Your search keyword '"O'Keeffe, Linda M."' showing total 7 results

1. Puberty timing and markers of cardiovascular structure and function at 25 years: a prospective cohort study

Author

Maher, Gillian M., Ryan, Lisa, McCarthy, Fergus P., Hughes, Alun, Park, Chloe, Fraser, Abigail, Howe, Laura D., Kearney, Patricia M., and O’Keeffe, Linda M.

Published

2021

2. Sex differences in systemic metabolites at four life stages: cohort study with repeated metabolomics

Author

Bell, Joshua A., Santos Ferreira, Diana L., Fraser, Abigail, Soares, Ana Luiza G., Howe, Laura D., Lawlor, Deborah A., Carslake, David, Davey Smith, George, and O’Keeffe, Linda M.

Published

2021

3. Epigenetic gestational age and trajectories of weight and height during childhood: a prospective cohort study

Author

Bright, Harold D., Howe, Laura D., Khouja, Jasmine N., Simpkin, Andrew J., Suderman, Matthew, and O’Keeffe, Linda M.

Published

2019

4. Life course effects of genetic susceptibility to higher body size on body fat and lean mass: prospective cohort study.

Author

Waterfield, Scott, Richardson, Tom G, Smith, George Davey, O'Keeffe, Linda M, and Bell, Joshua A

Subjects

ADIPOSE tissues, BODY composition, BODY size, FAT, LEAN body mass, DUAL-energy X-ray absorptiometry, COHORT analysis, LONGITUDINAL method

Abstract

Background/objectives Different genetic variants are associated with larger body size in childhood vs adulthood. Whether and when these variants predominantly influence adiposity are unknown. We examined how genetic variants influence total body fat and total lean mass trajectories. Methods Data were from the Avon Longitudinal Study of Parents and Children birth cohort (N  = 6926). Sex-specific genetic risk scores (GRS) for childhood and adulthood body size were generated, and dual-energy X-ray absorptiometry scans measured body fat and lean mass six times between the ages of 9 and 25 years. Multilevel linear spline models examined associations of GRS with fat and lean mass trajectories. Results In males, the sex-specific childhood and adulthood GRS were associated with similar differences in fat mass from 9 to 18 years; 8.3% [95% confidence interval (CI) 5.1, 11.6] and 7.5% (95% CI 4.3, 10.8) higher fat mass at 18 years per standard deviation (SD) higher childhood and adulthood GRS, respectively. In males, the sex-combined childhood GRS had stronger effects at ages 9 to 15 than the sex-combined adulthood GRS. In females, associations for the sex-specific childhood GRS were almost 2-fold stronger than the adulthood GRS from 9 to 18 years: 10.5% (95% CI 8.5, 12.4) higher fat mass at 9 years per SD higher childhood GRS compared with 5.1% (95% CI 3.2, 6.9) per-SD higher adulthood GRS. In females, the sex-combined GRS had similar effects, with slightly larger effect estimates. Lean mass effect sizes were much smaller. Conclusions Genetic variants for body size are more strongly associated with adiposity than with lean mass. Sex-combined childhood variants are more strongly associated with increased adiposity until early adulthood. This may inform future studies that use genetics to investigate the causes and impact of adiposity at different life stages. [ABSTRACT FROM AUTHOR]

Published

2023

5. Epigenetic gestational age acceleration: a prospective cohort study investigating associations with familial, sociodemographic and birth characteristics

Author

Khouja, Jasmine N., Simpkin, Andrew J., O’Keeffe, Linda M., Wade, Kaitlin H., Houtepen, Lotte C., Relton, Caroline L., Suderman, Matthew, and Howe, Laura D.

