Hostname: page-component-586b7cd67f-tf8b9 Total loading time: 0 Render date: 2024-11-26T08:08:31.624Z Has data issue: false hasContentIssue false

Early pregnancy probiotic supplementation with Lactobacillus rhamnosus HN001 may reduce the prevalence of gestational diabetes mellitus: a randomised controlled trial

Published online by Cambridge University Press:  03 April 2017

Kristin L. Wickens*
Affiliation:
University of Otago, Wellington 6021, New Zealand
Christine A. Barthow
Affiliation:
University of Otago, Wellington 6021, New Zealand
Rinki Murphy
Affiliation:
University of Auckland, Auckland 1142, New Zealand
Peter R. Abels
Affiliation:
University of Otago, Wellington 6021, New Zealand Capital and Coast DHB, Wellington 6021, New Zealand
Robyn M. Maude
Affiliation:
Victoria University, Wellington 6021, New Zealand
Peter R. Stone
Affiliation:
University of Auckland, Auckland 1142, New Zealand
Edwin A. Mitchell
Affiliation:
University of Auckland, Auckland 1142, New Zealand
Thorsten V. Stanley
Affiliation:
University of Otago, Wellington 6021, New Zealand Capital and Coast DHB, Wellington 6021, New Zealand
Gordon L. Purdie
Affiliation:
University of Otago, Wellington 6021, New Zealand
Janice M. Kang
Affiliation:
University of Otago, Wellington 6021, New Zealand
Fiona E. Hood
Affiliation:
University of Otago, Wellington 6021, New Zealand
Judy L. Rowden
Affiliation:
University of Auckland, Auckland 1142, New Zealand
Phillipa K. Barnes
Affiliation:
University of Otago, Wellington 6021, New Zealand
Penny F. Fitzharris
Affiliation:
Auckland Hospital, Auckland 1142, New Zealand
Julian Crane
Affiliation:
University of Otago, Wellington 6021, New Zealand
*
*Corresponding author: K. Wickens, fax +64 4 385 5489, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The study aims to assess whether supplementation with the probiotic Lactobacillus rhamnosus HN001 (HN001) can reduce the prevalence of gestational diabetes mellitus (GDM). A double-blind, randomised, placebo-controlled parallel trial was conducted in New Zealand (NZ) (Wellington and Auckland). Pregnant women with a personal or partner history of atopic disease were randomised at 14–16 weeks’ gestation to receive HN001 (6×109 colony-forming units) (n 212) or placebo (n 211) daily. GDM at 24–30 weeks was assessed using the definition of the International Association of Diabetes and Pregnancy Study Groups (IADPSG) (fasting plasma glucose ≥5·1 mmol/l, or 1 h post 75 g glucose level at ≥10 mmol/l or at 2 h ≥8·5 mmol/l) and NZ definition (fasting plasma glucose ≥5·5 mmol/l or 2 h post 75 g glucose at ≥9 mmol/l). All analyses were intention-to-treat. A total of 184 (87 %) women took HN001 and 189 (90 %) women took placebo. There was a trend towards lower relative rates (RR) of GDM (IADPSG definition) in the HN001 group, 0·59 (95 % CI 0·32, 1·08) (P=0·08). HN001 was associated with lower rates of GDM in women aged ≥35 years (RR 0·31; 95 % CI 0·12, 0·81, P=0·009) and women with a history of GDM (RR 0·00; 95 % CI 0·00, 0·66, P=0·004). These rates did not differ significantly from those of women without these characteristics. Using the NZ definition, GDM prevalence was significantly lower in the HN001 group, 2·1 % (95 % CI 0·6, 5·2), v. 6·5 % (95 % CI 3·5, 10·9) in the placebo group (P=0·03). HN001 supplementation from 14 to 16 weeks’ gestation may reduce GDM prevalence, particularly among older women and those with previous GDM.

Type
Full Papers
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Authors 2017

Lifestyle factors such as changes in patterns of food consumption with economic development have led to the well-recognised and increasing problems of obesity and associated diseases, including gestational diabetes mellitus (GDM), both in New Zealand (NZ)( 1 ) and other developed countries( 2 ). Pre-pregnancy overweight and obesity have been shown to account for 46 % of GDM( Reference Kim, England and Wilson 3 ), with excess weight gain during pregnancy, previous GDM or a family history of diabetes, polycystic ovary syndrome (PCOS), older age and higher parity also identified as risk factors( Reference Ben-Haroush, Yogev and Hod 4 ). GDM itself increases the risk for preeclampsia, miscarriage, preterm birth, macrosomia, induction of labour and caesarean section( 2 , Reference Kim, England and Wilson 3 ). GDM also increases the risk for later maternal and child obesity and subsequent type 2 diabetes mellitus( Reference Kim, Newton and Knopp 5 ).

