Tiny Diamonds, Big Impact: Unlocking the Structure-Activity Relationship of Antimicrobial Nanodiamonds.

Abstract

Nanodiamonds (NDs) have emerged as a highly promising nanomaterial due to their intrinsic biocompatibility and remarkable antimicrobial and anti-adhesive properties, which result from their unique surface morphology. NDs serve as an excellent platform for extensive functionalization with diverse chemical groups and complex bioactive molecules, including peptides, photosensitizers, antibiotics and polycations. The antimicrobial potential of NDs has gained considerable attention in recent years across numerous application areas, including drug-delivery platforms, wound dressings, dentistry, surface coatings, biomedical implants, the food industry and water treatment technologies. This article compiles and critically evaluates the current microbiological evidence on ND antimicrobial activity. However, translating these findings into practical guidelines remains challenging due to the wide variability in reported results and the limited diversity of bacterial strains employed. The antimicrobial mechanisms of NDs in the context of Gram positive, Gram negative, and flagellated bacteria are examined, and it is demonstrated that key factors, including particle size, surface charge, and the composition of testing media, profoundly influence experimental outcomes and underlie many apparent contradictions in the field. Moreover, this review summarizes the functionalization strategies available for NDs, their reported biomedical and industrial applications, and current knowledge regarding their cytotoxicity and biocompatibility. Collectively, the article provides an integrated view of the structure-activity relationship governing ND antimicrobial performance.