Shah Sachin S, Ohlsson Arne, Halliday Henry L, Shah Vibhuti S
Department of Pediatrics, Surya Hospital for Women and Children, Pune, India.
Cochrane Database Syst Rev. 2017 Oct 17;10(10):CD002058. doi: 10.1002/14651858.CD002058.pub3.
Bronchopulmonary dysplasia (BPD) remains an important cause of mortality and morbidity in preterm infants and inflammation plays a significant role in its pathogenesis. The use of inhaled corticosteroids may modulate the inflammatory process without concomitant high systemic steroid concentrations and less risk of adverse effects. This is an update of a review published in 2012 (Shah 2012). We recently updated the related review on "Inhaled versus systemic corticosteroids for treating bronchopulmonary dysplasia in ventilated very low birth weight preterm neonates".
To determine the effect of inhaled versus systemic corticosteroids started within the first 7 days of life on preventing death or BPD in ventilated very low birth weight infants.
We used the standard search strategy of Cochrane Neonatal to search the Cochrane Central Register of Controlled Trials (CENTRAL 2017, Issue 1), MEDLINE via PubMed (1966 to 23 February 2017), Embase (1980 to 23 February 2017), and CINAHL (1982 to 23 February 2017). We searched clinical trials registers, conference proceedings and the reference lists of retrieved articles for randomised controlled trials (RCTs) and quasi-randomised trials.
Randomised or quasi-randomised controlled trials comparing inhaled versus systemic corticosteroid therapy (irrespective of dose and duration) starting in the first seven days of life in very low birth weight preterm infants receiving assisted ventilation.
Clinical outcomes data were extracted and analysed using Review Manager. When appropriate, meta-analysis was performed using typical relative risk (RR), typical risk difference (RD) and weighted mean difference (WMD). Meta-analyses were performed using typical relative risk, typical risk difference (RD), and weighted mean difference with their 95% confidence intervals (CI). If RD was statistically significant, the number needed to benefit or the number needed to harm was calculated. We assessed the quality of evidence was evaluated using GRADE principles.
We included two trials that involved 294 infants. No new studies were included for the 2017 update. The incidence of death or BPD at 36 weeks' postmenstrual age was not statistically significantly different between infants who received inhaled or systemic steroids (RR 1.09, 95% CI 0.88 to 1.35; RD 0.05, 95% CI -0.07 to 0.16; 1 trial, N = 278). The incidence of BPD at 36 weeks' postmenstrual age among survivors was not statistically significant between groups (RR 1.34, 95% CI 0.94 to 1.90; RD 0.11, 95% CI -0.02 to 0.24; 1 trial, N = 206). There was no statistically significant difference in the outcomes of BPD at 28 days, death at 28 days or 36 weeks' postmenstrual age and the combined outcome of death or BPD by 28 days between groups (2 trials, N = 294). The duration of mechanical ventilation was significantly longer in the inhaled steroid group compared with the systemic steroid group (typical MD 4 days, 95% CI 0.2 to 8; 2 trials, N = 294; I² = 0%) as was the duration of supplemental oxygen (typical MD 11 days, 95% CI 2 to 20; 2 trials, N = 294; I² = 33%).The incidence of hyperglycaemia was significantly lower with inhaled steroids (RR 0.52, 95% CI 0.39 to 0.71; RD -0.25, 95% CI -0.37 to -0.14; 1 trial, N = 278; NNTB 4, 95% CI 3 to 7 to avoid 1 infant experiencing hyperglycaemia). The rate of patent ductus arteriosus increased in the group receiving inhaled steroids (RR 1.64, 95% CI 1.23 to 2.17; RD 0.21, 95% CI 0.10 to 0.33; 1 trial, N = 278; NNTH 5, 95% CI 3 to 10). In a subset of surviving infants in the United Kingdom and Ireland there were no significant differences in developmental outcomes at 7 years of age. However, there was a reduced risk of having ever been diagnosed as asthmatic by 7 years of age in the inhaled steroid group compared with the systemic steroid group (N = 48) (RR 0.42, 95% CI 0.19 to 0.94; RD -0.31, 95% CI -0.58 to -0.05; NNTB 3, 95% CI 2 to 20).According to GRADE the quality of the evidence was moderate to low. Evidence was downgraded on the basis of design (risk of bias), consistency (heterogeneity) and precision of the estimates.Both studies received grant support and the industry provided aero chambers and metered dose inhalers of budesonide and placebo for the larger study. No conflict of interest was identified.
