scispace - formally typeset
Search or ask a question
Posted ContentDOI

White Matter Hyperintensities, Grey Matter Atrophy, and Cognitive Decline in Neurodegenerative Diseases

Mahsa Dadar1, Ana L. Manera2, D.L. Collins2
McGill University1, Montreal Neurological Institute and Hospital2
08 Apr 2021-bioRxiv (Cold Spring Harbor Laboratory)-
TL;DR: In this article, different spatial patterns and relationships between WMHs and grey matter atrophy in normal aging, individuals with mild cognitive impairment (MCI), Alzheimer's dementia (AD), fronto-temporal dementia (FTD), and de novo Parkinson's disease (PD).
Abstract: Introduction White matter hyperintensities (WMHs) as seen on T2w and FLAIR scans represent small-vessel disease related changes in the brain. WMHs are associated with cognitive decline in the normal aging population in general and more specifically in patients with neurodegenerative diseases. In this study, we assessed the different spatial patterns and relationships between WMHs and grey matter (GM) atrophy in normal aging, individuals with mild cognitive impairment (MCI), Alzheimer’s dementia (AD), fronto-temporal dementia (FTD), and de novo Parkinson’s disease (PD). Methods Imaging and clinical data were obtained from 3 large multi-center databases: The Alzheimer’s Disease Neuroimaging Initiative (ADNI), the frontotemporal lobar degeneration neuroimaging initiative (NIFD), and the Parkinson’s Progression Markers Initiative (PPMI). WMHs and GM atrophy maps were measured in normal controls (N= 571), MCI (N= 577), AD (N= 222), FTD (N= 144), and PD (N= 363). WMHs were segmented using T1w and T2w/PD or FLAIR images and mapped onto 45 white matter tracts using the Yeh WM atlas. GM volume was estimated from the Jacobian determinant of the nonlinear deformation field required to map the subject’s MRI to a standard template. The CerebrA atlas was used to obtain volume estimates in 84 GM regions. Mixed effects models were used to compare WMH in different WM tracts and volume of multiple GM structures between patients and controls, assess the relationship between regional WMHs and GM loss for each disease, and investigate their impact on cognition. Results MCI, AD, and FTD patients had significantly higher WMH loads than the matched controls. There was no significant difference in WMHs between PD and controls. For each cohort, significant interactions between WMH load and GM atrophy were found for several regions and tracts, reflecting additional contribution of WMH burden to GM atrophy. While these associations were more relevant for insular and parieto-occipital regions in MCI and AD cohorts, WMH burden in FTD subjects had greater impact on frontal and basal ganglia atrophy. Finally, we found additional contribution of WMH burden to cognitive deficits in AD and FTD subjects compared with matched controls, whereas their impact on cognitive performance in MCI and PD were not significantly different from controls. Conclusions WMHs occur more extensively in MCI, AD, and FTD patients than age-matched normal controls. WMH burden on WM tracts also correlates with regional GM atrophy in regions anatomically and functionally related to those tracts, suggesting a potential involvement of WMHs in the neurodegenerative process.

Summary (3 min read)

Jump to: [Introduction][ADNI][PPMI][NIFD][WMHs][WM tracts and WMHs][Deformation Based Morphometry (DBM)][Cognitive Performance][Statistical Analysis][Results] and [Discussion]

Introduction

  • These age-related WMHs are considered to be the most common MRI signs of cerebral small vessel disease and are generally due to chronic hypoperfusion and alterations in the blood brain barrier (McAleese et al., 2016).
  • Few studies have investigated the relationship between the longitudinal changes in WMHs in different white matter tracts, neurodegenerative changes, and cognitive decline.
  • They found significantly greater total load of WMHs in AD, but not PD or DLB.
  • They did not investigate the relationships with measures of grey matter atrophy.

ADNI

  • The longitudinal MRI data used in this study included T1w, T2w/proton density–weighted acquisitions from ADNI1 patients and T1w and FLAIR acquisitions from ADNI2/GO patients.
  • The scanner information and image acquisition parameters have been previously described (Dadar et al., 2017a).
  • The ADNI1, ADNI2 and ADNIgo studies acquired data from subjects on a yearly basis.