Published

2018

6. Sex differences in systemic metabolites at four life stages:cohort study with repeated metabolomics

Author

Bell, Joshua A, Dos Santos Ferreira, Diana L, Fraser, Abigail, Goncalves Soares, Ana Luiza, Howe, Laura D, Lawlor, Debbie A, Carslake, David J, Davey Smith, George, and O'Keeffe, Linda M

Subjects

Coronary heart disease, NMR metabolomics, Epidemiology, Sex differences, Metabolites, ALSPAC

Abstract

Background: Males experience higher rates of coronary heart disease (CHD) than females, but the circulating traits underpinning this difference are poorly understood. We examined sex differences in systemic metabolites measured at four life stages, spanning childhood to middle-adulthood.Methods: Data were from the Avon Longitudinal Study of Parents and Children (7,727 offspring, 49% male; and 6,500 parents, 29% male). Proton nuclear magnetic resonance (1HNMR) spectroscopy from a targeted metabolomics platform was performed on EDTA-plasma or serum samples to quantify 229 systemic metabolites (including lipoprotein-subclass specific lipids, pre-glycemic factors, and inflammatory glycoprotein acetyls). Metabolites were measured in the same offspring once in childhood (mean age 8y), twice in adolescence (16y and 18y) and once in early-adulthood (25y), and in their parents once in middle adulthood (50y). Linear regression models estimated differences in metabolites for males versus females on each occasion (serial cross-sectional associations).Results: At 8y, total lipids in very-low-density lipoproteins (VLDL) were lower in males; levels were higher in males at 16y and higher still by 18y and 50y (among parents) for medium-or-larger subclasses. Larger sex differences at older ages were most pronounced for VLDL triglycerides – males had 0.19 standard deviations (SD) (95% CI=0.12, 0.26) higher at 18y, 0.50 SD (95% CI=0.42, 0.57) higher at 25y, and 0.62 SD (95% CI=0.55, 0.68) higher at 50y. Low-density lipoprotein (LDL) cholesterol, apolipoprotein-B, and glycoprotein acetyls were generally lower in males across ages. The direction and magnitude of effects were largely unchanged when adjusting for body mass index measured at the time of metabolite assessment on each occasion.Conclusions: Our results suggest that males begin to have higher VLDL triglyceride levels in adolescence, with larger sex differences at older ages. Sex differences in other CHD-relevant metabolites, including LDL cholesterol, show the opposite pattern with age, with higher levels among females. Such life course trends may inform causal analyses with clinical endpoints in specifying traits which underpin higher age-adjusted CHD rates commonly seen among males.

Published

2021

7. Associations of Body Mass and Fat Indexes With Cardiometabolic Traits.

Author

Bell, Joshua A, Carslake, David, O'Keeffe, Linda M, Frysz, Monika, Howe, Laura D, Hamer, Mark, Wade, Kaitlin H, Timpson, Nicholas J, and Davey Smith, George

Abstract

Background: Body mass index (BMI) is criticized for not distinguishing fat from lean mass and ignoring fat distribution, leaving its ability to detect health effects unclear.Objectives: The aim of this study was to compare BMI with total and regional fat indexes from dual-energy x-ray absorptiometry in their associations with cardiometabolic traits. Duration of exposure to and change in each index across adolescence were examined in relation to detailed traits in young adulthood.Methods: BMI was examined alongside total, trunk, arm, and leg fat indexes (each in kilograms per square meter) from dual-energy x-ray absorptiometry at ages 10 and 18 years in relation to 230 traits from targeted metabolomics at age 18 years in 2,840 offspring from the Avon Longitudinal Study of Parents and Children.Results: Higher total fat mass index and BMI at age 10 years were similarly associated with cardiometabolic traits at age 18 years, including higher systolic and diastolic blood pressure, higher very low-density lipoprotein and low-density lipoprotein cholesterol, lower high-density lipoprotein cholesterol, higher triglycerides, and higher insulin and glycoprotein acetyls. Associations were stronger for both indexes measured at age 18 years and for gains in each index from age 10 to 18 years (e.g., 0.45 SDs [95% confidence interval: 0.38 to 0.53] in glycoprotein acetyls per SD unit gain in fat mass index vs. 0.38 SDs [95% confidence interval: 0.27 to 0.48] per SD unit gain in BMI). Associations resembled those for trunk fat index. Higher lean mass index was weakly associated with traits and was not protective against higher fat mass index.Conclusions: The results of this study support abdominal fatness as a primary driver of cardiometabolic dysfunction and BMI as a useful tool for detecting its effects. [ABSTRACT FROM AUTHOR]

Published

2018