Your search keyword '"William D Thompson"' showing total 17 results

1. Association of maternal circulating 25(OH)D and calcium with birth weight: A mendelian randomisation analysis.

Author

William D Thompson, Jessica Tyrrell, Maria-Carolina Borges, Robin N Beaumont, Bridget A Knight, Andrew R Wood, Susan M Ring, Andrew T Hattersley, Rachel M Freathy, and Debbie A Lawlor

Subjects

Medicine

Abstract

BackgroundSystematic reviews of randomised controlled trials (RCTs) have suggested that maternal vitamin D (25[OH]D) and calcium supplementation increase birth weight. However, limitations of many trials were highlighted in the reviews. Our aim was to combine genetic and RCT data to estimate causal effects of these two maternal traits on offspring birth weight.Methods and findingsWe performed two-sample mendelian randomisation (MR) using genetic instrumental variables associated with 25(OH)D and calcium that had been identified in genome-wide association studies (GWAS; sample 1; N = 122,123 for 25[OH]D and N = 61,275 for calcium). Associations between these maternal genetic variants and offspring birth weight were calculated in the UK Biobank (UKB) (sample 2; N = 190,406). We used data on mother-child pairs from two United Kingdom birth cohorts (combined N = 5,223) in sensitivity analyses to check whether results were influenced by fetal genotype, which is correlated with the maternal genotype (r ≈ 0.5). Further sensitivity analyses to test the reliability of the results included MR-Egger, weighted-median estimator, 'leave-one-out', and multivariable MR analyses. We triangulated MR results with those from RCTs, in which we used randomisation to supplementation with vitamin D (24 RCTs, combined N = 5,276) and calcium (6 RCTs, combined N = 543) as an instrumental variable to determine the effects of 25(OH)D and calcium on birth weight. In the main MR analysis, there was no strong evidence of an effect of maternal 25(OH)D on birth weight (difference in mean birth weight -0.03 g [95% CI -2.48 to 2.42 g, p = 0.981] per 10% higher maternal 25[OH]D). The effect estimate was consistent across our MR sensitivity analyses. Instrumental variable analyses applied to RCTs suggested a weak positive causal effect (5.94 g [95% CI 2.15-9.73, p = 0.002] per 10% higher maternal 25[OH]D), but this result may be exaggerated because of risk of bias in the included RCTs. The main MR analysis for maternal calcium also suggested no strong evidence of an effect on birth weight (-20 g [95% CI -44 to 5 g, p = 0.116] per 1 SD higher maternal calcium level). Some sensitivity analyses suggested that the genetic instrument for calcium was associated with birth weight via exposures that are independent of calcium levels (horizontal pleiotropy). Application of instrumental variable analyses to RCTs suggested that calcium has a substantial effect on birth weight (178 g [95% CI 121-236 g, p = 1.43 × 10-9] per 1 SD higher maternal calcium level) that was not consistent with any of the MR results. However, the RCT instrumental variable estimate may have been exaggerated because of risk of bias in the included RCTs. Other study limitations include the low response rate of UK Biobank, which may bias MR estimates, and the lack of suitable data to test whether the effects of genetic instruments on maternal calcium levels during pregnancy were the same as those outside of pregnancy.ConclusionsOur results suggest that maternal circulating 25(OH)D does not influence birth weight in otherwise healthy newborns. However, the effect of maternal circulating calcium on birth weight is unclear and requires further exploration with more research including RCT and/or MR analyses with more valid instruments.

Published

2019

2. Learning to Learn Functions

Author

Michael Y. Li, Fred Callaway, William D. Thompson, Ryan P. Adams, and Thomas L. Griffiths

Subjects

Artificial Intelligence, Cognitive Neuroscience, Experimental and Cognitive Psychology

Published

2023

3. Fetal alleles predisposing to metabolically favorable adiposity are associated with higher birth weight

Author

William D Thompson, Robin N Beaumont, Alan Kuang, Nicole M Warrington, Yingjie Ji, Jessica Tyrrell, Andrew R Wood, Denise M Scholtens, Bridget A Knight, David M Evans, William L Lowe Jr, Gillian Santorelli, Raq Azad, Dan Mason, Andrew T Hattersley, Timothy M Frayling, Hanieh Yaghootkar, Maria Carolina Borges, Deborah A Lawlor, and Rachel M Freathy

