Maternal B-vitamin and vitamin D status before, during, and after pregnancy and the influence of supplementation preconception and during pregnancy: Prespecified secondary analysis of the NiPPeR double-blind randomized controlled trial.

Keith M Godfrey, Philip Titcombe, Sarah El-Heis, Benjamin B Albert, Elizabeth Huiwen Tham et al.

RCT PLoS medicine 2023 19 उद्धरण

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Study Design

अध्ययन प्रकार: randomized_controlled_trial
नमूना आकार: 1729

हस्तक्षेप: Maternal B-vitamin and vitamin D status before, during, and after pregnancy and the influence of supplementation preconception and during pregnancy: Prespecified secondary analysis of the NiPPeR doubl Enhanced vitamin supplement (riboflavin, vitamins B6, B12, D, myo-inositol, probiotics, zinc + stand
तुलनित्र: Placebo
प्रभाव की दिशा: Positive
पूर्वाग्रह का जोखिम: Low

Abstract

BACKGROUND: Maternal vitamin status preconception and during pregnancy has important consequences for pregnancy outcome and offspring development. Changes in vitamin status from preconception through early and late pregnancy and postpartum have been inferred from cross-sectional data, but longitudinal data on vitamin status from preconception throughout pregnancy and postdelivery are sparse. As such, the influence of vitamin supplementation on vitamin status during pregnancy remains uncertain. This study presents one prespecified outcome from the randomized controlled NiPPeR trial, aiming to identify longitudinal patterns of maternal vitamin status from preconception, through early and late pregnancy, to 6 months postdelivery, and determine the influence of vitamin supplementation. METHODS AND FINDINGS: In the NiPPeR trial, 1,729 women (from the United Kingdom, Singapore, and New Zealand) aged 18 to 38 years and planning conception were randomized to receive a standard vitamin supplement (control; n = 859) or an enhanced vitamin supplement (intervention; n = 870) starting in preconception and continued throughout pregnancy, with blinding of participants and research staff. Supplement components common to both treatment groups included folic acid, β-carotene, iron, calcium, and iodine; components additionally included in the intervention group were riboflavin, vitamins B6, B12, and D (in amounts available in over-the-counter supplements), myo-inositol, probiotics, and zinc. The primary outcome of the study was glucose tolerance at 28 weeks' gestation, measured by oral glucose tolerance test. The secondary outcome reported in this study was the reduction in maternal micronutrient insufficiency in riboflavin, vitamin B6, vitamin B12, and vitamin D, before and during pregnancy. We measured maternal plasma concentrations of B-vitamins, vitamin D, and markers of insufficiency/deficiency (homocysteine, hydroxykynurenine-ratio, methylmalonic acid) at recruitment, 1 month after commencing intervention preconception, in early pregnancy (7 to 11 weeks' gestation) and late pregnancy (around 28 weeks' gestation), and postdelivery (6 months after supplement discontinuation). We derived standard deviation scores (SDS) to characterize longitudinal changes among participants in the control group and measured differences between the 2 groups. At recruitment, the proportion of patients with marginal or low plasma status was 29.2% for folate (<13.6 nmol/L), 7.5% and 82.0% for riboflavin (<5 nmol/L and ≤26.5 nmol/L, respectively), 9.1% for vitamin B12 (<221 pmol/L), and 48.7% for vitamin D (<50 nmol/L); these proportions were balanced between the groups. Over 90% of all participants had low or marginal status for one or more of these vitamins at recruitment. Among participants in the control group, plasma concentrations of riboflavin declined through early and late pregnancy, whereas concentrations of 25-hydroxyvitamin D were unchanged in early pregnancy, and concentrations of vitamin B6 and B12 declined throughout pregnancy, becoming >1 SDS lower than baseline by 28 weeks gestation. In the control group, 54.2% of participants developed low late-pregnancy vitamin B6 concentrations (pyridoxal 5-phosphate <20 nmol/L). After 1 month of supplementation, plasma concentrations of supplement components were substantially higher among participants in the intervention group than those in the control group: riboflavin by 0.77 SDS (95% CI 0.68 to 0.87, p < 0.0001), vitamin B6 by 1.07 SDS (0.99 to 1.14, p < 0.0001), vitamin B12 by 0.55 SDS (0.46 to 0.64, p < 0.0001), and vitamin D by 0.51 SDS (0.43 to 0.60, p < 0.0001), with higher levels in the intervention group maintained during pregnancy. Markers of vitamin insufficiency/deficiency were reduced in the intervention group, and the proportion of participants with vitamin D insufficiency (<50 nmol/L) during late pregnancy was lower in the intervention group (35.1% versus 8.5%; p < 0.0001). Plasma vitamin B12 remained higher in the intervention group than in the control group 6 months postdelivery (by 0.30 SDS (0.14, 0.46), p = 0.0003). The main limitation is that generalizability to the global population is limited by the high-resource settings and the lack of African and Amerindian women in particular. CONCLUSIONS: Over 90% of the trial participants had marginal or low concentrations of one or more of folate, riboflavin, vitamin B12, or vitamin D during preconception, and many developed markers of vitamin B6 deficiency in late pregnancy. Preconception/pregnancy supplementation in amounts available in over-the-counter supplements substantially reduces the prevalence of vitamin deficiency and depletion markers before and during pregnancy, with higher maternal plasma vitamin B12 maintained during the recommended lactational period. TRIAL REGISTRATION: ClinicalTrials.gov NCT02509988; U1111-1171-8056.

