妊娠期生殖道沙眼衣原体感染的治疗干预措施。
Interventions for treating genital Chlamydia trachomatis infection in pregnancy.
作者信息
Cluver Catherine, Novikova Natalia, Eriksson David Oa, Bengtsson Kevin, Lingman Göran K
机构信息
Department of Obstetrics and Gynaecology, Faculty of Health Sciences, Stellenbosch University and Tygerberg Hospital, PO Box 19063, Tygerberg, Western Cape, South Africa, 7505.
出版信息
Cochrane Database Syst Rev. 2017 Sep 22;9(9):CD010485. doi: 10.1002/14651858.CD010485.pub2.
BACKGROUND
Genital Chlamydia trachomatis (C.trachomatis) infection may lead to pregnancy complications such as miscarriage, preterm labour, low birthweight, preterm rupture of membranes, increased perinatal mortality, postpartum endometritis, chlamydial conjunctivitis and C.trachomatis pneumonia.This review supersedes a previous review on this topic.
OBJECTIVES
To establish the most efficacious and best-tolerated therapy for treatment of genital chlamydial infection in preventing maternal infection and adverse neonatal outcomes.
SEARCH METHODS
We searched the Cochrane Pregnancy and Childbirth Group's Trials Register, ClinicalTrials.gov, the WHO International Clinical Trials Registry Platform (ICTRP) (26 June 2017) and reference lists of retrieved studies.
SELECTION CRITERIA
Randomised controlled trials (RCTs) as well as studies published in abstract form assessing interventions for treating genital C.trachomatis infection in pregnancy. Cluster-RCTs were also eligible for inclusion but none were identified. Quasi-randomised trials and trials using cross-over design are not eligible for inclusion in this review.
DATA COLLECTION AND ANALYSIS
Two review authors independently assessed studies for inclusion, assessed trial quality and extracted the data using the agreed form. Data were checked for accuracy. Evidence was assessed using the GRADE approach.
MAIN RESULTS
We included 15 trials (involving 1754 women) although our meta-analyses were based on fewer numbers of studies/women. All of the included studies were undertaken in North America from 1982 to 2001. Two studies were low risk of bias in all domains, all other studies had varying risk of bias. Four other studies were excluded and one study is ongoing.Eight comparisons were included in this review; three compared antibiotic (erythromycin, clindamycin, amoxicillin) versus placebo; five compared an antibiotic versus another antibiotic (erythromycin, clindamycin, amoxicillin, azithromycin). No study reported different antibiotic regimens. Microbiological cure (primary outcome) Antibiotics versus placebo: Erythromycin (average risk ratio (RR) 2.64, 95% confidence interval (CI) 1.60 to 4.38; two trials, 495 women; I = 68%; moderate-certainty evidence), and clindamycin (RR 4.08, 95% CI 2.35 to 7.08; one trial, 85 women;low-certainty evidence) were associated with improved microbiological cure compared to a placebo control. In one very small trial comparing amoxicillin and placebo, the results were unclear, but the evidence was graded very low (RR 2.00, 95% CI 0.59 to 6.79; 15 women). One antibiotic versus another antibiotic: Amoxicillin made little or no difference in microbiological cure in comparison to erythromycin (RR 0.97, 95% CI 0.93 to 1.01; four trials, 466 women; high-certainty