Department of Medicine, University of Toronto, Toronto, ON, Canada; Lunenfeld-Tanenbaum Research Institute, Toronto, ON, Canada; Sinai Health System, Mount Sinai Hospital, Toronto, ON, Canada.
Cumming School of Medicine, Department of Medicine, Department of Obstetrics and Gynecology, University of Calgary, Calgary, AB, Canada; Alberta Children's Hospital Research Institute, Calgary, AB, Canada.
Lancet Diabetes Endocrinol. 2020 Oct;8(10):834-844. doi: 10.1016/S2213-8587(20)30310-7.
Although metformin is increasingly being used in women with type 2 diabetes during pregnancy, little data exist on the benefits and harms of metformin use on pregnancy outcomes in these women. We aimed to investigate the effects of the addition of metformin to a standard regimen of insulin on neonatal morbidity and mortality in pregnant women with type 2 diabetes.
In this prospective, multicentre, international, randomised, parallel, double-masked, placebo-controlled trial, women with type 2 diabetes during pregnancy were randomly assigned from 25 centres in Canada and four in Australia to receive either metformin 1000 mg twice daily or placebo, added to insulin. Randomisation was done via a web-based computerised randomisation service and stratified by centre and pre-pregnancy BMI (<30 kg/m or ≥30 kg/m) in a ratio of 1:1 using random block sizes of 4 and 6. Women were eligible if they had type 2 diabetes, were on insulin, had a singleton viable pregnancy, and were between 6 and 22 weeks plus 6 days' gestation. Participants were asked to check their fasting blood glucose level before the first meal of the day, before the last meal of the day, and 2 h after each meal. Insulin doses were adjusted aiming for identical glucose targets (fasting glucose <5·3 mmol/L [95 mg/dL], 2-h postprandial glucose <6·7 mmol/L [120 mg/dL]). Study visits were done monthly and patients were seen every 1-4 weeks as was needed for standard clinical care. At study visits blood pressure and bodyweight were measured; patients were asked about tolerance to their pills, any hospitalisations, insulin doses, and severe hypoglycaemia events; and glucometer readings were downloaded to the central coordinating centre. Participants, caregivers, and outcome assessors were masked to the intervention. The primary outcome was a composite of fetal and neonatal outcomes, for which we calculated the relative risk and 95% CI between groups, stratifying by site and BMI using a log-binomial regression model with an intention-to-treat analysis. Secondary outcomes included several relevant maternal and neonatal outcomes. The trial was registered with ClinicalTrials.gov, NCT01353391.
Between May 25, 2011, and Oct 11, 2018, we randomly assigned 502 women, 253 (50%) to metformin and 249 (50%) to placebo. Complete data were available for 233 (92%) participants in the metformin group and 240 (96%) in the placebo group for the primary outcome. We found no significant difference in the primary composite neonatal outcome between the two groups (40% vs 40%; p=0·86; relative risk [RR] 1·02 [0·83 to 1·26]). Compared with women in the placebo group, metformin-treated women achieved better glycaemic control (HbA at 34 weeks' gestation 41·0 mmol/mol [SD 8·5] vs 43·2 mmol/mol [-10]; 5·90% vs 6·10%; p=0·015; mean glucose 6·05 [0·93] vs 6·27 [0·90]; difference -0·2 [-0·4 to 0·0]), required less insulin (1·1 units per kg per day vs 1·5 units per kg per day; difference -0·4 [95% CI -0·5 to -0·2]; p<0·0001), gained less weight (7·2 kg vs 9·0 kg; difference -1·8 [-2·7 to -0·9]; p<0·0001) and had fewer caesarean births (125 [53%] of 234 in the metformin group vs 148 [63%] of 236 in the placebo group; relative risk [RR] 0·85 [95% CI 0·73 to 0·99]; p=0·031). We found no significant difference between the groups in hypertensive disorders (55 [23%] in the metformin group vs 56 [23%] in the placebo group; p=0·93; RR 0·99 [0·72 to 1·35]). Compared with those in the placebo group, metformin-exposed infants weighed less (mean birthweight 3156 g [SD 742] vs 3375 g [742]; difference -218 [-353 to -82]; p=0·002), fewer were above the 97th centile for birthweight (20 [9%] in the metformin group vs 34 [15%] in the placebo group; RR 0·58 [0·34 to 0·97]; p=0·041), fewer weighed 4000 g or more at birth (28 [12%] in the metformin group vs 44 [19%] in the placebo group; RR 0·65 [0·43 to 0·99]; p=0·046), and metformin-exposed infants had reduced adiposity measures (mean sum of skinfolds 16·0 mm [SD 5·0] vs 17·4 [6·2] mm; difference -1·41 [-2·6 to -0·2]; p=0·024; mean neonatal fat mass 13·2 [SD 6·2] vs 14·6 [5·0]; p=0·017). 30 (13%) infants in the metformin group and 15 (7%) in the placebo group were small for gestational age (RR 1·96 [1·10 to 3·64]; p=0·026). We found no significant difference in the cord c-peptide between groups (673 pmol/L [435] in the metformin group vs 758 pmol/L [595] in the placebo group; p=0·10; ratio of means 0·88 [0·72 to 1·02]). The most common adverse event reported was gastrointestinal (38 events in the metformin group and 38 events in the placebo group).
We found several maternal glycaemic and neonatal adiposity benefits in the metformin group. Along with reduced maternal weight gain and insulin dosage and improved glycaemic control, the lower adiposity and infant size measurements resulted in fewer large infants but a higher proportion of small-for-gestational-age infants. Understanding the implications of these effects on infants will be important to properly advise patients who are contemplating the use of metformin during pregnancy.
