Phillips Patrick P J, Mendel Carl M, Nunn Andrew J, McHugh Timothy D, Crook Angela M, Hunt Robert, Bateson Anna, Gillespie Stephen H
MRC Clinical Trials Unit at UCL, London, UK.
Division of Pulmonary & Critical Care Medicine, University of California, San Francisco, San Francisco, USA.
BMC Med. 2017 Nov 24;15(1):207. doi: 10.1186/s12916-017-0955-9.
Tuberculosis kills more people than any other infectious disease, and new regimens are essential. The primary endpoint for confirmatory phase III trials for new regimens is a composite outcome that includes bacteriological treatment failure and relapse. Culture methodology is critical to the primary trial outcome. Patients in clinical trials can have positive cultures after treatment ends that may not necessarily indicate relapse, which was ascribed previously to laboratory cross-contamination or breakdown of old lesions. Löwenstein-Jensen (LJ) medium was the previous standard in clinical trials, but almost all current and future trials will use the Mycobacteria Growth Indicator Tube (MGIT) system due to its simplicity and consistency of use, which will affect phase III trial results. LJ was used for the definition of the primary endpoint in the REMoxTB trial, but every culture was also inoculated in parallel into the MGIT system. The data from this trial, therefore, provide a unique opportunity to investigate and compare the incidence of false 'isolated positives' in liquid and solid media and their potential impact on the primary efficacy results.
All post-treatment positive cultures were reviewed in the REMoxTB clinical trial. Logistic regression models were used to model the incidence of isolated positive cultures on MGIT and LJ.
A total of 12,209 sputum samples were available from 1652 patients; cultures were more often positive on MGIT than LJ. In 1322 patients with a favourable trial outcome, 126 (9.5%) had cultures that were positive in MGIT compared to 34 (2.6%) patients with positive cultures on LJ. Among patients with a favourable outcome, the incidence of isolated positives on MGIT differed by study laboratory (p < 0.0001) with 21.9% of these coming from one laboratory investigating only 4.9% of patients. No other baseline factors predicted isolated positives on MGIT after adjusting for laboratory. There was evidence of clustering of isolated positive cultures in some patients even after adjusting for laboratory, p < 0.0001. The incidence of isolated positives on MGIT did not differ by treatment arm (p = 0.845, unadjusted). Compared to negative MGIT cultures, positive MGIT cultures were more likely to be associated with higher grade TB symptoms reported within 7 days either side of sputum collection in patients with an unfavourable primary outcome (p < 0.0001) but not in patients with a favourable outcome (p = 0.481).
Laboratory cross-contamination was a likely cause of isolated positive MGIT cultures which were clustered in some laboratories. Certain patients had repeated positive MGIT cultures that did not meet the definition of a relapse. This pattern was too common to be explained by cross-contamination only, suggesting that host factors were also responsible. We conclude that MGIT can replace LJ in phase III TB trials, but there are implications for the definition of the primary outcome and patient management in trials in such settings. Most importantly, the methodologies differ in the incidence of isolated positives and in their capacity for capturing non-tuberculosis mycobacteria. It emphasises the importance of effective medical monitoring after treatment ends and consideration of clinical signs and symptoms for determining treatment failure and relapse.
结核病致死人数超过其他任何一种传染病,因此新的治疗方案至关重要。新治疗方案确证性III期试验的主要终点是一个综合结果,包括细菌学治疗失败和复发。培养方法对主要试验结果至关重要。临床试验中的患者在治疗结束后可能出现培养阳性,但这不一定表明复发,此前这被归因于实验室交叉污染或陈旧病灶破裂。罗-琴(LJ)培养基曾是临床试验的标准,但由于其使用简便且一致性好,几乎所有当前及未来的试验都将使用分枝杆菌生长指示管(MGIT)系统,这将影响III期试验结果。在REMoxTB试验中,LJ被用于定义主要终点,但每种培养物也同时平行接种到MGIT系统中。因此,该试验的数据为调查和比较液体及固体培养基中假“单一阳性”的发生率及其对主要疗效结果的潜在影响提供了独特机会。
对REMoxTB临床试验中所有治疗后培养阳性的样本进行复查。采用逻辑回归模型对MGIT和LJ上单一阳性培养物的发生率进行建模。
共获得1652例患者的12209份痰标本;MGIT上培养阳性的情况比LJ更常见。在1322例试验结果良好的患者中,126例(9.5%)的MGIT培养呈阳性,而LJ培养阳性的患者有34例(2.6%)。在结果良好的患者中,MGIT上单一阳性的发生率因研究实验室而异(p<0.0001),其中21.9%来自仅研究了4.9%患者的一个实验室。调整实验室因素后,没有其他基线因素能预测MGIT上的单一阳性。即使调整了实验室因素,仍有证据表明部分患者中单一阳性培养物存在聚集现象,p<0.0001。MGIT上单一阳性的发生率在各治疗组间无差异(p=0.845,未调整)。与MGIT培养阴性相比,在主要结果不佳的患者中,MGIT培养阳性更可能与痰标本采集前后7天内报告的较高级别结核症状相关(p<0.0001),但在结果良好的患者中并非如此(p=0.481)。
实验室交叉污染可能是MGIT单一阳性培养物的原因,且在一些实验室中存在聚集现象。部分患者多次出现MGIT培养阳性,但不符合复发的定义。这种模式过于常见,无法仅用交叉污染来解释,表明宿主因素也有作用。我们得出结论,在III期结核病试验中MGIT可替代LJ,但这对主要结果的定义和此类试验中的患者管理有影响。最重要的是,两种方法在单一阳性的发生率及其捕获非结核分枝杆菌的能力方面存在差异。这强调了治疗结束后有效医学监测以及考虑临床体征和症状以确定治疗失败和复发的重要性。
