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Publication - Mrs Carolina Borges

    Association of maternal circulating 25(OH)D and calcium with birth weight

    A mendelian randomisation analysis

    Citation

    Thompson, WD, Tyrrell, J, Borges, C, Beaumont, RN, Knight, BA, Wood, AR, Ring, S, Hattersley, AT, Freathy, R & Lawlor, D, 2019, ‘Association of maternal circulating 25(OH)D and calcium with birth weight: A mendelian randomisation analysis’. PLoS Medicine, vol 16., pp. e1002828

    Abstract

    Background
    Systematic reviews of randomized 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 UK 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 -0.03g (95%CI: -2.48 to 2.42g, 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
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    effect (5.94g (95% CI: 2.15 to 9.73, p=0.002) per 10% higher maternal 25(OH)D), but this result may be exaggerated due to 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 (-20g (95%CI: -44 to 5g, 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 (178g (95% CI 121 to 236g, p=1.43 x 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 owing to 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.

    Full details in the University publications repository