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Figures

Fig 1

CONSORT flow diagram for the NiPPeR randomized controlled trial examining maternal B-vitamin and vitamin D supplementation from preconception through pregnancy. Participant enrollment, randomization, and retention across study visits are documented.

flowchart

Fig 2

Longitudinal vitamin B12 and folate status trajectories from preconception through postpartum in women receiving active supplementation versus placebo. The data reveal how B-vitamin levels change across pregnancy stages and the influence of supplementation timing.

chart

Fig 3

Vitamin D status changes measured at multiple time points from preconception through postdelivery in the NiPPeR trial. Seasonal variation and supplementation effects on 25-hydroxyvitamin D levels are tracked across the intervention period.

chart

Fig 4

Comparison of vitamin status adequacy rates between supplementation and control groups at key pregnancy milestones. The proportion of women achieving sufficient vitamin B12, folate, and vitamin D levels varies by trimester and supplementation regimen.

chart

Fig 5

Relationship between preconception vitamin status and pregnancy outcomes in the NiPPeR trial cohort. Baseline nutrient levels may influence the magnitude of benefit derived from vitamin supplementation during pregnancy.

chart

Tables

Table 1

		Preconception		Baseline and late pregnancy⁺
Characteristic		Control (n = 857)	Intervention (n = 870)	Control (n = 287)	Intervention (n = 293)
Sociodemographic
Study site	UK	229 (26.7%)	232 (26.7%)	92 (32.1%)	97 (33.1%)
	Singapore	328 (38.3%)	332 (38.2%)	82 (28.6%)	84 (28.7%)
	New Zealand	300 (35.0%)	306 (35.2%)	113 (39.4%)	112 (38.2%)
Age, years	Mean (SD)	30.6 (3.7)	30.6 (3.7)	30.2 (3.3)	30.5 (3.4)
Ethnicity	White	396 (46.2%)	413 (47.5%)	165 (57.5%)	179 (61.1%)
	Chinese	220 (25.7%)	238 (27.4%)	73 (25.4%)	72 (24.6%)
	South Asian	60 (7.0%)	61 (7.0%)	15 (5.2%)	15 (5.1%)
	Malay	85 (9.9%)	80 (9.2%)	12 (4.2%)	11 (3.8%)
	Other	96 (11.2%)	78 (9.0%)	22 (7.7%)	16 (5.5%)
Household income^#	Low income	74 (9.3%)	76 (9.4%)	11 (4.0%)	12 (4.3%)
	Middle income	344 (43.2%)	354 (43.7%)	114 (41.2%)	114 (40.9%)
	High income	378 (47.5%)	380 (46.9%)	152 (54.9%)	153 (54.8%)
Gynecological
Parity	Nulliparous	593 (69.2%)	578 (66.4%)	196 (68.3%)	169 (57.7%)
	Parous	264 (30.8%)	292 (33.6%)	91 (31.7%)	124 (42.3%)
Lifestyle
Alcohol intake (per week)	None	271 (31.6%)	265 (30.5%)	61 (21.3%)	65 (22.2%)
	>0 to ≤2.5 units	312 (36.4%)	301 (34.6%)	115 (40.1%)	109 (37.2%)
	>2.5 units	274 (32.0%)	304 (34.9%)	111 (38.7%)	119 (40.6%)
Smoking status	Never	664 (77.7%)	662 (76.3%)	225 (78.7%)	237 (80.9%)
	Previous	131 (15.3%)	136 (15.7%)	49 (17.1%)	44 (15.0%)
	Active	60 (7.0%)	70 (8.1%)	12 (4.2%)	12 (4.1%)
Instances of moderate/vigorous physical activity in past 7 days	Median (IQR)	3 (2, 5)	3 (1, 5)	4 (2, 6)	3 (2, 5)
BMI category^##	Not overweight or obese	400 (46.7%)	432 (49.8%)	158 (55.1%)	163 (55.8%)
	Overweight	240 (28.0%)	224 (25.8%)	69 (24.0%)	89 (30.5%)
	Obese	216 (25.2%)	212 (24.4%)	60 (20.9%)	40 (13.7%)
Days between preconception baseline and post-supplementation sampling	Median (IQR)	28 (23, 31)	28 (23, 32)	27 (22, 31)	28 (23, 31)
Preconception baseline: Taking a multiple micronutrient supplement	No	583 (68.6%)	609 (70.2%)	198 (69.0%)	195 (66.6%)
	Yes	267 (31.4%)	259 (29.8%)	89 (31.0%)	98 (33.4%)

