(E, E)-farnesol and myristic acid-loaded lipid nanoparticles overcome colistin resistance in Acinetobacter baumannii

The rise of colistin-resistant Acinetobacter baumannii has severely limited treatment options for infections caused by this pathogen. While terpene alcohols and fatty acids have shown potential to enhance colistin’s efficacy, but their high lipophilicity limits their clinical application. To address this, we developed water-dispersible lipid nanoparticles (LNPs) in two sizes (40 nm and 130 nm), loaded with these compounds to act as colistin adjuvants. Among eleven LNP formulations, six significantly reduced colistin’s minimum inhibitory concentration (MIC) by 16- to 64-fold. The most effective, featuring (E,E)-farnesol and myristic acid, were further examined for bactericidal activity, membrane disruption, cytotoxicity, and in vivo efficacy in Galleria mellonella larvae. Time-kill studies demonstrated that at an adjuvant concentration of 60 mg/L, these LNPs eradicated bacteria when combined with 4 mg/L free colistin for resistant isolates (MIC = 128 mg/L) and 0.06 mg/L for susceptible isolates (MIC = 0.5 mg/L), without regrowth. Myristic acid-loaded LNPs combined with free colistin at 1/8 MIC resulted in a 4.2-fold higher mortality rate than the combination with (E,E)-farnesol-loaded LNPs in resistant strains. This result was correlated with a 45-fold faster increase in inner membrane permeability, measured by propidium iodide (PI) uptake, in the presence of myristic acid-loaded LNPs compared with a 13-fold faster increase with (E,E)-farnesol-loaded LNPs. DiSC3(5) assays revealed that LNPs alone depolarised the bacterial inner membrane, with enhanced effects when combined with colistin at 1/8 MIC, a result not observed with colistin alone at this concentration. As with PI uptake, this inner membrane depolarising effect was more pronounced with myristic acid-loaded LNPs than with (E,E)-farnesol-loaded LNPs in resistant strains, suggesting that the colistin adjuvant effect of these lipophilic compounds is due to their ability to help colistin destabilise the bacterial inner membrane. Cytotoxicity assays demonstrated no adverse effects on bone marrow macrophages after 6 h of exposure, although some toxicity was observed after 24 h. No mortality was observed in Galleria mellonella larvae over 7 days following three consecutive days of treatment with colistin and LNPs. Notably, the combination of (E,E)-farnesol-loaded LNPs and colistin significantly improved the survival of Galleria infected with A. baumannii. These results suggest that lipophilic-adjuvant-loaded LNPs may offer a promising strategy to enhance colistin efficacy and combat antibiotic-resistant A. baumannii infections.