewers, M

Abstract

In Alzheimer’s disease (AD), a single-nucleotide polymorphism in the gene encoding brain-derived neurotrophic factor (BDNFVal66Met) is associated with worse impact of primary AD pathology (beta-amyloid, Aβ) on neurodegeneration and cognitive decline, rendering BDNFVal66Met an important modulating factor of cognitive impairment in AD. However, the effect of BDNFVal66Met on functional networks that may underlie cognitive impairment in AD is poorly understood. Using a cross-validation approach, we first explored in subjects with autosomal dominant AD (ADAD) from the Dominantly Inherited Alzheimer Network (DIAN) the effect of BDNFVal66Met on resting-state fMRI assessed functional networks. In seed-based connectivity analysis of six major large-scale networks, we found a stronger decrease of hippocampus (seed) to medial-frontal connectivity in the BDNFVal66Met carriers compared to BDNFVal homozogytes. BDNFVal66Met was not associated with connectivity in any other networks. Next, we tested whether the finding of more pronounced decrease in hippocampal-medial-frontal connectivity in BDNFVal66Met could be also found in elderly subjects with sporadically occurring Aβ, including a group with subjective cognitive decline (N = 149, FACEHBI study) and a group ranging from preclinical to AD dementia (N = 114, DELCODE study). In both of these independently recruited groups, BDNFVal66Met was associated with a stronger effect of more abnormal Aβ-levels (assessed by biofluid-assay or amyloid-PET) on hippocampal-medial-frontal connectivity decreases, controlled for hippocampus volume and other confounds. Lower hippocampal-medial-frontal connectivity was associated with lower global cognitive performance in the DIAN and DELCODE studies. Together these results suggest that BDNFVal66Met is selectively associated with a higher vulnerability of hippocampus-frontal connectivity to primary AD pathology, resulting in greater AD-related cognitive impairment.

Published
2021

23. Assessing cortical cerebral microinfarcts on iron-sensitive MRI in cerebral small vessel disease

Author

Wiegertjes, K., Chan, K., Telgte, A. ter, Gesierich, B., Norris, D.G., Klijn, C.J.M., Duering, M., Tuladhar, A.M., Marques, J.P., Leeuw, H.F. de, Wiegertjes, K., Chan, K., Telgte, A. ter, Gesierich, B., Norris, D.G., Klijn, C.J.M., Duering, M., Tuladhar, A.M., Marques, J.P., and Leeuw, H.F. de

Abstract

Item does not contain fulltext, Recent studies suggest that a subset of cortical microinfarcts may be identifiable on T2* but invisible on T1 and T2 follow-up images. We aimed to investigate whether cortical microinfarcts are associated with iron accumulation after the acute stage. The RUN DMC - InTENse study is a serial MRI study including individuals with cerebral small vessel disease (SVD). 54 Participants underwent 10 monthly 3 T MRIs, including diffusion-weighted imaging, quantitative R1 (=1/T1), R2 (=1/T2), and R2* (=1/T2*) mapping, from which MRI parameters within areas corresponding to microinfarcts and control region of interests (ROIs) were retrieved within 16 participants. Finally, we compared pre- and post-lesional values with repeated measures ANOVA and post-hoc paired t-tests using the mean difference between lesion and control ROI values. We observed 21 acute cortical microinfarcts in 7 of the 54 participants (median age 69 years [IQR 66-74], 63% male). R2* maps demonstrated an increase in R2* values at the moment of the last available follow-up MRI (median [IQR], 5 [5-14] weeks after infarction) relative to prelesional values (p = .08), indicative of iron accumulation. Our data suggest that cortical microinfarcts are associated with increased R2* values, indicative of iron accumulation, possibly due to microhemorrhages, neuroinflammation or neurodegeneration, awaiting histopathological verification.

Published
2021

24. Peak Width of Skeletonized Mean Diffusivity as Neuroimaging Biomarker in Cerebral Amyloid Angiopathy

Author

Raposo, N., primary, Zanon Zotin, M.C., additional, Schoemaker, D., additional, Xiong, L., additional, Fotiadis, P., additional, Charidimou, A., additional, Pasi, M., additional, Boulouis, G., additional, Schwab, K., additional, Schirmer, M.D., additional, Etherton, M.R., additional, Gurol, M.E., additional, Greenberg, S.M., additional, Duering, M., additional, and Viswanathan, A., additional

Published
2021
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25. Temporal dynamics of cortical microinfarcts in cerebral small vessel disease

Author

Telgte, A. ter, Wiegertjes, K., Gesierich, Benno, Baskaran, Brendon Sri, Marques, J.P., Kuijf, H.J., Norris, D.G., Tuladhar, A.M., Duering, M., Leeuw, F.E. de, Telgte, A. ter, Wiegertjes, K., Gesierich, Benno, Baskaran, Brendon Sri, Marques, J.P., Kuijf, H.J., Norris, D.G., Tuladhar, A.M., Duering, M., and Leeuw, F.E. de

Abstract

Contains fulltext : 219820.pdf (Publisher’s version ) (Closed access)

Published
2020

26. Brain atrophy in cerebral small vessel diseases: Extent, consequences, technical limitations and perspectives: The HARNESS initiative

Author

Guio, F. De, Duering, M., Fazekas, F., Leeuw, F.E. de, Greenberg, S.M., Pantoni, L., Aghetti, A., Smith, E.E., Wardlaw, J., Jouvent, E., Guio, F. De, Duering, M., Fazekas, F., Leeuw, F.E. de, Greenberg, S.M., Pantoni, L., Aghetti, A., Smith, E.E., Wardlaw, J., and Jouvent, E.

Abstract

Contains fulltext : 218849.pdf (Publisher’s version ) (Closed access)

Published
2020

27. Histopathology of diffusion-weighted imaging-positive lesions in cerebral amyloid angiopathy

Author

Telgte, A. ter, Scherlek, A.A., Reijmer, Y.D., Kouwe, A.J. van der, Harten, T. van, Duering, M., Bacskai, B.J., Leeuw, F.E. de, Frosch, M.P., Greenberg, S.M., Veluw, S.J. van, Telgte, A. ter, Scherlek, A.A., Reijmer, Y.D., Kouwe, A.J. van der, Harten, T. van, Duering, M., Bacskai, B.J., Leeuw, F.E. de, Frosch, M.P., Greenberg, S.M., and Veluw, S.J. van

Abstract

Contains fulltext : 220659.pdf (Publisher’s version ) (Closed access), Small subclinical hyperintense lesions are frequently encountered on brain diffusion-weighted imaging (DWI) scans of patients with cerebral amyloid angiopathy (CAA). Interpretation of these DWI+ lesions, however, has been limited by absence of histopathological examination. We aimed to determine whether DWI+ lesions represent acute microinfarcts on histopathology in brains with advanced CAA, using a combined in vivo MRI-ex vivo MRI-histopathology approach. We first investigated the histopathology of a punctate cortical DWI+ lesion observed on clinical in vivo MRI 7 days prior to death in a CAA case. Subsequently, we assessed the use of ex vivo DWI to identify similar punctate cortical lesions post-mortem. Intact formalin-fixed hemispheres of 12 consecutive cases with CAA and three non-CAA controls were subjected to high-resolution 3 T ex vivo DWI and T2 imaging. Small cortical lesions were classified as either DWI+/T2+ or DWI-/T2+. A representative subset of lesions from three CAA cases was selected for detailed histopathological examination. The DWI+ lesion observed on in vivo MRI could be matched to an area with evidence of recent ischemia on histopathology. Ex vivo MRI of the intact hemispheres revealed a total of 130 DWI+/T2+ lesions in 10/12 CAA cases, but none in controls (p = 0.022). DWI+/T2+ lesions examined histopathologically proved to be acute microinfarcts (classification accuracy 100%), characterized by presence of eosinophilic neurons on hematoxylin and eosin and absence of reactive astrocytes on glial fibrillary acidic protein-stained sections. In conclusion, we suggest that small DWI+ lesions in CAA represent acute microinfarcts. Furthermore, our findings support the use of ex vivo DWI as a method to detect acute microinfarcts post-mortem, which may benefit future histopathological investigations on the etiology of microinfarcts.