Table 2

	Preconception baseline		Preconception 1 month post-supplementation		Early pregnancy(7–11 weeks gestation)		Late pregnancy(28 weeks gestation)		6 months postdelivery
	Controls(n = 735–854)	Intervention(n = 746–867)	Controls(n = 692–707)	Intervention(n = 724–747)	Controls(n = 303–305)	Intervention(n = 322–329)	Controls(n = 261–288)	Intervention(n = 270–293)	Controls(n = 217–251)	Intervention(n = 231–261)
Folate(nmol/L)	22.5(12.7, 41.3)	20.5(12.1, 41.3)	41.9(29.3, 55.0)	40.3(29.0, 52.8)	49.8(40.5, 60.0)	52.2(43.2, 63.0)	41.5(30.6, 51.6)	44.1(34.3, 54.5)	19.2(11.9, 32.7)	18.9(12.3, 32.2)
Homocysteine(μmol/L)	7.0(6.1, 8.4)	7.1(6.1, 8.5)	6.9(6.0, 8.0)	6.4(5.6, 7.4)	5.5(4.8, 6.4)	4.9(4.2, 5.6)	4.6(3.9, 5.2)	3.9(3.5, 4.6)	7.4(6.4, 9.0)	7.2(6.1, 8.5)
Riboflavin(nmol/L)	12.7(7.7, 21.7)	12.0(7.6, 21.2)	12.7(8.3, 22.3)	24.7(16.7, 36.8)	10.7(6.8, 18.0)	20.0(13.0, 30.3)	10.3(6.6, 15.1)	16.9(12.2, 23.3)	12.9(8.8, 21.1)	12.7(8.4, 22.6)
FMN(nmol/L)	14.4(11.5, 18.7)	14.6(11.9, 18.7)	15.6(12.4, 20.1)	18.4(15.0, 23.4)	14.5(11.4, 18.2)	17.2(14.3, 21.6)	10.1(8.4, 12.0)	11.5(9.8, 13.4)	14.2(11.8, 17.0)	14.4(11.2, 18.7)
Pyridoxal 5-phosphate(nmol/L)	55.8(40.3, 88.4)	57.1(41.1, 84.3)	56.9(43.0, 80.1)	140.0(102.0, 184.0)	47.6(34.3, 64.1)	106.0(76.0, 139.0)	19.1(14.7, 28.1)	41.9(30.3, 56.4)	56.3(40.0, 88.2)	56.1(40.5, 86.6)
HK ratio(no units)	0.35(0.29, 0.43)	0.36(0.29, 0.42)	0.35(0.29, 0.42)	0.29(0.24, 0.35)	0.35(0.28, 0.43)	0.29(0.24, 0.33)	0.51(0.41, 0.60)	0.44(0.37, 0.54)	0.40(0.32, 0.49)	0.39(0.32, 0.47)
Cobalamin(pmol/L)	355.2(283.1, 434.1)	350.9(278.8, 437.7)	358.9(284.0, 449.3)	438.2(353.3, 552.1)	307.4(240.2, 384.0)	411.1(332.0, 509.3)	214.6(177.3, 270.0)	298.7(247.9, 379.5)	340.4(264.5, 437.8)	385.6(312.3, 465.7)
MMA(μmol/L)	0.13(0.11, 0.17)	0.13(0.11, 0.17)	0.15(0.12, 0.19)	0.15(0.12, 0.19)	0.12(0.10, 0.15)	0.11(0.10, 0.14)	0.14(0.11, 0.20)	0.12(0.10, 0.15)	0.15(0.12, 0.20)	0.14(0.12, 0.17)
Vitamin D3(nmol/L)	51.0(36.0, 65.3)	50.1(36.1, 65.8)	51.7(37.0, 65.5)	61.1(51.1, 73.3)	53.3(41.8, 69.5)	69.6(57.3, 81.2)	62.9(41.0, 87.5)	92.8(73.0, 106.9)	62.5(45.3, 77.6)	64.6(48.5, 77.6)

