6株携带blaIMP-4基因耐碳青霉烯香坊肠杆菌耐药性研究

doi:10.12372/jcp.2023.21e1617

Abstract

Abstract:

Objective To explore the drug resistance characteristics of Enterobacter xiangfangensis (E. xiangfangensis) infection in neonatal intensive care unit. Methods Six strains of E. xiangfangensis were isolated from newborns in neonatal intensive care unit from December 2019 to February 2020. These strains were tested for drug resistance using both broth dilution method and disc diffusion method, and 150bp multiple insert size paired-end sequencing was performed using the Illuminanovaseq 6000 to detect drug resistant genes. Meanwhile, clinical data of the children infected with the drug-resistant strains were collected. Results Six strains of E. xiangfangensis were derived from 5 premature infants. One of them was positive in sputum culture, which was considered as colonization. The other 4 infants were sepsis, and 4 cases of sepsis had high risk factors for infection. A premature infant experienced E. xiangfangensis septicemia twice during hospitalization. Drug susceptibility test showed that 6 strains of E. xiangfangensis were sensitive to tigacycline, amikacin and cotrimoxazole. Sensitivity to ciprofloxacin was observed in 1 strain, sensitivity to piperacillin tazobactam was observed in 5 strains, sensitivity to cefoperazone sodium sulbactam was observed in 4 strains, and sensitivity to minocycline was observed in 2 strains. All strains were resistant or intermediate to carbapenems such as meropenem. Identification of the drug resistant genes showed that β-lactam resistance genes blaIMP-4 or laACT-55 and quinolone resistance gene qnrS1 were identified in all 6 strains, aminoglycoside resistance gene aac(6')-Ib4 was found in 5 strains, quinolone resistance gene qnrS1 and sulfonamide resistance gene sul1 coexisted in 5 strains, quinolone resistance genes oqxA9 or oqxB9 also coexisted in 5 strains. Multilocus sequence typing showed that all the 6 strains of E. xiangfangensis had the same sequence type of 148. Conclusions E. xiangfangensis resistance to carbapenems may not be caused by the expression of carbapenem-resistant genes. Antibiotics should be selected reasonably according to the characteristics of bacterial resistance to reduce the generations of resistant bacteria, rather than blindly selecting the carbapenem antibiotics.

Key words: Enterobacter xiangfangensis, carbapenemase, genotype, drug resistance

SUN Jinbo, YAO Bei, HAN Tongyan, TONG Xiaomei, LI Zailing. Study on drug resistance of six carbapenem-resistant Enterobacter xiangfangensis strains carrying blaIMP-4 gene[J].Journal of Clinical Pediatrics, 2023, 41(4): 284-288.

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References 18

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抗菌药物	MIC/μg·mL^-1
抗菌药物	菌株1	菌株2	菌株3	菌株4	菌株5	菌株6
替加环素	2 S	2 S	2 S	2 S	2 S	2 S
头孢他啶	≥64 R	≥64 R	≥64 R	≥64 R	≥64 R	≥64 R
头孢哌酮舒巴坦	16 S	16 S	16 S	32 I	16 S	≥64 R
头孢吡肟	≥32 R	≥32 R	≥32 R	≥32 R	2 S	≥32 R
左氧氟沙星	≥8 R	1 I	1I	1 I	2 R	≥8
哌拉西林他唑巴坦	16 S	16 S	16 S	8 S	8 S	64 R
厄他培南	≥8 R	2 R	2 R	2 R	2 R	2 R
头孢曲松	≥64 R	≥64 R	≥64 R	≥64 R	≥64 R	≥64 R
阿米卡星	≤2 S	≤2 S	≤2 S	≤2 S	≤2 S	≤2 S
复方新诺明	≤20 S	≤20 S	≤20 S	≤20 S	≤20 S	≤20 S
亚胺培南	2 I	≥16 R	≥16 R	≥16 R	≥16 R	≥16 R

抗菌药物	K-B/mm
抗菌药物	菌株1	菌株2	菌株3	菌株4	菌株5	菌株6
环丙沙星	36 S	20 R	20 R	25 I	20 R	24 I
美罗培南	14 R	17 R	20 I	20 I	13 R	20 I
米诺环素	14 I	15 I	15 I	16 S	14 I	17 S

耐药基因	菌株1	菌株2	菌株3	菌株4	菌株5	菌株6
blaIMP-4	+	+	+	+	+	+
blaACT-55	+	+	+	+	+	+
aac(6')-Ib4	+	+	+	+	+	-
qnrS1	+	+	+	+	+	+
sul1	+	+	+	+	+	-
oqxA9	+	+	-	+	+	+
oqxB9	+	+	-	+	+	+

Study on drug resistance of six carbapenem-resistant Enterobacter xiangfangensis strains carrying blaIMP-4 gene

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