Subcortical hyperintensity volumetrics in Alzheimer’s disease and normal elderly in the Sunnybrook Dementia Study: correlations with atrophy, executive function, mental processing speed, and verbal memory

MRI scans were obtained on patients with AD (AD: n = 265) and cognitively normal elderly volunteers (NC: n = 100) enrolled in the Sunnybrook Dementia Study (ClinicalTrials.gov: NCT01800214), which is a large ongoing longitudinal study conducted in the LC Campbell Cognitive Neurology Research Unit and the Heart & Stroke Foundation Canadian Partnership for Stroke Recovery, at Sunnybrook Health Sciences Centre in Toronto, Canada.

Patients with AD were slightly older (AD = 72.8 ± 9.0 versus NC = 69.5 ± 8.0, P <0.001) and less educated (AD = 13.8 ± 3.8 versus NC = 15.5 ± 3.0, P <0.001). The presence/non-presence of SH was not an exclusionary criterion for this study, and both groups showed a non-normal distribution of SH volumes. Participants were excluded if they had signs of Parkinson’s disease or neurological diseases other than dementia, history of significant head trauma, psychotic disorders unrelated to dementia, psychoactive substance abuse, major depression, and other clinically significant pathology such as overt stroke, tumors, or normal pressure hydrocephalus. Patients with AD met National Institute of Neurological and Communicative Disorders and Stroke (NINCDS) Alzheimer’s Disease and Related Disorders Association (ADRDA) criteria for probable or possible AD [20] and Diagnostic and Statistical Manual of Mental Disorders (4th ed.) [21] criteria for dementia. All patients received a standardized comprehensive clinical evaluation. NC participants were community-dwelling with no subjective or objective cognitive impairment and no history of significant psychiatric or neurological diseases. All NC met strict criteria, including pre-screening followed by a battery of neuropsychological testing with performance threshold requirements for consideration. The study protocol was approved by the Sunnybrook Research Ethics Board (REB PIN no. 009-1998), and written informed consent was obtained from all participants or their caregivers/decision-makers or both.

Neuropsychological testing was performed within 12 weeks of MRI acquisition and administered according to standard protocols. Executive function, mental processing speed, and memory domain tests were selected because these domains have been most consistently associated with SH in the previous literature. (See Table 1 for specific measures used.) Executive function was assessed by using performance scores obtained from the F-A-S phonemic verbal fluency task [22] and the Wisconsin Card Sorting Test [23]. The time to complete the Trails A trail-making test was used to assess speed of mental processing [24]. The California Verbal Learning Test [25], Wechsler Memory Scale-Revised immediate Visual Reproduction [26], and the Dementia Rating Scale memory subscore [27] were used to assess memory. Composite scores were generated by using normalized mean z-scores and normal elderly control population data from the Sunnybrook Dementia Study.

All brain imaging data were obtained on a 1.5 Tesla GE Signa (Milwaukee, WI, USA) system in compliance with consensus recommendations for studies examining vascular cognitive impairment [19]. Three image sets were used: a T1-weighted—axial three-dimensional (3D) Spoiled Gradient Recalled Echo (SPGR): 5 ms echo time (TE), 35 ms repetition time (TR), 1 number of excitations (NEX), 35° flip angle, 22 × 16.5 cm (FOV), 0.859 × 0.859 mm in-plane resolution, 1.2 to 1.4 mm slice thickness depending on head size—and an interleaved PD and T2 (interleaved axial dual-echo spin echo: TEs of 30 and 80 ms, 3 s TR, 0.5 NEX, 20 × 20 cm FOV, 0.781 × 0.781 mm in-plane resolution, 3 mm slice thickness).

Full methodological details and reliability results of the image processing pipeline are previously published [18, 28]. In brief, the Lesion Explorer (LE) processing pipeline (available for download at http://​sabre.​brainlab.​ca), a tri-feature (T1/PD/T2) segmentation and parcellation procedure, was applied to obtain regionalized and whole-brain volumetrics for GM, WM, sCSF, vCSF, periventricular SH (pvSH), deep white SH (dwSH), and cystic fluid filled lacunar-like infarcts (lacunes). The Brain-Sizer component of LE effectively removed skull and other non-brain structures to obtain a reliable measure of supra-tentorial total intracranial volume (ST-TIV), a process which included a measure of subarachnoid CSF immediately below the dura mater. A robust T1-based basic tissue (GM, WM, sCSF) segmentation, which fits localized voxel intensities to four Gaussian curves, was performed [29]. The Semi-Automatic Brain Region Extraction (SABRE) component of LE parcellated the brain into 26 standardized VOIs described in a previous publication [30]. The third component of LE segmented SH from PD/T2, parcellated each volume into the 26 SABRE VOIs, separated SH volumes into pvSH and dwSH by using a 3D connectivity algorithm, and further segmented lacunar-like infarcts within each SH volume by using information from the initial T1 segmentation. The final output provided a comprehensive volumetric profile for each individual that included volumetrics within 26 SABRE VOIs for GM, WM, sCSF, vCSF, pvSH, dwSH, and lacunes.

Terminology and definitions were in compliance with the international neuroimaging standards recently recommended by the STandards for ReportIng Vascular changes on nEuroimaging (STRIVE) [2].

Although mean raw volumetric data are presented for transparency purposes and volumetric comparisons across studies (Table 2), all statistical analyses were performed on normalized values following a previously published standard procedure [31] and subsequently converted to z-scores (with log transformation when required). Between-group volumetric differences (AD versus NC) were compared by using analysis of covariance (ANCOVA). Cohen’s d effect sizes were calculated for significant between-group comparison results by using the pooled standard deviation method on corrected data (note: volumetric tables show raw data). A standardized a priori VOI-based analysis approach was used to test the SABRE VOIs. In brief, step-wise modeling for exploratory analyses combined the SABRE VOIs for each of the four major lobes (frontal, parietal, temporal, and occipital) which yielded reasonable associations for our VOIs. After localizing the correlations to a particular lobe, subregional parcellations within each SABRE subregion were entered into the a priori subparcels into each regression model, which was limited to a maximum of six VOIs per model. Within-group SH VOI correlations with cognitive performance scores were assessed by using linear regression with backwards elimination of non-significant variables. All analyses accounted for age, sex, years of education, and brain parenchymal fraction (BPF), where BPF was defined as a measure of whole-brain atrophy, calculated by dividing the total parenchymal volume (GM + WM) by the ST-TIV. After removal of the cerebellum and subtentorial structures, ST-TIV was calculated for each individual and included all parenchyma (GM + WM), SH and lacunar volumes, sulcal and ventricular CSF, and all CSF immediately below the dura mater to provide an accurate measure of the intracranial cavity. In addition to BPF, head size-corrected vCSF volumes (vCSF/ST-TIV) were analyzed as another commonly used imaging biomarker of brain atrophy [32‐34]. Age, sex, years of education, and scores from the Mini-Mental State Exam (MMSE) [35] were entered as covariates to account for differences in disease severity.