GDM definitions are variable, and establishing an international consensus on diagnostic criteria that predict adverse pregnancy outcomes has been challenging. In 2008, the International Association of Diabetes and Pregnancy Study Group (IADPSG)( 6 ) used data from the Hyperglycemia and Adverse Pregnancy Outcome (HAPO) study( Reference Coustan, Lower and Metzger 7 ) to develop recommendations for oral glucose tolerance test (GTT) threshold glucose concentrations for the diagnosis of GDM (fasting plasma glucose ≥5·1 mmol/l or 1 h post 75 g glucose level ≥10 mmol/l or at 2 h ≥8·5 mmol/l). This was based on the findings of the HAPO study( Reference Coustan, Lower and Metzger 7 ) of a curvilinear dose–response relationship between fasting, 1 and 2 h glucose concentrations and adverse pregnancy outcomes, including macrosomia and caesarean section delivery. However, the NZ guideline definitions for GDM diagnosis specify a higher baseline and 2 h glucose test threshold (fasting plasma glucose ≥5·5 mmol/l or 2 h post 75 g glucose level ≥9 mmol/l)( 1 ).

The WHO has defined probiotics as live micro-organisms, which when administered in adequate amounts confer a health benefit to the host( 8 ). There is emerging evidence for a modulating effect of probiotics on gut microbiota and inflammatory responses( Reference Gomes, Beuno and de Souza 9 , Reference Zhang, Yucheng and Xiaoqiang 10 ), with a recent meta-analysis suggesting that probiotics can favourably influence glucose metabolism( Reference Thomas, Ockhuizen and Suzuki 11 ). A Finnish trial( Reference Luoto, Laitinen and Nermes 12 ) showed that a probiotic supplement containing Lactobacillus rhamnosus GG and Bifidobacterium lactis Bb12, taken from the first trimester of pregnancy, reduced the prevalence of GDM.

The aim of the current study was to investigate whether the probiotic L. rhamnosus HN001 (HN001) taken by pregnant mothers from early pregnancy could reduce the prevalence of GDM by 26–28 weeks’ gestation.

Methods

Study design

The study was a two-centre, double-blind, randomised, placebo-controlled parallel trial investigating the effects of the probiotic HN001 on the prevalence of GDM. This secondary outcome was decided a priori. The primary outcome was the development of eczema and atopic sensitisation in the child at age 12 months (Australia NZ Clinical Trials Registry: ACTRN12612000196842).

For a detailed description of study methods and outcomes refer to Barthow et al. ( Reference Barthow, Wickens and Stanley 13 ).

Participants

In brief, pregnant women in Auckland and Wellington, NZ, were recruited into the study via health professionals and study information placed in pregnancy packs. Women were considered eligible if they were <16 weeks’ gestation, English-speaking, had intention to breast-feed, and if either they or the unborn child’s biological father had a history of asthma, hayfever or eczema requiring medication. Women were excluded from the study if aged <16 years, were planning to move outside the study centres during the study duration, had a history of immunological disorders or medication, or cardiac valve disease, required in vitro fertilisation, had major fetal abnormalities, were using probiotic drinks or supplements, participating in another randomised controlled trial, refused notification of their clinical carers, carried adrenaline for cows’ milk allergy, had a history of a transplant or HIV, had used continuous antibiotic therapy for at least 3 months, miscarried between screening and enrolment, or were otherwise deemed unsuitable. Eligible women were enrolled into the study at 14–16 weeks’ gestation, where gestation was determined on the basis of the earliest first-trimester scan and, where this was not available, the date of the last menstrual period.

Study capsules

Participating women were randomised to receive capsules containing either HN001 (6×109 colony-forming units (cfu)) or placebo (maize-derived maltodextrin, identical in appearance and smell to the probiotic) to be taken daily from enrolment throughout pregnancy and until 6 months post birth if still breast-feeding. HN001 powder was manufactured by Fonterra Co-operative Group Ltd (Fonterra) using aseptic fermentation, concentration and freeze-drying, as previously described( Reference Wickens, Black and Stanley 14 ). The placebo powder, maize-derived maltodextrin, was manufactured by Grain Processing Corporation. Women were instructed to keep the capsules in a refrigerator and to avoid taking them within 10 min of consuming hot food or fluid.

Fonterra retained samples of capsules at 4°C, which were tested monthly to ensure viability of the contents over time. The viability of the contents of a selection of unused capsules returned from the field was tested 3 monthly. Loss in viability was <0·1 log, and within the limit of uncertainty of the counting method.

Randomisation of capsules was performed by a statistician at Fonterra who had no contact with the study investigators or participants. Randomisation was stratified by the study centre and performed in blocks of twenty according to a computer-generated randomisation schedule and an allocation ratio of 1:1. Research staff screened and enrolled participants, providing eligible participants with the next available sequentially numbered capsule container. All researchers, laboratory staff and participants were blinded to study allocation.

Baseline

Information collected included age, ethnicity, parity, previous PCOS, BMI (weight (kg)/height (m2)), waist circumference, antibiotic use during pregnancy but before enrolment and type 2 diabetes mellitus in the participant or a first-degree relative. Among women with previous pregnancies >20 weeks, we also collected a history of previous GDM and birth weight of previous babies.