Subjects

Adult, General Medicine, Polymorphism, Single Nucleotide, Body Mass Index, Genetics, Birth Weight, Humans, Genetic Predisposition to Disease, Obesity, Molecular Biology, Alleles, Genetics (clinical), Adiposity, Genome-Wide Association Study

Abstract

Background Higher birthweight is associated with higher adult body mass index (BMI). Alleles that predispose to greater adult adiposity might act in fetal life to increase fetal growth and birthweight. Whether there are fetal effects of recently identified adult metabolically favorable adiposity alleles on birthweight is unknown. Aim We aimed to test the effect on birthweight of fetal genetic predisposition to higher metabolically favorable adult adiposity and compare that with the effect of fetal genetic predisposition to higher adult BMI. Methods We used published genome wide association study data (n = upto 406 063) to estimate fetal effects on birthweight (adjusting for maternal genotype) of alleles known to raise metabolically favorable adult adiposity or BMI. We combined summary data across single nucleotide polymorphisms (SNPs) with random effects meta-analyses. We performed weighted linear regression of SNP-birthweight effects against SNP-adult adiposity effects to test for a dose-dependent association. Results Fetal genetic predisposition to higher metabolically favorable adult adiposity and higher adult BMI were both associated with higher birthweight (3 g per effect allele (95% CI: 1–5) averaged over 14 SNPs; P = 0.002; 0.5 g per effect allele (95% CI: 0–1) averaged over 76 SNPs; P = 0.042, respectively). SNPs with greater effects on metabolically favorable adiposity tended to have greater effects on birthweight (R2 = 0.2912, P = 0.027). There was no dose-dependent association for BMI (R2 = −0.0019, P = 0.602). Conclusions Fetal genetic predisposition to both higher adult metabolically favorable adiposity and BMI is associated with birthweight. Fetal effects of metabolically favorable adiposity-raising alleles on birthweight are modestly proportional to their effects on future adiposity, but those of BMI-raising alleles are not.

Published

2021

4. Higher maternal adiposity reduces offspring birthweight if associated with a metabolically favourable profile

Author

William D. Thompson, Rafaq Azad, Jessica Tyrrell, Timothy M. Frayling, Dan Mason, Yingjie Ji, Gillian Santorelli, Bridget A. Knight, Robin N Beaumont, Debbie A Lawlor, Maria Carolina Borges, Alan Kuang, Rachel M. Freathy, David M. Evans, Nicole M. Warrington, Hanieh Yaghootkar, Andrew T. Hattersley, Denise M. Scholtens, Andrew R. Wood, and William L. Lowe

Subjects

Offspring, Endocrinology, Diabetes and Metabolism, Physiology, Single-nucleotide polymorphism, Body fat percentage, Article, Body Mass Index, 03 medical and health sciences, BMI, 0302 clinical medicine, Insulin resistance, Pregnancy, Internal Medicine, medicine, Birth Weight, Humans, Insulin, 030212 general & internal medicine, Mendelian randomisation, 030304 developmental biology, Adiposity, 2. Zero hunger, 0303 health sciences, business.industry, Leptin, Infant, Newborn, UKB, Reproducibility of Results, Anthropometry, ALSPAC, medicine.disease, Glucose, HAPO, BiB, Gestation, Female, business, EFSOCH, Genome-Wide Association Study