AUTHORS' CONCLUSIONS: We found no evidence that early inhaled steroids confer important advantages over systemic steroids in the management of ventilator-dependent preterm infants. Based on this review inhaled steroids cannot be recommended over systemic steroids as a part of standard practice for ventilated preterm infants. Because they might have fewer adverse effects than systemic steroids, further randomised controlled trials of inhaled steroids are needed that address risk/benefit ratio of different delivery techniques, dosing schedules and long-term effects, with particular attention to neurodevelopmental outcome.
支气管肺发育不良(BPD)仍是早产儿死亡和发病的重要原因,炎症在其发病机制中起重要作用。吸入性糖皮质激素的使用可调节炎症过程,而不会伴随高全身性类固醇浓度,且不良反应风险较低。这是对2012年发表的一篇综述(Shah 2012)的更新。我们最近更新了关于“吸入性与全身性糖皮质激素治疗机械通气的极低出生体重早产儿支气管肺发育不良”的相关综述。
确定出生后7天内开始使用吸入性与全身性糖皮质激素对预防机械通气的极低出生体重婴儿死亡或BPD的效果。
我们使用Cochrane新生儿标准检索策略,检索Cochrane对照试验中心注册库(CENTRAL 2017年第1期)、通过PubMed检索的MEDLINE(1966年至2017年2月23日)、Embase(1980年至2017年2月23日)和CINAHL(1982年至2017年2月23日)。我们检索了临床试验注册库、会议论文集以及检索到的文章的参考文献列表,以查找随机对照试验(RCT)和半随机试验。
比较出生后前七天开始接受辅助通气的极低出生体重早产儿吸入性与全身性糖皮质激素治疗(不论剂量和疗程)的随机或半随机对照试验。
使用Review Manager提取和分析临床结局数据。在适当情况下,使用典型相对风险(RR)、典型风险差(RD)和加权平均差(WMD)进行荟萃分析。荟萃分析使用典型相对风险、典型风险差(RD)和加权平均差及其95%置信区间(CI)进行。如果RD具有统计学意义,则计算受益所需人数或伤害所需人数。我们使用GRADE原则评估证据质量。
我们纳入了两项涉及294名婴儿的试验。2017年更新未纳入新的研究。在接受吸入性或全身性类固醇治疗的婴儿中,孕龄36周时死亡或BPD的发生率无统计学显著差异(RR 1.09,95%CI 0.88至1.35;RD 0.05,95%CI -0.07至0.16;1项试验,N = 278)。幸存者中孕龄36周时BPD的发生率在两组间无统计学显著差异(RR 1.34,95%CI 0.94至1.90;RD 0.11,95%CI -0.02至0.24;1项试验,N = 206)。两组间28天时BPD结局、28天或孕龄36周时死亡以及28天时死亡或BPD联合结局无统计学显著差异(2项试验,N = 294)。与全身性类固醇组相比,吸入性类固醇组机械通气时间显著更长(典型MD 4天,95%CI 0.2至8;2项试验,N = 294;I² = 0%),补充氧气时间也是如此(典型MD 11天,95%CI 2至20;2项试验,N = 294;I² = 33%)。吸入性类固醇治疗时高血糖发生率显著更低(RR 0.52,95%CI 0.39至0.71;RD -0.25,95%CI -0.37至-0.14;1项试验,N = 278;避免1例婴儿发生高血糖的NNTB 4,95%CI 3至7)。接受吸入性类固醇治疗组动脉导管未闭发生率增加(RR 1.64,95%CI 1.23至2.17;RD 0.21,95%CI 0.10至0.33;1项试验,N = 278;NNTH 5,95%CI 3至10)。在英国和爱尔兰存活婴儿的一个亚组中,7岁时发育结局无显著差异。然而,与全身性类固醇组相比,吸入性类固醇组7岁时曾被诊断为哮喘的风险降低(N = 48)(RR 0.42,95%CI 0.19至0.94;RD -0.31,95%CI -0.58至-0.05;NNTB 3,95%CI 2至20)。根据GRADE,证据质量为中等到低等。证据因设计(偏倚风险)、一致性(异质性)和估计精度而降级。两项研究均获得资助支持,行业为较大规模研究提供了雾化器以及布地奈德和安慰剂的定量吸入器。未发现利益冲突。
我们没有发现证据表明在机械通气依赖的早产儿管理中,早期吸入性类固醇比全身性类固醇具有重要优势。基于本综述,作为机械通气早产儿标准治疗的一部分,不推荐使用吸入性类固醇而非全身性类固醇。由于它们可能比全身性类固醇具有更少的不良反应,因此需要进一步进行吸入性类固醇的随机对照试验,以探讨不同给药技术、给药方案和长期影响的风险/效益比,尤其要关注神经发育结局。