Published
2020

28. Cellular and Molecular Probing of Intact Human Organs.

Author

Wolf E., Lipfert J., Puelles V.G., Bechmann I., Erturk A., Zhao S., Todorov M.I., Cai R., Maskari R.A., Steinke H., Kemter E., Mai H., Rong Z., Warmer M., Stanic K., Schoppe O., Paetzold J.C., Gesierich B., Wong M.N., Huber T.B., Duering M., Bruns O.T., Menze B., Wolf E., Lipfert J., Puelles V.G., Bechmann I., Erturk A., Zhao S., Todorov M.I., Cai R., Maskari R.A., Steinke H., Kemter E., Mai H., Rong Z., Warmer M., Stanic K., Schoppe O., Paetzold J.C., Gesierich B., Wong M.N., Huber T.B., Duering M., Bruns O.T., and Menze B.

Abstract

Zhao et al. present an approach for intact human organ mapping that uses a new tissue permeabilization method to clear and deeply label whole organs followed by light-sheet microscopy imaging and a deep learning-based pipeline for 3D reconstruction and data analysis. Optical tissue transparency permits scalable cellular and molecular investigation of complex tissues in 3D. Adult human organs are particularly challenging to render transparent because of the accumulation of dense and sturdy molecules in decades-aged tissues. To overcome these challenges, we developed SHANEL, a method based on a new tissue permeabilization approach to clear and label stiff human organs. We used SHANEL to render the intact adult human brain and kidney transparent and perform 3D histology with antibodies and dyes in centimeters-depth. Thereby, we revealed structural details of the intact human eye, human thyroid, human kidney, and transgenic pig pancreas at the cellular resolution. Furthermore, we developed a deep learning pipeline to analyze millions of cells in cleared human brain tissues within hours with standard lab computers. Overall, SHANEL is a robust and unbiased technology to chart the cellular and molecular architecture of large intact mammalian organs.Copyright © 2020 Elsevier Inc.

Published
2020

29. Age-Related Changes of Peak Width Skeletonized Mean Diffusivity (PSMD) Across the Adult Lifespan: A Multi-Cohort Study

Author

Beaudet, G, Tsuchida, A, Petit, L, Tzourio, C, Caspers, S, Schreiber, J, Pausova, Z, Patel, Y, Paus, T, Schmidt, R, Pirpamer, L, Sachdev, PS, Brodaty, H, Kochan, N, Trollor, J, Wen, W, Armstrong, NJ, Deary, IJ, Bastin, ME, Wardlaw, JM, Munõz Maniega, S, Witte, AV, Villringer, A, Duering, M, Debette, S, Mazoyer, B, Beaudet, G, Tsuchida, A, Petit, L, Tzourio, C, Caspers, S, Schreiber, J, Pausova, Z, Patel, Y, Paus, T, Schmidt, R, Pirpamer, L, Sachdev, PS, Brodaty, H, Kochan, N, Trollor, J, Wen, W, Armstrong, NJ, Deary, IJ, Bastin, ME, Wardlaw, JM, Munõz Maniega, S, Witte, AV, Villringer, A, Duering, M, Debette, S, and Mazoyer, B

Abstract

Parameters of water diffusion in white matter derived from diffusion-weighted imaging (DWI), such as fractional anisotropy (FA), mean, axial, and radial diffusivity (MD, AD, and RD), and more recently, peak width of skeletonized mean diffusivity (PSMD), have been proposed as potential markers of normal and pathological brain ageing. However, their relative evolution over the entire adult lifespan in healthy individuals remains partly unknown during early and late adulthood, and particularly for the PSMD index. Here, we gathered and analyzed cross-sectional diffusion tensor imaging (DTI) data from 10 population-based cohort studies in order to establish the time course of white matter water diffusion phenotypes from post-adolescence to late adulthood. DTI data were obtained from a total of 20,005 individuals aged 18.1 to 92.6 years and analyzed with the same pipeline for computing skeletonized DTI metrics from DTI maps. For each individual, MD, AD, RD, and FA mean values were computed over their FA volume skeleton, PSMD being calculated as the 90% peak width of the MD values distribution across the FA skeleton. Mean values of each DTI metric were found to strongly vary across cohorts, most likely due to major differences in DWI acquisition protocols as well as pre-processing and DTI model fitting. However, age effects on each DTI metric were found to be highly consistent across cohorts. RD, MD, and AD variations with age exhibited the same U-shape pattern, first slowly decreasing during post-adolescence until the age of 30, 40, and 50 years, respectively, then progressively increasing until late life. FA showed a reverse profile, initially increasing then continuously decreasing, slowly until the 70s, then sharply declining thereafter. By contrast, PSMD constantly increased, first slowly until the 60s, then more sharply. These results demonstrate that, in the general population, age affects PSMD in a manner different from that of other DTI metrics. The constant incre

Published
2020

30. Predicting sporadic Alzheimer's disease progression via inherited Alzheimer's disease-informed machine-learning

Author

Franzmeier, N, Koutsouleris, N, Benzinger, T, Goate, A, Karch, CM, Fagan, AM, McDade, E, Duering, M, Dichgans, M, Levin, J, Gordon, BA, Lim, YY, Masters, CL, Rossor, M, Fox, NC, O'Connor, A, Chhatwal, J, Salloway, S, Danek, A, Hassenstab, J, Schofield, PR, Morris, JC, Bateman, RJ, Ewers, M, Franzmeier, N, Koutsouleris, N, Benzinger, T, Goate, A, Karch, CM, Fagan, AM, McDade, E, Duering, M, Dichgans, M, Levin, J, Gordon, BA, Lim, YY, Masters, CL, Rossor, M, Fox, NC, O'Connor, A, Chhatwal, J, Salloway, S, Danek, A, Hassenstab, J, Schofield, PR, Morris, JC, Bateman, RJ, and Ewers, M

Abstract

INTRODUCTION: Developing cross-validated multi-biomarker models for the prediction of the rate of cognitive decline in Alzheimer's disease (AD) is a critical yet unmet clinical challenge. METHODS: We applied support vector regression to AD biomarkers derived from cerebrospinal fluid, structural magnetic resonance imaging (MRI), amyloid-PET and fluorodeoxyglucose positron-emission tomography (FDG-PET) to predict rates of cognitive decline. Prediction models were trained in autosomal-dominant Alzheimer's disease (ADAD, n = 121) and subsequently cross-validated in sporadic prodromal AD (n = 216). The sample size needed to detect treatment effects when using model-based risk enrichment was estimated. RESULTS: A model combining all biomarker modalities and established in ADAD predicted the 4-year rate of decline in global cognition (R2 = 24%) and memory (R2 = 25%) in sporadic AD. Model-based risk-enrichment reduced the sample size required for detecting simulated intervention effects by 50%-75%. DISCUSSION: Our independently validated machine-learning model predicted cognitive decline in sporadic prodromal AD and may substantially reduce sample size needed in clinical trials in AD.

Published
2020

31. Age-Related changes of Peak Width Skeletonized Mean Diffusivity (PSMD) across the adult lifespan: A Multi-Cohort Study

Author

Beaudet, G., Tsuchida, A., Petit, L., Tzourio, C., Caspers, S., Schreiber, J., Pausova, Z., Patel, Y., Paus, T., Schmidt, R., Pirpamer, L., Sachdev, P.S., Brodaty, H., Kochan, N., Trollor, J., Wen, W., Armstrong, N.J., Deary, I.J., Bastin, M.E., Wardlaw, J.M., Munoz Maniega, S., Witte, A.V., Villringer, A., Duering, M., Debette, S., Mazoyer, B., Beaudet, G., Tsuchida, A., Petit, L., Tzourio, C., Caspers, S., Schreiber, J., Pausova, Z., Patel, Y., Paus, T., Schmidt, R., Pirpamer, L., Sachdev, P.S., Brodaty, H., Kochan, N., Trollor, J., Wen, W., Armstrong, N.J., Deary, I.J., Bastin, M.E., Wardlaw, J.M., Munoz Maniega, S., Witte, A.V., Villringer, A., Duering, M., Debette, S., and Mazoyer, B.