Canadian Institutes of Health Research, Lunenfeld-Tanenbaum Research Institute, University of Toronto.
尽管二甲双胍在妊娠期 2 型糖尿病女性中越来越多地被使用,但关于这些女性使用二甲双胍对妊娠结局的益处和危害的数据很少。我们旨在研究在妊娠 2 型糖尿病女性中,添加二甲双胍至胰岛素标准治疗方案对新生儿发病率和死亡率的影响。
在这项前瞻性、多中心、国际、随机、平行、双盲、安慰剂对照试验中,来自加拿大 25 个中心和澳大利亚 4 个中心的妊娠 2 型糖尿病女性被随机分配至接受二甲双胍 1000mg 每日两次或安慰剂,添加至胰岛素。通过基于网络的计算机随机分配服务,按照中心和孕前 BMI(<30kg/m2 或≥30kg/m2)进行分层,随机分组大小为 4 和 6,比例为 1:1。符合条件的女性为患有 2 型糖尿病、正在接受胰岛素治疗、有单胎活产且妊娠 6-22 周加 6 天的女性。要求参与者在每天第一餐前、最后一餐前和每餐 2 小时后检查空腹血糖水平。调整胰岛素剂量,以达到相同的血糖目标(空腹血糖<5.3mmol/L[95mg/dL],餐后 2 小时血糖<6.7mmol/L[120mg/dL])。每月进行研究访问,根据标准临床护理的需要,每 1-4 周对患者进行一次就诊。在就诊时测量血压和体重;询问患者对其药物的耐受性、任何住院治疗、胰岛素剂量和严重低血糖事件;并将血糖仪读数下载到中央协调中心。参与者、照顾者和结局评估者对干预措施均设盲。主要结局为胎儿和新生儿结局的复合结局,我们对各分组之间的相对风险和 95%置信区间进行了计算,分层时按地点和 BMI 使用对数二项式回归模型进行意向治疗分析。次要结局包括几项相关的母婴和新生儿结局。该试验在 ClinicalTrials.gov 上注册,NCT01353391。
2011 年 5 月 25 日至 2018 年 10 月 11 日,我们随机分配了 502 名女性,253 名(50%)接受二甲双胍治疗,249 名(50%)接受安慰剂治疗。在接受二甲双胍治疗的 233 名(92%)参与者和接受安慰剂治疗的 240 名(96%)参与者中,我们获得了完整的数据,用于主要结局。我们没有发现两组之间主要复合新生儿结局有显著差异(40%比 40%;p=0.86;相对风险[RR]1.02[0.83 至 1.26])。与安慰剂组女性相比,接受二甲双胍治疗的女性血糖控制更好(34 周时的糖化血红蛋白 41.0mmol/mol[8.5]比 43.2mmol/mol[-10];5.90%比 6.10%;p=0.015;平均血糖 6.05[0.93]比 6.27[0.90];差值-0.2[-0.4 至 0.0]),需要的胰岛素更少(每天每公斤 1.1 单位比每天每公斤 1.5 单位;差值-0.4[95%置信区间-0.5 至-0.2];p<0.0001),体重增加更少(7.2kg 比 9.0kg;差值-1.8[-2.7 至-0.9];p<0.0001),剖宫产更少(二甲双胍组 234 名中有 125 名[53%],安慰剂组 236 名中有 148 名[63%];相对风险[RR]0.85[95%置信区间 0.73 至 0.99];p=0.031)。我们没有发现两组之间高血压疾病有显著差异(二甲双胍组 55 名[23%],安慰剂组 56 名[23%];p=0.93;RR 0.99[0.72 至 1.35])。与安慰剂组相比,接受二甲双胍治疗的婴儿体重更轻(平均出生体重 3156g[SD 742]比 3375g[742];差值-218[-353 至-82];p=0.002),出生体重在第 97 百分位数以上的婴儿比例更低(二甲双胍组 20 名[9%],安慰剂组 34 名[15%];RR 0.58[0.34 至 0.97];p=0.041),出生体重 4000g 或以上的婴儿比例更低(二甲双胍组 28 名[12%],安慰剂组 44 名[19%];RR 0.65[0.43 至 0.99];p=0.046),接受二甲双胍治疗的婴儿脂肪量减少(平均皮褶厚度 16.0mm[SD 5.0]比 17.4mm[6.2];差值-1.41[-2.6 至-0.2];p=0.024;新生儿脂肪量中位数 13.2[SD 6.2]比 14.6[5.0];差值-1.46[-2.6 至-0.2];p=0.017)。二甲双胍组有 30 名(13%)婴儿和安慰剂组有 15 名(7%)婴儿为小于胎龄儿(RR 1.96[1.10 至 3.64];p=0.026)。我们没有发现两组之间脐带 c 肽有显著差异(二甲双胍组 673pmol/L[435],安慰剂组 758pmol/L[595];p=0.10;均值比 0.88[0.72 至 1.02])。最常见的不良事件是胃肠道(二甲双胍组 38 例,安慰剂组 38 例)。
我们发现二甲双胍组在母亲血糖和新生儿脂肪方面有一些益处。除了降低母亲体重增加和胰岛素剂量以及改善血糖控制外,较低的脂肪量和婴儿大小测量结果导致较少的巨大儿,但更多的是小于胎龄儿。了解这些影响对婴儿的意义将对正确指导考虑在妊娠期间使用二甲双胍的患者非常重要。
加拿大卫生研究院、伦纳德-塔南鲍姆研究所以及多伦多大学。
