Copper Reduces Risk of Infection by Over 40%
Author: University of Southampton
Published: 2011/07/01 - Updated: 2015/04/19
Topic: Surgery and Operations - Publications List
Page Content: Synopsis - Introduction - Main
Synopsis: Coppers rapid destruction of pathogens could prevent mutational resistance developing and also help reduce the spread of antibiotic resistance genes.
Introduction
Copper reduces infection risk by more than 40 percent.
Focus
Professor Bill Keevil, Head of the Microbiology Group and Director of the Environmental Healthcare Unit at the University of Southampton, has presented research into the mechanism by which copper exerts its antimicrobial effect on antibiotic-resistant organisms at the World Health Organization's first International Conference on Prevention and Infection Control (ICPIC).
'New Insights into the Antimicrobial Mechanisms of Copper Touch Surfaces' observes the survival of pathogens on conventional hospital touch surfaces contributes to increasing incidence and spread of antibiotic resistance and infections. Keevil proposes antimicrobial copper surfaces as one way to address this, since they achieve a rapid kill of significant bacterial, viral and fungal pathogens.
He reported studies on dry surfaces with a range of pathogens, concluding that: "Copper's rapid destruction of pathogens could prevent mutational resistance developing and also help reduce the spread of antibiotic resistance genes to receptive and potentially more virulent organisms, as well as genes responsible for virulence. Additionally, copper touch surfaces could have a key role in preventing the transmission of healthcare-associated infections. Extensive laboratory tests have demonstrated copper's antimicrobial efficacy against key organisms responsible for these infections, and clinical trials around the world are now reporting on its efficacy in busy, real-world environments."
The latest trial - conducted in intensive care units at three facilities in the United States - has shown that the use of antimicrobial copper surfaces in intensive care unit rooms resulted in a 40.4% reduction in the risk of acquiring a hospital infection.
The study, funded by the US Department of Defense, was designed to determine the efficacy of antimicrobial copper in reducing the level of pathogens in hospital rooms, and whether such a reduction would translate into a lower rate of infection.
Researchers at the three hospitals involved in the trial - Memorial Sloan Kettering Cancer Center in New York, the Medical University of South Carolina (MUSC) and the Ralph H. Johnson VA Medical Center, both in Charleston, South Carolina - replaced commonly-touched items such as bed rails, over-bed tray tables, nurse call buttons and IV poles with antimicrobial copper versions.
Data presented today by trial leader Dr Michael Schmidt, Professor and Vice Chairman of Microbiology and Immunology at MUSC, at ICPIC, demonstrated a 97% reduction in surface pathogens in rooms with copper surfaces, the same level achieved by "terminal" cleaning: the regimen conducted after each patient vacates a room.
Dr Schmidt said of the results: "Bacteria present on ICU room surfaces are probably responsible for 35-80% of patient infections, demonstrating how critical it is to keep hospitals clean. The copper objects used in the clinical trial supplemented cleaning protocols, lowered microbial levels, and resulted in a statistically significant reduction in the number of infections contracted by patients treated in those rooms."
Professor Keevil and Dr Schmidt will be taking questions at the conference during an 'Ask The Experts' session on July 1st.
For further information, contact Glenn Harris, Media Officer, University of Southampton on 023 8059 3212 g.harris@soton.ac.uk