Abstract

Parameters of water diffusion in white matter derived from diffusion-weighted imaging (DWI), such as fractional anisotropy (FA), mean, axial, and radial diffusivity (MD, AD, and RD), and more recently, peak width of skeletonized mean diffusivity (PSMD), have been proposed as potential markers of normal and pathological brain ageing. However, their relative evolution over the entire adult lifespan in healthy individuals remains partly unknown during early and late adulthood, and particularly for the PSMD index. Here, we gathered and analyzed cross-sectional diffusion tensor imaging (DTI) data from 10 population-based cohort studies in order to establish the time course of white matter water diffusion phenotypes from post-adolescence to late adulthood. DTI data were obtained from a total of 20,005 individuals aged 18.1 to 92.6 years and analyzed with the same pipeline for computing skeletonized DTI metrics from DTI maps. For each individual, MD, AD, RD, and FA mean values were computed over their FA volume skeleton, PSMD being calculated as the 90% peak width of the MD values distribution across the FA skeleton. Mean values of each DTI metric were found to strongly vary across cohorts, most likely due to major differences in DWI acquisition protocols as well as pre-processing and DTI model fitting. However, age effects on each DTI metric were found to be highly consistent across cohorts. RD, MD, and AD variations with age exhibited the same U-shape pattern, first slowly decreasing during post-adolescence until the age of 30, 40, and 50 years, respectively, then progressively increasing until late life. FA showed a reverse profile, initially increasing then continuously decreasing, slowly until the 70s, then sharply declining thereafter. By contrast, PSMD constantly increased, first slowly until the 60s, then more sharply. These results demonstrate that, in the general population, age affects PSMD in a manner different from that of other DTI metrics. The constant incre

Published
2020

35. Contribution of acute infarcts to cerebral small vessel disease progression

Author

Telgte, A. ter, Wiegertjes, K., Gesierich, B., Marques, J.P., Huebner, M., Klerk, J.J. de, Schreuder, F.H.B.M., Araque Caballero, M.A., Kuijf, H.J., Norris, D.G., Klijn, C.J.M., Dichgans, M., Tuladhar, A.M., Duering, M., Leeuw, F.E. de, Telgte, A. ter, Wiegertjes, K., Gesierich, B., Marques, J.P., Huebner, M., Klerk, J.J. de, Schreuder, F.H.B.M., Araque Caballero, M.A., Kuijf, H.J., Norris, D.G., Klijn, C.J.M., Dichgans, M., Tuladhar, A.M., Duering, M., and Leeuw, F.E. de

Abstract

Contains fulltext : 208985.pdf (publisher's version ) (Closed access), OBJECTIVE: To determine the contribution of acute infarcts, evidenced by diffusion-weighted imaging positive (DWI+) lesions, to progression of white matter hyperintensities (WMH) and other cerebral small vessel disease (SVD) markers. METHODS: We performed monthly 3T magnetic resonance imaging (MRI) for 10 consecutive months in 54 elderly individuals with SVD. MRI included high-resolution multishell DWI, and 3-dimensional fluid-attenuated inversion recovery, T1, and susceptibility-weighted imaging. We determined DWI+ lesion evolution, WMH progression rate (ml/mo), and number of incident lacunes and microbleeds, and calculated for each marker the proportion of progression explained by DWI+ lesions. RESULTS: We identified 39 DWI+ lesions on 21 of 472 DWI scans in 9 of 54 subjects. Of the 36 DWI+ lesions with follow-up MRI, 2 evolved into WMH, 4 evolved into a lacune (3 with cavity <3mm), 3 evolved into a microbleed, and 27 were not detectable on follow-up. WMH volume increased at a median rate of 0.027 ml/mo (interquartile range = 0.005-0.073), but was not significantly higher in subjects with DWI+ lesions compared to those without (p = 0.195). Of the 2 DWI+ lesions evolving into WMH on follow-up, one explained 23% of the total WMH volume increase in one subject, whereas the WMH regressed in the other subject. DWI+ lesions preceded 4 of 5 incident lacunes and 3 of 10 incident microbleeds. INTERPRETATION: DWI+ lesions explain only a small proportion of the total WMH progression. Hence, WMH progression seems to be mostly driven by factors other than acute infarcts. DWI+ lesions explain the majority of incident lacunes and small cavities, and almost one-third of incident microbleeds, confirming that WMH, lacunes, and microbleeds, although heterogeneous on MRI, can have a common initial appearance on MRI. ANN NEUROL 2019;86:582-592.

Published
2019

36. Association of Apolipoprotein E With Intracerebral Hemorrhage Risk by Race/Ethnicity A Meta-analysis

Author

Marini, S, Crawford, K, Morotti, A, Lee, MJ, Pezzini, A, Moomaw, CJ, Flaherty, ML, Montaner, J, Roquer, J, Jimenez-Conde, J, Giralt-Steinhauer, E, Elosua, R, Cuadrado-Godia, E, Soriano-Tarraga, C, Slowik, A, Jagiella, JM, Pera, J, Urbanik, A, Pichler, A, Hansen, BM, McCauley, JL, Tirschwell, DL, Selim, M, Brown, DL, Silliman, SL, Worrall, BB, Meschia, JF, Kidwell, CS, Testai, FD, Kittner, SJ, Schmidt, H, Enzinger, C, Deary, LJ, Rannikmae, K, Samarasekera, N, Salman, RA-S, Sudlow, CL, Klijn, CJM, van Nieuwenhuizen, KM, Fernandez-Cadenas, I, Delgado, P, Nonving, B, Lindgren, A, Goldstein, JN, Viswanathan, A, Greenberg, SM, Falcone, GJ, Biffi, A, Langefeld, CD, Woo, D, Rosand, J, Anderson, CD, Smoller, S, Sorkin, J, Wang, X, Pikula, A, Wolf, P, Debette, S, Seshadri, S, de Bakker, P, Chasman, D, Rexrode, K, Chen, I, Rotter, J, Luke, M, Sale, M, Lee, T-H, Chang, K-C, Elkind, M, Goldstein, L, James, ML, Breteler, M, O'Donnell, C, Leys, D, Carty, C, Kidwell, C, Olesen, J, Sharma, P, Rich, S, Tatlisumak, T, Happola, O, Bijlenga, P, Soriano, C, Giralt, E, Cotlarcius, L, Hardy, J, Korostynski, M, Boncoraglio, G, Ballabio, E, Parati, E, Mateusz, A, Dziedzic, T, Jagiella, J, Gasowski, J, Wnuk, M, Olszanecki, R, Juchniewicz, KJ, Levi, C, Nyquist, P, Cendes, I, Cabral, N, Franca, P, Goncalves, A, Keller, L, Crisby, M, Kostulas, K, Lennnnens, R, Ahmadi, K, Opherk, C, Duering, M, Dichgans, M, Malik, R, Gonik, M, Staals, J, Melander, O, Burri, P, Sadr-Nabavi, A, Romero, J, Anderson, C, Falcone, G, Brouwers, B, Rost, N, Du, R, Kourkoulis, C, Battey, T, Lubitz, S, Mueller-Myhsok, B, Meschia, J, Brott, T, Pare, G, Schmidt, R, Seiler, S, Blanton, S, Yamada, Y, Bersano, A, Rundek, T, Sacco, R, Chan, Y-FY, Gschwendtner, A, Deng, Z, Barr, T, Gwinn, K, Corriveau, R, Singleton, A, Waddy, S, Launer, L, Chen, C, Le, KE, Lee, WL, Tan, EK, Olugbodi, A, Rothwell, P, Schilling, S, Mok, V, Lebedeva, E, Jem, C, Jood, K, Olsson, S, Kim, H, Lee, C, Kilarski, L, Markus, H, Peycke, J, Bevan, S, Sheu, W, Chiou, HY, Chern, J, Giraldo, E, Taqi, M, Jain, V, Lam, O, Howard, G, Kittner, S, Mitchell, B, Cole, J, O'Connell, J, Milewicz, D, Illoh, K, Worrall, B, Stine, C, Karaszewski, B, Werring, D, Sofat, R, Smalley, J, Hansen, B, Norrving, B, Smith, G, Martin, JJ, Thijs, V, Klijn, K, van't Hof, F, Algra, A, Macleod, M, Perry, R, Arnett, D, Padovani, A, Cramer, S, Fisher, M, Saleheen, D, Broderick, J, Kissela, B, Doney, A, Sudlow, C, Silliman, S, McDonough, C, Walters, M, Pedersen, A, Nakagawa, K, Chang, C, Dobbins, M, McArdle, P, Chang, Y-C, Brown, R, Brown, D, Holliday, E, Kalaria, R, Maguire, J, Hunter, J, Attia, J, Farrall, M, Giese, A-K, Fomage, M, Majersik, J, Cushman, M, Keene, K, Bennett, S, Tirschwell, D, Psaty, B, Reiner, A, Longstreth, W, Spence, D, Langefeld, C, Bushnell, C, Heitsch, L, Lee, J-M, Sheth, K, Marini, S, Crawford, K, Morotti, A, Lee, MJ, Pezzini, A, Moomaw, CJ, Flaherty, ML, Montaner, J, Roquer, J, Jimenez-Conde, J, Giralt-Steinhauer, E, Elosua, R, Cuadrado-Godia, E, Soriano-Tarraga, C, Slowik, A, Jagiella, JM, Pera, J, Urbanik, A, Pichler, A, Hansen, BM, McCauley, JL, Tirschwell, DL, Selim, M, Brown, DL, Silliman, SL, Worrall, BB, Meschia, JF, Kidwell, CS, Testai, FD, Kittner, SJ, Schmidt, H, Enzinger, C, Deary, LJ, Rannikmae, K, Samarasekera, N, Salman, RA-S, Sudlow, CL, Klijn, CJM, van Nieuwenhuizen, KM, Fernandez-Cadenas, I, Delgado, P, Nonving, B, Lindgren, A, Goldstein, JN, Viswanathan, A, Greenberg, SM, Falcone, GJ, Biffi, A, Langefeld, CD, Woo, D, Rosand, J, Anderson, CD, Smoller, S, Sorkin, J, Wang, X, Pikula, A, Wolf, P, Debette, S, Seshadri, S, de Bakker, P, Chasman, D, Rexrode, K, Chen, I, Rotter, J, Luke, M, Sale, M, Lee, T-H, Chang, K-C, Elkind, M, Goldstein, L, James, ML, Breteler, M, O'Donnell, C, Leys, D, Carty, C, Kidwell, C, Olesen, J, Sharma, P, Rich, S, Tatlisumak, T, Happola, O, Bijlenga, P, Soriano, C, Giralt, E, Cotlarcius, L, Hardy, J, Korostynski, M, Boncoraglio, G, Ballabio, E, Parati, E, Mateusz, A, Dziedzic, T, Jagiella, J, Gasowski, J, Wnuk, M, Olszanecki, R, Juchniewicz, KJ, Levi, C, Nyquist, P, Cendes, I, Cabral, N, Franca, P, Goncalves, A, Keller, L, Crisby, M, Kostulas, K, Lennnnens, R, Ahmadi, K, Opherk, C, Duering, M, Dichgans, M, Malik, R, Gonik, M, Staals, J, Melander, O, Burri, P, Sadr-Nabavi, A, Romero, J, Anderson, C, Falcone, G, Brouwers, B, Rost, N, Du, R, Kourkoulis, C, Battey, T, Lubitz, S, Mueller-Myhsok, B, Meschia, J, Brott, T, Pare, G, Schmidt, R, Seiler, S, Blanton, S, Yamada, Y, Bersano, A, Rundek, T, Sacco, R, Chan, Y-FY, Gschwendtner, A, Deng, Z, Barr, T, Gwinn, K, Corriveau, R, Singleton, A, Waddy, S, Launer, L, Chen, C, Le, KE, Lee, WL, Tan, EK, Olugbodi, A, Rothwell, P, Schilling, S, Mok, V, Lebedeva, E, Jem, C, Jood, K, Olsson, S, Kim, H, Lee, C, Kilarski, L, Markus, H, Peycke, J, Bevan, S, Sheu, W, Chiou, HY, Chern, J, Giraldo, E, Taqi, M, Jain, V, Lam, O, Howard, G, Kittner, S, Mitchell, B, Cole, J, O'Connell, J, Milewicz, D, Illoh, K, Worrall, B, Stine, C, Karaszewski, B, Werring, D, Sofat, R, Smalley, J, Hansen, B, Norrving, B, Smith, G, Martin, JJ, Thijs, V, Klijn, K, van't Hof, F, Algra, A, Macleod, M, Perry, R, Arnett, D, Padovani, A, Cramer, S, Fisher, M, Saleheen, D, Broderick, J, Kissela, B, Doney, A, Sudlow, C, Silliman, S, McDonough, C, Walters, M, Pedersen, A, Nakagawa, K, Chang, C, Dobbins, M, McArdle, P, Chang, Y-C, Brown, R, Brown, D, Holliday, E, Kalaria, R, Maguire, J, Hunter, J, Attia, J, Farrall, M, Giese, A-K, Fomage, M, Majersik, J, Cushman, M, Keene, K, Bennett, S, Tirschwell, D, Psaty, B, Reiner, A, Longstreth, W, Spence, D, Langefeld, C, Bushnell, C, Heitsch, L, Lee, J-M, and Sheth, K

