PHENOTYPIC CHARACTERIZATION OF UROPATHOGENIC ISOLATES FROM CONTAMINATED URINARY CATHETERS

CASTAGNARO E; VILLEGAS JM; RAPISARDA VA; FARIZANO JV; GRILLO-PUERTAS M

Congreso; LVII SAIB Meeting - XVI SAMIGE Meeting; 2021

The ability of pathogens to adhere and form biofilms in medical devices is a relevant issue. Urology is one of the main fields in which biofilm can become a serious problem, specifically in catheter-associated urinary tract infections (CAUTI). Often the main strategy against CAUTIs is catheter removal and replacement. However, this could lead to additional complications such as the detachment of the biofilm from the device that would cause the spread of uropathogens (UP) to non-colonized sites. The biofilm formation ability vary in every single UP isolates. Therefore, it is important to extend the study of UP of medical devices in order to understand their behavior and design new detection protocols, appropriate antibiotic treatments and consequently avoid the severity, persistence and spread of infections. The aim of this study was to perform the phenotypic characterization of UP isolates obtained from catheters removed of patients without primary symptoms of urinary tract infection (UTI). A total of 26 UP isolates were collected from 9 catheters. Following their isolation and identification; biofilm formation patterns (BFP), colony morphology, motility, hemolytic capacity, and antibiotic susceptibility was analyzed in all the isolates. 20 out of 26 UP isolates (76.9%) were able to form biofilm either in M63 or McConkey medium, among them 2 isolates showed a robust BFP, 7 isolates a strong BFP, 4 isolates a moderate BFP, and 7 isolates a weak BFP. Kinetic of biofilm formation showed that most of biofilm forming isolates increased their BFP from 24 to 96 h in both media. The expression of curli fimbriae and cellulose was observed in approximately the 70% of the isolates, denoted by the rdar, pdar, ras, bdar and bas morphotypes. Motility, hemolysis and antibiotic resistance phenotypes showed a significant variability among isolates. This preliminary description of the isolates is be relevant as an insight in the CAUTI field that would constitutes progress in the understanding of clinical isolates, their physiology and interaction in clinical settings. Data would contribute to the understanding of biofilm formation in medical devices.