Abstract

Data availability: Our study uses two-sample MR. We used both published summary results (i.e. taking results from published research papers and websites) and individual participant cohort data: journal-published and website summary data were used for sample one of the two-sample MR (published GWAS of BMI and body fat percentage). The references to the published data sources are provided in the main paper. The data for the GWAS of BMI are available at https://portals.broadinstitute.org/collaboration/giant/index.php/GIANT_consortium_data_files. The data for the GWAS of body fat percentage are available at https://walker05.u.hpc.mssm.edu. We used individual participant data for the second MR sample and for undertaking sensitivity analyses from the UKB, ALSPAC, BiB, EFSOCH and HAPO cohorts. The data in UKB, ALSPAC and BiB are fully available, via managed systems, to any researchers. The managed system for both studies is a requirement of the study funders but access is not restricted on the basis of overlap with other applications to use the data or on the basis of peer review of the proposed science. Researchers have to pay for a dataset to be prepared for them. Full information on how to access UKB data can be found at www.ukbiobank.ac.uk/using-the-resource/. The ALSPAC data management plan (www.bristol.ac.uk/alspac/researchers/data-access/documents/alspac-data-management-plan.pdf) describes, in detail, the policy regarding data sharing, which is through a system of managed open access. The following steps highlight how to apply for access to the data included in this paper and all other ALSPAC data: (1) please read the ALSPAC access policy (PDF, 627 kB), which describes the process of accessing the data and samples in detail, and outlines the costs associated with doing so; (2) you may also find it useful to browse the fully searchable ALSPAC research proposals database, which lists all research projects that have been approved since April 2011; (3) please submit your research proposal for consideration by the ALSPAC Executive Committee and you will receive a response within 10 working days to advise you whether your proposal has been approved. If you have any questions about accessing data, please e-mail alspac-data@bristol.ac.uk. Full information on how to access BiB data can be found at https://borninbradford.nhs.uk/research/how-to-access-data/. Requests for access to the original EFSOCH dataset should be made in writing in the first instance to the EFSOCH data team via the Exeter Clinical Research Facility (crf@exeter.ac.uk). Copyright © The Author(s) 2022. Aims/hypothesis: Higher maternal BMI during pregnancy is associated with higher offspring birthweight, but it is not known whether this is solely the result of adverse metabolic consequences of higher maternal adiposity, such as maternal insulin resistance and fetal exposure to higher glucose levels, or whether there is any effect of raised adiposity through non-metabolic (e.g. mechanical) factors. We aimed to use genetic variants known to predispose to higher adiposity, coupled with a favourable metabolic profile, in a Mendelian randomisation (MR) study comparing the effect of maternal ‘metabolically favourable adiposity’ on offspring birthweight with the effect of maternal general adiposity (as indexed by BMI). Methods: To test the causal effects of maternal metabolically favourable adiposity or general adiposity on offspring birthweight, we performed two-sample MR. We used variants identified in large, published genetic-association studies as being associated with either higher adiposity and a favourable metabolic profile, or higher BMI (n = 442,278 and n = 322,154 for metabolically favourable adiposity and BMI, respectively). We then extracted data on the metabolically favourable adiposity and BMI variants from a large, published genetic-association study of maternal genotype and offspring birthweight controlling for fetal genetic effects (n = 406,063 with maternal and/or fetal genotype effect estimates). We used several sensitivity analyses to test the reliability of the results. As secondary analyses, we used data from four cohorts (total n = 9323 mother–child pairs) to test the effects of maternal metabolically favourable adiposity or BMI on maternal gestational glucose, anthropometric components of birthweight and cord-blood biomarkers. Results: Higher maternal adiposity with a favourable metabolic profile was associated with lower offspring birthweight (−94 [95% CI −150, −38] g per 1 SD [6.5%] higher maternal metabolically favourable adiposity, p = 0.001). By contrast, higher maternal BMI was associated with higher offspring birthweight (35 [95% CI 16, 53] g per 1 SD [4 kg/m2] higher maternal BMI, p = 0.0002). Sensitivity analyses were broadly consistent with the main results. There was evidence of outlier SNPs for both exposures; their removal slightly strengthened the metabolically favourable adiposity estimate and made no difference to the BMI estimate. Our secondary analyses found evidence to suggest that a higher maternal metabolically favourable adiposity decreases pregnancy fasting glucose levels while a higher maternal BMI increases them. The effects on neonatal anthropometric traits were consistent with the overall effect on birthweight but the smaller sample sizes for these analyses meant that the effects were imprecisely estimated. We also found evidence to suggest that higher maternal metabolically favourable adiposity decreases cord-blood leptin while higher maternal BMI increases it. Conclusions/interpretation: Our results show that higher adiposity in mothers does not necessarily lead to higher offspring birthweight. Higher maternal adiposity can lead to lower offspring birthweight if accompanied by a favourable metabolic profile. US National Institute of Health (R01 DK10324); European Research Council under the European Union’s Seventh Framework Programme (FP7/2007-2013) / ERC grant agreement no 669545; British Heart Foundation (CS/16/4/32482 and AA/18/7/34219); NIHR Biomedical Centre at the University Hospitals Bristol NHS Foundation Trust; University of Bristol.