Published
2019

38. Serum neurofilament light chain levels are related to small vessel disease burden

Author

Duering, M., Konieczny, Marek J., Tiedt, Steffen, Baykara, E., Tuladhar, A.M., Leijsen, E.M.C. van, Leeuw, F.E. de, Peters, N.C., Duering, M., Konieczny, Marek J., Tiedt, Steffen, Baykara, E., Tuladhar, A.M., Leijsen, E.M.C. van, Leeuw, F.E. de, and Peters, N.C.

Abstract

Contains fulltext : 193410.pdf (publisher's version ) (Open Access)

Published
2018

39. Free water determines diffusion alterations and clinical status in cerebral small vessel disease

Author

Duering, M., Finsterwalder, Sofia, Baykara, E., Tuladhar, A.M., Gesierich, B., Konieczny, Marek J., Leeuw, F.E. de, Pasternak, Ofer, Dichgans, M., Duering, M., Finsterwalder, Sofia, Baykara, E., Tuladhar, A.M., Gesierich, B., Konieczny, Marek J., Leeuw, F.E. de, Pasternak, Ofer, and Dichgans, M.

Abstract

Contains fulltext : 192607.pdf (publisher's version ) (Closed access)

Published
2018

40. White matter diffusion alterations precede symptom onset in autosomal dominant Alzheimer's disease

Author

Caballero, MÁA, Suárez-Calvet, M, Duering, M, Franzmeier, N, Benzinger, T, Fagan, AM, Bateman, RJ, Jack, CR, Levin, J, Dichgans, M, Jucker, M, Karch, C, Masters, CL, Morris, JC, Weiner, M, Rossor, M, Fox, NC, Lee, JH, Salloway, S, Danek, A, Goate, A, Yakushev, I, Hassenstab, J, Schofield, PR, Haass, C, Ewers, M, Caballero, MÁA, Suárez-Calvet, M, Duering, M, Franzmeier, N, Benzinger, T, Fagan, AM, Bateman, RJ, Jack, CR, Levin, J, Dichgans, M, Jucker, M, Karch, C, Masters, CL, Morris, JC, Weiner, M, Rossor, M, Fox, NC, Lee, JH, Salloway, S, Danek, A, Goate, A, Yakushev, I, Hassenstab, J, Schofield, PR, Haass, C, and Ewers, M

Abstract

White matter alterations are present in the majority of patients with Alzheimer's disease type dementia. However, the spatiotemporal pattern of white matter changes preceding dementia symptoms in Alzheimer's disease remains unclear, largely due to the inherent diagnostic uncertainty in the preclinical phase and increased risk of confounding age-related vascular disease and stroke in late-onset Alzheimer's disease. In early-onset autosomal-dominantly inherited Alzheimer's disease, participants are destined to develop dementia, which provides the opportunity to assess brain changes years before the onset of symptoms, and in the absence of ageing-related vascular disease. Here, we assessed mean diffusivity alterations in the white matter in 64 mutation carriers compared to 45 non-carrier family non-carriers. Using tract-based spatial statistics, we mapped the interaction of mutation status by estimated years from symptom onset on mean diffusivity. For major atlas-derived fibre tracts, we determined the earliest time point at which abnormal mean diffusivity changes in the mutation carriers were detectable. Lastly, we assessed the association between mean diffusivity and cerebrospinal fluid biomarkers of amyloid, tau, phosphorylated-tau, and soluble TREM2, i.e. a marker of microglia activity. Results showed a significant interaction of mutations status by estimated years from symptom onset, i.e. a stronger increase of mean diffusivity, within the posterior parietal and medial frontal white matter in mutation carriers compared with non-carriers. The earliest increase of mean diffusivity was observed in the forceps major, forceps minor and long projecting fibres-many connecting default mode network regions-between 5 to 10 years before estimated symptom onset. Higher mean diffusivity in fibre tracts was associated with lower grey matter volume in the tracts' projection zones. Global mean diffusivity was correlated with lower cerebrospinal fluid levels of amyloid-β 1-42 but

