Purpose: A previous study showed decreased uropathogen adherence using a novel anti-fouling coating consisting of mussel adhesive protein mimics conjugated to poly(ethylene glycol). We assessed the ability of methoxy polyethylene glycol-dihydroxyphenylalanine (Nerites Corp. Ltd., Madison, Wisconsin) coated ureteral stents to resist bacterial adherence, infection development and encrustation in a rabbit model of uropathogenic Escherichia coli cystitis.
Materials and Methods:Sof-Flex® stent curls that were uncoated and coated with 3 coatings, including Surphys™ 002, 008 and 009, respectively, and uncoated Percuflex Plus® stents were inserted transurethrally into the bladder of 50 male New Zealand White rabbits (Charles River Laboratories, Montreal, Quebec, Canada), followed by instillation of uropathogenic E. coli strain GR12 (10 7 cfu). Urine was examined for bacteria on days 0, 1, 3 and 7, and for cytokine levels on day 7. On day 7 the animals were sacrificed. Stent curls and bladders were harvested for analysis. In a parallel experiment stents were challenged in vitro for 7 days with GR12 in human urine.Results: Surphys 009 coated devices showed decreased urine and stent bacterial counts compared to those in controls. Eight of 10 rabbits in the Surphys 009 group had sterile urine by day 3 vs 1 in each control group (p = 0.013), while stent adherent organisms were decreased by more than 75%. While no statistical differences were found in encrustation and bladder inflammation across the groups, immune scoring was lowest in the uncoated Sof-Flex control and Surphys 009 groups (p = 0.030).
Conclusions:Surphys 009 strongly resisted bacterial attachment, resulting in improved infection clearance over that of uncoated devices. However, this did not translate to decreased encrustation, which appeared to be independent of infection in this model.
Keywordsureter; stents; rabbits; Escherichia coli; dihydroxyphenylalanine BACTERIAL attachment and biofilm formation are serious problems associated with urinary stents and catheters since they lead to chronic infections that cannot be resolved without device Copyright © 2009 Despite numerous strategies to prevent these events, including anti-fouling and antimicrobial coatings, dietary and urinary modification, and oral antibiotics, nothing has yet proved efficacious. [3][4][5][6] The urinary tract has multiple strategies for dealing with invading microorganisms but the presence of a foreign device provides a novel nonhost surface to which they can attach and form a biofilm. This is supported by studies highlighting the ability of normally nonuropathogenic microorganisms to readily cause device associated UTIs. [7][8][9] Recently we performed an in vitro study using surfaces coated with PEG conjugated to a synthetic mimic of MAPs. 10 MAP mimics consisted of tripeptides of DOPA, the key adhesive component in MAPs. These peptides served as anchors and were coupled to the terminus of a 5,000 Da mPEG-DOPA 3 . Coated surfaces inhibited attachment by greater than 94% for 7 ...
