The value of fluorescent PCR probe melting curve technique in detecting anti-tuberculosis drug resistance of Mycobacterium tuberculosis using sputum samples from smear-positive patients

doi:10.3969/j.issn.1000-6621.2019.02.006

Abstract

Abstract:

Objective To evaluate the detection performance of the fluorescent PCR probe melting curve (MeltPro) technique in detecting anti-tuberculosis drug resistance using smear-positive sputum specimens. Methods Sputum specimens from 500 sputum-positive tuberculosis patients in Xi’an Chest Hospital from September 2016 to August 2018 were collected. Sputum smear microscopy, GeneXpert MTB /RIF, BECTEC MGIT 960 liquid culture, phenotypic drug susceptibility test and MeltPro technique were applied to detect the drug resistance to rifampicin, isoniazid, second-line injection drugs and fluoroquinolones. Phenotypic drug susceptibility test was used as the reference standard to assess the detection performance. Results The sensitivity and specificity of MeltPro technique for rifampicin resistance detection were 98.7% (76/77) and 94.2% (343/364), for isoniazid were 82.3% (102/124) and 96.2% (304/316), for amikacin were 8/9 and 99.5% (432/434), for capreomycin were 6/7 and 99.1% (432/436), for levofloxacin were 90.6% (48/53) and 99.2% (386/389), and for moxifloxacin were 88.1% (37/42) and 96.5% (386/400), respectively. The sensitivity and specificity of GeneXpert MTB/RIF for detection of M.tuberculosis rifampicin resistance were 94.8% (73/77) and 94.0% (342/364), respectively. The results of both GeneXpert-MTB/RIF and MeltPro methods were well consistent with the phenotypic susceptibility test (Kappa values were 0.81 and 0.84, respectively), but the MeltPro method was more consistent. Conclusion MeltPro technique shows a good capability in detecting the drug resistance of anti-tuberculosis drugs of MTB including rifampicin, isoniazid, second-line injection drugs and fluoroquinolone using smear-positive sputum specimen.

Key words: Mycobacterium tuberculosis, Microbial sensitivity tests, Molecular probe techniques, Tuberculosis,multidrug-resistant, Sensitivity and specificity, Comparative study

Guo-lian ZHAO,Xiao-li CUI,Lei KANG,Yuan LIU,Li-yun DANG. The value of fluorescent PCR probe melting curve technique in detecting anti-tuberculosis drug resistance of Mycobacterium tuberculosis using sputum samples from smear-positive patients[J]. Chinese Journal of Antituberculosis, 2019, 41(2): 149-155. doi: 10.3969/j.issn.1000-6621.2019.02.006

Figures/Tables 5

References 19

[1]	Mustazzolu A, Iacobino A, Giannoni F , et al. Improved Bactec MGIT 960 pyrazinamide test decreases detection of false Mycobacterium tuberculosis pyrazinamide resistance. J Clin Microbiol, 2017,55(12):3552-3553. doi: 10.1128/JCM.01437-17 URL
[2]	Dheda K . Better treatment of XDR tuberculosis needed in South Africa-Author’s reply. Lancet, 2014,384(9943):582.
[3]	Zhang T, Hu S, Li G , et al. Evaluation of the MeltPro TB/STR assay for rapid detection of streptomycin resistance in Mycobacterium tuberculosis. Tuberculosis (Edinb), 2015,95(2):162-169. doi: 10.1016/j.tube.2014.12.004 URL
[4]	Xie YL, Chakravorty S, Armstrong DT , et al. Evaluation of a Rapid Molecular Drug-Susceptibility Test for Tuberculosis. N Engl J Med, 2017,377(11):1043-1054. doi: 10.1056/NEJMoa1614915 URL
[5]	中国防痨协会基础专业委员会. 结核病诊断实验室检验规程. 北京: 中国教育文化出版社, 2006.
[6]	Pang Y, Dong H, Tan Y , et al. Rapid diagnosis of MDR and XDR tuberculosis with the MeltPro TB assay in China. Sci Rep, 2016,6:25330. doi: 10.1038/srep25330 URL
[7]	Helb D, Jones M, Story E , et al. Rapid detection of Mycobacterium tuberculosis and rifampin resistance by use of on-demand, near-patient technology. J Clin Microbiol, 2010,48(1):229-237. doi: 10.1128/JCM.01463-09 URL
[8]	Ou X, Xia H, Li Q , et al. A feasibility study of the Xpert MTB/RIF test at the peripheral level laboratory in China. Int J Infect Dis, 2015,31:41-46. doi: 10.1016/j.ijid.2014.09.011 URL
[9]	冉兵, 蔡林 . 基因芯片检测耐利福平结核分枝杆菌准确性的Meta分析. 中国防痨杂志, 2015,37(1):56-65. doi: 10.3969/j.issn.1000-6621.2015.01.012
[10]	Chakravorty S, Aladegbami B, Thoms K , et al. Rapid detection of fluoroquinolone-resistant and heteroresistant Mycobacterium tuberculosis by use of sloppy molecular beacons and dual melting-temperature codes in a real-time PCR assay. J Clin Microbiol, 2011,49:932-940. doi: 10.1128/JCM.02271-10 URL
[11]	Singh BK, Sharma SK, Sharma R , et al. Diagnostic utility of a line probe assay for multidrug resistant-TB in smear-negative pulmonary tuberculosis. PLoS One, 2017,12(8):e0182988. doi: 10.1371/journal.pone.0182988 URL
[12]	林明冠, 吴元东, 朱中元 , 等. 基因芯片技术在结核分枝杆菌耐药检测中的效果分析. 中国防痨杂志, 2018,40(1):58-62.
[13]	Pang Y, Xia H, Zhang Z , et al. Multicenter evaluation of genechip for detection of multidrug-resistant Mycobacterium tuberculosis. J Clin Microbiol, 2013,51(6):1707-1713. doi: 10.1128/JCM.03436-12 URL
[14]	张俊仙, 吴雪琼, 阳幼荣 , 等. 应用基因芯片方法检测结核分枝杆菌利福平和异烟肼的耐药性. 中国防痨杂志, 2011,33(10):680-685.
[15]	Tomasicchio M, Theron G, Pietersen E , et al. The diagnostic accuracy of the MTBDRplus and MTBDRsl assays for drug-resistant TB detection when performed on sputum and culture isolates. Sci Rep, 2016,6:17850. doi: 10.1038/srep17850 URL
[16]	Gardee Y, Dreyer AW, Koornhof HJ , et al. Evaluation of the GenoType MTBDRsl version 2.0 assay for second-line drug resistance detection of Mycobacterium tuberculosis isolates in South Africa. J Clin Microbiol, 2017,55(3):791-800. doi: 10.1128/JCM.01865-16 URL
[17]	Georghiou SB, Magana M, Garfein RS , et al. Evaluation of genetic mutations associated with Mycobacterium tuberculosis resistance to amikacin, kanamycin and capreomycin: a systema-tic review. PLoS One, 2012,7(3):e33275. doi: 10.1371/journal.pone.0033275 URL
[18]	张治国, 杜春英, 张倩 , 等. 我国结核分枝杆菌gyrA不同突变类型对氟喹诺酮类药物耐药水平的相关性研究. 中国防痨杂志, 2016,38(9):706-711.
[19]	李国利, 陈澎, 孙昌文 , 等. 结核分枝杆菌对左氧氟沙星与莫西沙星的交叉耐药性及gyrA和gyrB基因突变分析. 中国防痨杂志, 2010,32(10):14-19.