Published
2018

41. Left frontal hub connectivity delays cognitive impairment in autosomal-dominant and sporadic Alzheimer's disease

Author

Franzmeier, N, Duezel, E, Jessen, F, Buerger, K, Levin, J, Duering, M, Dichgans, M, Haass, C, Suarez-Calvet, M, Fagan, AM, Paumier, K, Benzinger, T, Masters, CL, Morris, JC, Perneczky, R, Janowitz, D, Catak, C, Wolfsgruber, S, Wagner, M, Teipel, S, Kilimann, I, Ramirez, A, Rossor, M, Jucker, M, Chhatwal, J, Spottke, A, Boecker, H, Brosseron, F, Falkai, P, Fliessbach, K, Heneka, MT, Laske, C, Nestor, P, Peters, O, Fuentes, M, Menne, F, Priller, J, Spruth, EJ, Franke, C, Schneider, A, Kofler, B, Westerteicher, C, Speck, O, Wiltfang, J, Bartels, C, Caballero, MAA, Metzger, C, Bittner, D, Weiner, M, Lee, J-H, Salloway, S, Danek, A, Goate, A, Schofield, PR, Bateman, RJ, Ewers, M, Franzmeier, N, Duezel, E, Jessen, F, Buerger, K, Levin, J, Duering, M, Dichgans, M, Haass, C, Suarez-Calvet, M, Fagan, AM, Paumier, K, Benzinger, T, Masters, CL, Morris, JC, Perneczky, R, Janowitz, D, Catak, C, Wolfsgruber, S, Wagner, M, Teipel, S, Kilimann, I, Ramirez, A, Rossor, M, Jucker, M, Chhatwal, J, Spottke, A, Boecker, H, Brosseron, F, Falkai, P, Fliessbach, K, Heneka, MT, Laske, C, Nestor, P, Peters, O, Fuentes, M, Menne, F, Priller, J, Spruth, EJ, Franke, C, Schneider, A, Kofler, B, Westerteicher, C, Speck, O, Wiltfang, J, Bartels, C, Caballero, MAA, Metzger, C, Bittner, D, Weiner, M, Lee, J-H, Salloway, S, Danek, A, Goate, A, Schofield, PR, Bateman, RJ, and Ewers, M

Abstract

Patients with Alzheimer's disease vary in their ability to sustain cognitive abilities in the presence of brain pathology. A major open question is which brain mechanisms may support higher reserve capacity, i.e. relatively high cognitive performance at a given level of Alzheimer's pathology. Higher functional MRI-assessed functional connectivity of a hub in the left frontal cortex is a core candidate brain mechanism underlying reserve as it is associated with education (i.e. a protective factor often associated with higher reserve) and attenuated cognitive impairment in prodromal Alzheimer's disease. However, no study has yet assessed whether such hub connectivity of the left frontal cortex supports reserve throughout the evolution of pathological brain changes in Alzheimer's disease, including the presymptomatic stage when cognitive decline is subtle. To address this research gap, we obtained cross-sectional resting state functional MRI in 74 participants with autosomal dominant Alzheimer's disease, 55 controls from the Dominantly Inherited Alzheimer's Network and 75 amyloid-positive elderly participants, as well as 41 amyloid-negative cognitively normal elderly subjects from the German Center of Neurodegenerative Diseases multicentre study on biomarkers in sporadic Alzheimer's disease. For each participant, global left frontal cortex connectivity was computed as the average resting state functional connectivity between the left frontal cortex (seed) and each voxel in the grey matter. As a marker of disease stage, we applied estimated years from symptom onset in autosomal dominantly inherited Alzheimer's disease and cerebrospinal fluid tau levels in sporadic Alzheimer's disease cases. In both autosomal dominant and sporadic Alzheimer's disease patients, higher levels of left frontal cortex connectivity were correlated with greater education. For autosomal dominant Alzheimer's disease, a significant left frontal cortex connectivity × estimated years of onset intera

