Introduction Neuroaxonal damage may contribute to cognitive changes preceding clinical dementia. Accessible biomarkers are critical for detecting such damage. Methods Plasma and cerebrospinal fluid (CSF) neurofilament light (NFL) were related to neuropsychological performance among Vanderbilt Memory & Aging Project participants (plasma n = 333, 73 ± 7 years; CSF n = 149, 72 ± 6 years) ranging from normal cognition (NC) to mild cognitive impairment (MCI). Models adjusted for age, sex, race/ethnicity, education, apolipoprotein E ε4 carriership, and Framingham Stroke Risk Profile. Results Plasma NFL was related to all domains (P values ≤ .008) except processing speed (P values ≥ .09). CSF NFL was related to memory and language (P values ≤ .04). Interactions with cognitive diagnosis revealed widespread plasma associations, particularly in MCI participants, which were further supported in head‐to‐head comparison models. Discussion Plasma and CSF NFL (reflecting neuroaxonal injury) relate to cognition among non‐demented older adults albeit with small to medium effects. Plasma NFL shows particular promise as an accessible biomarker with relevance to cognition in MCI.
Perivascular spaces (PVS) are fluid filled compartments that are part of the cerebral blood vessel wall and represent the conduit for fluid transport in and out of the brain. PVS are considered pathologic when sufficiently enlarged to be visible on magnetic resonance imaging. Recent studies have demonstrated that enlarged PVS (ePVS) may have clinical consequences related to cognition. Emerging literature points to arterial stiffening and abnormal protein aggregation in vessel walls as two possible mechanisms that drive ePVS formation. In this review, we describe the clinical consequences, anatomy, fluid dynamics, physiology, risk factors, and in vivo quantification methods of ePVS. Given competing views of PVS physiology, we detail the two most prominent theoretical views and review ePVS associations with other common small vessel disease markers. As ePVS are a marker of small vessel disease and ePVS burden is higher in Alzheimer’s disease, a comprehensive understanding about ePVS is essential in developing prevention and treatment strategies.
Ascorbate (vitamin C) is critical as a first line of defense antioxidant within the brain, and specifically within the synapse. Ascorbate is released by astrocytes during glutamate clearance and disruption of this exchange mechanism may be critical in mediating glutamate toxicity within the synapse. This is likely even more critical in neurodegenerative disorders with associated excitotoxicity and seizures, in particular Alzheimer's disease, in which ascorbate levels are often low. Using Gulo mice that are dependent on dietary ascorbate, we established that low brain ascorbate increased sensitivity to kainic acid as measured via behavioral observations, electroencephalography (EEG) measurements, and altered regulation of several glutamatergic system genes. Kainic acid-induced immobility was improved in wild-type mice following treatment with ceftriaxone, which upregulates glutamate transporter GLT-1. The same effect was not observed in ascorbate-deficient mice in which sufficient ascorbate is not available for release. A single, mild seizure event was sufficient to disrupt performance in the water maze in low-ascorbate mice and in APP/PSEN1 mice. Together, the data support the critical role of brain ascorbate in maintaining protection during glutamatergic hyperexcitation events, including seizures. The study further supports a role for mild, subclinical seizures in cognitive decline in Alzheimer's disease.
BackgroundSubtle reductions in cardiac output relate to lower cerebral blood flow, especially in regions where Alzheimer's disease pathology first develops. Apolipoprotein E (APOE)‐ε4 is a genetic susceptibility risk factor for Alzheimer's disease that also moderates vascular damage. This study investigated whether APOE‐ε4 carrier status modifies the cross‐sectional association between cardiac output and cognition.Methods and ResultsVanderbilt Memory & Aging Project participants free of clinical stroke and dementia (n=306, 73±7 years, 42% female) underwent echocardiography to determine cardiac output (L/min), comprehensive neuropsychological assessment, and venous blood draw to determine APOE genotype and ε4 carrier status. Linear regressions related cardiac output to neuropsychological test performance, adjusting for age, sex, education, race/ethnicity, body surface area, cognitive diagnosis, Framingham Stroke Risk Profile, and APOE‐ε4 status. Main effect models were null (P>0.19). With identical covariates, models were repeated testing a cardiac output×APOE‐ε4 status interaction and again stratified by ε4 carrier status. Cardiac output×APOE‐ε4 status related to naming (β=0.91, P=0.0009), category fluency (β=1.2, P=0.01), information processing speed (β=−5.4, P=0.001), visuospatial skill (β=0.85, P=0.003), and executive function performances (β=0.22, P=0.002). Stratified models suggested that lower cardiac output was associated with worse neuropsychological performances among APOE‐ε4 carriers.Conclusions APOE‐ε4 carrier status appears to modify the cross‐sectional association between cardiac output and neuropsychological performance such that lower cardiac output relates to poorer performances among carriers of the ε4 allele. These findings add to increasing evidence that APOE‐ε4 carrier status has important implications for associations between vascular and brain health in aging adults.