evidence), probably no difference compared to clindamycin (RR 0.96, 95% CI 0.89 to 1.04; one trial, 101 women; moderate-quality evidence), and evidence is very low certainty when compared to azithromycin so the effect is not certain (RR 0.89, 95% CI 0.71 to 1.12; two trials, 144 women; very low-certainty evidence). Azithromycin versus erythromycin (average RR 1.11, 95% CI 1.00 to 1.23; six trials, 374 women; I = 53%; moderate-certainty evidence) probably have similar efficacy though results appear to favour azithromycin. Clindamycin versus erythromycin (RR 1.06, 95% CI 0.97 to 1.15; two trials, 173 women; low-certainty evidence) may have similar numbers of women with a microbiological cure between groups.Evidence was downgraded for design limitations, inconsistency, and imprecision in effect estimates. Side effects of the treatment (maternal) (secondary outcome) Antibiotics versus placebo: side effects including nausea, vomiting, and abdominal pain, were reported in two studies (495 women) but there was no clear evidence whether erythromycin was associated with more side effects than placebo and a high level of heterogeneity (I = 78%) was observed (average RR 2.93, 95% CI 0.36 to 23.76). There was no clear difference in the number of women experiencing side effects when clindamycin was compared to placebo in one small study (5/41 versus 1/44) (RR 6.35, 95% CI 0.38 to 107.45, 62 women). The side effects reported were mostly gastrointestinal and also included resolving skin rashes. One antibiotic versus another antibiotic: There was no clear difference in incidence of side effects (including nausea, vomiting, diarrhoea and abdominal pain) when amoxicillin was compared to azithromycin based on data from one small study (36 women) (RR 0.56, 95% CI 0.24 to 1.31).However, amoxicillin was associated with fewer side effects compared to erythromycin with data from four trials (513 women) (RR 0.31, 95% CI 0.21 to 0.46; I = 27%). Side effects included nausea, vomiting, diarrhoea, abdominal cramping, rash, and allergic reaction.Both azithromycin (RR 0.24, 95% CI 0.17 to 0.34; six trials, 374 women) and clindamycin (RR 0.44, 95% CI 0.22 to 0.87; two trials, 183 women) were associated with a lower incidence of side effects compared to erythromycin. These side effects included nausea, vomiting, diarrhoea and abdominal cramping.One small study (101 women) reported there was no clear difference in the number of women with side effects when amoxicillin was compared with clindamycin (RR 0.57, 95% CI 0.14 to 2.26; 107 women). The side effects reported included rash and gastrointestinal complaints. Other secondary outcomes Single trials reported data on repeated infections, preterm birth, preterm rupture of membranes, perinatal mortality and low birthweight and found no clear differences between treatments.Many of this review's secondary outcomes were not reported in the included studies.
