Distribution and drug resistance characteristics of pathogens in patients with pulmonary tuberculosis and non-pulmonary tuberculosis complicated with lower respiratory tract infections

doi:10.19982/j.issn.1000-6621.20250128

Abstract

Abstract:

Objective: To explore the distribution characteristics and drug resistance differences of pathogenic bacteria in patients with pulmonary tuberculosis and non-pulmonary tuberculosis combined with lower respiratory tract infections, and to provide a basis for clinical precise medication. Methods: A cross-sectional survey design was adopted. A total of 11854 patients with pulmonary infections who were admitted to the Public Health Clinical Center of Shandong Province from January 2021 to December 2024 were selected as the research subjects. Through medical record inquiries, those with incomplete medical records were excluded, and the patients were divided into the pulmonary tuberculosis complicated with lower respiratory tract infection (PTB-LRTI) group (2047 cases), the non-tuberculous mycobacterial lung disease complicated with lower respiratory tract infection (PNTM-LRTI) group (385 cases), and the bacterial pneumonia (BP) group (1869 cases) based on clinical diagnosis. Respiratory tract specimens such as sputum, bronchoalveolar lavage fluid, and brushes of the research subjects were collected for bacterial culture. The positive bacterial strains were subjected to drug sensitivity tests, and duplicate isolates from the same patient were excluded. The pathogen spectra and drug resistance characteristics of the respiratory tract specimens of the three groups of research subjects were compared and analyzed. Results: Gram-negative bacteria were the main pathogens in the three groups. Klebsiella pneumoniae (32.30%,773/2397), Pseudomonas aeruginosa (14.95%,358/2397), Enterobacter cloacae (9.02%,216/2397), Escherichia coli (8.40%,201/2397), and Acinetobacter baumannii (4.22%,101/2397) were the top five pathogens detected in the PTB-LRTI group, which were the same as those in the PNTM-LRTI group. Pseudomonas aeruginosa (27.38%,555/2027), Klebsiella pneumonia (21.41%,434/2027), Stenotrophomonas maltophilia (7.05%, 143/2027), Acinetobacter baumannii (6.66%,135/2027) and Staphylococcus aureus (5.28%,107/2027) were the top five pathogens detected in the BP group. The resistance rate of Klebsiella pneumoniae to piperacillin/tazobactam (4.40%, 24/773) and imipenem (0.78%, 6/773) was low in the PTB-LRTI group; the resistance rates of Pseudomonas aeruginosa to piperacillin/tazobactam (5.31%, 19/358), ceftazidime (5.59%, 20/358), and imipenem (13.41%, 48/358) were significantly different from those of the PTB-LRTI group and BP group (χ²=15.139, P=0.001; χ²=15.524, P<0.001; χ²=9.148, P=0.010); the resistance rate of Acinetobacter baumannii to the tested antibiotics is less than 30%; the resistance rate of Staphylococcus aureus to rifampicin (13.89%, 5/36) was significantly higher than that of the BP group (2.80%, 3/107), and the difference was statistically significant (χ²=8.308, P=0.016). There were differences in the distribution of carbapenem-resistant enterobacteriaceae (CRE) bacteria among the three groups. In the PTB-LRTI group, the detection rate of CRE was the highest for Enterobacter cloacae (35.42%, 17/48), followed by Klebsiella pneumoniae (14.58%, 7/48) and Escherichia coli (14.58%, 7/48). Conclusion: There are significant differences in the distribution of pathogenic bacteria and drug resistance characteristics between PTB-LRTI, PNTM-LRTI and BP. Clinically, it was necessary to use antibacterial drugs rationally based on the results of drug sensitivity tests, and at the same time, strengthen infection control measures to reduce the risk of infection with drug-resistant bacteria.

Key words: Tuberculosis, pulmonary, Pneumonia, bacterial, Respiratory tract infections, Drug resistance, bacterial

CLC Number:

R521
R563.1

Wang Liping, Zhang Pei, Qin Xiaohua, Zhou Xin, Jiang Caihua, Li Xuezheng. Distribution and drug resistance characteristics of pathogens in patients with pulmonary tuberculosis and non-pulmonary tuberculosis complicated with lower respiratory tract infections[J]. Chinese Journal of Antituberculosis, 2025, 47(10): 1333-1341. doi: 10.19982/j.issn.1000-6621.20250128

