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Calibration of optimal use parameters for an ultraviolet light‐emitting diode in eliminating bacterial contamination on needleless connectors
Author(s) -
Hutchens M.P.,
Drennan S.L.,
Cambronne E.D.
Publication year - 2015
Publication title -
journal of applied microbiology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.889
H-Index - 156
eISSN - 1365-2672
pISSN - 1364-5072
DOI - 10.1111/jam.12802
Subject(s) - contamination , human decontamination , ultraviolet , staphylococcus aureus , materials science , cable gland , optoelectronics , bacteria , biology , electrical engineering , engineering , waste management , ecology , genetics
Aims Needleless connectors may develop bacterial contamination and cause central‐line‐associated bloodstream infections ( CLABSI ) despite rigorous application of best‐practice. Ultraviolet ( UV ) light‐emitting diodes ( LED ) are an emerging, increasingly affordable disinfection technology. We tested the hypothesis that a low‐power UV LED could reliably eliminate bacteria on needleless central‐line ports in a laboratory model of central‐line contamination. Methods and Results Needleless central‐line connectors were inoculated with Staphylococcus aureus . A 285 nm UV LED was used in calibrated fashion to expose contaminated connectors. Ports were directly applied to agar plates and flushed with sterile saline, allowing assessment of bacterial survival on the port surface and in simulated usage flow‐through fluid. UV applied to needleless central‐line connectors was highly lethal at 0·5 cm distance at all tested exposure times. At distances >1·5 cm both simulated flow‐through and port surface cultures demonstrated significant bacterial growth following UV exposure. Logarithmic‐phase S. aureus subcultures were highly susceptible to UV induction/maintenance dosing. Conclusions Low‐power UV LED doses at fixed time and distance from needleless central‐line connector ports reduced cultivable S. aureus from >10 6 CFU to below detectable levels in this laboratory simulation of central‐line port contamination. Significance and Impact of the study Low‐power UV LED s may represent a feasible alternative to current best‐practice in connector decontamination.