Outcomes

The GDM outcome was defined a priori primarily as the diagnosis of GDM according to the IADPSG recommendations( 6 ): a fasting plasma glucose ≥5·1 mmol/l, or 1 h post 75 g glucose load ≥10 mmol/l or at 2 h ≥8·5 mmol/l. A secondary analysis was conducted using NZ thresholds ≥5·5 mmol/l fasting or ≥9 mmol/l at 2 h to define GDM( 1 ).

The assessment for GDM was conducted at 24–30 weeks’ gestation following a 12 h overnight fast, using a GTT undertaken at a community laboratory. Only women without pre-pregnancy diabetes were invited to undertake a study GTT. Women who received a GTT-based diagnosis of GDM before the study GTT were included in the study outcome only if there was evidence of earlier negative tests confirming that their diabetes was gestational. When repeat GTTs were performed later in pregnancy (for clinical purposes), the test completed at 24–30 weeks’ gestation determined their study GDM status.

Women with GDM were asked to have a postpartum HbA1c measured at least 3 months after birth. A postpartum HbA1c level ≥6·5 % (48 mmol/mol) or a postpartum fasting glucose ≥7 mmol/l and/or 2 h glucose ≥11·1 mmol/l was used to indicate the presence of co-existing type 2 diabetes. If women met these criteria they were excluded from the GDM analysis.

We collected other outcomes at 4–7 d post birth, including maternal weight (kg) and waist circumference (cm), gestation (in weeks) and prematurity (<37 weeks). Infant Apgar score at 5 min and birth weight were collected from medical records. Infant length (cm), ponderal index (PI) (birth weight (kg)/length (m3)), head circumference (cm), type of delivery (vaginal or caesarean) and admission to the neonatal intensive care unit (NICU) were assessed by the researcher at 4–7 d post birth.

Adherence

More than 3 months’ supply of capsules (n 105) were placed in each bottle. Bottles were replaced at 26–28 weeks’ gestation and birth, at which time two bottles were given to the mother to cover the period up to 6 months post birth. Returned capsules were counted by staff not involved in the study assessments, and adherence rates (number taken/time period) were calculated.

Power

Assuming a 15 % prevalence of GDM, a 63 % reduction due to the probiotic, as found in a Finnish study( Reference Luoto, Laitinen and Nermes 12 ), and a sample size of 195 in each group, the study would have 87 % power at the 5 % level of significance.

Statistical analysis

Analysis was performed using SAS 9.3 and 9.4 (SAS Institute). All analyses were intention-to-treat. Differences between the treatment groups in the prevalence of GDM and dichotomous birth outcomes were estimated using relative rates (RR) and 95 % CI. Although not pre-specified, we conducted an analysis of GDM stratified by factors that were significantly associated with GDM (maternal age, BMI, a history of GDM) and by antibiotic use during the study before the GTT using a generalised linear model with a log-link and binomial distribution. For continuous variables, differences between treatment groups are reported as differences in means (95 % CI) compared using t tests, or as ratios of geometric means (95 %CI) compared using ANCOVA on logged values, adjusted for logged baseline measures; other differences were compared with Wilcoxon’s rank-sum tests. The Apgar score was compared between groups using ordinal logistic regression. Tests were two-sided and P<0·05 was considered statistically significant.

Missing GTT measurements were estimated with 1000 multiple imputations using treatment, fasting, 1 and 2 h measurements, ethnicity, age, BMI at enrolment, a family history of diabetes in first-degree relatives, previous PCOS, and the combination of previous GDM and number of previous pregnancies of >20 weeks’ gestation (grouped as no previous pregnancies, one previous pregnancy with GDM or one previous pregnancy without GDM, two or more previous pregnancies with GDM or two or more previous pregnancies without GDM). One participant who did not undergo the GTT because she had been diagnosed with GDM and prescribed insulin from early pregnancy was assumed to have GDM in all imputations.

This study was conducted according to the guidelines laid down in the Declaration of Helsinki, and all procedures involving human subjects were approved by the Multi-Region Health and Disability Ethics Committee. Written informed consent was obtained from all subjects. The trial was registered at the Australia NZ Clinical Trials Registry: ACTRN12612000196842, https://www.anzctr.org.au/Trial/Registration/TrialReview.aspx?id=362049&isReview=true.

Results

Participants (n 423) were randomised to the HN001 (n 212) or placebo group (n 211) between December 2012 and November 2014 at an average rate of 4·2 a week. Gestational diabetes assessments were completed by February 2015 and the final infant was born in May 2015. Loss-to-follow-up rates were similar between study groups, but more participants in the HN001 group had discontinued the intervention before the GTT (Fig. 1). In contrast, most participants lost to follow-up between the GTT and birth visits were in the placebo group, with small numbers discontinuing the intervention in both study groups. There was one maternal death in the placebo group due to a subarachnoid haemorrhage.

