beta-lactamase production
β-内酰胺酶产生
detecting beta-lactamase
检测β-内酰胺酶
beta-lactamase activity
β-内酰胺酶活性
beta-lactamase gene
β-内酰胺酶基因
beta-lactamase inhibitors
β-内酰胺酶抑制剂
expresses beta-lactamase
表达β-内酰胺酶
beta-lactamase test
β-内酰胺酶试验
beta-lactamase mediated
β-内酰胺酶介导的
beta-lactamase presence
β-内酰胺酶存在
beta-lactamase resistant
耐β-内酰胺酶
the bacteria produced beta-lactamase, rendering the antibiotic ineffective.
细菌产生了β-内酰胺酶,使抗生素失效了。
clinical labs routinely test for beta-lactamase production in staphylococcus aureus.
临床实验室常规检测葡萄球菌中的β-内酰胺酶产生情况。
beta-lactamase inhibitors are often combined with penicillin to overcome resistance.
β-内酰胺酶抑制剂通常与青霉素联合使用以克服耐药性。
the presence of beta-lactamase significantly impacts antibiotic selection.
β-内酰胺酶的存在对抗生素的选择有重大影响。
rapid beta-lactamase detection is crucial for guiding antimicrobial therapy.
快速检测β-内酰胺酶对于指导抗菌治疗至关重要。
some bacteria exhibit high levels of beta-lactamase, leading to treatment failure.
某些细菌表现出高水平的β-内酰胺酶,导致治疗失败。
genetic mutations can result in increased beta-lactamase expression.
基因突变会导致β-内酰胺酶表达增加。
the mechanism of beta-lactamase involves hydrolysis of the beta-lactam ring.
β-内酰胺酶的作用机制涉及β-内酰胺环的水解。
new beta-lactamase variants pose a challenge to antibiotic stewardship programs.
新的β-内酰胺酶变异对抗菌管理计划构成了挑战。
understanding beta-lactamase epidemiology is vital for infection control.
了解β-内酰胺酶的流行病学对感染控制至关重要。
beta-lactamase enzymes are a major cause of antibiotic resistance worldwide.
β-内酰胺酶是全球抗生素耐药性的主要原因。
beta-lactamase production
β-内酰胺酶产生
detecting beta-lactamase
检测β-内酰胺酶
beta-lactamase activity
β-内酰胺酶活性
beta-lactamase gene
β-内酰胺酶基因
beta-lactamase inhibitors
β-内酰胺酶抑制剂
expresses beta-lactamase
表达β-内酰胺酶
beta-lactamase test
β-内酰胺酶试验
beta-lactamase mediated
β-内酰胺酶介导的
beta-lactamase presence
β-内酰胺酶存在
beta-lactamase resistant
耐β-内酰胺酶
the bacteria produced beta-lactamase, rendering the antibiotic ineffective.
细菌产生了β-内酰胺酶,使抗生素失效了。
clinical labs routinely test for beta-lactamase production in staphylococcus aureus.
临床实验室常规检测葡萄球菌中的β-内酰胺酶产生情况。
beta-lactamase inhibitors are often combined with penicillin to overcome resistance.
β-内酰胺酶抑制剂通常与青霉素联合使用以克服耐药性。
the presence of beta-lactamase significantly impacts antibiotic selection.
β-内酰胺酶的存在对抗生素的选择有重大影响。
rapid beta-lactamase detection is crucial for guiding antimicrobial therapy.
快速检测β-内酰胺酶对于指导抗菌治疗至关重要。
some bacteria exhibit high levels of beta-lactamase, leading to treatment failure.
某些细菌表现出高水平的β-内酰胺酶,导致治疗失败。
genetic mutations can result in increased beta-lactamase expression.
基因突变会导致β-内酰胺酶表达增加。
the mechanism of beta-lactamase involves hydrolysis of the beta-lactam ring.
β-内酰胺酶的作用机制涉及β-内酰胺环的水解。
new beta-lactamase variants pose a challenge to antibiotic stewardship programs.
新的β-内酰胺酶变异对抗菌管理计划构成了挑战。
understanding beta-lactamase epidemiology is vital for infection control.
了解β-内酰胺酶的流行病学对感染控制至关重要。
beta-lactamase enzymes are a major cause of antibiotic resistance worldwide.
β-内酰胺酶是全球抗生素耐药性的主要原因。
探索常用高频词汇