PPMI

  • //www.ppmi-info.org) is a longitudinal multi-site clinical study of approximately 600 de novo PD patients and 200 age-matched healthy controls followed over the course of five years (Marek et al., 2011), also known as The PPMI (http.
  • The study was approved by the institutional review board of all participating sites and written informed consent was obtained from all participants before inclusion in the study.

NIFD

  • The frontotemporal lobar degeneration neuroimaging initiative is founded through the National Institute of Aging and started in 2010.
  • The primary goals of FTLDNI are to identify neuroimaging modalities and methods of analysis for tracking frontotemporal lobar degeneration (FTLD) and to assess the value of imaging versus other biomarkers in diagnostic roles.
  • The Principal Investigator of FTLDNI is Dr. Howard Rosen, MD at the University of California, San Francisco.
  • The data is the result of collaborative efforts at three sites in North America.
  • For up-todate information on participation and protocol, please visit: http://memory.ucsf.edu/research/studies/nifd.

WMHs

  • All T1-weighted, T2-weighted, proton density (PD), and FLAIR MRI scans were preprocessed in 3 steps using their standardized pipeline: denoising (Manjón et al., 2010), intensity non-uniformity correction (Sled et al., 1998), and intensity normalization into the range 0–100.
  • For each subject, the T2-weighted, PD, and FLAIR scans were then co-registered to the T1-weighted scan of the same visit using a 6-parameter rigid registration and a mutual information objective function (Collins et al., 1994; Dadar et al., 2018a).
  • Using a previously validated fully automated WMH segmentation method and a library of manual segmentations based on 53 patients from ADNI1 and 46 patients from ADNI2/GO, the WMHs were automatically segmented for all longitudinal visits (Dadar et al., 2017b).
  • The quality of the registrations and segmentations was visually assessed, and the results that did not pass this quality control were excluded (N=102 out of 5774 timepoints).

WM tracts and WMHs

  • Using the atlas of the white matter tracts by Yeh et al. derived from diffusion MRI data of 842 young healthy individuals from the human connectome project (https://db.humanconnectome.org/) and labeled by a team of expert neuroanatomists based on tractography and neuroanatomical knowledge, the WMH volume in 80 WM tracts were calculated (Yeh et al., 2018).
  • To avoid computing regressions in tracts with little WMH data, regions that had no WMH voxels in more than 80% of the subjects were discarded, leaving 45 WM tracts with some WMHs in at least 20% of the population.

Deformation Based Morphometry (DBM)

  • All the T1-weighted images were nonlinearly registered to the MNI-ICBM152 template using the symmetric diffeomorphic image registration (SyN) tool from ANTS (Avants et al., 2009, 2008).
  • Deformation-based morphology (DBM) maps were calculated by computing the Jacobian determinant of the deformation fields obtained from these nonlinear transformations, as a proxy of the relative local volume difference between the individual and MNI-ICBM152 template.
  • Similarly, the CerebrA atlas was used to calculate average regional grey matter volume in 102 cortical and subcortical regions (Manera et al., 2020, 2019).
  • The CerebrA grey matter atlas is based on the Mindboogle-101 atlas (Klein and Tourville, 2012), which was nonlinearly registered to the MNI-ICBM152 template and manually corrected to remove any remaining partial volume effects.

Cognitive Performance

  • The Alzheimer's Disease (AD) Assessment Scale-Cognitive Subscale (ADAS13) scores (Mohs and Cohen, 1987) were used to assess cognitive performance for the ADNI subjects and the Montreal Cognitive Assessment (MoCA) scores (Nasreddine et al., 2005) were used as the cognitive scores of interest for the NIFD and PPMI subjects (no single cognitive score was consistently available for all datasets).
  • In each study, the cognitive performance of the disease cohort was compared against the control group from the same study.

Statistical Analysis

  • The relationship between regional GM DBM values and regional WMH burden was assessed using the following model for each possible combination of the 102 GM regions and the WM tracts: Regional GM volume ~ 1 + Regional WMH load +.
  • The variable of interest in eq. 1 and eq. 2 was Cohort, reflecting the differences between the patients and the appropriate age-matched controls.
  • Similarly, the variables of interest in eq. 4 was Regional WMH load:Cohort, reflecting the additional contribution of WMHs to cognitive performance in each cohort.
  • All statistical analysis was performed in MATLAB (version R2015b).

