肥大细胞稳定剂预防运动诱发的支气管收缩。
Mast-cell stabilising agents to prevent exercise-induced bronchoconstriction.
作者信息
Spooner C H, Spooner G R, Rowe B H
机构信息
Division of Emergency Medicine, University of Alberta, 1G1.50 Walter Mackenzie Health Centre, 8440 - 112 ST, Edmonton, Alberta, Canada, T6G 2B7.
出版信息
Cochrane Database Syst Rev. 2003;2003(4):CD002307. doi: 10.1002/14651858.CD002307.
BACKGROUND
Exercise-induced bronchoconstriction (or asthma) following strenuous physical exertion is common and can cause sub-optimal performance, symptoms such as cough, dyspnea, wheeze, chest tightness, and can lead people to avoid physical activity. Management focuses on prevention with pre-exercise treatment using various pharmacologic agents. Mast cell stabilizing agents are effective in attenuating exercise-induced bronchoconstriction but their effectiveness compared to bronchodilator agents is unclear.
OBJECTIVES
To quantitatively compare the effects of inhaling a single dose of either mast cell stabiliser - nedocromil sodium or sodium cromoglycate - to a single dose of short acting beta-agonists or anti-cholinergic agents - atropine or ipratropium bromide - prior to a strenuous exercise challenge in participants with asthma who are at least 6 years of age and suffer from reproducible exercise-induced bronchoconstriction. The review also compares the effects between a short acting beta-agonist alone to a combination of a short acting beta-agonist + mast cell stabiliser.
SEARCH STRATEGY
We searched the Cochrane Airways Group ASTHMA and WHEEZ* trials register, Cochrane CENTRAL, Current Contents, review articles, textbooks and reference lists of articles. We also contacted the drug manufacturer and primary authors for additional citations.
SELECTION CRITERIA
Randomised trials comparing a single prophylactic dose of a mast cell stabiliser to a short acting beta-agonist, anti-cholinergic agent, or a short acting beta-agonist alone to a combination of short acting beta-agonist plus a mast cell stabiliser to prevent exercise-induced bronchoconstriction in asthmatics over six years old. The exercise challenge had to conform to acceptable standards and pulmonary function (PFT) reported as percent decrease from baseline of FEV1 or peak flow. Complete protection (maximum % fall PFT <15% post-exercise) and clinical protection (50% improvement over placebo effect) measures were included.
DATA COLLECTION AND ANALYSIS
Trial inclusion and quality assessments were conducted independently by two reviewers using standardised forms. A second reviewer confirmed data extraction and calculations. Attempts were made to contact study authors. The pooled estimate involving continuous pulmonary function measures are reported as a weighted mean difference (WMD), dichotomous data as an odds ratio (OR), both with 95% confidence intervals (95%CI) using a random effects model. Heterogeneity tests for pooled results were performed.
MAIN RESULTS
Twenty-four trials (518 participants) conducted in 13 countries between 1976 and 1998 were included. All drugs were effective at attenuating the exercise-induced bronchoconstriction response but to varying degrees even within the same individual. Compared to anti-cholinergic agents, mast cell stabilisers were somewhat more effective at attenuating bronchoconstriction. On average the maximum fall on MCS was reduced to 7.1% compared to 13.8% on AC ( WMD = 6.7%; 95% CI: 3.3 to 10.0), provided more individuals with complete protection (73% vs 56%; OR = 2.2; 95% CI: 1.3 to 3.7) and clinical protection (73% vs 52%; OR = 2.7; 95% CI: 1.1 to 6.4). There were no subgroup differences based on age, severity, or study quality, and no adverse effects were reported for either agent group. When compared to short acting beta-agonists mast cell stabilisers were not as effective at preventing deterioration. On average the maximum fall on MCS was 11.2% compared to 4.3% on beta agonists ( WMD = 6.8%; 95% CI: 4.5 to 9.2). MCS provided fewer individuals with complete protection (66% vs 85%; OR = 0.3; 95% CI: 0.2 to 0.5) or clinical protection (55% vs 77%; OR = 0.4; 95% CI: 0.2 to 0.8). There were no significant subgroup differences based on age, severity, drug, delivery, or study quality. A non-significant difference in side effects was demonstrated with 11% of short acting beta-agonist patients experiencing side effects compared to 3% of those receiving mast cell stabilisers (OR = 0.2; 95% CI: 0.0 to 8.2). Combining masta-agonist patients experiencing side effects compared to 3% of those receiving mast cell stabilisers (OR = 0.2; 95% CI: 0.0 to 8.2). Combining mast cell stabilisers with a short acting beta-agonist did not produce significant advantages to pulmonary function over short acting beta-agonists alone. On average the maximum fall on SABA only was reduced to 5.3% compared to 3.5% on the combination ( WMD = 1.8%; 95% CI: -1.1 to 4.6). Beta-agonists alone provided fewer individuals with complete protection (68% vs 80%; OR = 0.5; 95% CI: 0.2 to 1.4) or clinical protection (70% vs 86%; OR=0.4; 95% CI: 0.1 to 1.2) but the difference did not reach significance (p=0.17). There were no subgroup differences.