检测方法	表型药敏试验(例)		合计 (例)	敏感度 [%(95%CI)]	特异度 [%(95%CI)]	阳性预测值(%)	阴性预测值(%)	Kappa值
检测方法	耐药	敏感	合计 (例)	敏感度 [%(95%CI)]	特异度 [%(95%CI)]	阳性预测值(%)	阴性预测值(%)	Kappa值
MeltPro检测				98.7 (91.9~99.9)	94.2 (91.2~96.3)	78.4	99.7	0.84
耐药	76	21	97
敏感	1	343	344
GeneXpert MTB/RIF检测				94.8 (91.9~99.9)	94.0 (91.2~96.3)	76.8	98.8	0.81
耐药	73	22	95
敏感	4	342	346

MeltPro检测	表型药敏试验(例)		合计 (例)	敏感度 [%(95%CI)]	特异度 [%(95%CI)]	阳性预测值(%)	阴性预测值(%)	Kappa值
MeltPro检测	耐药	敏感	合计 (例)	敏感度 [%(95%CI)]	特异度 [%(95%CI)]	阳性预测值(%)	阴性预测值(%)	Kappa值
阿米卡星				88.9(50.6~99.4)	99.5(98.1~99.9)	80.0	99.8	0.84
耐药	8	2	10
敏感	1	432	433
卷曲霉素				85.7(42.0~99.2)	99.1(97.5~99.7)	60.0	99.8	0.70
耐药	6	4	10
敏感	1	432	433

MeltPro检测	表型药敏试验(例)		合计 (例)	敏感度 [%(95%CI)]	特异度 [%(95%CI)]	阳性预测值(%)	阴性预测值(%)	Kappa值
MeltPro检测	耐药	敏感	合计 (例)	敏感度 [%(95%CI)]	特异度 [%(95%CI)]	阳性预测值(%)	阴性预测值(%)	Kappa值
左氧氟沙星				90.6(78.5~96.4)	99.2(97.5~99.8)	94.1	98.7	0.91
耐药	48	3	51
敏感	5	386	391
莫西沙星				88.1(73.5~95.5)	96.5(94.1~97.9)	72.5	98.7	0.77
耐药	37	14	51
敏感	5	386	391

痰涂片阳性分级	MeltPro法检测例数	MeltPro法耐药性检测无效例数					检测无效率(%)
痰涂片阳性分级	MeltPro法检测例数	利福平	异烟肼	二线注射类药物	氟喹诺酮类药物	合计	检测无效率(%)
1~8条/300个视野	75	2	2	1	2	7	9.3
抗酸染色阳性(+)	474	3	3	2	2	10	2.1
抗酸染色阳性(++)	447	0	2	1	1	4	0.9
抗酸染色阳性(+++)	373	1	0	0	0	1	0.3
抗酸染色阳性(++++)	419	0	0	0	0	0	0.0
合计	1788	6	7	4	5	22	1.2