Results

  • Table 1 provides a summary of the descriptive characteristics for the participants included in this study.
  • In the MCI cohort, the results show significant increase over controls in WMH burden predominantly in the fornix, anterior commissure, corpus callosum, bilateral cortico-striatal tract and inferior fronto-occipital vertical occipital fasciculi.
  • Colder colors indicate significant shrinkage of the area compared with the ICBM-MNI152-2009c template, i.e. presence of regional atrophy.
  • Table S2 in the Supplementary materials shows tstatistics for the top 20 GM regions with greater atrophy for MCI, AD, FTD, PD cohorts compared to their corresponding study age-matched controls.
  • The FTD cohort presented with extensive levels of atrophy, more remarkable in the cingulate, deep nuclei (thalamus and putamen) and cortical areas in the frontal and temporal lobes bilaterally .

Discussion

  • The authors combined data from three publicly available large databases to investigate the prevalence of regional WMHs in WM tracts and regional GM atrophy, as well as their interplay and impact on cognitive function in three most common neurodegenerative diseases; namely AD, FTD, and PD.
  • Other studies investigating later stage PD patients do however report higher incidence of WMHs (Mak et al., 2015; Piccini et al., 1995), substantiating the possibility that the increase might occur at later stages of the disease.
  • This might indicate a specific synergistic contribution of the cerebrovascular pathology to the disease-specific patterns of atrophy, as opposed to a nonspecific additional pattern of atrophy over all brain regions.
  • One major limitation of the present study was the inconsistencies between the three datasets used.
  • WMH burden on WM tracts also correlates with regional grey matter atrophy in pathologically relevant areas (i.e. the frontal lobe for FTD, and diffuse but mainly parietal and temporal lobes for AD).

Did you find this useful? Give us your feedback

Figures (5)

