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JOURNAL ARTICLE
RESEARCH SUPPORT, N.I.H., EXTRAMURAL
RESEARCH SUPPORT, N.I.H., INTRAMURAL
Electrically conductive catheter inhibits bacterial colonization.
PURPOSE: To design, prototype, and assess a custom vascular access catheter for its ability to inhibit bacterial colonization in vitro and to optimize electric parameters for efficacy and safe translation.
MATERIALS AND METHODS: A vascular access catheter with conductive elements was designed and custom fabricated with two electrodes at the tip, separated by a nonconductive segment. The catheter was colonized with Staphylococcus aureus and incubated at predetermined current levels (4-8 µA) and durations (4-24 h). Catheters were compared using bacterial counts and scanning electron microscopy (SEM).
RESULTS: Bacteria colony-forming units were reduced significantly (P < .05) by > 90% (91.7%-100%) in all uninterrupted treatment arms that included electric current (4 µA or 8 µA) of at least 8 hours' duration. Qualitative analysis using SEM revealed that the treated catheter exposed to electric current had markedly less bacteria compared with the untreated catheter.
CONCLUSIONS: This catheter with conductive elements inhibits bacterial colonization in vitro when very small electric current (4-8 µA) is applied across the tip for 8-24 hours. In vivo validation is requisite to future translation to the clinical setting.
MATERIALS AND METHODS: A vascular access catheter with conductive elements was designed and custom fabricated with two electrodes at the tip, separated by a nonconductive segment. The catheter was colonized with Staphylococcus aureus and incubated at predetermined current levels (4-8 µA) and durations (4-24 h). Catheters were compared using bacterial counts and scanning electron microscopy (SEM).
RESULTS: Bacteria colony-forming units were reduced significantly (P < .05) by > 90% (91.7%-100%) in all uninterrupted treatment arms that included electric current (4 µA or 8 µA) of at least 8 hours' duration. Qualitative analysis using SEM revealed that the treated catheter exposed to electric current had markedly less bacteria compared with the untreated catheter.
CONCLUSIONS: This catheter with conductive elements inhibits bacterial colonization in vitro when very small electric current (4-8 µA) is applied across the tip for 8-24 hours. In vivo validation is requisite to future translation to the clinical setting.
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