Published

2021

5. Genome-wide association analyses of chronotype in 697,828 individuals provides insights into circadian rhythms

Author

Samuel E, Jones, Jacqueline M, Lane, Andrew R, Wood, Vincent T, van Hees, Jessica, Tyrrell, Robin N, Beaumont, Aaron R, Jeffries, Hassan S, Dashti, Melvyn, Hillsdon, Katherine S, Ruth, Marcus A, Tuke, Hanieh, Yaghootkar, Seth A, Sharp, Yingjie, Jie, William D, Thompson, Jamie W, Harrison, Amy, Dawes, Enda M, Byrne, Henning, Tiemeier, Karla V, Allebrandt, Jack, Bowden, David W, Ray, Rachel M, Freathy, Anna, Murray, Diego R, Mazzotti, Philip R, Gehrman, Debbie A, Lawlor, Timothy M, Frayling, Martin K, Rutter, David A, Hinds, Richa, Saxena, and Michael N, Weedon

Subjects

Adult, Male, Science, Glutamic Acid, Middle Aged, United Kingdom, White People, Article, Circadian Rhythm, Genetic Loci, Cyclic AMP, Humans, Female, lcsh:Q, Sleep, lcsh:Science, Aged, Genome-Wide Association Study

Abstract

Being a morning person is a behavioural indicator of a person’s underlying circadian rhythm. Using genome-wide data from 697,828 UK Biobank and 23andMe participants we increase the number of genetic loci associated with being a morning person from 24 to 351. Using data from 85,760 individuals with activity-monitor derived measures of sleep timing we find that the chronotype loci associate with sleep timing: the mean sleep timing of the 5% of individuals carrying the most morningness alleles is 25 min earlier than the 5% carrying the fewest. The loci are enriched for genes involved in circadian regulation, cAMP, glutamate and insulin signalling pathways, and those expressed in the retina, hindbrain, hypothalamus, and pituitary. Using Mendelian Randomisation, we show that being a morning person is causally associated with better mental health but does not affect BMI or risk of Type 2 diabetes. This study offers insights into circadian biology and its links to disease in humans., GWAS have previously found 24 genomic loci associated with chronotype, an individual’s preference for early or late sleep timing. Here, the authors identify 327 additional loci in a sample of 697,828 individuals and further explore the relationships of chronotype with metabolic and psychiatric diseases.

Published

2019

6. Higher maternal adiposity reduces offspring birth weight if associated with a metabolically favourable profile

Author

Nicole M. Warrington, Andrew T. Hattersley, Dan Mason, Alan Kuang, William D. Thompson, Rafaq Azad, David M. Evans, Debbie A Lawlor, Jessica Tyrrell, Andrew R. Wood, Hanieh Yaghootkar, Yingjie Ji, Timothy M. Frayling, Rachel M. Freathy, Denise M. Scholtens, Beatrice Knight, Maria Carolina Borges, William L. Lowe, Gillian Santorelli, and Robin N Beaumont

Subjects

medicine.medical_specialty, Pregnancy, business.industry, Offspring, Birth weight, Context (language use), Overweight, medicine.disease, Obesity, Insulin resistance, Endocrinology, Internal medicine, medicine, Gestation, medicine.symptom, business