Content maybe subject to copyright    Report

White Matter Hyperintensities, Grey Matter Atrophy, and Cognitive Decline in
Neurodegenerative Diseases
Mahsa Dadar
1,2
(PhD) mahsa.dadar@mail.mcgill.ca
Ana Laura Manera
1,2
(MD) ana.manera@mail.mcgill.ca
D. Louis Collins
1,2
(PhD) louis.collins@mcgill.ca
1. NeuroImaging and Surgical Tools Laboratory, Montreal Neurological Institute, McGill University, Montreal,
Quebec, Canada.
2. McConnell Brain Imaging Centre, Montreal Neurological Institute, McGill University, Montreal, Quebec,
Canada.
Corresponding Author Information:
Mahsa Dadar, Montreal Neurological Institute, 3801 University Street, Room WB320, Montréal, QC, H3A 2B4
Email: mahsa.dadar@mcgill.ca
.CC-BY-ND 4.0 International licenseavailable under a
was not certified by peer review) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity. It is made
The copyright holder for this preprint (whichthis version posted April 8, 2021. ; https://doi.org/10.1101/2021.04.06.438619doi: bioRxiv preprint
Abstract:
Introduction: White matter hyperintensities (WMHs) as seen on T2w and FLAIR scans represent
small-vessel disease related changes in the brain. WMHs are associated with cognitive decline in
the normal aging population in general and more specifically in patients with neurodegenerative
diseases. In this study, we assessed the different spatial patterns and relationships between WMHs
and grey matter (GM) atrophy in normal aging, individuals with mild cognitive impairment (MCI),
Alzheimer’s dementia (AD), fronto-temporal dementia (FTD), and de novo Parkinson’s disease
(PD).
Methods: Imaging and clinical data were obtained from 3 large multi-center databases: The
Alzheimer's Disease Neuroimaging Initiative (ADNI), the frontotemporal lobar degeneration
neuroimaging initiative (NIFD), and the Parkinson’s Progression Markers Initiative (PPMI).
WMHs and GM atrophy maps were measured in normal controls (N= 571), MCI (N= 577), AD
(N= 222), FTD (N= 144), and PD (N= 363). WMHs were segmented using T1w and T2w/PD or
FLAIR images and mapped onto 45 white matter tracts using the Yeh WM atlas. GM volume was
estimated from the Jacobian determinant of the nonlinear deformation field required to map the
subject’s MRI to a standard template. The CerebrA atlas was used to obtain volume estimates in
84 GM regions. Mixed effects models were used to compare WMH in different WM tracts and
volume of multiple GM structures between patients and controls, assess the relationship between
regional WMHs and GM loss for each disease, and investigate their impact on cognition.
Results: MCI, AD, and FTD patients had significantly higher WMH loads than the matched
controls. There was no significant difference in WMHs between PD and controls. For each cohort,
significant interactions between WMH load and GM atrophy were found for several regions and
tracts, reflecting additional contribution of WMH burden to GM atrophy. While these associations
were more relevant for insular and parieto-occipital regions in MCI and AD cohorts, WMH burden
in FTD subjects had greater impact on frontal and basal ganglia atrophy. Finally, we found
additional contribution of WMH burden to cognitive deficits in AD and FTD subjects compared
with matched controls, whereas their impact on cognitive performance in MCI and PD were not
significantly different from controls.
Conclusions: WMHs occur more extensively in MCI, AD, and FTD patients than age-matched
normal controls. WMH burden on WM tracts also correlates with regional GM atrophy in regions
anatomically and functionally related to those tracts, suggesting a potential involvement of WMHs
in the neurodegenerative process.
Keywords: White matter hyperintensities, small-vessel disease, neurodegenerative disease,
Alzheimer’s disease, fronto-temporal dementia, Parkinson’s disease, mild cognitive impairment
.CC-BY-ND 4.0 International licenseavailable under a
was not certified by peer review) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity. It is made
The copyright holder for this preprint (whichthis version posted April 8, 2021. ; https://doi.org/10.1101/2021.04.06.438619doi: bioRxiv preprint
Introduction
White matter hyperintensites (WMHs), defined as nonspecific hyperintense regions in the white
matter tissue of the brain on T2-weighted or FLuid-Attenuated Inversion Recovery (FLAIR)
magnetic resonance images (MRIs) are common findings in the aging population in general
(Hachinski et al., 1987). These age-related WMHs are considered to be the most common MRI
signs of cerebral small vessel disease and are generally due to chronic hypoperfusion and
alterations in the blood brain barrier (McAleese et al., 2016). Other pathological correlates of
WMHs include demyelination, axonal and neuronal loss, higher levels of microglial activation, as
well as arteriosclerosis due to hypoxia, inflammation, degeneration, and amyloid angiopathy
(Abraham et al., 2016; Gouw et al., 2010).
WMHs are known to have a higher incidence in neurodegenerative diseases such as Alzheimer’s
disease (AD) (Capizzano et al., 2004; Dadar et al., 2017a; Dubois et al., 2014; Tosto et al., 2014),
dementia with Lewy bodies (DLB) (Barber et al., 1999), Parkinsons disease (PD) (Mak et al.,
2015; Piccini et al., 1995), fronto-temporal dementia (FTD) (Varma et al., 2002), as well as
individuals with mild cognitive impairment (MCI) (DeCarli et al., 2001; Lopez et al., 2003; Dadar
et al., 2017a). Patients with WMHs generally present with significantly more severe cognitive
deficits and suffer greater future cognitive decline compared with individuals with the same level
of neurodegeneration related pathologies without WMHs (Au et al., 2006; Carmichael et al., 2010;
Prins and Scheltens, 2015; Dadar et al., 2020b, 2019, 2020a, 2018b, 2020b).
Few studies have investigated the relationship between the longitudinal changes in WMHs in
different white matter tracts, neurodegenerative changes, and cognitive decline. In a relatively
small sample, Burton et al. studied the impact of WMHs in late-life dementia in DLB, PD and AD