Figures/Tables 5

药品	鲍曼不动杆菌					铜绿假单胞菌
药品	BP组 (135株)	PTB-LRTI 组(101株)	PNTM-LRTI 组(18株)	χ²值	P值	BP组 (555株)	PTB-LRTI 组(358株)	PNTM-LRTI 组(89株)	χ²值	P值
哌拉西林	74(54.81)^a	25(24.75)	6(33.33)	22.044	<0.001	92(16.58)^a	35(9.78)	5(5.62)	13.673	0.001
哌拉西林/他唑巴坦	73(54.07)^a	22(21.78)	6(33.33)	25.487	<0.001	63(11.35)^a	19(5.31)	2(2.25)	15.139	0.001
氨苄西林/舒巴坦	70(51.85)^a	25(24.75)	7(38.89)	17.669	<0.001	-	-	-	-	-
头孢哌酮/舒巴坦	64(47.41)^a	17(16.83)	5(27.78)	24.439	<0.001	62(11.17)^a	20(5.59)	2(2.25)	13.625	0.001
头孢曲松	75(55.56)^a	27(26.73)	8(44.44)	19.559	<0.001	-	-	-	-	-
头孢噻肟	75(55.56)^a	27(26.73)	9(50.00)	19.821	<0.001	-	-	-	-	-
头孢他啶	72(53.33)^a	21(20.79)	7(38.89)	25.632	<0.001	62(11.17)^a	20(5.59)	1(1.12)	15.524	<0.001
氨曲南	-	-	-	-	-	126(22.70)	67(18.72)	13(14.61)	4.238	0.120
头孢吡肟	68(50.37)^a	21(20.79)	7(38.89)	21.509	<0.001	46(8.29)	20(5.59)	5(5.62)	2.732	0.255
庆大霉素	69(51.11)^a	22(21.78)	7(38.89)	20.973	<0.001	64(11.53)	37(10.34)	8(8.99)	0.681	0.711
妥布霉素	67(49.63)^a	18(17.82)	7(38.89)	25.363	<0.001	21(3.78)	17(4.75)	5(5.62)	0.912	0.634
阿米卡星	39(28.89)	17(16.83)	7(38.89)	6.554	0.038	30(5.41)	15(4.19)	7(7.87)	2.075	0.354
左氧氟沙星	74(54.81)^a	26(25.74)	8(44.44)	20.009	<0.001	174(31.35)	92(25.70)	31(34.83)	4.597	0.100
环丙沙星	76(56.30)^a	26(25.74)	8(44.44)	21.978	<0.001	134(24.14)	72(20.11)	20(22.47)	2.026	0.363
复方新诺明	52(38.52)^a	19(18.81)	7(38.89)	11.154	0.004	-	-	-	-	-
亚胺培南	72(53.33)^a	21(20.79)	7(38.89)	25.632	<0.001	115(20.72)^a	48(13.41)	12(13.48)	9.148	0.010
美洛培南	72(53.33)^a	21(20.79)	7(38.89)	25.632	<0.001	69(12.43)^a	25(6.98)	4(4.49)	10.416	0.005
四环素	59(43.70)^a	18(17.82)	7(38.89)	17.782	<0.001	-	-	-	-	-
米诺环素	1(0.74)	2(1.98)	0(0.00)	0.992	0.609	-	-	-	-	-
替加环素	0(0.00)	0(0.00)	0(0.00)	NA	NA	-	-	-	-	-
多黏菌素B	0(0.00)	2(9.52)^b	0(0.00)	14.741	<0.001	4(3.48)^c	2(4.17)^d	0(0.00)	0.506	0.777

