Midlife Aging in the Dunedin Study Phase 52
Lead Research Organisation:
King's College London
Department Name: Social Genetic and Dev Psychiatry Centre
Abstract
The overarching goal of our research program is to discover why some people age earlier and faster than others, and what might be done to prevent this. Increasingly, prevention-minded gerontologists and geroscientists look to midlife as the life stage offering a propitious opportunity to prevent or delay the multiple diseases that shrink older adults' health span. But because most studies of aging have enrolled participants well past midlife, and most studies of younger adults have not measured aging as a process of change over time, there is surprisingly little basic knowledge about aging during midlife. Our research program uniquely fills this gap. This is a proposal to follow up at age 52 a cohort of all 1037 infants born in one city in one year and exhaustively studied ever since: the Dunedin Longitudinal Study, in New Zealand. Some cohort members are becoming biologically older than their peers as they pass through midlife, others remain biologically younger. The proposed follow-up will allow us to quantify how fast or slowly each cohort member is aging in each of 8 different domains: the pace of biological aging, functional aging, facial aging, social aging, sexual aging, inflammatory aging, microvascular aging, and cognitive aging (Objective 1). These 8 domains are typically studied by different scientific disciplines in silos, but we will study them together in one cohort to attract scientific recognition to the great heterogeneity within the whole-person experience of aging. We will develop a measure of each of the 8 kinds of aging, by modelling 3 or more waves of data on each. Three data waves are the minimum requirement to disentangle each person's decline (aging-related decline, how people have changed; their slope) from their level (initial health, where people started; their intercept). Studies with fewer than 3 waves conflate decline over the years (aging) with low scores present since earlier life (not aging). The proposed follow-up at age 52 is necessary to add the essential 3rd midlife wave for this cohort of participants. This follow-up will create an unprecedented unique dataset. We will further generate new knowledge about the early-life antecedents of each kind of aging (Objective 2). We will also generate new knowledge about the risk each of the 8 kinds of aging poses for late-life dementing disease (Objective 3). This involves testing the hypothesis that fast-aging individuals exhibit accelerated brain aging. This will be established through a second wave of neuroimaging at age 52. We previously imaged the brains of Dunedin participants at age 45. We will test 7-year changes in functional neural connectivity and clinical measures of brain structure, while correcting for measurement error. It also involves testing the hypothesis that fast-aging individuals have elevated scores at age 52 on plasma Alzheimers disease biomarkers. To amplify scientific progress, we will deliver to the research community a reliable, valid, open-access DNA-methylation version of each of the 8 new measures of how rapidly a person has been aging (Objective 4). To evaluate generalizability of findings for under-represented ethnic-ancestry groups, we will export the 8 new DNA-methylation measures to Black, Hispanic, and Asian cohorts with methylation, where we have established collaborations to study the pace of aging.
Technical Summary
This is a proposal to follow up at age 52 a cohort of all 1037 infants born in one city in one year and exhaustively studied ever since: the Dunedin Longitudinal Study, in New Zealand. The proposed follow-up will allow us to quantify how fast or slowly each cohort member is aging in each of 8 different domains: the pace of biological aging, functional aging, facial aging, social aging, sexual aging, inflammatory aging, microvascular aging, and cognitive aging (Objective 1). We will develop a measure of each of the 8 kinds of aging, by modelling 3 or more waves of data on each. Three data waves are the minimum requirement to disentangle each person's decline (aging-related decline, how people have changed; their slope) from their level (initial health, where people started; their intercept). The proposed follow-up at age 52 is necessary to add the essential 3rd midlife wave for this cohort of participants. This follow-up will create an unprecedented unique dataset. We will further generate new knowledge about the early-life antecedents of each kind of aging (Objective 2). We will also generate new knowledge about the risk each of the 8 kinds of aging poses for late-life dementing disease (Objective 3). This involves testing the hypothesis that fast-aging individuals exhibit accelerated brain aging, as assessed by 7-year changes in functional neural connectivity and clinical measures of brain structure from neuroimaging. It also involves testing the hypothesis that fast-aging individuals have elevated scores at age 52 on plasma Alzheimer disease biomarkers. To amplify scientific progress, we will deliver to the research community a reliable, valid, open-access DNA-methylation version of each of the 8 new measures of how rapidly a person has been aging (Objective 4). To evaluate generalizability of findings for under-represented ethnic-ancestry groups, we will export the 8 new DNA-methylation measures to Black, Hispanic, and Asian cohorts with methylation.
Publications
Barrett-Young A
(2023)
Childhood Social Isolation as a Predictor of Retinal Neuronal Thickness in Middle Age: A Lifecourse Birth Cohort Study.
in Psychosomatic medicine
Barrett-Young A
(2023)
Associations Between Thinner Retinal Neuronal Layers and Suboptimal Brain Structural Integrity in a Middle-Aged Cohort.
in Eye and brain
Bourassa KJ
(2023)
Childhood Adversity and Midlife Health: Shining a Light on the Black Box of Psychosocial Mechanisms.
in Prevention science : the official journal of the Society for Prevention Research
Brennan GM
(2023)
Tracing the origins of midlife despair: association of psychopathology during adolescence with a syndrome of despair-related maladies at midlife.
in Psychological medicine
Caspi A
(2023)
Accelerated Pace of Aging in Schizophrenia: Five Case-Control Studies
in Biological Psychiatry
Caspi A
(2023)
The General Factor of Psychopathology (p): Choosing Among Competing Models and Interpreting p
in Clinical Psychological Science
Guiney H
(2023)
Kidney-Function Trajectories From Young Adulthood to Midlife: Identifying Risk Strata and Opportunities for Intervention.
in Kidney international reports
Hong CL
(2023)
Oral Health-Related Quality of Life from Young Adulthood to Mid-Life.
in Healthcare (Basel, Switzerland)
Knodt AR
(2023)
Test-retest reliability and predictive utility of a macroscale principal functional connectivity gradient.
in Human brain mapping
Description | Columbia Univ School of Public Health |
Organisation | Columbia University |
Department | School of Public Health |
Country | United States |
Sector | Academic/University |
PI Contribution | we provide data |
Collaborator Contribution | Columbia provides funded young researcher |
Impact | none yet |
Start Year | 2012 |
Description | Evan Macosko, Genomics, Broad Institute, MIT. |
Organisation | Broad Institute |
Country | United States |
Sector | Charity/Non Profit |
PI Contribution | Shared depletable tissue |
Collaborator Contribution | New Technology |
Impact | genomics |
Start Year | 2021 |
Description | Go-DMC methylation consortium |
Organisation | University of Exeter |
Department | Exeter University Arts Faculty |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | data collaboration |
Collaborator Contribution | data collaboration |
Impact | none yet |
Start Year | 2018 |
Description | PROMENTA Centre University of Oslo Norway |
Organisation | University of Oslo |
Country | Norway |
Sector | Academic/University |
PI Contribution | PROMENTA Centre University of Oslo Norway |
Collaborator Contribution | collab |
Impact | Psychology, public health |
Start Year | 2018 |
Description | Singapore Eye Inst Retinal micro-vasculature |
Organisation | Singapore Eye Research Institute |
Country | Singapore |
Sector | Academic/University |
PI Contribution | we contributed the cohort sample, and wrote the papers |
Collaborator Contribution | SERI did the grading of digital retinal photos |
Impact | 2 papers in press |
Start Year | 2010 |