Akselband Y, Cabral C, Shapiro D S, McGrath P
One Cell Systems, Inc., Suite 200, 100 Inman Street, Cambridge, MA 02139, United States.
J Microbiol Methods. 2005 Aug;62(2):181-97. doi: 10.1016/j.mimet.2005.02.012. Epub 2005 Mar 29.
Control of multi-drug-resistant tuberculosis has been hampered by the lack of simple, rapid and sensitive methods for assessing bacterial growth and antimicrobial susceptibility. Due to the increasing incidence and high frequency of mutations, it is unlikely that culture methods will disappear in the foreseeable future. Therefore, the need to modernize methods for rapid detection of viable clinical isolates, at a minimum as a gold standard, will persist. Previously, we confirmed the feasibility of using the Gel Microdrop (GMD) Growth Assay for identifying sub-populations of resistant Mycobacteria by testing different laboratory strains. Briefly, this assay format relies on encapsulating single bacterium in agarose microspheres and identifying clonogenic growth using flow cytometry and fluorescent staining. In this study, we modified the GMD Growth Assay to make it suitable for clinical applications. We demonstrated the effectiveness and safety of this novel approach for detecting drug susceptibility in clinically relevant laboratory strains as well as clinical isolates of Mycobacterium tuberculosis. Correlation between results using the GMD Growth Assay format and results using two well characterized methods (Broth Microdilution MIC and BACTEC 460TB) was 87.5% and 90%, respectively. However, due to the inherent sensitivity of flow cytometry and the ability to detect small (<1%) sub-populations of resistant mycobacteria, the GMD Growth Assay identified more cases of drug resistance. Using 4 clinically relevant mycobacterial strains, we assessed susceptibility to primary anti-tuberculosis drugs using both the Broth Microdilution MIC method and the GMD Growth Assay. We performed 24 tests on isoniazid-resistant BCG, Mycobacterium tuberculosis H37Ra and Mycobacterium avium strains. The Broth Microdilution MIC method identified 7 cases (29.1%) of resistance to INH and EMB compared to the GMD Growth Assay which identified resistance in 10 cases (41.6%); in 3 cases (12.5%), resistance to INH and EMB was detected only with the GMD Growth Assay. In addition, using 20 Mycobacterium tuberculosis clinical isolates, we compared results using BACTEC 460TB method performed by collaborators and the GMD Growth Assay. Eight of 20 (40%) clinical isolates, which were not identified as drug-resistant using the conventional BACTEC 460TB method, were resistant to 1, 2, or 3 different concentrations of drugs using the GMD Growth Assay (13 cases of 140 experiments). In one case (isolate 1879), resistance to 10.0 microg/ml of STR detected using BACTEC 460TB method was not confirmed by the GMD Growth Assay. Thus, the overall agreement between these methods was 90% (14 discrepant results of 140 experiments). These data demonstrate that the GMD Growth Assay is an accurate and sensitive method for rapid susceptibility testing of Mycobacterium tuberculosis for use in clinical reference laboratory settings.
缺乏简单、快速且灵敏的方法来评估细菌生长及抗菌药敏性,这一直阻碍着耐多药结核病的控制。由于发病率不断上升以及突变频率较高,在可预见的未来,培养方法不太可能消失。因此,至少作为金标准,对快速检测临床活菌株的方法进行现代化改进的需求将持续存在。此前,我们通过测试不同的实验室菌株,证实了使用凝胶微滴(GMD)生长测定法鉴定耐药分枝杆菌亚群的可行性。简而言之,这种测定形式依赖于将单个细菌封装在琼脂糖微球中,并使用流式细胞术和荧光染色来鉴定克隆生长。在本研究中,我们对GMD生长测定法进行了改进,使其适用于临床应用。我们证明了这种新方法在检测临床相关实验室菌株以及结核分枝杆菌临床分离株药敏性方面的有效性和安全性。使用GMD生长测定形式得到的结果与使用两种特征明确的方法(肉汤微量稀释法MIC和BACTEC 460TB)得到的结果之间的相关性分别为87.5%和90%。然而,由于流式细胞术固有的灵敏度以及检测耐药分枝杆菌小(<1%)亚群的能力,GMD生长测定法鉴定出了更多的耐药病例。我们使用4种临床相关的分枝杆菌菌株,通过肉汤微量稀释法MIC和GMD生长测定法评估了对一线抗结核药物的药敏性。我们对耐异烟肼卡介苗、结核分枝杆菌H37Ra和鸟分枝杆菌菌株进行了24次测试。肉汤微量稀释法MIC鉴定出7例(29.1%)对异烟肼和乙胺丁醇耐药,而GMD生长测定法鉴定出10例(41.6%)耐药;在3例(12.5%)中,仅GMD生长测定法检测到对异烟肼和乙胺丁醇耐药。此外,我们使用20株结核分枝杆菌临床分离株,比较了合作者采用BACTEC 460TB方法得到的结果与GMD生长测定法得到的结果。在20株(40%)临床分离株中,使用传统BACTEC 460TB方法未鉴定为耐药,但使用GMD生长测定法对1、2或3种不同浓度药物耐药(140次实验中的13例)。在1例(分离株1879)中,GMD生长测定法未证实BACTEC 460TB方法检测到的对10.0μg/ml链霉素的耐药性。因此,这些方法之间的总体一致性为90%(140次实验中有14个不一致结果)。这些数据表明,GMD生长测定法是一种准确且灵敏的方法,可用于临床参考实验室环境中结核分枝杆菌的快速药敏测试。