Fig. 1 Status of study participants through the trial. GDM, gestational diabetes mellitus; NZ, New Zealand; GTT, glucose tolerance test.

Median adherence rates were 94·9 % (interquartile range (IQR) 85·7–98·8 %) (n 179) in the HN001 group and 94·0 % (IQR 85·9–98·8 %) (n 183) in the placebo group (Wilcoxon’s rank-sum test, P=0·59).

Among randomised participants, the 24–30-week GTT results included all three time points (fasting, 1 h and 2 h values, as required by IADPSG guideline definitions) in 184 (87 %) participants in the HN001 group and 189 (90 %) in the placebo group, at mean 27·7 (sd 4·6) and 28·0 (sd 8·6) weeks’ gestation, respectively. An additional ten HN001 participants and eleven placebo participants had only the fasting and 2-h time-point GTT results available, which were sufficient for a diagnosis of GDM by standard NZ guidelines. A total of 194 (92 %) in the HN001 group and 200 (95 %) in the placebo group participated in either GTT assessment, all of whom were able to contribute data to the analysis on the basis of NZ guidelines.

There were no substantial differences between the study groups in any maternal characteristic at enrolment, including age, ethnicity, parity, weight, waist, BMI, antibiotic use or corticosteroid use during pregnancy before enrolment, family history of diabetes, household income, maternal smoking or maternal treated allergic disease (asthma, eczema or hayfever), and among those with previous births, weight of largest infant and having a history of GDM (Table 1).

Table 1 Characteristics of the study population at enrolment (Numbers and percentages; medians and interquartile ranges (IQR))

HN001, Lactobacillus rhamnosus HN001.

The prevalence of GDM (defined using the IADPSG criteria) in the HN001 group was lower than that in the placebo group, but this difference was not statistically significant (Table 2). However, using the more specific NZ definition, the prevalence of GDM was significantly lower in the HN001 group. There were three participants in the HN001 group and five in the placebo group using oral or injected corticosteroids between enrolment and the GTT (P=0·48). Among this small number of participants there was no increased risk for gestational diabetes (data not shown). Adjustment for systemic corticosteroid use during this time period made only minimal differences to the treatment effects on gestational diabetes for both the IADPSG (RR 0·59; 95 % CI 0·32, 1·08) and the NZ (RR 0·31; 95 % CI 0·10, 0·95) guidelines. These analyses were repeated with imputed results for missing values but there was little change in the RR estimates. Using the IADPSG guidelines the imputed RR=0·64 (95 % CI 0·36, 1·11), and using the NZ guidelines imputed RR=0·33 (95 % CI 0·11, 0·99).

Table 2 Treatment effects on the prevalence of gestational diabetes mellitus defined according to International Association of Diabetes and Pregnancy Study Groups (IADPSG)Footnote * and New Zealand (NZ)Footnote definitions, and mean blood glucose levels (Prevalence percentages and 95 % confidence intervals; relative rates (RR) and 95 % confidence intervals; mean values and 95 % confidence intervals)

HN001, Lactobacillus rhamnosus HN001.

* Fasting ≥5·1 mmol/l, 1 h≥10 mmol/l, 2 h≥8·5 mmol/l.

Fasting ≥5·5 mmol/l, 2 h≥9 mmol/l.

The mean blood glucose levels at baseline and after 1 and 2 h were slightly lower in the HN001 group compared with the placebo group, but were significant only at baseline (Table 2).

Among forty-four participants diagnosed with GDM according to either the NZ or IADPSG guidelines, forty participants had HbA1c measured between 1 and 15 months post birth, with values between 5·0 % (31 mmol/mol) and 6·4 % (46 mmol/mol). One participant had a post-birth GTT, with values within the normal range. Three participants did not have post-birth HbA1c measured because one had declined, one had withdrawn from the study, and one had died.

Table 3 shows that only maternal age, BMI and having a history of GDM were significantly associated with GDM in this study. These factors were then used to stratify the analysis (Fig. 2) using only the IADPSG definition of GDM, as this definition reflects our a priori hypothesis. There was a significant treatment-by-age (as a continuous variable) interaction (P=0·005) and a non-significant interaction with age dichotomised as ≥35 v. <35 years (P interaction=0·06). In the older group, HN001 was associated with a 3-fold reduction in the prevalence of GDM compared with the prevalence among women in the placebo group (RR 0·31; 95 % CI 0·12, 0·81, P=0·009). In women aged <35 years the prevalence in each study group was similar (RR 1·04; 95 % CI 0·45, 2·39). There were also no significant differences in effect dependent on whether BMI was ≥30 kg/m2 (RR 0·86; 95 % CI 0·37, 1·96), or <30 kg/m2 (RR 0·51; 95 % CI 0·22, 1·17) (P interaction 0·39). GDM did not recur in any of the HN001 participants who had a history of GDM. Thus, we could not test for an interaction effect. Among those with a history of GDM, HN001 protected against a recurrence of GDM, RR=0·00 (95 % CI 0·00, 0·66), and for those without previous GDM, RR=0·50 (95 % CI 0·20, 1·27). Three women (20 %) with a history of GDM did not complete the GTT according to the IADSPG guidelines. In all imputations, these were GDM positive, giving an imputed RR=0·38 (95 % CI 0·05, 1·00, P=0·043, Barnard’s exact test). As HN001 is susceptible to a range of antibiotics( Reference Zhou, Pillidge and Gopal 15 ), we examined the effect of HN001 on GDM by use of antibiotics between study enrolment and the GTT test. The HN001 effect on GDM was significantly protective among participants who had not used antibiotics between study enrolment and the GTT test but there was no significant effect of HN001 for those who had used antibiotics during this period (P interaction=0·10).

