Attenuation of Proteus mirabilis colonization and swarming motility on indwelling urinary catheter by antibiofilm impregnation: An in vitro study

[Display omitted] •Antibiofilm-impregnated SFC has sustained release profiles of more than a month.•LIN & HMB-impregnated SFCs have long-term antibiofilm performance.•LIN & HMB-impregnated SFCs did not allow the pathogens to migrate over it.•Uropathogens did not develop resistance against LI...

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Published in:Colloids and surfaces, B, Biointerfaces B, Biointerfaces, 2020-10, Vol.194, p.111207-111207, Article 111207
Main Authors: Durgadevi, Ravindran, Kaleeshwari, Ramaiah, Swetha, Thirukannamangai Krishnan, Alexpandi, Rajaiah, Karutha Pandian, Shunmugaiah, Veera Ravi, Arumugam
Format: Article
Language:English
Subjects:
Antibiofilm
Impregnation
Proteus mirabilis
Solvent-Swelling
Swarming
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Summary:[Display omitted] •Antibiofilm-impregnated SFC has sustained release profiles of more than a month.•LIN & HMB-impregnated SFCs have long-term antibiofilm performance.•LIN & HMB-impregnated SFCs did not allow the pathogens to migrate over it.•Uropathogens did not develop resistance against LIN & HMB. Proteus mirabilis is one of the important etiologic agents of urinary tract infections (UTI), which complicates the long-term urinary catheterization process in clinical settings. Owing to its crystalline biofilm forming ability and flagellar motility, elimination of P. mirabilis from urinary system becomes very difficult. Thus, the present study is focused to prepare antibiofilm-impregnated Silicone Foley Catheter (SFC) to prevent P. mirabilis instigated UTIs. Through solvent swelling method, the antibiofilm compounds such as linalool (LIN) and 2-hydroxy-4-methoxy benzaldehyde (HMB) were successfully infused into SFCs. Surface topography was studied using AFM analysis, which unveiled the unmodified surface roughness of normal and antibiofilm-impregnated SFCs. In addition, UV-spectrometric and FT-IR analyses revealed good impregnation efficacy and prolonged stability of antibiofilm compounds. Further, in vitro biofilm biomass quantification assay exhibited a maximum of 87 % and 84 % crystalline biofilm inhibition in LIN (350 μg/cm3) and HMB (120 μg/cm3) impregnated SFCs, respectively against P. mirabilis in artificial urine medium. Also, the LIN & HMB-impregnated SFCs demonstrated long-term crystalline biofilm inhibitory activity for more than 30 days, which is ascribed to the sustained release of the compounds. Furthermore, the results of swarming motility analysis revealed the efficacy of antibiofilm-impregnated catheters to mitigate the migration of pathogens over them. Thus, antibiofilm-impregnated catheter is proposed to act as a suitable strategy for reducing P. mirabilis infections and associated complications in long-term urinary catheter users.
ISSN:0927-7765
1873-4367
DOI:10.1016/j.colsurfb.2020.111207