REVIEWER'S CONCLUSIONS: In a population of stable asthmatics short acting beta-agonists, mast cell stabilisers, or anticholinergics will provide a significant protective effect against exercise-induced bronchoconstriction with few adverse effects. On average, SABAs resulted in more effective attenuation than mast cell stabilisers, while mast cell stabilisers were more effective than anti-cholinergic agents. Combining SABA and mast cell stabilisers may be appropriate in selected cases. The variability in the individual degree of response to these drugs in multi arm trials suggests clinicians and patients work together to identify the most effective prophylactic therapy.
背景
剧烈运动后运动诱发的支气管收缩(或哮喘)很常见,会导致表现欠佳,并引发咳嗽、呼吸困难、喘息、胸闷等症状,还会使人们回避体育活动。管理重点在于通过使用各种药物进行运动前治疗来预防。肥大细胞稳定剂可有效减轻运动诱发的支气管收缩,但其与支气管扩张剂相比的有效性尚不清楚。
目的
在至少6岁且患有可重复性运动诱发支气管收缩的哮喘参与者中,定量比较吸入单剂量肥大细胞稳定剂(奈多罗米钠或色甘酸钠)与单剂量短效β-激动剂或抗胆碱能药物(阿托品或异丙托溴铵)在剧烈运动激发前的效果。本综述还比较了单独使用短效β-激动剂与短效β-激动剂+肥大细胞稳定剂联合使用的效果。
检索策略
我们检索了Cochrane气道组哮喘与喘息试验注册库、Cochrane中心对照试验注册库、《现刊目次》、综述文章、教科书以及文章的参考文献列表。我们还联系了药品制造商和主要作者以获取更多引用文献。
选择标准
随机试验,比较单剂量预防性使用肥大细胞稳定剂与短效β-激动剂、抗胆碱能药物,或单独使用短效β-激动剂与短效β-激动剂加肥大细胞稳定剂联合使用,以预防6岁以上哮喘患者运动诱发的支气管收缩。运动激发必须符合可接受的标准,肺功能(PFT)报告为FEV1或峰值流速较基线下降的百分比。纳入了完全保护(运动后最大PFT下降百分比<15%)和临床保护(比安慰剂效应改善50%)的测量指标。
数据收集与分析
两名评价者使用标准化表格独立进行试验纳入和质量评估。另一名评价者确认数据提取和计算。尝试联系研究作者。涉及连续肺功能测量指标的合并估计值报告为加权平均差(WMD),二分数据报告为比值比(OR),均采用随机效应模型并给出95%置信区间(95%CI)。对合并结果进行异质性检验。
主要结果
纳入了1976年至1998年在全球13个国家开展的24项试验(518名参与者)。所有药物均能有效减轻运动诱发的支气管收缩反应,但即使在同一个体内,程度也有所不同。与抗胆碱能药物相比,肥大细胞稳定剂在减轻支气管收缩方面更有效。平均而言,肥大细胞稳定剂组的最大下降率降至7.1%,而抗胆碱能药物组为13.8%(WMD = 6.7%;95%CI:3.3至10.0),为更多个体提供了完全保护(73%对56%;OR = 2.2;95%CI:1.3至3.7)和临床保护(73%对52%;OR = 2.7;95%CI:1.1至6.4)。基于年龄、严重程度或研究质量未发现亚组差异,且两组均未报告不良反应。与短效β-激动剂相比,肥大细胞稳定剂在预防病情恶化方面效果较差。平均而言,肥大细胞稳定剂组的最大下降率为11.2%,而β-激动剂组为4.3%(WMD = 6.8%;95%CI:4.5至9.2)。肥大细胞稳定剂组获得完全保护(66%对85%;OR = 0.3;95%CI:0.2至0.5)或临床保护(55%对77%;OR = 0.4;95%CI:0.2至0.8)的个体较少。基于年龄、严重程度、药物、给药方式或研究质量未发现显著亚组差异。在副作用方面显示出无显著差异,11%的短效β-激动剂患者出现副作用,而接受肥大细胞稳定剂的患者为3%(OR = 0.2;95%CI:0.0至8.2)。将肥大细胞稳定剂与短效β-激动剂联合使用相比单独使用短效β-激动剂在肺功能方面未产生显著优势。平均而言,仅使用短效β-激动剂时最大下降率降至5.3%,联合使用时为3.5%(WMD = 1.8%;95%CI:-1.1至4.6)。单独使用β-激动剂获得完全保护(68%对80%;OR = 0.5;95%CI:0.2至1.4)或临床保护(70%对86%;OR = 0.4;95%CI:0.1至1.2)的个体较少,但差异未达到显著水平(p = 0.17)。未发现亚组差异。
评价者结论
在稳定哮喘患者群体中,短效β-激动剂、肥大细胞稳定剂或抗胆碱能药物对运动诱发的支气管收缩均有显著保护作用,且副作用较少。平均而言,短效β-激动剂在减轻症状方面比肥大细胞稳定剂更有效,而肥大细胞稳定剂比抗胆碱能药物更有效。在某些特定情况下,联合使用短效β-激动剂和肥大细胞稳定剂可能是合适的。在多组试验中,个体对这些药物的反应程度存在差异,这表明临床医生和患者应共同努力确定最有效的预防性治疗方法。
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