Metabolic correlates of late midlife cognitive outcomes: findings from the 1946 British Birth Cohort

Green, Rebecca; Lord, Jodie; Xu, Jin; Maddock, Jane; Kim, Min; Dobson, Richard; Legido‐Quigley, Cristina; Wong, Andrew; Richards, Marcus; Proitsi, Petroula

doi:10.1093/braincomms/fcab291

Cited by 10 publications

(15 citation statements)

References 54 publications

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“…In line with our previous analysis in the full NSHD (10,19), covariables were: sex, blood collection information (clinic location, age, fasting status), age at scan, APOE genotype (ε4 carrier/non carrier; blood samples at age 53 or 69y), BMI (60-64y nurse visit), lipid medication (yes/no; self-reported use in 24 hours preceding blood collection at 60-64y), childhood cognition (15y), highest level of educational attainment (no qualifications/'O level'/'A level' or higher; 26y), childhood socioeconomic position (SEP) (Father's current or last known occupation categorised according to the UK Registrar General; 11y), and midlife SEP (own occupation categorised as for childhood SEP; 53y).…”

Section: Covariablessupporting

confidence: 91%

“…Fourteen modules of highly connected metabolites were then identified, and the first principal component of each module (termed “module eigenvalue”) was derived to allow for relationships between modules and outcomes to be examined. Overrepresentation analyses were conducted, using the hypergeometric test, to identify enriched pathways within the module and provide insight into potential biological function (10). Modules were allocated an arbitrary colour name using the WGCNA package for ease of discussion.…”

Section: Methodsmentioning

confidence: 99%

“…To explore associations of clusters (termed "modules") of co-expressed metabolites, we applied weighted gene coexpression network analysis (WGCNA) (21)(22)(23) to metabolite data, as detailed previously (10). First, metabolite data were adjusted for sex and blood clinic information and the standardised residuals were used for WGCNA.…”

Section: Network Analysismentioning

confidence: 99%

“…Metabolite data underwent strict quality control (QC), as detailed in (10), resulting in 1019 metabolites (Supplementary Notes).…”

Section: Metabolite Quality Controlmentioning

confidence: 99%

“…Additionally, little is known about the involvement of groups of interrelated metabolites; utilising systems-level approaches could offer an improved understanding of these complex relationships and facilitate the identification of candidate markers. We previously employed a systems-level approach to explore the metabolic correlates of late midlife cognition in the Medical Research Council National Survey of Health and Development (NSHD; the British 1946 birth cohort) (10). We identified groups of highly coexpressed metabolites that associated with cognitive outcomes and key metabolites within these to explore further, including acylcarnitines, modified nucleotides and amino acids, vitamins, and sphingolipids; although many associations with late midlife cognition were explained by social factors and childhood cognition (10).…”

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confidence: 99%

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Investigating associations between blood metabolites, later life brain imaging measures, and genetic risk for Alzheimer’s disease

Green

Lord

Scelsi

et al. 2022

Preprint

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Identifying blood-based signatures of brain health and preclinical pathology may offer insights into early disease mechanisms and highlight avenues for intervention. Here, we systematically profiled associations between blood metabolites and whole-brain volume, hippocampal volume, and amyloid-β status among participants of Insight 46 — the neuroscience sub-study of the National Survey of Health and Development (NSHD). We additionally explored whether key metabolites were associated with polygenic risk for Alzheimer's disease (AD). Following quality control, concentrations of 1019 metabolites – detected with liquid chromatography-mass spectrometry – were available for 1740 participants at age 60-64. Metabolite data were subsequently clustered into modules of co-expressed metabolites using weighted coexpression network analysis. Accompanying MRI and amyloid-PET imaging data were present for 437 participants (age 69-71). Regression analyses tested relationships between metabolite measures – modules and hub metabolites – and imaging outcomes. Hub metabolites were defined as metabolites that were highly connected within significant (pFDR<0.05) modules or previously identified as a hub for cognition in the same cohort. Regression models included adjustments for age, sex, APOE genotype, lipid medication use, childhood cognition and social factors. Finally, AD polygenic risk scores (PRS), including and excluding the APOE region, were tested for relationships with metabolites and modules that associated (pFDR<0.05) with an imaging outcome (N=1638). In the fully adjusted model, three lipid modules were associated with a brain volume measure (pFDR<0.05): one enriched in sphingolipids (hippocampal volume: β=0.14, 95%CI=[0.055,0.23]), one in several fatty acid pathways (whole-brain volume: β=-0.072, 95%CI=[-0.12,-0.026]), and another in diacylglycerols and phosphatidylethanolamines (whole-brain volume: β=-0.066, 95%CI=[-0.11,-0.020]). Twenty-two hub metabolites were associated (pFDR<0.05) with an imaging outcome (whole-brain volume: 22; hippocampal volume: 4). Some nominal associations were reported for amyloid-β, and with an AD PRS in our genetic analysis, but none survived multiple testing correction. Our findings highlight key metabolites, with functions in membrane integrity and cell signalling, that associated with structural brain measures in later life. Future research should focus on replicating this work and interrogating causality.

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Section: Covariablessupporting

confidence: 91%

Section: Methodsmentioning

confidence: 99%

Section: Network Analysismentioning

confidence: 99%

“…Metabolite data underwent strict quality control (QC), as detailed in (10), resulting in 1019 metabolites (Supplementary Notes).…”

Section: Metabolite Quality Controlmentioning

confidence: 99%

mentioning

confidence: 99%

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Investigating associations between blood metabolites, later life brain imaging measures, and genetic risk for Alzheimer’s disease

Green

Lord

Scelsi

et al. 2022

Preprint

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Artificial intelligence for dementia prevention

Newby,

Orgeta,

Marshall

et al. 2023

Alzheimer's & Dementia

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INTRODUCTIONA wide range of modifiable risk factors for dementia have been identified. Considerable debate remains about these risk factors, possible interactions between them or with genetic risk, and causality, and how they can help in clinical trial recruitment and drug development. Artificial intelligence (AI) and machine learning (ML) may refine understanding.METHODSML approaches are being developed in dementia prevention. We discuss exemplar uses and evaluate the current applications and limitations in the dementia prevention field.RESULTSRisk‐profiling tools may help identify high‐risk populations for clinical trials; however, their performance needs improvement. New risk‐profiling and trial‐recruitment tools underpinned by ML models may be effective in reducing costs and improving future trials. ML can inform drug‐repurposing efforts and prioritization of disease‐modifying therapeutics.DISCUSSIONML is not yet widely used but has considerable potential to enhance precision in dementia prevention.Highlights Artificial intelligence (AI) is not widely used in the dementia prevention field. Risk‐profiling tools are not used in clinical practice. Causal insights are needed to understand risk factors over the lifespan. AI will help personalize risk‐management tools for dementia prevention. AI could target specific patient groups that will benefit most for clinical trials.

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