Published
2018

42. Atrial fibrillation genetic risk differentiates cardioembolic stroke from other stroke subtypes

Author

Pulit, SL, Weng, L-C, McArdle, PF, Trinquart, L, Choi, SH, Mitchell, BD, Rosand, J, de Bakker, PIW, Benjamin, EJ, Ellinor, PT, Kittner, SJ, Lubitz, SA, Anderson, CD, Christophersen, IE, Rienstra, M, Roselli, C, Yin, X, Geelhoed, B, Barnard, J, Lin, H, Arking, DE, Smith, A, Albert, CM, Chaffin, M, Tucker, NR, Li, M, Klarin, D, Bihlmeyer, NA, Low, S-K, Weeke, PE, Mueller-Nurasyid, M, Smith, JG, Brody, JA, Niemeijer, MN, Doerr, M, Trompet, S, Huffman, J, Gustafsson, S, Schurmann, C, Kleber, ME, Lyytikainen, L-P, Seppala, I, Malik, R, Horimoto, ARVR, Perez, M, Sinisalo, J, Aeschbacher, S, Theriault, S, Yao, J, Radmanesh, F, Weiss, S, Teumer, A, Clauss, S, Deo, R, Rader, DJ, Shah, S, Sun, A, Hopewell, JC, Debette, S, Chauhan, G, Yang, Q, Worrall, BB, Pare, G, Kamatani, Y, Hagemeijer, YP, Verweij, N, Siland, JE, Kubo, M, Smith, JD, Van Wagoner, DR, Bis, JC, Perz, S, Psaty, BM, Ridker, PM, Magnani, JW, Harris, TB, Launer, LJ, Shoemaker, MB, Padmanabhan, S, Haessler, J, Bartz, TM, Waldenberger, M, Lichtner, P, Arendt, M, Krieger, JE, Kahonen, M, Risch, L, Mansur, AJ, Peters, A, Smith, BH, Lind, L, Scott, SA, Lu, Y, Bottinger, EB, Hernesniemi, J, Lindgren, CM, Wong, JA, Huang, J, Eskola, M, Morris, AP, Ford, I, Reiner, AP, Delgado, G, Chen, LY, Chen, Y-DI, Sandhu, RK, Boerwinkle, E, Eisele, L, Lannfelt, L, Rost, N, Taylor, KD, Campbell, A, Magnusson, PK, Porteous, D, Hocking, LJ, Vlachopoulou, E, Pedersen, NL, Nikus, K, Orho-Melander, M, Hamsten, A, Heeringa, J, Denny, JC, Kriebel, J, Darbar, D, Newton-Cheh, C, Shaffer, C, Macfarlane, PW, Heilmann, S, Almgren, P, Huang, PL, Sotoodehnia, N, Soliman, EZ, Uitterlinden, AG, Hofman, A, Franco, OH, Voelker, U, Joeckel, K-H, Sinner, MF, Lin, HJ, Guo, X, Dichgans, M, Ingelsson, E, Kooperberg, C, Melander, O, Loos, RJF, Laurikka, J, Conen, D, van der Harst, P, Lokki, M-L, Kathiresan, S, Pereira, A, Jukema, JW, Hayward, C, Rotter, J, Maerz, W, Lehtimaki, T, Stricker, BH, Chung, MK, Felix, SB, Gudnason, V, Alonso, A, Roden, DM, Kaeaeb, S, Chasman, D, Heckbert, SR, Tanaka, T, Lunetta, KL, Smoller, S, Sorkin, J, Wang, X, Selim, M, Pikula, A, Wolf, P, Seshadri, S, de Bakker, P, Rexrode, K, Chen, I, Luke, M, Sale, M, Lee, T-H, Chang, K-C, Elkind, M, Goldstein, L, James, ML, Breteler, M, O'Donnell, C, Leys, D, Carty, C, Kidwell, C, Olesen, J, Sharma, P, Rich, S, Tatlisumak, T, Happola, O, Bijlenga, P, Soriano, C, Giralt, E, Roquer, J, Jimenez-Conde, J, Cotlarcius, I, Hardy, J, Korostynski, M, Boncoraglio, G, Ballabio, E, Parati, E, Mateusz, A, Urbanik, A, Dziedzic, T, Jagiella, J, Gasowski, J, Wnuk, M, Olszanecki, R, Pera, J, Slowik, A, Juchniewicz, KJ, Levi, C, Nyquist, P, Cendes, I, Cabral, N, Franca, P, Goncalves, A, Keller, L, Crisby, M, Kostulas, K, Lemmens, R, Ahmadi, K, Opherk, C, Duering, M, Gonik, M, Staals, J, Burri, P, Sadr-Nabavi, A, Romero, J, Biffi, A, Anderson, C, Falcone, G, Brouwers, B, Du, R, Kourkoulis, C, Battey, T, Lubitz, S, Mueller-Myhsok, B, Meschia, J, Brott, T, Pichler, A, Enzinger, C, Schmidt, H, Schmidt, R, Seiler, S, Blanton, S, Yamada, Y, Bersano, A, Rundek, T, Sacco, R, Chan, Y-FY, Gschwendtner, A, Deng, Z, Barr, T, Gwinn, K, Corriveau, R, Singleton, A, Waddy, S, Launer, L, Chen, C, Le, KE, Lee, WL, Tan, EK, Olugbodi, A, Rothwell, P, Schilling, S, Mok, V, Lebedeva, E, Jern, C, Jood, K, Olsson, S, Kim, H, Lee, C, Kilarski, L, Markus, H, Peycke, J, Bevan, S, Sheu, W, Chiou, HY, Chern, J, Giraldo, E, Taqi, M, Jain, V, Lam, O, Howard, G, Woo, D, Kittner, S, Mitchell, B, Cole, J, O'Connell, J, Milewicz, D, Illoh, K, Worrall, B, Stine, C, Karaszewski, B, Werring, D, Sofat, R, Smalley, J, Lindgren, A, Hansen, B, Norrving, B, Smith, G, Jose Martin, J, Thijs, V, Klijn, K, van't Hof, F, Algra, A, Macleod, M, Perry, R, Arnett, D, Pezzini, A, Padovani, A, Cramer, S, Fisher, M, Saleheen, D, Broderick, J, Kissela, B, Doney, A, Sudlow, C, Rannikmae, K, Silliman, S, McDonough, C, Walters, M, Pedersen, A, Nakagawa, K, Chang, C, Dobbins, M, McArdle, P, Chang, Y-C, Brown, R, Brown, D, Holliday, E, Kalaria, R, Maguire, J, Attia, J, Farrall, M, Giese, A-K, Fornage, M, Majersik, J, Cushman, M, Keene, K, Bennett, S, Tirschwell, D, Psaty, B, Reiner, A, Longstreth, W, Spence, D, Montaner, J, Fernandez-Cadenas, I, Langefeld, C, Bushnell, C, Heitsch, L, Lee, J-M, Sheth, K, Pulit, SL, Weng, L-C, McArdle, PF, Trinquart, L, Choi, SH, Mitchell, BD, Rosand, J, de Bakker, PIW, Benjamin, EJ, Ellinor, PT, Kittner, SJ, Lubitz, SA, Anderson, CD, Christophersen, IE, Rienstra, M, Roselli, C, Yin, X, Geelhoed, B, Barnard, J, Lin, H, Arking, DE, Smith, A, Albert, CM, Chaffin, M, Tucker, NR, Li, M, Klarin, D, Bihlmeyer, NA, Low, S-K, Weeke, PE, Mueller-Nurasyid, M, Smith, JG, Brody, JA, Niemeijer, MN, Doerr, M, Trompet, S, Huffman, J, Gustafsson, S, Schurmann, C, Kleber, ME, Lyytikainen, L-P, Seppala, I, Malik, R, Horimoto, ARVR, Perez, M, Sinisalo, J, Aeschbacher, S, Theriault, S, Yao, J, Radmanesh, F, Weiss, S, Teumer, A, Clauss, S, Deo, R, Rader, DJ, Shah, S, Sun, A, Hopewell, JC, Debette, S, Chauhan, G, Yang, Q, Worrall, BB, Pare, G, Kamatani, Y, Hagemeijer, YP, Verweij, N, Siland, JE, Kubo, M, Smith, JD, Van Wagoner, DR, Bis, JC, Perz, S, Psaty, BM, Ridker, PM, Magnani, JW, Harris, TB, Launer, LJ, Shoemaker, MB, Padmanabhan, S, Haessler, J, Bartz, TM, Waldenberger, M, Lichtner, P, Arendt, M, Krieger, JE, Kahonen, M, Risch, L, Mansur, AJ, Peters, A, Smith, BH, Lind, L, Scott, SA, Lu, Y, Bottinger, EB, Hernesniemi, J, Lindgren, CM, Wong, JA, Huang, J, Eskola, M, Morris, AP, Ford, I, Reiner, AP, Delgado, G, Chen, LY, Chen, Y-DI, Sandhu, RK, Boerwinkle, E, Eisele, L, Lannfelt, L, Rost, N, Taylor, KD, Campbell, A, Magnusson, PK, Porteous, D, Hocking, LJ, Vlachopoulou, E, Pedersen, NL, Nikus, K, Orho-Melander, M, Hamsten, A, Heeringa, J, Denny, JC, Kriebel, J, Darbar, D, Newton-Cheh, C, Shaffer, C, Macfarlane, PW, Heilmann, S, Almgren, P, Huang, PL, Sotoodehnia, N, Soliman, EZ, Uitterlinden, AG, Hofman, A, Franco, OH, Voelker, U, Joeckel, K-H, Sinner, MF, Lin, HJ, Guo, X, Dichgans, M, Ingelsson, E, Kooperberg, C, Melander, O, Loos, RJF, Laurikka, J, Conen, D, van der Harst, P, Lokki, M-L, Kathiresan, S, Pereira, A, Jukema, JW, Hayward, C, Rotter, J, Maerz, W, Lehtimaki, T, Stricker, BH, Chung, MK, Felix, SB, Gudnason, V, Alonso, A, Roden, DM, Kaeaeb, S, Chasman, D, Heckbert, SR, Tanaka, T, Lunetta, KL, Smoller, S, Sorkin, J, Wang, X, Selim, M, Pikula, A, Wolf, P, Seshadri, S, de Bakker, P, Rexrode, K, Chen, I, Luke, M, Sale, M, Lee, T-H, Chang, K-C, Elkind, M, Goldstein, L, James, ML, Breteler, M, O'Donnell, C, Leys, D, Carty, C, Kidwell, C, Olesen, J, Sharma, P, Rich, S, Tatlisumak, T, Happola, O, Bijlenga, P, Soriano, C, Giralt, E, Roquer, J, Jimenez-Conde, J, Cotlarcius, I, Hardy, J, Korostynski, M, Boncoraglio, G, Ballabio, E, Parati, E, Mateusz, A, Urbanik, A, Dziedzic, T, Jagiella, J, Gasowski, J, Wnuk, M, Olszanecki, R, Pera, J, Slowik, A, Juchniewicz, KJ, Levi, C, Nyquist, P, Cendes, I, Cabral, N, Franca, P, Goncalves, A, Keller, L, Crisby, M, Kostulas, K, Lemmens, R, Ahmadi, K, Opherk, C, Duering, M, Gonik, M, Staals, J, Burri, P, Sadr-Nabavi, A, Romero, J, Biffi, A, Anderson, C, Falcone, G, Brouwers, B, Du, R, Kourkoulis, C, Battey, T, Lubitz, S, Mueller-Myhsok, B, Meschia, J, Brott, T, Pichler, A, Enzinger, C, Schmidt, H, Schmidt, R, Seiler, S, Blanton, S, Yamada, Y, Bersano, A, Rundek, T, Sacco, R, Chan, Y-FY, Gschwendtner, A, Deng, Z, Barr, T, Gwinn, K, Corriveau, R, Singleton, A, Waddy, S, Launer, L, Chen, C, Le, KE, Lee, WL, Tan, EK, Olugbodi, A, Rothwell, P, Schilling, S, Mok, V, Lebedeva, E, Jern, C, Jood, K, Olsson, S, Kim, H, Lee, C, Kilarski, L, Markus, H, Peycke, J, Bevan, S, Sheu, W, Chiou, HY, Chern, J, Giraldo, E, Taqi, M, Jain, V, Lam, O, Howard, G, Woo, D, Kittner, S, Mitchell, B, Cole, J, O'Connell, J, Milewicz, D, Illoh, K, Worrall, B, Stine, C, Karaszewski, B, Werring, D, Sofat, R, Smalley, J, Lindgren, A, Hansen, B, Norrving, B, Smith, G, Jose Martin, J, Thijs, V, Klijn, K, van't Hof, F, Algra, A, Macleod, M, Perry, R, Arnett, D, Pezzini, A, Padovani, A, Cramer, S, Fisher, M, Saleheen, D, Broderick, J, Kissela, B, Doney, A, Sudlow, C, Rannikmae, K, Silliman, S, McDonough, C, Walters, M, Pedersen, A, Nakagawa, K, Chang, C, Dobbins, M, McArdle, P, Chang, Y-C, Brown, R, Brown, D, Holliday, E, Kalaria, R, Maguire, J, Attia, J, Farrall, M, Giese, A-K, Fornage, M, Majersik, J, Cushman, M, Keene, K, Bennett, S, Tirschwell, D, Psaty, B, Reiner, A, Longstreth, W, Spence, D, Montaner, J, Fernandez-Cadenas, I, Langefeld, C, Bushnell, C, Heitsch, L, Lee, J-M, and Sheth, K