Table 3

	Preconception baseline		Preconception 1 month post supplementation		Early pregnancy (7–11 weeks gestation)		Late pregnancy (28 weeks gestation)		6 months postdelivery
	Controls(n = 816–854)	Intervention(n = 826–867)	Controls(n = 704–707)	Intervention(n = 746–747)	Controls(n = 304–305)	Intervention(n = 327–329)	Controls(n = 279–288)	Intervention(n = 288–293)	Controls(n = 239–251)	Intervention(n = 252–261)
Folate<13.6 nmol/L	28.1%[25.0, 31.3]	30.4%[27.3, 33.7]	4.1%[2.8, 5.9]	3.6%[2.4, 5.2]	1.0%[0.2, 2.8]	0.6%[0.1, 2.2]	6.1%[3.6, 9.6]	3.5%[1.7, 6.3]	31.8%[25.9, 38.1]	32.9%[27.2, 39.1]
Homocysteine≥15 μmol/L	0.9%[0.4, 1.8]	0.8%[0.3, 1.7]	0.7%[0.2, 1.6]	0.1%[0.0, 0.7]	0.0%[0.0, 1.2]	0.0%[0.0, 1.1]	0.0%[0.0, 1.3]	0.0%[0.0, 1.3]	0.4%[0.0, 2.2]	2.3%[0.8, 4.9]
Riboflavin<5 nmol/L	7.3%[5.6, 9.2]	7.7%[6.0, 9.7]	6.2%[4.6, 8.3]	0.4%*[0.1, 1.2]	12.5%[9.0, 16.7]	0.9%*[0.2, 2.6]	12.8%[9.2, 17.3]	2.7%*[1.2, 5.3]	4.0%[1.9, 7.2]	3.4%[1.6, 6.4]
Riboflavin≤26.5 nmol/L	81.1%[78.4, 83.7]	82.8%[80.1, 85.3]	80.3%[77.2, 83.2]	56.1%*[52.4, 59.7]	85.6%[81.1, 89.3]	66.9%*[61.5, 71.9]	92.4%[88.7, 95.2]	81.9%*[77.0, 86.1]	82.5%[77.2, 87.0]	82.8%[77.6, 87.1]
Pyridoxal 5-phosphate<20 nmol/L	0.8%[0.3, 1.7]	1.8%[1.1, 3.0]	0.1%[0.0, 0.8]	0.4%[0.1, 1.2]	2.6%[1.1, 5.1]	0.0%*[0.0, 1.1]	54.2%[48.2, 60.0]	10.2%*[7.0, 14.3]	1.2%[0.2, 3.5]	0.8%[0.1, 2.7]
Cobalamin<148 pmol/L	0.6%[0.2, 1.4]	0.5%[0.1, 1.2]	0.6%[0.2, 1.4]	0.0%[0.0, 0.5]	1.6%[0.5, 3.8]	0.3%[0.0, 1.7]	11.1%[7.7, 15.3]	4.8%*[2.6, 7.9]	0.8%[0.1, 2.9]	0.4%[0.0, 2.1]
Cobalamin<221 pmol/L	7.5%[5.8, 9.5]	10.8%*[8.8, 13.0]	7.0%[5.2, 9.1]	2.4%*[1.4, 3.8]	18.1%[13.9, 22.9]	3.7%*[1.9, 6.3]	55.2%[49.3, 61.0]	16.7%*[12.6, 21.5]	12.4%[8.6, 17.1]	5.4%*[3.0, 8.8]
MMA>0.26 μmol/L	6.2%[4.7, 8.0]	8.7%[6.9, 10.7]	8.5%[6.5, 10.8]	8.6%[6.7, 10.8]	7.5%[4.8, 11.1]	3.6%*[1.9, 6.3]	11.8%[8.3, 16.1]	5.8%*[3.4, 9.1]	10.0%[6.5, 14.4]	5.4%[3.0, 8.8]
Vitamin D3<50 nmol/L	47.7%[44.3, 51.1]	49.7%[46.3, 53.1]	47.5%[43.8, 51.3]	22.0%*[19.0, 25.1]	43.0%[37.3, 48.7]	12.2%*[8.8, 16.2]	35.1%[29.6, 40.9]	8.5%*[5.6, 12.3]	30.7%[25.0, 36.8]	27.2%[21.9, 33.0]
Vitamin D3<75 nmol/L	85.7%[83.2, 88.0]	85.0%[82.5, 87.3]	85.1%[82.3, 87.7]	78.2%*[75.0, 81.1]	82.3%[77.5, 86.4]	65.7%*[60.2, 70.8]	64.6%[58.8, 70.1]	27.3%*[22.3, 32.8]	70.5%[64.5, 76.1]	70.5%[64.6, 76.0]