Abstract

Aims/HypothesisHigher maternal BMI during pregnancy results in higher offspring birth weight, but it is not known whether this is solely the result of adverse metabolic consequences of higher maternal adiposity, such as maternal insulin resistance and fetal exposure to higher glucose levels, or whether there is any effect of raised adiposity through non-metabolic (e.g. mechanical) factors. We aimed to use genetic variants known to predispose to higher adiposity coupled with a favourable metabolic profile, in a Mendelian Randomisation (MR) study comparing the effect of maternal “metabolically favourable adiposity” on offspring birth weight with the effect of maternal general adiposity (as indexed by BMI).MethodsTo test the causal effects of maternal metabolically favourable adiposity or general adiposity on offspring birth weight, we performed two sample MR. We used variants identified in large genetic association studies as associated with either higher adiposity and a favourable metabolic profile, or higher BMI (N = 442,278 and N = 322,154 for metabolically favourable adiposity and BMI, respectively). We then used data from the same variants in a large genetic study of maternal genotype and offspring birth weight independent of fetal genetic effects (N = 406,063 with maternal and/or fetal genotype effect estimates). We used several sensitivity analyses to test the reliability of the results. As secondary analyses, we used data from four cohorts (total N = 9,323 mother-child pairs) to test the effects of maternal metabolically favourable adiposity or BMI on maternal gestational glucose, anthropometric components of birth weight and cord-blood biomarkers.ResultsHigher maternal adiposity with a favourable metabolic profile was associated with lower offspring birth weight (−94 (95% CI: −150 to −38) grams per 1 SD (6.5%) higher maternal metabolically favourable adiposity). By contrast, higher maternal BMI was associated with higher offspring birth weight (35 (95% CI: 16 to 53) grams per 1 SD (4 kg/m2) higher maternal BMI). Sensitivity analyses were broadly consistent with the main results. There was evidence of outlier SNPs for both exposures and their removal slightly strengthened the metabolically favourable adiposity estimate and made no difference to the BMI estimate. Our secondary analyses found evidence to suggest that maternal metabolically favourable adiposity decreases pregnancy fasting glucose levels whilst maternal BMI increases them.The effects on neonatal anthropometric traits were consistent with the overall effect on birth weight, but the smaller sample sizes for these analyses meant the effects were imprecisely estimated. We also found evidence to suggest that maternal metabolically favourable adiposity decreases cord-blood leptin whilst maternal BMI increases it.Conclusions/InterpretationOur results show that higher adiposity in mothers does not necessarily lead to higher offspring birth weight. Higher maternal adiposity can lead to lower offspring birth weight if accompanied by a favourable metabolic profile.Research in ContextWhat is already known about this subject?Studies in non-pregnant people with obesity suggest many people can have a “metabolically healthy” form of obesity, but effects in pregnancy and on offspring are not known.Multiple lines of evidence show that higher maternal BMI is causally associated with higher offspring birth weight, and that this may be mediated by the fetal insulin response to higher maternal gestational glucose.Recently, genetic variants have been identified, where one allele is associated with higher adiposity but lower risk of type II diabetes and favourable metabolic profile, including lower insulin and glucose levels, so called “metabolically favourable adiposity”; the mechanism is thought to be due to greater subcutaneous adipose storage capacity that leads to higher insulin sensitivity.What is the key question?What is the effect of maternal metabolically favourable adiposity on birth weight, and how does it compare with the effect of maternal BMI on birth weight?What are the new findings?Higher maternal adiposity can lead to lower, not higher birth weight, if it is also associated with a metabolically favourable profile; this contrasts with the effect of higher maternal general adiposity (BMI), on higher birth weight.Higher maternal metabolically favourable adiposity causes lower maternal fasting plasma glucose levels, most likely due to higher insulin sensitivity; in contrast higher maternal general adiposity leads to higher maternal fasting plasma glucose levels, most likely due to lower insulin sensitivity.How might this impact on clinical practice in the foreseeable future?Identifying ways of stratifying overweight and obese pregnant women into those with and without metabolically favourable adiposity could allow for targeted management to obtain healthy fetal growth and birth weight.

Published

2020

7. Association of maternal circulating 25(OH)D and calcium with birth weight: A mendelian randomisation analysis

Author

Bridget A. Knight, Robin N Beaumont, William D. Thompson, Rachel M. Freathy, Andrew R. Wood, Andrew T. Hattersley, Susan M. Ring, Jessica Tyrrell, Maria Carolina Borges, and Debbie A Lawlor

Subjects

Male, Physiology, Maternal Health, Organic chemistry, 030204 cardiovascular system & hematology, Pediatrics, law.invention, 0302 clinical medicine, Mathematical and Statistical Techniques, Randomized controlled trial, law, Pregnancy, Medicine and Health Sciences, Medicine, Birth Weight, Public and Occupational Health, 030212 general & internal medicine, Longitudinal Studies, Vitamin D, 2. Zero hunger, 25(OH)D, Obstetrics, Statistics, Child Health, Obstetrics and Gynecology, General Medicine, Genomics, Vitamins, ALSPAC, 3. Good health, Chemistry, Physiological Parameters, Physical Sciences, Female, EFSOCH, Research Article, Adult, medicine.medical_specialty, UK Biobank, Drug Research and Development, Offspring, Birth weight, chemistry.chemical_element, Single-nucleotide polymorphism, Calcium, Mendelian, Research and Analysis Methods, Instrumental Variable Analysis, Molecular Genetics, 03 medical and health sciences, Chemical compounds, Organic compounds, Vitamin D and neurology, Genome-Wide Association Studies, Genetics, Humans, Clinical Trials, Statistical Methods, Molecular Biology, Pharmacology, Fetus, calcium, business.industry, Body Weight, Infant, Newborn, Genetic Variation, Biology and Life Sciences, Computational Biology, birth weight, Human Genetics, Mendelian Randomization Analysis, medicine.disease, Genome Analysis, Randomized Controlled Trials, instrumental variable, chemistry, Women's Health, Clinical Medicine, business, Biomarkers, Mathematics, Genome-Wide Association Study

