Intrinsic antimicrobial resistance: Molecular biomaterials to combat microbial biofilms and bacterial persisters

生物膜 微生物学 抗生素耐药性 材料科学 抗菌剂 多药耐受 抗药性 纳米技术 细菌 抗生素 生物 遗传学
作者
Swagatam Barman,Leman Buzoglu Kurnaz,Ryan Leighton,Md Waliullah Hossain,Alan W. Decho,Chuanbing Tang
出处
期刊:Biomaterials [Elsevier BV]
卷期号:311: 122690-122690 被引量:45
标识
DOI:10.1016/j.biomaterials.2024.122690
摘要

The escalating rise in antimicrobial resistance (AMR) coupled with a declining arsenal of new antibiotics is imposing serious threats to global public health. A pervasive aspect of many acquired AMR infections is that the pathogenic microorganisms exist as biofilms, which are equipped with superior survival strategies. In addition, persistent and recalcitrant infections are seeded with bacterial persister cells at infection sites. Together, conventional antibiotic therapeutics often fail in the complete treatment of infections associated with bacterial persisters and biofilms. Novel therapeutics have been attempted to tackle AMR, biofilms, and persister-associated complex infections. This review focuses on the progress in designing molecular biomaterials and therapeutics to address acquired and intrinsic AMR, and the fundamental microbiology behind biofilms and persisters. Starting with a brief introduction of AMR basics and approaches to tackling acquired AMR, the emphasis is placed on various biomaterial approaches to combating intrinsic AMR, including (1) semi-synthetic antibiotics; (2) macromolecular or polymeric biomaterials mimicking antimicrobial peptides; (3) adjuvant effects in synergy; (4) nano-therapeutics; (5) nitric oxide-releasing antimicrobials; (6) antimicrobial hydrogels; (7) antimicrobial coatings. Particularly, the structure-activity relationship is elucidated in each category of these biomaterials. Finally, illuminating perspectives are provided for the future design of molecular biomaterials to bypass AMR and cure chronic multi-drug resistant (MDR) infections.
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