Abstract
Background/Objectives: Antimicrobial resistance (AMR) continues to expand under sustained exposure to conventional antibiotics, contributing to the emergence of multidrug- and pan-resistant bacterial pathogens. There remains a critical need for antimicrobial agents that maintain activity during prolonged selective pressure while minimizing the potential for resistance development. This study aimed to evaluate EVQ-218, a non-ionic silver-based antimicrobial, against World Health Organization-designated ESKAPE pathogens. Methods: EVQ-218 was assessed using extended serial passage experiments performed under both sub- and supra-minimum inhibitory concentration (MIC) conditions. Comparative resistance selection experiments were conducted in parallel using tobramycin and ciprofloxacin, and susceptibility was evaluated through MIC determination and phenotypic analysis. Results: Across extended serial passage experiments, EVQ-218 did not exhibit measurable increases in MIC or phenotypic indicators of adaptive resistance. In contrast, parallel exposure to tobramycin and ciprofloxacin resulted in rapid and sustained MIC elevation. Notably, isolates that acquired resistance to either comparator antibiotic retained susceptibility to EVQ-218, indicating a lack of cross-resistance. Mechanistic analyses were consistent with a non-lytic, intracellular mode of antibacterial activity involving disruption of sulfur-associated biomolecular processes, suggestive of a multi-site mechanism distinct from classical antibiotics. Conclusions: These findings support EVQ-218 as a promising broad-spectrum antimicrobial candidate with resistance-resilient activity and warrant further investigation of its potential role in addressing unmet needs in AMR therapeutics.