Abstract

Background Systematic reviews of randomised controlled trials (RCTs) have suggested that maternal vitamin D (25[OH]D) and calcium supplementation increase birth weight. However, limitations of many trials were highlighted in the reviews. Our aim was to combine genetic and RCT data to estimate causal effects of these two maternal traits on offspring birth weight. Methods and findings We performed two-sample mendelian randomisation (MR) using genetic instrumental variables associated with 25(OH)D and calcium that had been identified in genome-wide association studies (GWAS; sample 1; N = 122,123 for 25[OH]D and N = 61,275 for calcium). Associations between these maternal genetic variants and offspring birth weight were calculated in the UK Biobank (UKB) (sample 2; N = 190,406). We used data on mother–child pairs from two United Kingdom birth cohorts (combined N = 5,223) in sensitivity analyses to check whether results were influenced by fetal genotype, which is correlated with the maternal genotype (r ≈ 0.5). Further sensitivity analyses to test the reliability of the results included MR-Egger, weighted-median estimator, ‘leave-one-out’, and multivariable MR analyses. We triangulated MR results with those from RCTs, in which we used randomisation to supplementation with vitamin D (24 RCTs, combined N = 5,276) and calcium (6 RCTs, combined N = 543) as an instrumental variable to determine the effects of 25(OH)D and calcium on birth weight. In the main MR analysis, there was no strong evidence of an effect of maternal 25(OH)D on birth weight (difference in mean birth weight −0.03 g [95% CI −2.48 to 2.42 g, p = 0.981] per 10% higher maternal 25[OH]D). The effect estimate was consistent across our MR sensitivity analyses. Instrumental variable analyses applied to RCTs suggested a weak positive causal effect (5.94 g [95% CI 2.15–9.73, p = 0.002] per 10% higher maternal 25[OH]D), but this result may be exaggerated because of risk of bias in the included RCTs. The main MR analysis for maternal calcium also suggested no strong evidence of an effect on birth weight (−20 g [95% CI −44 to 5 g, p = 0.116] per 1 SD higher maternal calcium level). Some sensitivity analyses suggested that the genetic instrument for calcium was associated with birth weight via exposures that are independent of calcium levels (horizontal pleiotropy). Application of instrumental variable analyses to RCTs suggested that calcium has a substantial effect on birth weight (178 g [95% CI 121–236 g, p = 1.43 × 10−9] per 1 SD higher maternal calcium level) that was not consistent with any of the MR results. However, the RCT instrumental variable estimate may have been exaggerated because of risk of bias in the included RCTs. Other study limitations include the low response rate of UK Biobank, which may bias MR estimates, and the lack of suitable data to test whether the effects of genetic instruments on maternal calcium levels during pregnancy were the same as those outside of pregnancy. Conclusions Our results suggest that maternal circulating 25(OH)D does not influence birth weight in otherwise healthy newborns. However, the effect of maternal circulating calcium on birth weight is unclear and requires further exploration with more research including RCT and/or MR analyses with more valid instruments., William Thompson and colleagues, using mendelian randomisation methods, reveal no association between levels of maternal circulating vitamin D and birth weight of newborns., Author summary Why was this study done? Birth weight that is lower or higher than average has been associated with poor health outcomes across the life span, including infant mortality, cardiovascular disease, and type 2 diabetes. If we can identify modifiable maternal factors in pregnancy that are causally related to birth weight, we may be able to reduce the number of babies that are born with lower or higher than optimal birth weight. This may in turn help to reduce the associated poor health outcomes. Previous studies have suggested that higher maternal 25(OH)D and calcium in pregnancy are associated with higher birth weight. However, many of those studies used conventional multivariable regression in observational studies and may be subject to residual confounding. Few of them estimated the size of the effect of either maternal 25(OH)D or calcium levels on birth weight. What did the researchers do and find? We estimated the effects of maternal gestational 25(OH)D and calcium levels on offspring birth weight using mendelian randomisation, a method that uses genetic data to overcome certain limitations of traditional observational studies—for example, residual confounding. We analysed genetic data on 190,406 women from the UK Biobank who reported the birth weight of their first child, along with the results from published studies of genetic associations with 25(OH)D and calcium levels in 122,123 and 61,275 individuals, respectively. We checked that the results were not biased by offspring genotype using data from two UK birth cohorts, the Avon Longitudinal Study of Parents and Children (ALSPAC; n = 4,576 mother–child pairs) and Exeter Family Study of Childhood Health (EFSOCH; n = 647 mother–child pairs), respectively. To strengthen our causal understanding, we triangulated the mendelian randomisation results with findings from randomised controlled trials in which we used randomised status (to vitamin D or calcium supplementation) as an instrumental variable to estimate the effect of 25(OH)D or calcium on birth weight. We found no evidence of a strong effect of maternal 25(OH)D on birth weight. We found inconsistent evidence of effects of maternal calcium on birth weight. What do these findings mean? Our findings do not support using vitamin D supplementation during pregnancy or preconceptually to influence offspring birth weight. The effect of calcium on birth weight is still unclear and needs further investigation in well-powered genetic studies and/or well-conducted randomised controlled trials.