AUTHORS' CONCLUSIONS: Treatment with antibacterial agents achieves microbiological cure from C.trachomatis infection during pregnancy. There was no apparent difference between assessed agents (amoxicillin, erythromycin, clindamycin, azithromycin) in terms of efficacy (microbiological cure and repeat infection) and pregnancy complications (preterm birth, preterm rupture of membranes, low birthweight). Azithromycin and clindamycin appear to result in fewer side effects than erythromycin.All of the studies in this review were conducted in North America, which may limit the generalisability of the results. In addition, study populations may differ in low-resource settings and these results are therefore only applicable to well-resourced settings. Furthermore, the trials in this review mainly took place in the nineties and early 2000's and antibiotic resistance may have changed since then.Further well-designed studies, with appropriate sample sizes and set in a variety of settings, are required to further evaluate interventions for treating C.trachomatis infection in pregnancy and determine which agents achieve the best microbiological cure with the least side effects. Such studies could report on the outcomes listed in this review.
背景
生殖道沙眼衣原体(C. trachomatis)感染可能导致妊娠并发症,如流产、早产、低出生体重、胎膜早破、围产期死亡率增加、产后子宫内膜炎、衣原体结膜炎和沙眼衣原体肺炎。本综述取代了之前关于该主题的综述。
目的
确定治疗生殖道衣原体感染以预防母体感染和不良新生儿结局的最有效且耐受性最佳的疗法。
检索方法
我们检索了Cochrane妊娠与分娩组试验注册库、ClinicalTrials.gov、世界卫生组织国际临床试验注册平台(ICTRP)(2017年6月26日)以及检索到的研究的参考文献列表。
入选标准
随机对照试验(RCTs)以及以摘要形式发表的评估孕期生殖道沙眼衣原体感染治疗干预措施的研究。整群RCTs也符合纳入标准,但未检索到。准随机试验和采用交叉设计的试验不符合本综述的纳入标准。
数据收集与分析
两位综述作者独立评估纳入研究,评估试验质量,并使用商定的表格提取数据。检查数据的准确性。采用GRADE方法评估证据。
主要结果
我们纳入了15项试验(涉及1754名女性),尽管我们的荟萃分析基于较少数量的研究/女性。所有纳入研究均于1982年至2001年在北美进行。两项研究在所有领域的偏倚风险较低,所有其他研究的偏倚风险各不相同。另外四项研究被排除,一项研究正在进行中。本综述纳入了八项比较;三项比较了抗生素(红霉素、克林霉素、阿莫西林)与安慰剂;五项比较了一种抗生素与另一种抗生素(红霉素、克林霉素、阿莫西林、阿奇霉素)。没有研究报告不同的抗生素治疗方案。微生物学治愈(主要结局)抗生素与安慰剂:与安慰剂对照相比,红霉素(平均风险比(RR)2.64,95%置信区间(CI)1.60至4.38;两项试验,495名女性;I² = 68%;中等确定性证据)和克林霉素(RR 4.08,95% CI 2.35至7.08;一项试验,85名女性;低确定性证据)与微生物学治愈改善相关。在一项比较阿莫西林和安慰剂的非常小的试验中,结果不明确,但证据等级非常低(RR 2.00,95% CI 0.59至6.79;15名女性)。一种抗生素与另一种抗生素:与红霉素相比,阿莫西林在微生物学治愈方面几乎没有差异(RR 0.97,95% CI 0.93至1.01;四项试验,466名女性;高确定性证据),与克林霉素相比可能没有差异(RR 0.96,95% CI 0.89至1.04;一项试验,101名女性;中等质量证据),与阿奇霉素相比证据确定性非常低,因此效果不确定(RR 0.89,95% CI 0.71至1.12;两项试验,144名女性;非常低确定性证据)。阿奇霉素与红霉素(平均RR 1.11,95% CI 1.00至1.23;六项试验,374名女性;I² = 53%;中等确定性证据)可能具有相似的疗效,尽管结果似乎有利于阿奇霉素。克林霉素与红霉素(RR 1.06,95% CI 0.97至1.15;两项试验,173名女性;低确定性证据)在两组中微生物学治愈的女性数量可能相似。由于设计局限性、不一致性和效应估计的不精确性,证据等级被下调。治疗的副作用(母体)(次要结局)抗生素与安慰剂:两项研究(495名女性)报告了包括恶心、呕吐和腹痛在内的副作用,但没有明确证据表明红霉素比安慰剂有更多副作用,并且观察到高度异质性(I² = 78%)(平均RR 2.93,95% CI 0.36至23.76)。在一项小型研究(5/41对1/44)(RR 6.35,95% CI 0.38至107.45,62名女性)中,将克林霉素与安慰剂比较时,出现副作用的女性数量没有明显差异。报告 的副作用主要是胃肠道方面的,还包括消退的皮疹。一种抗生素与另一种抗生素:根据一项小型研究(36名女性)的数据,将阿莫西林与阿奇霉素比较时,副作用发生率没有明显差异(RR 0.56,95% CI 0.24至1.31)。然而,根据四项试验(513名女性)的数据,阿莫西林与红霉素相比副作用较少(RR 0.31,95% CI 0.21至0.46;I² = 27%)。副作用包括恶心、呕吐、腹泻、腹部绞痛、皮疹和过敏反应。与红霉素相比,阿奇霉素(RR 0.24,95% CI 0.17至0.34;六项试验,374名女性)和克林霉素(RR 0.44,95% CI 0.22至0.87;两项试验,183名女性)的副作用发生率较低。这些副作用包括恶心、呕吐、腹泻和腹部绞痛。一项小型研究(101名女性)报告,将阿莫西林与克林霉素比较时,出现副作用的女性数量没有明显差异(RR 0.57,95% CI 0.14至2.26;107名女性)。报告的副作用包括皮疹和胃肠道不适。其他次要结局单项试验报告了关于重复感染、早产、胎膜早破、围产期死亡率和低出生体重的数据,发现治疗之间没有明显差异。本综述的许多次要结局在纳入研究中未报告。
作者结论
孕期使用抗菌药物可实现沙眼衣原体感染的微生物学治愈。在疗效(微生物学治愈和重复感染)和妊娠并发症(早产、胎膜早破、低出生体重)方面,评估的药物(阿莫西林、红霉素、克林霉素、阿奇霉素)之间没有明显差异。阿奇霉素和克林霉素似乎比红霉素副作用更少。本综述中的所有研究均在北美进行,这可能会限制结果的普遍性。此外,在资源匮乏地区,研究人群可能不同,因此这些结果仅适用于资源丰富的地区。此外,本综述中的试验主要发生在20世纪90年代和21世纪初,从那时起抗生素耐药性可能已经发生了变化。需要进一步设计良好、样本量合适且在各种环境中进行的研究,以进一步评估孕期治疗沙眼衣原体感染的干预措施,并确定哪种药物能以最少的副作用实现最佳的微生物学治愈。此类研究可以报告本综述中列出的结局。
Zotero 插件