Table 4

Analyte	Preconception baseline				Preconception 1 month post-supplementation				Early pregnancy(7–11 weeks gestation)				Late pregnancy(28 weeks gestation)				6 months postdelivery
Analyte	n	beta	p-value	95% CI	n	beta	p-value	95% CI	n	beta	p-value	95% CI	n	beta	p-value	95% CI	n	beta	p-value	95% CI
Folate	1,642	−0.048	0.357	(−0.15, 0.05)	1,451	−0.033	0.381	(−0.11, 0.04)	633	0.059	0.243	(−0.04, 0.16)	567	0.123	0.029	(0.01, 0.23)	491	−0.045	0.594	(−0.21, 0.12)
Homocysteine	1,721	0.033	0.419	(−0.05, 0.11)	1,454	−0.232	<0.0001	(−0.30, −0.16)	634	−0.406	<0.0001	(−0.51, -0.30)	581	−0.401	<0.0001	(−0.52, −0.29)	512	−0.101	0.188	(−0.25, 0.05)
Riboflavin	1,721	−0.063	0.181	(−0.16, 0.03)	1,454	0.775	<0.0001	(0.68, 0.87)	634	0.783	<0.0001	(0.64, 0.93)	581	0.656	<0.0001	(0.52, 0.79)	512	−0.012	0.877	(−0.17, 0.14)
FMN	1,721	0.055	0.232	(−0.04, 0.15)	1,454	0.368	<0.0001	(0.27, 0.47)	634	0.485	<0.0001	(0.34, 0.63)	581	0.336	<0.0001	(0.22, 0.45)	512	0.065	0.399	(−0.09, 0.22)
Pyridoxal 5-phosphate	1,721	−0.018	0.667	(−0.10, 0.06)	1,454	1.072	<0.0001	(1.00, 1.14)	634	0.974	<0.0001	(0.86, 1.09)	581	0.863	<0.0001	(0.73, 0.99)	512	0.036	0.649	(−0.12, 0.19)
HK ratio	1,481	−0.018	0.694	(−0.11, 0.07)	1,416	−0.52	<0.0001	(−0.61, −0.43)	625	−0.648	<0.0001	(−0.77, −0.53)	531	−0.339	<0.0001	(−0.49, −0.19)	448	−0.183	0.073	(−0.38, 0.02)
Cobalamin	1,717	−0.035	0.393	(−0.12, 0.05)	1,450	0.549	<0.0001	(0.46, 0.63)	631	0.776	<0.0001	(0.65, 0.91)	581	0.809	<0.0001	(0.67, 0.95)	511	0.303	<0.0001	(0.16, 0.45)
MMA	1,721	0.086	0.066	(−0.01, 0.18)	1,454	−0.04	0.4	(−0.13, 0.05)	634	−0.228	0.002	(−0.37, −0.09)	581	−0.509	<0.0001	(−0.68, −0.34)	512	−0.185	0.016	(−0.34, −0.03)
Vitamin D3	1,721	−0.028	0.49	(−0.11, 0.05)	1,454	0.496	<0.0001	(0.42, 0.57)	634	0.601	<0.0001	(0.49, 0.71)	581	0.877	<0.0001	(0.72, 1.04)	512	0.126	0.087	(−0.02, 0.27)

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D Iron के लिए प्रसवोत्तर बाल झड़ना

Maternal B-vitamin and vitamin D status before, during, and after pregnancy and the influence of supplementation preconception and during pregnancy: Prespecified secondary analysis of the NiPPeR double-blind randomized controlled trial.

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