Published

2019

8. Using genetics to understand the causal influence of higher BMI on depression

Author

Jessica, Tyrrell, Anwar, Mulugeta, Andrew R, Wood, Ang, Zhou, Robin N, Beaumont, Marcus A, Tuke, Samuel E, Jones, Katherine S, Ruth, Hanieh, Yaghootkar, Seth, Sharp, William D, Thompson, Yingjie, Ji, Jamie, Harrison, Rachel M, Freathy, Anna, Murray, Michael N, Weedon, Cathryn, Lewis, Timothy M, Frayling, and Elina, Hyppönen

Subjects

Adult, Male, Depressive Disorder, Obesity, Metabolically Benign, UK Biobank, Mendelian Randomization Analysis, Middle Aged, United Kingdom, Body Mass Index, Causality, Mendelian Randomization, depression, Humans, Female, Obesity, Aged

Abstract

Background Depression is more common in obese than non-obese individuals, especially in women, but the causal relationship between obesity and depression is complex and uncertain. Previous studies have used genetic variants associated with BMI to provide evidence that higher body mass index (BMI) causes depression, but have not tested whether this relationship is driven by the metabolic consequences of BMI nor for differences between men and women. Methods We performed a Mendelian randomization study using 48 791 individuals with depression and 291 995 controls in the UK Biobank, to test for causal effects of higher BMI on depression (defined using self-report and Hospital Episode data). We used two genetic instruments, both representing higher BMI, but one with and one without its adverse metabolic consequences, in an attempt to ‘uncouple’ the psychological component of obesity from the metabolic consequences. We further tested causal relationships in men and women separately, and using subsets of BMI variants from known physiological pathways. Results Higher BMI was strongly associated with higher odds of depression, especially in women. Mendelian randomization provided evidence that higher BMI partly causes depression. Using a 73-variant BMI genetic risk score, a genetically determined one standard deviation (1 SD) higher BMI (4.9 kg/m2) was associated with higher odds of depression in all individuals [odds ratio (OR): 1.18, 95% confidence interval (CI): 1.09, 1.28, P = 0.00007) and women only (OR: 1.24, 95% CI: 1.11, 1.39, P = 0.0001). Meta-analysis with 45 591 depression cases and 97 647 controls from the Psychiatric Genomics Consortium (PGC) strengthened the statistical confidence of the findings in all individuals. Similar effect size estimates were obtained using different Mendelian randomization methods, although not all reached P

Published

2018

9. A common allele in FGF21 associated with preference for sugar consumption lowers body fat in the lower body and increases blood pressure

Author

Jonathan M. Locke, William D. Thompson, Jess Tyrrell, Rachel M. Freathy, West B, Beaumont Rn, James W. Harrison, Niels Grarup, C M Lindgren, Anna Murray, Francesco Casanova, Andrew R. Wood, Ruth Ks, Seth A. Sharp, Timothy M. Frayling, Yingjie Ji, Marcus A. Tuke, Samuel E. Jones, Michael N. Weedon, and Hanieh Yaghootkar

Subjects

2. Zero hunger, Genetics, 0303 health sciences, medicine.medical_specialty, FGF21, 030209 endocrinology & metabolism, Biology, Phenotype, 03 medical and health sciences, 0302 clinical medicine, Lower body, Blood pressure, Endocrinology, Weight loss, Internal medicine, medicine, Allele, medicine.symptom, Gene, 030304 developmental biology, Hormone

Abstract

SummaryFibroblast Growth Factor 21 (FGF21) is a hormone that induces weight loss in model organisms. These findings have led to trials in humans of FGF21 analogues with some showing weight loss and lipid lowering effects. Recent genetic studies have shown that a common allele in the FGF21 gene alters the balance of macronutrients consumed but there was little evidence of an effect on metabolic traits. We studied a common FGF21 allele (A:rs838133) in 451,099 people from the UK Biobank study. We replicated the association between the A allele and higher percentage carbohydrate intake. We then showed that this allele is more strongly associated with body fat distribution, with less fat in the lower body, and higher blood pressure, than it is with BMI, where there is only nominal evidence of an effect. These human phenotypes of naturally occurring variation in the FGF21 gene will inform decisions about FGF21’s therapeutic potential.