(Burton et al., 2006). They found significantly greater total load of WMHs in AD, but not PD or
DLB. They did not find a significant association between the rate of change in WMH load and
cognitive performance (Burton et al., 2006). In a community-based cohort of 519 older adults,
Rizvi et al. found that increased WMH load in association and projection tracts were related to
worse memory function (Rizvi et al., 2020). However, they did not investigate the relationships
with measures of grey matter atrophy. In another aging sample of 2367 adults (age range 20-90
years), Habes et al. reported that WMHs in most tracts were related to age-related atrophy patterns,
as measured by Spatial Pattern of Alteration for Recognition of Brain Aging index (Habes et al.,
.CC-BY-ND 4.0 International licenseavailable under a
was not certified by peer review) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity. It is made
The copyright holder for this preprint (whichthis version posted April 8, 2021. ; https://doi.org/10.1101/2021.04.06.438619doi: bioRxiv preprint
2018). However, they did not investigate regional grey matter atrophy patterns or the relationships
with cognitive performance.
In this study, we used a previously validated automated WMH segmentation technique (Dadar et
al., 2017c, 2017b) to quantify the WMHs in 3 large multi-center cohorts of neurodegenerative
diseases, with a total of 1730 subjects and 5774 timepoints, and investigated the differences
between spatial distribution of regional WMHs in AD, PD, FTD, MCI, and cognitively normal
individuals. In addition, we investigated the relationship between WM tracts containing WMH
lesions and regional grey matter atrophy and cognitive performance.
Methods
Participants
Data used in this study includes subjects from Alzheimer's Disease Neuroimaging Initiative
(ADNI) database, the Parkinson's Progression Markers Initiative (PPMI), and the frontotemporal
lobar degeneration neuroimaging initiative (NIFD) that had either FLAIR or T2-weighted MR
images.
ADNI
The ADNI (adni.loni.usc.edu) was launched in 2003 as a public-private partnership led by
Principal Investigator Michael W. Weiner, MD. The primary goal of ADNI has been to test
whether serial MRI, positron emission tomography, other biological markers, and clinical and
neuropsychological assessment can be combined to measure the progression of MCI and early AD.
ADNI was carried out with the goal of recruiting 800 adults aged from 55 to 90 years and consists
of approximately 200 cognitively normal patients, 400 patients with MCI, and 200 patients with
AD (http://adni.loni.usc.edu/wp-content/uploads/2010/09/ADNI_GeneralProceduresManual.pdf).
ADNIGO is a later study that followed ADNI participants who were in cognitively normal or early
MCI stages (http://adni.loni.usc.edu/wp-
content/uploads/2008/07/ADNI_GO_Procedures_Manual_06102011.pdf). The ADNI2 study
followed patients in the same categories, recruiting 550 new patients (http://adni.loni.usc.edu/wp-
content/uploads/2008/07/adni2-procedures-manual.pdf). The longitudinal MRI data used in this
study included T1w, T2w/proton densityweighted acquisitions from ADNI1 patients and T1w
and FLAIR acquisitions from ADNI2/GO patients. The scanner information and image acquisition
.CC-BY-ND 4.0 International licenseavailable under a
was not certified by peer review) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity. It is made
The copyright holder for this preprint (whichthis version posted April 8, 2021. ; https://doi.org/10.1101/2021.04.06.438619doi: bioRxiv preprint
parameters have been previously described (Dadar et al., 2017a). The ADNI1, ADNI2 and
ADNIgo studies acquired data from subjects on a yearly basis.
PPMI
The PPMI (http://www.ppmi-info.org) is a longitudinal multi-site clinical study of approximately
600 de novo PD patients and 200 age-matched healthy controls followed over the course of five
years (Marek et al., 2011). The study was approved by the institutional review board of all
participating sites and written informed consent was obtained from all participants before inclusion
in the study.
NIFD
The frontotemporal lobar degeneration neuroimaging initiative (FTLDNI) is founded through the
National Institute of Aging and started in 2010. The primary goals of FTLDNI are to identify
neuroimaging modalities and methods of analysis for tracking frontotemporal lobar degeneration
(FTLD) and to assess the value of imaging versus other biomarkers in diagnostic roles. The
Principal Investigator of FTLDNI is Dr. Howard Rosen, MD at the University of California, San
Francisco. The data is the result of collaborative efforts at three sites in North America. For up-to-
date information on participation and protocol, please
visit: http://memory.ucsf.edu/research/studies/nifd. The FTLDNI contains 120 cognitively normal
controls and 120 patients with FTD followed yearly for three years.
MRI Measurements
WMHs
All T1-weighted, T2-weighted, proton density (PD), and FLAIR MRI scans were preprocessed in
3 steps using our standardized pipeline: denoising (Manjón et al., 2010), intensity non-uniformity
correction (Sled et al., 1998), and intensity normalization into the range 0100. For each subject,
the T2-weighted, PD, and FLAIR scans were then co-registered to the T1-weighted scan of the
same visit using a 6-parameter rigid registration and a mutual information objective function
(Collins et al., 1994; Dadar et al., 2018a). Using a previously validated fully automated WMH
segmentation method and a library of manual segmentations based on 53 patients from ADNI1
and 46 patients from ADNI2/GO, the WMHs were automatically segmented for all longitudinal
.CC-BY-ND 4.0 International licenseavailable under a
was not certified by peer review) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity. It is made
The copyright holder for this preprint (whichthis version posted April 8, 2021. ; https://doi.org/10.1101/2021.04.06.438619doi: bioRxiv preprint
References
More filters
Journal ArticleDOI
Population-averaged atlas of the macroscale human structural connectome and its network topology.