Fig. 2 Lactobacillus rhamnosus HN001 (HN001) associations with gestational diabetes mellitus (GDM) stratified by (a) age ≥35 v. <35 years, (b) BMI≥30 v. <30 kg/m2, (c) history of GDM and (d) systemic antibiotic use since enrolment.

Table 3 Association of maternal risk factors with gestational diabetes mellitus, after adjustment for treatment group (Relative rates (RR) and 95 % confidence intervals)

* For each additional year of age.

For each additional BMI unit; two values >45 truncated at 45 to ensure model fit.

For each additional miscarriage.

§ Birth weight ≥4000 g.

Similarly, among those not using antibiotics, fasting mean blood glucose levels were significantly lower (P=0·001) in the HN001 group (4·28; 95 % CI 4·23, 4·33) compared with that in the placebo group (4·42; 95 % CI 4·35, 4·48). Differences in mean glucose levels at 1 and 2 h post glucose load were also lower but were not significant. At 1 h, blood glucose levels were 6·63 (95 % CI 6·37, 6·89) in the HN001 group and 6·88 (95 % CI 6·60, 7·16) in the placebo group (P=0·20), and at 2 h the levels were 5·56 (95 % CI 5·38, 5·73) in the HN001 group and 5·77 (95 % CI 5·53, 6·01) in the placebo group (P=0·15).

HN001 was not significantly associated with any maternal anthropometric measures (after adjustment for baseline measurements), or infant birth weight, gestation, caesarean delivery or admission to the NICU or, at 4–7 d post birth, infant length, PI or head circumference. Infants whose mothers were in the HN001 group had a significantly higher 5-min Apgar score than did infants in the placebo group (Table 4).

Table 4 Treatment effects on birth outcomes (Geometric means and 95 % confidence intervals; median and interquartile range (IQR); mean values and 95 % confidence intervals; relative rates (RR) and 95 % confidence intervals)

HN001, Lactobacillus rhamnosus HN001; NICU, Neonatal Intensive Care Unit.

* ANCOVA on logged values, adjusted for logged baseline measures, geometric means are fitted for the baseline geometric mean.

Wilcoxon’s rank-sum test.

OR of having a higher Apgar score; Apgar scores grouped 0–3, 4–6, 7, 8, 9, 10: ordinal logistic regression.

GDM in the mother, defined according to the IADPSG recommendations, was associated with higher maternal weight (P=0·0002), waist circumference (P<0·0001) and BMI (P<0·0001) post birth but was not associated with any infant anthropometric measures, gestation, caesarean delivery, NICU admission or Apgar score at 5 min (data not shown).

Discussion

As far as we are aware, this is the first study to report a role for probiotics in preventing GDM among women not selected on the basis of risk for GDM. Our data suggest that the probiotic HN001 at a dose of 6×109 cfu/d may lower the rate of GDM from 13·8 to 8·2 %, a 40 % reduction using the IADPSG guidelines( 6 ) or a 68 % reduction from 6·5 to 2·1 % using the NZ guidelines. Differences in mean blood glucose levels were small at baseline, and at 1 and 2 h post glucose load. Nevertheless, these differences in absolute values correspond to the difference in GDM prevalence we found using thresholds.

The HN001 protective effect on GDM (defined using the IADPSG criteria) found in this study was weaker than the probiotic effect on GDM found among women at risk for GDM in Finland( Reference Luoto, Laitinen and Nermes 12 ), but older women and women with a history of GDM had similar risks to the at-risk Finnish population. This Finnish study intervened from the first trimester of pregnancy with a combination of two probiotics (L. rhamnosus GG and B. lactis Bb12) and reported a significant reduction in GDM prevalence from 36 to 13 % due to the probiotics. Both active and placebo groups also had a dietary intervention. It is possible that the probiotics interacted with diet to enhance protection against GDM, or that the combination of the two probiotics used in the Finnish study was more effective than HN001 alone. The higher prevalence of GDM in the Finnish trial may be a consequence of limiting the test to an at-risk sub-group and the different diagnostic thresholds applicable in Finland at that time (≥4·8 mmol/l at baseline, ≥10 mmol/l at 1 h, or ≥8·7 mmol/l at 2 h)( Reference Luoto, Laitinen and Nermes 12 ). Applying the Finnish at-risk criteria( Reference Laitinen, Poussa and Isolauri 16 ) to our study population, at least 58 % of the women would have been at risk, and applying the Finnish GDM diagnostic criteria to these women at risk, 27 % of women in the placebo group and 22 % of women in the HN001 group would have been classified as having GDM. In smaller studies, Lindsay et al. have shown no significant effect of Lactobacillus salivarius UCC118 on fasting glucose levels among obese women when taken between 24 and 28 weeks’ gestation( Reference Lindsay, Kennelly and Culliton 17 ) or as a 4–6-week treatment for women with either impaired glucose tolerance or GDM( Reference Lindsay, Brennan and Kennelly 18 ). This may indicate that this particular strain of probiotic is an ineffective intervention for prevention or treatment of GDM, or that the intervention period was too short or too late in pregnancy to observe an effect, or the studies lacked statistical power.

