Biomaterial-associated infections (BAIs) pose significant challenges in modern medical technologies, being a major postoperative complication and leading cause of implant failure. These infections significantly risk patient health, resulting in prolonged hospitalization, increased morbidity and mortality rates, and elevated treatment expenses. This comprehensive review examines the mechanisms driving bacterial adhesion and biofilm formation on biomaterial surfaces, offering an in-depth analysis of current antimicrobial strategies for preventing BAIs. We explore antimicrobial-eluting biomaterials, contact-killing surfaces, and antifouling coatings, emphasizing the application of antifouling polymer brushes on medical devices. Recent advancements in multifunctional antimicrobial biomaterials, which integrate multiple mechanisms for superior protection against BAIs, are also discussed. By evaluating the advantages and limitations of these strategies, this review aims to guide the design and development of highly efficient and biocompatible antimicrobial biomaterials. We highlight potential design routes that facilitate the transition from laboratory research to clinical applications. Additionally, we provide insights into the potential of synthetic biology as a novel approach to combat antimicrobial resistance. This review aspires to inspire future research and innovation, ultimately improving patient outcomes and advancing medical device technology.
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Article Synopsis
- The study investigates the effectiveness of combining antimicrobial peptide (AMP)-functionalized hydrogels with traditional antibiotics like vancomycin (VCM) and oxacillin (OXA) to fight infections caused by antibiotic-resistant bacteria, specifically MRSA.
- Results from checkerboard assays showed strong synergistic effects between the free AMP and both antibiotics, especially a significant enhancement with OXA against MRSA, achieving a 512-fold reduction in OXA's minimum inhibitory concentration (MIC).
- The findings suggest that AMP-functionalized materials could improve the efficacy of antibiotics, making them vital for the development of future medical devices to tackle infections associated with resistant bacteria.
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