LubriShield^TM- a unique permanent coating for indwelling urinary catheters that impedes surface-associated uropathogens from forming biofilm

Catheter-associated urinary tract infection (CAUTI) is one of the most common healthcare-associated infections and biofilm formation plays a key role in its pathogenesis. Indwelling medical devices introduce ideal pathways inside the body for invading pathogens and feature surfaces conducive to biofilm development. These devices are the root cause of severe clinical infections often recalcitrant to antimicrobials. When bacteria and fungi switch to biofilm mode of growth, they produce a matrix in the form of extracellular polymeric substances (EPS). This creates a unique environment for growing virulent colonizers and persisting cells while also forming a shielding barrier against immune system attacks, antimicrobial agents and mechanical removal by fluid shear forces.

To address this challenge, LubriShield^TM- a novel permanent coating was invented, and evenly applied to both the internal and external surfaces of indwelling urinary Foley catheters. Without releasing active substances, it effectively prevented pathogens from producing biofilm. The coating was superhydrophilic and incorporated a proprietary anti-fouling ligand, which created a surface that significantly inhibited up to 99% of colonizing uropathogens from forming biofilm for the duration of use without any microbial killing (p< 0.001). The predominant uropathogens, including Gram-positive and Gram-negative as well as Candida albicans, were inhibited from forming biofilm on the LubriShield^TMcoated surfaces for up to 14 days in artificial urine medium. After challenging the adhering bacteria in a glass bladder flow model, the coating still significantly reduced biofilm formation by 83% (p<0.001).

The growth mode and emergent properties of adhering bacteria on uncoated silicone catheter surfaces were compared with those on LubriShield^TMcoated surfaces. RNA-seq analysis revealed that gene expression associated with microbial EPS formation was significantly downregulated on the coated surfaces. Additionally, microorganisms adhering to LubriShield^TMcoated catheters were 46% more susceptible to antibiotics compared to those on uncoated silicone catheters (p<0.01).