[...]

Fang-Cheng Yeh1, Sandip S. Panesar1, David Fernandes1, Antonio Meola2, Masanori Yoshino, Juan C. Fernandez-Miranda1, Jean M. Vettel3, Timothy Verstynen4 
University of Pittsburgh1, Stanford University2, University of California, Santa Barbara3, Carnegie Mellon University4
24 May 2018-NeuroImage
TL;DR: An expert‐vetted, population‐averaged atlas of the structural connectome derived from diffusion MRI data is reported, providing representative organization of human brain white matter, complementary to traditional histologically‐derived and voxel‐based white matter atlases.

346 citations

Journal ArticleDOI
Association of white matter hyperintensity volume with decreased cognitive functioning: the Framingham Heart Study.

[...]

Rhoda Au1, Joseph M. Massaro1, Philip A. Wolf1, Megan E. Young1, Alexa S. Beiser1, Sudha Seshadri1, Ralph B. D'Agostino1, Charles DeCarli 
Boston University1
01 Feb 2006-JAMA Neurology
TL;DR: In this younger community-based population of nondemented individuals, those with large WMH volume, as compared with those with less or no WMH volumes, performed significantly worse in cognitive domains generally associated with frontal lobe systems and, to a lesser extent, the medial temporal area.
Abstract: Objective To examine the relationship between white matter hyperintensity (WMH) volume on magnetic resonance images and cognitive tests in a large, population-based sample. Methods Quantitative magnetic resonance imaging and neuropsychological evaluations were performed in 1820 dementia- and stroke-free participants from the Framingham Offspring Cohort. The WMH volume relative to total cranial volume was computed; WMH volumes more than 1 SD above the age-predicted mean were defined as large. Adjusting for age, sex, education, height, and Framingham Stroke Risk Profile, we examined the relationship between WMH and 3 cognitive factors derived from a neuropsychological test battery (verbal memory, visuospatial memory and organization, and visual scanning and motor speed) and 3 individual measures of new learning, abstract reasoning, and naming. Results Compared with those with no or little WMH volume, participants with large WMH volume performed worse on the cognitive factors of visuospatial memory and organization (P = .04) and visual scanning and motor speed (P = .01), as well as on new learning (P = .04), but not on verbal memory (P = .52). Conclusions In this younger community-based population of nondemented individuals, those with large WMH volume, as compared with those with less or no WMH volumes, performed significantly worse in cognitive domains generally associated with frontal lobe systems and, to a lesser extent, the medial temporal area. Further study will clarify whether large WMH volume and associated cognitive impairment lead to future risk of stroke or dementia.

342 citations

Journal ArticleDOI
Cerebrovascular and brain morphologic correlates of Mild cognitive impairment in the National Heart, Lung, and Blood Institute Twin study

[...]

