Integrated biofilm dispersion and virulence responsiveness for targeted treatment of pseudomonas aeruginosa infection in lungs

Abstract

The self-organization of microbes into biofilms provides multiple benefits including tolerance to mechanical stress and resistance to immune defences and antibiotics. Coupled to a compromised mucociliary function, these traits have dire consequences in cystic fibrosis patients – persistent infections are the main reason for morbidity and mortality. Thereby, disease progression is associated with universal colonization by Pseudomonas aeruginosa, which selects for a slimy phenotype to adapt to the lung microenvironment. Recognizing this, drug-delivery vehicles that break down the mucoid extracellular matrix made of alginate are designed to enable better penetration and biofilm dispersion. In parallel, a protective layer responds to the proteolytic activity of the pathogen and thus controls drug availability. To realize this architecture, silica nanoparticles are loaded with imipenem, and then coated with elastin and alginate lyase in a layer-by-layer fashion using ultrasound. The nanoscale formulations eradicate up to 80% of the total biomass and reduce the bacterial viability in biofilms by 3 logs, considerably outperforming the bulk antibiotic in vitro, whereby the effects are correlated to changes in the viscoelasticity. Furthermore, the stimuli-responsive nanocarriers are safe and effective in animal models of P. aeruginosa infection, presenting a considerable therapeutic promise in the challenging context of lung diseases