Abstract

OBJECTIVE: We sought to assess whether genetic risk factors for atrial fibrillation (AF) can explain cardioembolic stroke risk. METHODS: We evaluated genetic correlations between a previous genetic study of AF and AF in the presence of cardioembolic stroke using genome-wide genotypes from the Stroke Genetics Network (N = 3,190 AF cases, 3,000 cardioembolic stroke cases, and 28,026 referents). We tested whether a previously validated AF polygenic risk score (PRS) associated with cardioembolic and other stroke subtypes after accounting for AF clinical risk factors. RESULTS: We observed a strong correlation between previously reported genetic risk for AF, AF in the presence of stroke, and cardioembolic stroke (Pearson r = 0.77 and 0.76, respectively, across SNPs with p < 4.4 × 10-4 in the previous AF meta-analysis). An AF PRS, adjusted for clinical AF risk factors, was associated with cardioembolic stroke (odds ratio [OR] per SD = 1.40, p = 1.45 × 10-48), explaining ∼20% of the heritable component of cardioembolic stroke risk. The AF PRS was also associated with stroke of undetermined cause (OR per SD = 1.07, p = 0.004), but no other primary stroke subtypes (all p > 0.1). CONCLUSIONS: Genetic risk of AF is associated with cardioembolic stroke, independent of clinical risk factors. Studies are warranted to determine whether AF genetic risk can serve as a biomarker for strokes caused by AF.

Published
2018

44. A Novel Imaging Marker for Small Vessel Disease Based on Skeletonization of White Matter Tracts and Diffusion Histograms

Author

Baykara, E., Gesierich, B., Adam, R., Tuladhar, A.M., Biesbroek, J.M., Koek, H.L., Ropele, S., Jouvent, E., Chabriat, H., Ertl-Wagner, B., Ewers, M., Schmidt, R., Leeuw, F.E. de, Biessels, G.J., Dichgans, M., and Duering, M.

Subjects
Medicine(all), Neurology, Clinical Neurology, Journal Article, Validation Studies, Disorders of movement Donders Center for Medical Neuroscience [Radboudumc 3]
Abstract

Item does not contain fulltext OBJECTIVE: To establish a fully automated, robust imaging marker for cerebral small vessel disease (SVD) and related cognitive impairment that is easy to implement, reflects disease burden, and is strongly associated with processing speed, the predominantly affected cognitive domain in SVD. METHODS: We developed a novel magnetic resonance imaging marker based on diffusion tensor imaging, skeletonization of white matter tracts, and histogram analysis. The marker (peak width of skeletonized mean diffusivity [PSMD]) was assessed along with conventional SVD imaging markers. We first evaluated associations with processing speed in patients with genetically defined SVD (n = 113). Next, we validated our findings in independent samples of inherited SVD (n = 57), sporadic SVD (n = 444), and memory clinic patients with SVD (n = 105). The new marker was further applied to healthy controls (n = 241) and to patients with Alzheimer's disease (n = 153). We further conducted a longitudinal analysis and interscanner reproducibility study. RESULTS: PSMD was associated with processing speed in all study samples with SVD (p-values between 2.8 x 10(-3) and 1.8 x 10(-10) ). PSMD explained most of the variance in processing speed (R(2) ranging from 8.8% to 46%) and consistently outperformed conventional imaging markers (white matter hyperintensity volume, lacune volume, and brain volume) in multiple regression analyses. Increases in PSMD were linked to vascular but not to neurodegenerative disease. In longitudinal analysis, PSMD captured SVD progression better than other imaging markers. INTERPRETATION: PSMD is a new, fully automated, and robust imaging marker for SVD. PSMD can easily be applied to large samples and may be of great utility for both research studies and clinical use. Ann Neurol 2016;80:581-592.

Published
2016

45. Genome-wide meta-analysis of cerebral white matter hyperintensities in patients with stroke

Author

Traylor, M, Zhang, Cr, Adib Samii, P, Devan, Wj, Parsons, Oe, Lanfranconi, S, Gregory, S, Cloonan, L, Falcone, Gj, Radmanesh, F, Fitzpatrick, K, Kanakis, A, Barrick, Tr, Moynihan, B, Lewis, Cm, Boncoraglio, Gb, Lemmens, R, Thijs, V, Sudlow, C, Wardlaw, J, Rothwell, Pm, Meschia, Jf, Worrall, Bb, Levi, C, Bevan, S, Furie, Kl, Dichgans, M, Rosand, J, Markus, Hs, Rost, N, Smoller, S, Sorkin, J, Wang, X, Selim, M, Pikula, A, Wolf, P, Debette, S, Seshadri, S, de Bakker, P, Chasman, D, Rexrode, K, Chen, I, Rotter, J, Luke, M, Sale, M, Lee, Th, Chang, Kc, Elkind, M, Goldstein, L, James, Ml, Breteler, M, O'Donnell, C, Leys, D, Carty, C, Kidwell, C, Olesen, J, Sharma, P, Rich, S, Tatlisumak, T, Happola, O, Bijlenga, P, Soriano, C, Giralt, E, Roquer, J, Jimenez Conde, J, Cotlarcius, I, Hardy, J, Korostynski, M, Boncoraglio, G, Ballabio, E, Parati, E, Mateusz, A, Urbanik, A, Dziedzic, T, Jagiella, J, Gasowski, J, Wnuk, M, Olszanecki, R, Pera, J, Slowik, A, Juchniewicz, Kj, Nyquist, P, Cendes, I, Cabral, N, Franca, P, Goncalves, A, Keller, L, Crisby, M, Kostulas, K, Ahmadi, K, Opherk, C, Duering, M, Malik, R, Gonik, M, Staals, J, Melander, O, Burri, P, Sadr Nabavi, A, Romero, J, Biffi, A, Anderson, C, Falcone, G, Brouwers, B, Du, R, Kourkoulis, C, Battey, T, Lubitz, S, Mueller Myhsok, B, Meschia, J, Brott, T, Pare, G, Pichler, A, Enzinger, C, Schmidt, H, Schmidt, R, Seiler, S, Blanton, S, Yamada, Y, Bersano, A, Rundek, T, Sacco, R, Yvonne Chan, Yf, Gschwendtner, A, Deng, Z, Barr, T, Gwinn, K, Corriveau, R, Singleton, A, Waddy, S, Launer, L, Chen, C, Ke, Le, Lee, Wl, Tan, Ek, Olugbodi, A, Rothwell, P, Schilling, S, Mok, V, Lebedeva, E, Jern, C, Jood, K, Olsson, S, Kim, H, Lee, C, Kilarski, L, Markus, H, Peycke, J, Sheu, W, Chiou, Hy, Chern, J, Giraldo, E, Taqi, M, Jain, V, Lam, O, Howard, G, Woo, D, Kittner, S, Mitchell, B, Cole, J, O'Connell, J, Milewicz, D, Illoh, K, Worrall, B, Stine, C, Karaszewski, B, Werring, D, Sofat, R, Smalley, J, Lindgren, A, Hansen, B, Norrving, B, Smith, G, Martín, Jj, Klijn, K, Van't Hof, F, Algra, A, Macleod, M, Perry, R, Arnett, D, Pezzini, Alessandro, Padovani, Alessandro, Cramer, S, Fisher, M, Saleheen, D, Broderick, J, Kissela, B, Doney, A, Rannikmae, K, Silliman, S, Mcdonough, C, Walters, M, Pedersen, A, Nakagawa, K, Chang, C, Dobbins, M, Mcardle, P, Chang, Yc, Brown, R, Brown, D, Holliday, E, Kalaria, R, Maguire, J, Attia, J, Farrall, M, Giese, Ak, Fornage, M, Majersik, J, Cushman, M, Keene, K, Bennett, S, Tirschwell, D, Psaty, B, Reiner, A, Longstreth, W, Spence, D, Montaner, J, Fernandez Cadenas, I, Langefeld, C, Bushnell, C, Heitsch, L, Lee, Jm, and Sheth, K.