Charles DeCarli1, Bruce L. Miller2, Gary E. Swan2, Terry Reed2, Philip A. Wolf2, Dorit Carmelli2 
University of California, Davis1, University of California, Berkeley2
01 Apr 2001-JAMA Neurology
TL;DR: Elevated midlife blood pressures, and the resulting increased white matter hyperintensities, increase the risk for MCI in a group of community-dwelling older men to at least the same degree as apolipoprotein E4 genotype.
Abstract: Objective To evaluate the relative risk (RR) of mild cognitive impairment (MCI) associated with cerebrovascular risk factors and cerebrovascular-related brain changes. Design Mild cognitive impairment was determined for the subjects of the prospective National Heart, Lung, and Blood Institute Twin Study. Quantitative measures of brain, white matter hyperintensity, cerebral infarction, apolipoprotein E genotype, and psychometric testing were obtained. Results Subjects with MCI were older (73.5 ± 3.0 vs 72.1 ± 2.8 years), consumed less alcohol (3.7 ± 5.8 vs 7.0 ± 10.7 drinks per week), had greater white matter hyperintensity volumes (0.56% ± 0.82% vs 0.25% ± 0.34% of cranial volume), and had an increased prevalance of apolipoprotein E4 genotype (31.4% vs 19.2%) than normal subjects. White matter hyperintensity and the presence of the apolipoprotein E4 genotype were associated with a significantly increased risk for MCI. When all subjects were included in the analysis, alcohol consumption was associated with a reduced risk for MCI (RR = 0.93, P P Conclusions Elevated midlife blood pressures, and the resulting increased white matter hyperintensities, increase the risk for MCI in a group of community-dwelling older men to at least the same degree as apolipoprotein E4 genotype. Given the common occurrence of elevations in midlife blood pressure, early and effective treatment may be warranted to prevent late-life brain abnormalities and MCI. Moreover, since many individuals with MCI progress to clinical dementia, longitudinal evaluations of this cohort will be important.

271 citations

Journal ArticleDOI
Longitudinal Changes in White Matter Disease and Cognition in the First Year of the Alzheimer Disease Neuroimaging Initiative

[...]

Owen Carmichael1, Christopher G. Schwarz, David Drucker1, Evan Fletcher1, Danielle J Harvey1, Laurel A. Beckett1, Clifford R. Jack2, Michael W. Weiner3, Charles DeCarli1 
University of California, Davis1, Mayo Clinic2, University of California, San Francisco3
08 Nov 2010-JAMA Neurology
TL;DR: White matter hyperintensity volume predicts 1-year cognitive decline in a relatively healthy convenience sample that was similar to clinical trial samples, and therefore should be considered as a covariate of interest at baseline and longitudinally in future AD treatment trials.
Abstract: Objective To evaluate relationships between magnetic resonance imaging (MRI)–based measures of white matter hyperintensities (WMHs), measured at baseline and longitudinally, and 1-year cognitive decline using a large convenience sample in a clinical trial design with a relatively mild profile of cardiovascular risk factors Design Convenience sample in a clinical trial design Subjects A total of 804 participants in the Alzheimer Disease Neuroimaging Initiative who received MRI scans, cognitive testing, and clinical evaluations at baseline, 6-month follow-up, and 12-month follow-up visits For each scan, WMHs were detected automatically on coregistered sets of T1, proton density, and T2 MRI images using a validated method Mixed-effects regression models evaluated relationships between risk factors for WMHs, WMH volume, and change in outcome measures including Mini-Mental State Examination (MMSE), Alzheimer Disease Assessment Scale–Cognitive Subscale (ADAS-Cog), and Clinical Dementia Rating Scale sum of boxes scores Covariates in these models included race, sex, years of education, age, apolipoprotein E genotype, baseline clinical diagnosis (cognitively normal, mild cognitive impairment, or Alzheimer disease), cardiovascular risk score, and MRI-based hippocampal and brain volumes Results Higher baseline WMH volume was associated with greater subsequent 1-year increase in ADAS-Cog and decrease in MMSE scores Greater WMH volume at follow-up was associated with greater ADAS-Cog and lower MMSE scores at follow-up Higher baseline age and cardiovascular risk score and more impaired baseline clinical diagnosis were associated with higher baseline WMH volume Conclusions White matter hyperintensity volume predicts 1-year cognitive decline in a relatively healthy convenience sample that was similar to clinical trial samples, and therefore should be considered as a covariate of interest at baseline and longitudinally in future AD treatment trials

230 citations

Journal ArticleDOI
Regional white matter hyperintensity volume, not hippocampal atrophy, predicts incident Alzheimer disease in the community.