Published

2017

10. Are you running a 'risky' business

Author

William D, Thompson

Subjects

Risk Management, Hospice Care, Actuarial Analysis, Fees and Charges, Malpractice, Humans, Insurance Carriers, Liability, Legal, Insurance, Liability, Home Care Services, Risk Assessment, United States

Published

2004

11. Text and Sermon

Author

William D. Thompson

Subjects

Literature, business.industry, Religious studies, Normative, Sociology, business, Sermon, Epistemology

Abstract

The normative relationship between text and sermon is one of mutuality in which the preacher creates an interplay between the agenda of the text and the agenda of the congregation.

Published

1981

12. Behavioral Effects of Stimulation by UHF Radio Fields

Author

William D. Thompson and Susan Korbel Eakin

Subjects

medicine.medical_specialty, Behavior, Animal, 05 social sciences, 050301 education, 050109 social psychology, Stimulation, Low frequency, Radio, Water consumption, Rats, Intensity (physics), Radiation Effects, Endocrinology, Ultra high frequency, Internal medicine, Convulsion, medicine, Animals, 0501 psychology and cognitive sciences, Gradual increase, medicine.symptom, Psychology, 0503 education, General Psychology

Abstract

20 male albino rats were used as Ss in determining behavioral effects of ultra high frequency radiation. Experimental Ss were exposed to low intensity (50,000 mV), low frequency (300 mc to 920 mc) UHF radio waves for 47 consecutive days. Radiated rats were more active than non-radiated rats during the early part of the experiment, but became less active as the days of radiation increased. The UHF group was more emotional than the non-UHF group and showed a gradual increase in the latency of recovery from electroshock convulsion. No differences were found for weight, audiogenic seizures, and water consumption. Results suggest that (a) some time is required for UHF to have a consistent effect on behavior, and (b) the effects on behavior may be non-thermal and related to neurophysiological substrates.

Published

1965

13. Effect of Repeated Administration of Delvinal Sodium [5-ethyl-S-(l-methyl-l-butenyl) barbituric acid] to Guinea Pigs

Author

Emmett B. Carmichael and William D. Thompson

Subjects

Drug, chemistry.chemical_compound, Barbituric acid, chemistry, Stereochemistry, Sodium, media_common.quotation_subject, chemistry.chemical_element, Pharmacology, Body weight, General Biochemistry, Genetics and Molecular Biology, media_common

Abstract

SummaryGuinea pigs were found to show a tolerance to delvinal sodium [5-ethyl-5-(l-methyl-1-butenyl) barbituric acid] on repeated administration of large doses of the drug. The average length of sleep dropped from 127.3 to 48.2 minutes following 8 semi-weekly injections of the drug, while the average length of hypnosis dropped from 191.9 to 104.1 minutes. The average weight of the guinea pigs increased from 250 to 380 g, which was more than a 50% increase in weight.

Published

1941

14. Test of the law of initial values in four species of primates

Author

William D. Thompson and Thomas B. Downer

Subjects

Primates, Old World, Behavior, Animal, 05 social sciences, 050301 education, 050109 social psychology, Galvanic Skin Response, Haplorhini, Stimulus (physiology), humanities, Acoustic Stimulation, Heart Rate, Law, Auditory Perception, Animals, 0501 psychology and cognitive sciences, Psychology, 0503 education, health care economics and organizations, General Psychology, Psychophysiology

Abstract

The law of initial values was tested in the serial responses of monkeys to an auditory stimulus. The “law” was not confirmed for heart rates. GSRs were absent in the new world monkeys but supported the law of initial values for half of the Ss of old world species. Less support was found when conductance scores were used.

Published

1972

15. Nonionizing Radiations

Author

William D. Thompson and Anthony E. Bourgeois

Subjects

Materials science

Published

1971

16. Pass the Word!

Author

William D. Thompson

Subjects

Computer science, Speech recognition, Word (computer architecture)

Published

1961

17. Effects of Microwave Radiation on Activity Level of Rats

Author

Suzy Eakin and William D. Thompson

Subjects

Activity level, Radiochemistry, Psychology, General Psychology, Microwave

Published

1962