Subjects
Cerebral Small Vessel Diseases, Genetic Predisposition to Disease, Genetic Testing, Humans, Polymorphism, Single Nucleotide, Risk Factors, Stroke, White Matter, Genome-Wide Association Study, Neurology (clinical), Single Nucleotide, C420 Human Genetics, Article, C431 Medical Genetics, C400 Genetics, Polymorphism, C440 Molecular Genetics
Abstract

Objective: For 3,670 stroke patients from the United Kingdom, United States, Australia, Belgium, and Italy, we performed a genome-wide meta-analysis of white matter hyperintensity volumes (WMHV) on data imputed to the 1000 Genomes reference dataset to provide insights into disease mechanisms. Methods: We first sought to identify genetic associations with white matter hyperintensities in a stroke population, and then examined whether genetic loci previously linked to WMHV in community populations are also associated in stroke patients. Having established that genetic associations are shared between the 2 populations, we performed a meta-analysis testing which associations with WMHV in stroke-free populations are associated overall when combined with stroke populations. Results: There were no associations at genome-wide significance with WMHV in stroke patients. All previously reported genome-wide significant associations with WMHV in community populations shared direction of effect in stroke patients. In a meta-analysis of the genome-wide significant and suggestive loci (p Conclusions: Genetic associations with WMHV are shared in otherwise healthy individuals and patients with stroke, indicating common genetic susceptibility in cerebral small vessel disease.

Published
2016

48. Reproducibility and variability of quantitative magnetic resonance imaging markers in cerebral small vessel disease

Author

Guio, F. De, Jouvent, E., Biessels, G.J., Black, S.E., Brayne, C., Chen, C., Cordonnier, C., Leeuw, F.E. de, Dichgans, M., Doubal, F., Duering, M., Dufouil, C., Duzel, E., Fazekas, F., Hachinski, V., Ikram, M.A., Linn, J., Matthews, P.M., Mazoyer, B., Mok, V., Norrving, B., O'Brien, J.T., Pantoni, L., Ropele, S., Sachdev, P., Schmidt, R., Seshadri, S., Smith, E.E., Sposato, L.A., Stephan, B., Swartz, R.H., Tzourio, C., Buchem, M. van, Lugt, A. van der, Oostenbrugge, R., Vernooij, M.W., Viswanathan, A., Werring, D., Wollenweber, F., Wardlaw, J.M., Chabriat, H., Guio, F. De, Jouvent, E., Biessels, G.J., Black, S.E., Brayne, C., Chen, C., Cordonnier, C., Leeuw, F.E. de, Dichgans, M., Doubal, F., Duering, M., Dufouil, C., Duzel, E., Fazekas, F., Hachinski, V., Ikram, M.A., Linn, J., Matthews, P.M., Mazoyer, B., Mok, V., Norrving, B., O'Brien, J.T., Pantoni, L., Ropele, S., Sachdev, P., Schmidt, R., Seshadri, S., Smith, E.E., Sposato, L.A., Stephan, B., Swartz, R.H., Tzourio, C., Buchem, M. van, Lugt, A. van der, Oostenbrugge, R., Vernooij, M.W., Viswanathan, A., Werring, D., Wollenweber, F., Wardlaw, J.M., and Chabriat, H.

Abstract

Item does not contain fulltext, Brain imaging is essential for the diagnosis and characterization of cerebral small vessel disease. Several magnetic resonance imaging markers have therefore emerged, providing new information on the diagnosis, progression, and mechanisms of small vessel disease. Yet, the reproducibility of these small vessel disease markers has received little attention despite being widely used in cross-sectional and longitudinal studies. This review focuses on the main small vessel disease-related markers on magnetic resonance imaging including: white matter hyperintensities, lacunes, dilated perivascular spaces, microbleeds, and brain volume. The aim is to summarize, for each marker, what is currently known about: (1) its reproducibility in studies with a scan-rescan procedure either in single or multicenter settings; (2) the acquisition-related sources of variability; and, (3) the techniques used to minimize this variability. Based on the results, we discuss technical and other challenges that need to be overcome in order for these markers to be reliably used as outcome measures in future clinical trials. We also highlight the key points that need to be considered when designing multicenter magnetic resonance imaging studies of small vessel disease.

Published
2016

49. Reproducibility and variability of quantitative magnetic resonance imaging markers in cerebral small vessel disease

Author

De Guio, F. (François), Jouvent, E. (Eric), Biessels, G.J. (Geert Jan), Black, S.E. (Sandra), Brayne, C. (Carol), Chen, C. (Christopher), Cordonnier, C. (Charlotte), Leeuw, H.F. (Frank) de, Kubisch, C. (Christian), Doubal, F. (Fergus), Duering, M. (Marco), Dufouil, C. (Carole), Duzel, E. (Emrah), Fazekas, F. (Franz), Hachinski, V. (Vladimir), Ikram, M.K. (Kamran), Linn, J. (Jennifer), Matthews, P.M. (P.), Mazoyer, B. (Bernard), Mok, V. (Vincent), Norrving, B. (Bo), O'Brien, J.T. (John T.), Pantoni, L. (Leonardo), Ropele, S. (Stefan), Sachdev, P.S. (Perminder), Schmidt, R. (Reinhold), Seshadri, S. (Sudha), Smith, E.E. (Eric), Sposato, L.A. (Luciano A), Stephan, B.C.M., Swartz, R.H. (Richard H.), Tzourio, C. (Christophe), Buchem, M.A. (Mark) van, Lugt, A. (Aad) van der, Oostenbrugge, R.J. (Robert) van, Vernooij, M.W. (Meike), Viswanathan, A. (Anand), Werring, D.J. (David), Wollenweber, F. (Frank), Wardlaw, J.M. (J.), Chabriat, H. (Hugues), De Guio, F. (François), Jouvent, E. (Eric), Biessels, G.J. (Geert Jan), Black, S.E. (Sandra), Brayne, C. (Carol), Chen, C. (Christopher), Cordonnier, C. (Charlotte), Leeuw, H.F. (Frank) de, Kubisch, C. (Christian), Doubal, F. (Fergus), Duering, M. (Marco), Dufouil, C. (Carole), Duzel, E. (Emrah), Fazekas, F. (Franz), Hachinski, V. (Vladimir), Ikram, M.K. (Kamran), Linn, J. (Jennifer), Matthews, P.M. (P.), Mazoyer, B. (Bernard), Mok, V. (Vincent), Norrving, B. (Bo), O'Brien, J.T. (John T.), Pantoni, L. (Leonardo), Ropele, S. (Stefan), Sachdev, P.S. (Perminder), Schmidt, R. (Reinhold), Seshadri, S. (Sudha), Smith, E.E. (Eric), Sposato, L.A. (Luciano A), Stephan, B.C.M., Swartz, R.H. (Richard H.), Tzourio, C. (Christophe), Buchem, M.A. (Mark) van, Lugt, A. (Aad) van der, Oostenbrugge, R.J. (Robert) van, Vernooij, M.W. (Meike), Viswanathan, A. (Anand), Werring, D.J. (David), Wollenweber, F. (Frank), Wardlaw, J.M. (J.), and Chabriat, H. (Hugues)

Abstract

Brain imaging is essential for the diagnosis and characterization of cerebral small vessel disease. Several magnetic resonance imaging markers have therefore emerged, providing new information on the diagnosis, progression, and mechanisms of small vessel disease. Yet, the reproducibility of these small vessel disease markers has received little attention despite being widely used in cross-sectional and longitudinal studies. This review focuses on the main small vessel disease-related markers on magnetic resonance imaging including: white matter hyperintensities, lacunes, dilated perivascular spaces, microbleeds, and brain volume. The aim is to summarize, for each marker, what is currently known about: (1) its reproducibility in studies with a scan-rescan procedure either in single or multicenter settings; (2) the acquisition-related sources of variability; and, (3) the techniques used to minimize this variability. Based on the results, we discuss technical and other challenges that need to be overcome in order for these markers to be reliably used as outcome measures in future clinical trials. We also highlight the key points that need to be considered when designing multicenter magnetic resonance imaging studies of small vessel disease.

Published
2016
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50. White matter pathology and disconnection in the frontal lobe in cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL)

Author

Craggs, LJL, Yamamoto, Y, Ihara, M, Fenwick, R, Burke, M, Oakley, AE, Roeber, S, Duering, M, Kretzschmar, H, and Kalaria, RN

Abstract

Background; Magnetic resonance imaging indicates diffuse white matter (WM) changes are associated with cognitive impairment in cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL). We examined whether the distribution of axonal abnormalities is related to microvascular pathology in the underlying WM. Methods; We used post‐mortem brains from CADASIL subjects and similar age cognitively normal controls to examine WM axonal changes, microvascular pathology, and glial reaction in up to 16 different regions extending rostro‐caudally through the cerebrum. Using unbiased stereological methods, we estimated length densities of affected axons immunostained with neurofilament antibody SMI32. Standard immunohistochemistry was used to assess amyloid precursor protein immunoreactivity per WM area. To relate WM changes to microvascular pathology, we also determined the sclerotic index (SI) in WM arterioles. Results; The degree of WM pathology consistently scored higher across all brain regions in CADASIL subjects (P

Published
2014

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