[...]

Adam M. Brickman, Frank A. Provenzano, Jordan Muraskin, Jennifer J. Manly, Sonja Blum, Zoltan L. Apa, Yaakov Stern, Truman R. Brown, José A. Luchsinger, Richard Mayeux 
01 Dec 2012-JAMA Neurology
TL;DR: The findings highlight the regional specificity of the association of white matter hyperintensities with AD, and it is not clear whether parietal WMHs solely represent a marker for cerebrovascular burden or point to distinct injury compared with other regions.
Abstract: Background New-onset Alzheimer disease (AD) is often attributed to degenerative changes in the hippocampus. However, the contribution of regionally distributed small vessel cerebrovascular disease, visualized as white matter hyperintensities (WMHs) on magnetic resonance imaging, remains unclear. Objective To determine whether regional WMHs and hippocampal volume predict incident AD in an epidemiological study. Design A longitudinal community-based epidemiological study of older adults from northern Manhattan, New York. Setting The Washington Heights/Inwood Columbia Aging Project. Participants Between 2005 and 2007, 717 participants without dementia received magnetic resonance imaging scans. A mean (SD) of 40.28 (9.77) months later, 503 returned for follow-up clinical examination and 46 met criteria for incident dementia (45 with AD). Regional WMHs and relative hippocampal volumes were derived. Three Cox proportional hazards models were run to predict incident dementia, controlling for relevant variables. The first included all WMH measurements; the second included relative hippocampal volume; and the third combined the 2 measurements. Main Outcome Measure Incident AD. Results White matter hyperintensity volume in the parietal lobe predicted time to incident dementia (hazard ratio [HR] = 1.194; P = .03). Relative hippocampal volume did not predict incident dementia when considered alone (HR = 0.419; P = .77) or with the WMH measures included in the model (HR = 0.302; P = .70). Including hippocampal volume in the model did not notably alter the predictive utility of parietal lobe WMHs (HR = 1.197; P = .049). Conclusions The findings highlight the regional specificity of the association of WMHs with AD. It is not clear whether parietal WMHs solely represent a marker for cerebrovascular burden or point to distinct injury compared with other regions. Future work should elucidate pathogenic mechanisms linking WMHs and AD pathology.

211 citations

Related Papers (5)
White Matter Hyperintensities and Mild Cognitive Impairment in Parkinson's Disease

[...]

01 Sep 2015-Journal of Neuroimaging
Elijah Mak, Michael G. Dwyer, Deepa P. Ramasamy, Wing Lok Au, Louis C.S. Tan, Robert Zivadinov, Nagaendran Kandiah 
White matter in different regions evolves differently during progression to dementia.

[...]

01 Apr 2019-Neurobiology of Aging
Mahsa Dadar, Josefina Maranzano, Simon Ducharme, D. Louis Collins, Alzheimer’s Disease Neuroimaging Initiative 
Regional white matter hyperintensity volume, not hippocampal atrophy, predicts incident Alzheimer disease in the community.

[...]

01 Dec 2012-JAMA Neurology
Adam M. Brickman, Frank A. Provenzano, Jordan Muraskin, Jennifer J. Manly, Sonja Blum, Zoltan L. Apa, Yaakov Stern, Truman R. Brown, José A. Luchsinger, Richard Mayeux 
Cognitive and motor correlates of grey and white matter pathology in Parkinson's disease.

[...]

01 Jan 2020-NeuroImage: Clinical
Mahsa Dadar, Myrlene Gee, Ashfaq Shuaib, Simon Duchesne, Richard Camicioli 
Extent and distribution of white matter hyperintensities in normal aging, MCI, and AD

[...]

26 Dec 2006-Neurology
Mitsuhiro Yoshita, Evan Fletcher, Danielle J Harvey, Mario Ortega, Oliver Martinez, Dan M Mungas, Bruce R Reed, Charles DeCarli