Our study showed that the HN001 effect was stronger using the higher NZ glucose thresholds than the IADPSG thresholds to define GDM, suggesting that the effect is greater in preventing more severe GDM.

Taking one or more systemic antibiotic courses during the same period as the HN001 may negate any effect of HN001 on GDM, with benefits of taking HN001 found only among those who did not require antibiotics. However, because of the small percentage (11 %) taking antibiotics, the study had low power to assess differences in HN001 effect dependent on antibiotic use (P=0·10). There was a similar strengthening effect of HN001 on blood glucose levels, particularly at baseline, after excluding those taking antibiotics. These data might indicate the deleterious effect that antibiotics have on gut microbiota composition and function( Reference Francino 19 ), possibly compromising the viability of HN001.

The HN001 intervention appeared to have no effect on maternal or infant anthropometric measures post birth. Gestation duration, rate of caesarean delivery and admission to the NICU were also unaffected by HN001, findings that are consistent with other studies( Reference Luoto, Laitinen and Nermes 12 , Reference Lindsay, Kennelly and Culliton 17 ). One explanation for a lack of effect may be that maternal use of medication or dietary/exercise regimens to reduce blood glucose levels could have obscured any effect of untreated GDM on post-birth measures in the infant or the mother. The effects of antibiotics on the gut microbiota if taken during the third trimester, but before labour, could also have obscured an effect. However, removal of the 13 % using systemic antibiotics during this period had little impact on the associations of HN001 with anthropometric measures. Assuming this discrepancy between an HN001 effect on GDM but not on anthropometric measures at birth is not explained by obstetric interventions to limit excessive weight gain, there may be a mechanism whereby HN001 has an effect on blood sugar levels but not on maternal weight.

There was a significant (P=0·04) beneficial effect of HN001 on the 5-min Apgar score, possibly due to chance given the number of comparisons performed.

The gut microbiota is profoundly altered during the three trimesters of pregnancy towards a less diverse state, with the most depleted microbial richness found in women with GDM( Reference Koren, Goodrich and Tyler 20 ). In contrast to obesity-related gut microbiota, the last-trimester gut microbiota has been associated with greater amounts of energy lost in stool compared with the first trimester, indicating that the impact of gut microbiota alterations during pregnancy on host adiposity and host glucose metabolism is not necessarily identical( Reference Koren, Goodrich and Tyler 20 ). We speculate that HN001 supplementation altered the composition and function of the gut microbiota in favour of improved insulin sensitivity and inflammation in the host, which reduced the propensity towards GDM.

The lack of any deleterious effect on birth outcomes supports HN001 as a safe intervention to take from early pregnancy (14–16 weeks’ gestation), which may also be beneficial to the infant, as reflected by the Apgar score. These findings are important given the small amount of data available on effects of early-pregnancy probiotic interventions.

A limitation of our study is that we did not collect maternal anthropometric measures at the time of the GTT. We were also unable to measure pre-pregnancy maternal anthropometric measures, and hence changes in maternal weight and waist circumference during pregnancy were based on measurements taken at enrolment (14–16 weeks’ gestation), when differences may already reflect a change from pre-pregnancy weight. However, women are recommended to gain less than 2 kg in their first trimester( 21 ), and many women gain considerably less( Reference Fattah, Farah and Barry 22 ). Given the smaller reduction in GDM we found compared with Luoto et al.( Reference Luoto, Laitinen and Nermes 12 ), we may also have overestimated the power of the study to find a difference by basing it on their findings.

The strengths of this study are the larger sample size and good follow-up rates compared with previous studies, and good generalisability because our population was not selected for high risk for GDM. As underlying low-grade inflammation may be a predisposing factor in obesity, diabetes and allergic disease( Reference Prescott 23 ), our study population, selected to be at risk for allergic disease, may also be at greater risk for diabetes. Further, systemic corticosteroid use, most likely for asthma management in our study population, may have increased the rate of insulin resistance and gestational diabetes( Reference Fisher, Smith and Lagrandeur 24 ). However, it is unlikely that these factors explain our study findings, given that the 6·5 % prevalence of GDM in the placebo group is representative of the NZ prevalence (1) and corticosteroid use was not associated with increased gestational diabetes for either GDM definition. The generalisability of the study may also be compromised because women self-selected for study may be better educated and have higher incomes than women not included in the study. However, these factors are unlikely to be associated with an HN001 effect.