References 28

[1]	World Health Organization. Global tuberculosis report 2024. Geneva: World Health Organization, 2024.
[2]	Li M, Liu M, Liu J. Trends in the Mortality, Deaths, and Aetiologies of Lower Respiratory Infections Among 204 Countries from 1991 to 2021: An Updated Systematic Study. Viruses, 2025, 17(7):892. doi:10.3390/v17070892.
[3]	中华人民共和国国家卫生和计划生育委员会. WS 288—2017 肺结核诊断. 结核与肺部疾病杂志, 2024, 5(4): 376-378. doi:10.19983/j.issn.2096-8493.2024022.
[4]	王辰, 王建安. 内科学. 3版. 北京: 人民卫生出版社, 2015.
[5]	杨松, 郭建琼, 严晓峰, 等. 欧美2020年版《非结核分枝杆菌肺病临床实践指南》解读. 中华结核和呼吸杂志, 2021, 44(8):699-704. doi:10.3760/cma.j.cn112147-20210222-00115.
[6]	尚红, 王毓三, 申子瑜. 全国临床检验操作规程. 5版. 北京: 人民卫生出版社, 2021.
[7]	中华人民共和国国家卫生和计划生育委员会. WS/T 499—2017 下呼吸道感染细菌培养操作指南. 2017-07-01.
[8]	Clinical and Laboratory Standards Institute. Performance standards for antimicrobial susceptibility testing, 33rd informational supplement(M100-S33). Wayne, PA: Clinical and Laboratory Standards Institute, 2023.
[9]	崔坤平, 毛毅, 杨娇, 等. 活动性肺结核合并重症肺炎患者死亡相关危险因素分析及风险预测模型构建. 国际流行病学传染病学杂志, 2023, 50(6):397-403. doi:10.3760/cma.j.cn331340-20230509-00074.
[10]	刘聪颖. 153例肺结核合并下呼吸道感染患者痰标本中病原菌的分布与药敏性分析. 抗感染药学, 2022, 19(4):543-545. doi:10.13493/j.issn.1672-7878.2022.04-022.
[11]	张云玲, 李孳, 王东萍, 等. 肺结核合并多重耐药菌下呼吸道感染的病原学及危险因素分析. 临床肺科杂志, 2019, 24(11):1995-1999. doi:10.3969/j.issn.1009-6663.2019.11.015.
[12]	李嫒, 崔金霞. 肺结核治疗后感染性并发症研究进展. 临床医学进展, 2021, 11(7): 3232-3237. doi:10.12677/ACM.2021.117469.
[13]	陈艳, 潘殿柱, 王波, 等. 604例细菌性肺炎患者病原菌分类及耐药性分析. 中国病原生物学杂志, 2024, 19(6):695-698, 702. doi:10.13350/j.cjpb.240615.
[14]	Li ZJ, Zhang HY, Ren LL, et al. Etiological and epidemiolo-gical features of acute respiratory infections in China. Nat Commun, 2021, 12(1):5026. doi:10.1038/s41467-021-25120-6.
[15]	GBD 2019 LRI Collaborators. Age-sex differences in the global burden of lower respiratory infections and risk factors, 1990—2019: results from the Global Burden of Disease Study 2019. Lancet Infect Dis, 2022, 22(11): 1626-1647. doi:10.1016/S1473-3099(22)00510-2.
[16]	全国细菌耐药监测网. 2023年全国细菌耐药监测报告(简要版)[EB/OL]. [2025-03-29]. https://www.carss.cn/Report/Details?aId=978 .
[17]	中国细菌耐药检测网. CHINET2024年全年细菌耐药监测结果[EB/OL]. [2025-03-29]. https://www.chinets.com/Data/AntibioticDrugFast .
[18]	章莹, 刘蔚. 产超广谱β-内酰胺酶大肠埃希菌感染调查及耐药性分析. 中国实用医刊, 2020, 47(4):41-44. doi:10.3760/cma.j.issn.1674-4756.2020.04.013.
[19]	中华医学会呼吸病学分会感染学组. 中国铜绿假单胞菌下呼吸道感染诊治专家共识(2022年版). 中华结核和呼吸杂志, 2022, 45(8): 739-752. doi:10.3760/cam.j.cn112147-20220407-00290.
[20]	World Health Organization. WHO publishes list of bacteria for which new antibiotics are urgently needed. Geneva: World Health Organization, 2024.
[21]	Wang Y, Luo Q, Chen T, et al. Clinical, biological and genome-wide comparison of carbapenem-resistant Klebsiella pneumoniae with susceptibility transformation to polymyxin B during therapy. Clin Microbiol Infect, 2023, 29(10): 1336.e1-1336.e8. doi:10.1016/j.cmi.2023.06.029.
[22]	Zhang S, Di L, Qi Y, et al. Treatment of infections caused by carbapenem-resistant Acinetobacter baumannii. Front Cell Infect Microbiol, 2024, 18(14):1395260. doi:10.3389/fcimb.2024.1395260.
[23]	Fang GY, Wu FH, Mu XJ, et al. Monitoring longitudinal antimicrobial resistance trends of Staphylococcus aureus strains worldwide over the past 100 years to decipher its evolution and transmission. J Hazard Mater, 2024, 465:133136. doi:10.1016/j.jhazmat.2023.133136.
[24]	Wipperman MF, Fitzgerald DW, Juste MAJ, et al. Antibiotic treatment for Tuberculosis induces a profound dysbiosis of the microbiome that persists long after therapy is completed. Sci Rep, 2017, 7(1):10767. doi:10.1038/s41598-017-10346-6. pmid: 28883399
[25]	Langdon A, Crook N, Dantas G. The effects of antibiotics on the microbiome throughout development and alternative approaches for therapeutic modulation. Genome Med, 2016, 8(1):39. doi:10.1186/s13073-016-0294-z. pmid: 27074706
[26]	封彬彬, 金锋, 景辉, 等. 山东地区439株非结核分枝杆菌临床分离株菌种鉴定及耐药情况. 中国防痨杂志, 2021, 43(5): 516-520. doi:10.3969/j.issn.1000-6621.2021.05.019.
[27]	Zimmermann P, Curtis N. The effect of antibiotics on the composition of the intestinal microbiota-a systematic review. J Infect, 2019, 79(6):471-489. doi:10.1016/j.jinf.2019.10.008. pmid: 31629863
[28]	Wei DW, Song Y, Li Y, et al. Insertion sequences accelerate genomic convergence of multidrug resistance and hypervirulence in Klebsiella pneumoniae via capsular phase variation. Genome Med, 2025, 17(1):45. doi:10.1186/s13073-025-01474-0.

