Predicting the Emergence of Major Neurocognitive Disorder Within Three Months After a Stroke

Aamodt, Eva Birgitte; Schellhorn, Till; Stage, Edwin; Sanjay, Apoorva Bharthur; Logan, Paige E.; Svaldi, Diana Otero; Apostolova, Liana G.; Saltvedt, Ingvild; Beyer, Mona K.

doi:10.3389/fnagi.2021.705889

Cited by 8 publications

(21 citation statements)

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“…Due to noticeable underestimation of WMH across multiple thresholds, manual editing of the FSL BIANCA output was performed. Full description of WMH segmentation methods is given elsewhere (5).…”

Section: Stroke Location Stroke Volume and Wmh Volume Extractionmentioning

confidence: 99%

“…Stroke and dementia both pose risks for each other and share many of the same neurodegenerative and cerebrovascular risk factors (2), with preexisting structural brain pathology being a frequent finding in stroke patients (3). Early onset (<3 months) of post-stroke dementia (PSD) has been found to be primarily associated with stroke lesion volume and white matter hyperintensity (WMH) load (4)(5)(6)(7). The likelihood of developing cognitive impairment after a stroke does however remain elevated for many years after the incident (8), with late onset (>6 months) being mainly associated with the presence of lacunes and a history of ischemic heart disease and stroke (9).…”

Section: Introductionmentioning

confidence: 99%

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Longitudinal Brain Changes After Stroke and the Association With Cognitive Decline

et al. 2022

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BackgroundCognitive impairment is common after stroke. So is cortical- and subcortical atrophy, with studies reporting more atrophy in the ipsilesional hemisphere than the contralesional hemisphere. The current study aimed to investigate the longitudinal associations between (I) lateralization of brain atrophy and stroke hemisphere, and (II) cognitive impairment and brain atrophy after stroke. We expected to find that (I) cortical thickness and hippocampal-, thalamic-, and caudate nucleus volumes declined more in the ipsilesional than the contralesional hemisphere up to 36 months after stroke. Furthermore, we predicted that (II) cognitive decline was associated with greater stroke volumes, and with greater cortical thickness and subcortical structural volume atrophy across the 36 months.MethodsStroke survivors from five Norwegian hospitals were included from the multisite-prospective “Norwegian Cognitive Impairment After Stroke” (Nor-COAST) study. Analyses were run with clinical, neuropsychological and structural magnetic resonance imaging (MRI) data from baseline, 18- and 36 months. Cortical thicknesses and subcortical volumes were obtained via FreeSurfer segmentations and stroke lesion volumes were semi-automatically derived using ITK-SNAP. Cognition was measured using MoCA.ResultsFindings from 244 stroke survivors [age = 72.2 (11.3) years, women = 55.7%, stroke severity NIHSS = 4.9 (5.0)] were included at baseline. Of these, 145 (59.4%) had an MRI scan at 18 months and 72 (49.7% of 18 months) at 36 months. Most cortices and subcortices showed a higher ipsi- compared to contralesional atrophy rate, with the effect being more prominent in the right hemisphere. Next, greater degrees of atrophy particularly in the medial temporal lobe after left-sided strokes and larger stroke lesion volumes after right-sided strokes were associated with cognitive decline over time.ConclusionAtrophy in the ipsilesional hemisphere was greater than in the contralesional hemisphere over time. This effect was found to be more prominent in the right hemisphere, pointing to a possible higher resilience to stroke of the left hemisphere. Lastly, greater atrophy of the cortex and subcortex, as well as larger stroke volume, were associated with worse cognition over time and should be included in risk assessments of cognitive decline after stroke.

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Section: Stroke Location Stroke Volume and Wmh Volume Extractionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Longitudinal Brain Changes After Stroke and the Association With Cognitive Decline

et al. 2022

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“…As previously described (Aamodt et al, 2021), WMH segmentation was performed using the fully automated and supervised tool BIANCA (Griffanti et al, 2016). BIANCA is based on an algorithm using the k-nearest neighbor and classifies the probability of WMHs based on intensity and spatial features of voxels.…”

Section: Methodsmentioning

confidence: 99%

“…Several factors are associated with poorer outcomes after stroke, including old age, lower education, pre-stroke disability, left-sided stroke (Pendlebury, 2012; Pendlebury & Rothwell, 2009), diabetes mellitus, a history of stroke (Lo et al, 2019), larger stroke lesions and vascular factors, such as white matter hyperintensities (WMH) (Schellhorn et al, 2021a; Aamodt et al, 2021). Brain atrophy after stroke (Brodtmann et al, 2020; Levine et al, 2015) is also associated with cognitive decline (Mijajlovic et al, 2017; Haque et al, 2019), particularly if accompanied by hypertension (Sayed et al, 2020) or other vasculopathies (Schellhorn et al, 2021b), with global and medial temporal lobe atrophy and WMH load among the most predictive factors 12 months post-stroke (Jokinen et al, 2020; Casolla, 2019; Wang et al, 2021; Ball et al, 2021; Schellhorn et al, 2021a).…”

Section: Introductionmentioning

confidence: 99%

“…Advanced age is a major risk factor for both stroke and of poorer prognosis following stroke (Pendlebury & Rothwell, 2009), and is the primary risk factor for neurodegeneration (Hou et al, 2019) and lower cognitive reserve and resilience, rendering the individual more vulnerable to post stroke NCD (Mattson & Arumugam, 2018;Hou et al, 2019; Aamodt et al, 2021). The individual differences in cognitive function among seniors are substantial (Sanchez-Izquierdo & Fernandez-Ballesteros, 2021) and chronological age alone is therefore not a reliable predictor for pre-stroke function and post stroke outcome (Wagner et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

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Longitudinal brain age prediction and cognitive function after stroke

Aamodt

Alnæs

Lange

et al. 2022

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BackgroundAdvanced age and poor brain health have been associated with higher risk for more severe clinical and cognitive outcomes following stroke, but more accurate models for clinical prediction are needed. Machine learning based on brain scans can be used to estimate brain age of individual patients, and the corresponding difference from chronological age, the brain age gap (BAG) has been investigated in a range of clinical conditions. Yet, the predictive value for post stroke NCD has not been established. To this end, using longitudinal data we aimed to investigate the association between BAG and post-stroke neurocognitive disorder (NCD) over time.Methods269 stroke survivors (55.4% women, mean (SD) age = 71 (11) years) were included from the Norwegian Cognitive Impairment After Stroke (Nor-COAST) study. MRI and clinical data were collected shortly after the acute stroke (neuropsychological data first after 3 months) and at 18- and 36 months follow-up. The brain age model was trained in an independent sample using established protocols based on machine learning and brain structural features from Freesurfer and applied to the current dataset. We used linear mixed effects (LME) models and survival analysis to assess the associations between cognitive status and longitudinal brain age.ResultsLMEs revealed a main effect of BAG on post stroke NCD across time, confirming our main hypothesis that a younger appearing brain may protect against post stroke NCD. For patients with no NCD at baseline, survival analysis suggested that higher baseline BAG was associated with higher risk of post stroke NCD at 18 and 36 months.ConclusionA younger appearing brain is associated with lower risk of post stroke NCD up to 36 months after a stroke, even among those showing no evidence of impairments 3 months after hospital admission. Brain age prediction based on brain scans provides a reliable assessment of brain structure and is sensitive to post stroke NCD with predictive value for cognitive decline among patients with no impairment at the initial assessment.

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