We were also able to exclude the possibility that women with undiagnosed type 2 diabetes mellitus were misclassified as GDM by measuring their postpartum HbA1c or GTT. Most of these women (40/44) underwent postpartum evaluation of their glycaemic status but none met a level indicative of type 2 diabetes mellitus( Reference Braatvedt, Cundy and Crooke 25 ), suggesting that the cases of GDM are likely to be gestational only.

Promoting good health in pregnancy through weight control programmes or diet has been largely ineffective, partly due to poor adherence with the interventions. If our results for probiotics are confirmed in other larger trials, the promise of a simple, cheap and safe intervention is an attractive option to reduce the prevalence of GDM, which is increasing not only in affluent countries but also in less-affluent countries as they become more Westernised.

Acknowledgements

The authors thank the women who willingly gave their time and provided their data for the study, and also Sherron Kneebone, Amy Norman and Barbara Wright, all from Auckland University, for assistance with study recruitment and fieldwork.

This study was funded by grants and support from the Health Research Council of NZ (HRC 11/318) and Fonterra. Fonterra contributed funds, provided and maintained quality control of the study capsules and performed the participant randomisation for the study. Fonterra had no role in the design, analysis or writing of this article.

K. L. W. conceived the idea, raised the funds, coordinated the project, contributed to the data analysis and drafted the manuscript. J. C. had overall responsibility for the study. E. A. M. led the Auckland arm of the study, and together with P. R. S., R. M. and P. F. F. contributed to the study design. C. A. B. was largely responsible for the development and management of the study in Wellington. J. L. R. managed the Auckland team. R. M., R. M. M., P. R. A., P. R. S. and F. E. H. also contributed to the study design by providing advice on diabetes testing during pregnancy, and R. M. M., T. V. S., P. R. A., P. R. S. and F. E. H. provided advice on design issues at birth. P. K. B. and J. M. K. developed the database and helped with study design. C. A. B., J. M. K., F. E. H. and J. L. R. also helped with data collection. G. L. P. was responsible for the data analysis. K. L. W. takes responsibility for the content of the manuscript. All authors reviewed and commented on the manuscript.

The authors declare that there are no conflicts of interest.