Objective: To determine whether baseline aortic stiffness, measured by aortic pulse wave velocity (PWV), relates to longitudinal cerebral gray or white matter changes among older adults. Baseline cardiac magnetic resonance imaging will be used to assess aortic PWV while brain magnetic resonance imaging will be used to assess gray matter and white matter hyperintensity (WMH) volumes at baseline, 18 months, 3 years, 5 years, and 7 years. Approach and Results: Aortic PWV (m/s) was quantified from cardiac magnetic resonance. Multimodal 3T brain magnetic resonance imaging included T 1 -weighted imaging for quantifying gray matter volumes and T 2 -weighted fluid-attenuated inversion recovery imaging for quantifying WMHs. Mixed-effects regression models related baseline aortic PWV to longitudinal gray matter volumes (total, frontal, parietal, temporal, occipital, hippocampal, and inferior lateral ventricle) and WMH volumes (total, frontal, parietal, temporal, and occipital) adjusting for age, sex, race/ethnicity, education, cognitive diagnosis, Framingham stroke risk profile, APOE (apolipoprotein E)-ε4 carrier status, and intracranial volume. Two hundred seventy-eight participants (73±7 years, 58% male, 87% self-identified as non-Hispanic White, 159 with normal cognition, and 119 with mild cognitive impairment) from the Vanderbilt Memory & Aging Project (n=335) were followed on average for 4.9±1.6 years with PWV measurements occurring from September 2012 to November 2014 and longitudinal brain magnetic resonance imaging measurements occurring from September 2012 to June 2021. Higher baseline aortic PWV was related to greater decrease in hippocampal (β=−3.6 [mm 3 /y]/[m/s]; [95% CI, −7.2 to −0.02] P =0.049) and occipital lobe (β=−34.2 [mm 3 /y]/[m/s]; [95% CI, −67.8 to −0.55] P =0.046) gray matter volume over time. Higher baseline aortic PWV was related to greater increase in WMH volume over time in the temporal lobe (β=17.0 [mm 3 /y]/[m/s]; [95% CI, 7.2–26.9] P <0.001). All associations may be driven by outliers. Conclusions: In older adults, higher baseline aortic PWV related to greater decrease in gray matter volume and greater increase in WMHs over time. Because of unmet cerebral metabolic demands and microvascular remodeling, arterial stiffening may preferentially affect certain highly active brain regions like the temporal lobes. These same regions are affected early in the course of Alzheimer disease.
Background Subjective cognitive decline (SCD), a potential harbinger of Alzheimer’s disease (AD), has been cross‐sectionally associated with neurodegeneration and cerebrovascular disease markers on brain MRI. However, longitudinal associations are less clear with few existing studies that yield inconsistent findings. Here, we related baseline SCD to longitudinal structural and hemodynamic markers of brain health in older adults free of clinical dementia and stroke. Methods Vanderbilt Memory & Aging Project participants (n=299,72±7 years, 58% male) completed a baseline SCD protocol and multimodal 3T brain MRI, including T 1‐weighted imaging (grey matter volumes) and pseudo‐continuous arterial spin labeling (cerebral blood flow (CBF)) at baseline and multiple follow‐ups (18‐months, 3‐years, 5‐years). Baseline SCD (total and subdomain memory, language, and executive functioning scores) was longitudinally related to global and regional grey matter volumes and CBF (mL/100g/min). Linear mixed effects models, with random intercepts and slopes and a follow‐up time interaction, covaried for baseline age, sex, race/ethnicity, education, diagnosis, mood, and apolipoprotein E (APOE)‐e4 status. Grey matter volume models covaried for intracranial volume. CBF models covaried for associated tissue volume. Results Mean follow‐up time was 3.8 years. Higher total SCD predicted hippocampal volume reductions (p=0.04), increased inferior lateral ventricular volume (p<0.001; Figure 1A), and global CBF reductions (p<0.001; Figure 1B). Higher scores within each SCD domain predicted hippocampal volume reductions, increased inferior lateral ventricular volume, and global CBF reductions (p‐values<0.04). Higher executive functioning‐SCD related only to frontal and occipital CBF reductions (p‐values<0.003; Figure 1C) but not temporal CBF or lobar atrophy (p‐values>0.07). Language‐SCD predicted reduced frontal CBF (p=0.01; Figure 1D) and temporal lobe volume (p=0.02). Surprisingly, memory‐SCD was not associated with temporal lobe volume or CBF (p‐values>0.05). Sensitivity analyses excluding outliers revealed the same associations. Conclusions Higher baseline SCD predicted multiple pathways of longitudinal brain changes, including cerebral hemodynamics and volume loss within areas first affected by AD. Executive functioning‐SCD predicted hemodynamic changes and language‐SCD related to alterations within the frontal and temporal lobes. Results suggest the relevance of considering the type of SCD, as specific domains may predict different pathologies over time with important prognostic implications. Future research is needed to understand the clinical consequences of these findings.
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