病原菌	BP组		PTB-LRTI组		PNTM-LRTI组		χ²值	P值
病原菌	株数	检出率 (%)	株数	检出率 (%)	株数	检出率 (%)	χ²值	P值
革兰阴性菌
肺炎克雷伯菌	434	21.41^a	773	32.30	160	34.78	75.984	<0.001
铜绿假单胞菌	555	27.38^a	358	14.95	89	19.35	104.324	<0.001
阴沟肠杆菌	92	4.54^a	216	9.02	36	7.83	34.155	<0.001
大肠埃希菌	99	4.88^a	201	8.40	36	7.83	21.823	<0.001
鲍曼不动杆菌	135	6.66^a	101	4.22	18	3.91	14.976	0.001
黏质沙雷菌	52	2.57^a	97	4.05	16	3.48	7.440	0.024
嗜麦芽窄食单胞菌	143	7.05^a	81	3.38	10	2.17	40.053	<0.001
产酸克雷伯菌	24	1.18^a	99	4.14	14	3.04	35.151	<0.001
产气克雷伯菌	19	0.94	29	1.21	10	2.17	4.904	0.086
弗劳地柠檬酸杆菌	11	0.54^a	33	1.38	12	2.61	16.324	<0.001
木糖氧化无色杆菌	23	1.13	18	0.75	7	1.52	3.163	0.206
流感嗜血杆菌	75	3.70^a	25	1.04	10	2.17	35.159	<0.001
卡他莫拉菌	21	1.04^a	8	0.33	2	0.43	8.890	0.012
其他革兰阴性杆菌	128	6.32^a	238	9.94	29	6.31(	22.044	<0.001
革兰阳性菌
金黄色葡萄球菌	107	5.28^a	36	1.50	4	0.87	61.528	<0.001
肺炎链球菌	34	1.68^a	8	0.33	2	0.44	23.406	<0.001
β溶血链球菌	8	0.39	4	0.17	0	0.00	3.570	0.168
纹带棒状杆菌	61	3.01^a	15	0.63	1	0.22	46.190	<0.001
其他革兰阳性菌	6	0.30^a	54	2.26	4	0.87	33.339	<0.001
合计	2027	100.00	2397	100.00	460	100.00	-	-

药品	BP组 (107株)	PTB-LRTI组 (36株)	PNTM-LRTI组 (4株)	χ²值	P值
甲氧西林	35(32.71)	8(22.22)	1/4	1.461	0.482
青霉素	102(95.33)	32(88.89)	4/4	2.211	0.331
苯唑西林	35(32.71)	8(22.22)	1/4	1.461	0.482
红霉素	81(75.70)	27(75.00)	2/4	1.353	0.508
克林霉素	43(40.19)	17(47.22)	2/4	0.650	0.723
左氧氟沙星	24(22.43)	6(16.67)	2/4	2.450	0.294
环丙沙星	26(24.30)	6(16.67)	2/4	2.552	0.279
莫西沙星	20(18.69)	6(16.67)	2/4	2.626	0.269
利福平	3(2.80)	5(13.89)	1/4	8.308	0.016
庆大霉素	13(12.15)	3(8.33)	0/4	0.907	0.636
四环素	17(15.89)	2(5.56)	2/4	6.632	0.032
复方新诺明	24(22.43)	8(22.22)	1/4	0.016	0.992
利奈唑胺	0(0.00)	0(0.00)	0/4	NA	NA
替加环素	0(0.00)	0(0.00)	0/4	NA	NA
万古霉素	0(0.00)	0(0.00)	0/4	NA	NA

病原菌	BP组		PTB-LRTI组		PNTM-LRTI组		χ²值	P值
病原菌	株数	构成比(%)	株数	构成比(%)	株数	构成比(%)	χ²值	P值
CRPA	132	49.25	53	43.44	13	41.94	1.485	0.476
CRAB	73	27.24	21	17.21	7	22.58	4.658	0.097
CRE	63	23.51^a	48	39.35	11	35.48	10.904	0.004
合计	268	100.00	122	100.00	31	100.00	-	-