References

1. Ministry of Health (2014) Screening, Diagnosis and Management of Gestational Diabetes in New Zealand: A Clinical Practice Guideline. Wellington: Ministry of Health.Google Scholar
2. American College of Obstetricians and Gynecologists Committee (2013) ACOG Committee opinion number 549: Obesity in pregnancy. Obstet Gynecol 121, 213217.CrossRefGoogle Scholar
3. Kim, SY, England, L, Wilson, HG, et al. (2010) Percentage of gestational diabetes mellitus attributable to overweight and obesity. Am J Public Health 100, 10471052.CrossRefGoogle ScholarPubMed
4. Ben-Haroush, A, Yogev, Y & Hod, M (2004) Epidemiology of gestational diabetes mellitus and its association with type 2 diabetes. Diabet Med 21, 103113.CrossRefGoogle ScholarPubMed
5. Kim, C, Newton, KM & Knopp, RH (2002) Gestational diabetes and the incidence of type 2 diabetes. Diabetes Care 25, 18621868.CrossRefGoogle ScholarPubMed
6. International Association of Diabetes and Pregnancy Study Groups Consensus Panel (2010) International Association of Diabetes and Pregnancy Study Groups Recommendations on the diagnosis and classification of hyperglycemia in pregnancy. Diabetes Care 33, 676682.CrossRefGoogle Scholar
7. Coustan, DR, Lower, LP, Metzger, BE, et al. (2010) The Hyperglycemia and Adverse Pregnancy Outcome (HAPO) study: paving the way for new diagnostic criteria for gestational diabetes mellitus. Am J Obstet Gynecol 202, 654.e651e656.CrossRefGoogle ScholarPubMed
8. Food and Agriculture Organization/World Health Organization (2002) Guidelines for the Evaluation of Probiotics in Food. Report of a Joint FAO/WHO Working Group on Drafting Guidelines for the Evaluation of Probiotics in Food. London: FAO/WHO.Google Scholar
9. Gomes, AC, Beuno, AA, de Souza, RGM, et al. (2014) Gut microbiota, probiotics and diabetes. Nutr J 13, 60.CrossRefGoogle ScholarPubMed
10. Zhang, Q, Yucheng, W & Xiaoqiang, F (2016) Effect of probiotics on glucose metabolism in patients with type 2 diabetes mellitus: a meta-analysis of randomized controlled trials. Medicina 52, 2834.CrossRefGoogle ScholarPubMed
11. Thomas, LV, Ockhuizen, T & Suzuki, K (2014) Exploring the influence of the gut microbiota and probiotics on health: a symposium report. Br J Nutr 112, S1S18.CrossRefGoogle Scholar
12. Luoto, R, Laitinen, K, Nermes, M, et al. (2010) Impact of maternal probiotic-supplemented dietary counselling on pregnancy outcome and prenatal and postnatal growth: a double-blind, placebo-controlled study. Br J Nutr 103, 17921799.CrossRefGoogle ScholarPubMed
13. Barthow, C, Wickens, K, Stanley, T, et al. (2016) The Probiotics in Pregnancy Study (PiP Study): rationale and design of a double-blind randomised controlled trial to improve maternal health during pregnancy and prevent infant eczema and allergy. BMC Pregnancy Childbirth 16, 133.CrossRefGoogle ScholarPubMed
14. Wickens, K, Black, PN, Stanley, TV, et al. (2008) A differential effect of 2 probiotics in the prevention of eczema and atopy: a double-blind, randomized, placebo-controlled trial. J Allergy Clin Immunol 122, 788794.CrossRefGoogle ScholarPubMed
15. Zhou, JS, Pillidge, CJ, Gopal, PK, et al. (2005) Antibiotic susceptibility profiles of new probiotic Lactobacillus and Bifidobacterium strains. Int J Food Microbiol 98, 211217.CrossRefGoogle ScholarPubMed
16. Laitinen, K, Poussa, T, Isolauri, E, et al. (2009) Probiotics and dietary counselling contribute to glucose regulation during and after pregnancy: a randomized controlled trial. Br J Nutr 101, 16791687.CrossRefGoogle Scholar
17. Lindsay, KL, Kennelly, M, Culliton, M, et al. (2014) Probotics in obese pregnancy do not reduce maternal fasting glucose: a double-blind, placebo-controlled, randomized trial (Probiotics in Pregnancy Study). Am J Clin Nutr 99, 14321439.CrossRefGoogle Scholar
18. Lindsay, KL, Brennan, L, Kennelly, MA, et al. (2015) Impact of probiotics in women with gestational diabetes mellitus on metabolic health: a randomized trial. Am J Obstet Gynecol 212, 496.e1e11.CrossRefGoogle Scholar
19. Francino, MP (2016) Antibiotics and the human gut microbiome: dysbiosis and accumulation of resistances. Front Microbiol 6, 1543.CrossRefGoogle ScholarPubMed
20. Koren, O, Goodrich, JK, Tyler, CC, et al. (2012) Host remodelling of the gut microbiome and metabolic changes during pregnancy. Cell 150, 470480.CrossRefGoogle ScholarPubMed
21. Ministry of Health (2014) Guidance for Healthy Weight Gain During Pregnancy. Wellington: Ministry of Health.Google Scholar
22. Fattah, C, Farah, N, Barry, SC, et al. (2010) Maternal weight and body composition in the first trimester of pregnancy. Acta Obstet Gynecol Scand 89, 952955.CrossRefGoogle ScholarPubMed
23. Prescott, SL (2013) Early-life environmental determinants of allergic diseases and the wider pandemic of inflammatory noncommunicable diseases. J Allergy Clin Immunol 131, 2330.CrossRefGoogle ScholarPubMed
24. Fisher, JE, Smith, RS, Lagrandeur, R, et al. (1997) Gestational diabetes mellitus in women receiving beta-adrenergics and corticosteroids for threatened preterm delivery. Obstet Gynecol 90, 880883.CrossRefGoogle ScholarPubMed
25. Braatvedt, GD, Cundy, T, Crooke, M, et al. (2012) Understanding the new HbA1c units for the diagnosis of type 2 diabetes. N Z Med J 125, 7080.Google ScholarPubMed
Figure 0

Fig. 1 Status of study participants through the trial. GDM, gestational diabetes mellitus; NZ, New Zealand; GTT, glucose tolerance test.

Figure 1

Table 1 Characteristics of the study population at enrolment (Numbers and percentages; medians and interquartile ranges (IQR))

Figure 2

Table 2 Treatment effects on the prevalence of gestational diabetes mellitus defined according to International Association of Diabetes and Pregnancy Study Groups (IADPSG)* and New Zealand (NZ)† definitions, and mean blood glucose levels (Prevalence percentages and 95 % confidence intervals; relative rates (RR) and 95 % confidence intervals; mean values and 95 % confidence intervals)

Figure 3

Fig. 2 Lactobacillus rhamnosus HN001 (HN001) associations with gestational diabetes mellitus (GDM) stratified by (a) age ≥35 v. <35 years, (b) BMI≥30 v. <30 kg/m2, (c) history of GDM and (d) systemic antibiotic use since enrolment.

Figure 4

Table 3 Association of maternal risk factors with gestational diabetes mellitus, after adjustment for treatment group (Relative rates (RR) and 95 % confidence intervals)

Figure 5

Table 4 Treatment effects on birth outcomes (Geometric means and 95 % confidence intervals; median and interquartile range (IQR); mean values and 95 % confidence intervals; relative rates (RR) and 95 % confidence intervals)