A review paper newly-published in Internal Medicine Review looks at the large body of peer-reviewed literature demonstrating—through laboratory testing and clinical trials—the efficacy of antimicrobial copper in rapidly killing bacteria and contributing to more hygienic hospital environments. This article highlights some of the most interesting findings of the paper.
7 April 2017
Providing an initial overview of clinical research, the paper says: ‘The findings suggest that copper alloys enhance hospital hygiene protocols because they act passively, requiring neither training nor human intervention to kill bacteria and reduce hospital-acquired infections.’
It also observes that hand washing and surface disinfection—pillars of infection control—as well as interventions such as UV light and HP systems are ‘episodic or one-time approaches.’ As soon as the decontamination process ends, contamination can immediately begin to accumulate. Copper alloys provide a continuously-active solid surface that can alleviate this problem.
Lab work vs. clinical trials
The paper goes on to compare laboratory versus clinical research, noting that lab tests are conducted under ideal, controlled conditions, with surfaces sanitised before being inoculated with a known bacterial strain. By contrast, clinical samples are taken in hospitals by swabbing component surfaces that may be contaminated with several different species of bacteria. They may also contain residues from cleaning solutions, oil from people’s hands and other chemical contaminants. This underlines the need for both types of research.
Highlights from the review of clinical trial results include a study conducted in a US medical ICU, where it was found that bacterial burden rebounded by 30–45% 6.5 hours after disinfection (depending on the type of disinfectant used, in line with the hospital’s standard practice). This underscores that cleaning helps to reduce bacterial burden, but its benefit dissipates within a few hours.
In a subsequent study in the same hospital setting, three beds were equipped with antimicrobial copper bed rails, with three standard plastic beds serving as controls. The bacterial burdens on the copper rails were significantly lower than those on the plastic rails, with those on the copper rails approaching the proposed ‘terminal cleaning’ target of just 250 colony forming units per square centimetre. This is the cleaning goal after a room is vacated, prior to the next patient occupying it.
Describing another US clinical trial exploring bioburden reduction, the paper notes that when copper chair arms and trays were compared to wooden arms and plastic trays, the copper trays showed an 88% reduction in bacterial burden and the copper arms showed a 90% reduction. Even the wood at the side of the copper arm inlays displayed a 70% reduction, which was attributed to a lower rate of cross contamination from the copper surface. ‘Fewer bacteria survived on the copper alloy surface and therefore a smaller number of bacteria were available to be transferred to the adjacent wood on the side of the arm of the chair.’
A further example of this 'halo effect' is described in a clinical trial that took place in a Chilean paediatric ICU, where eight rooms had antimicrobial copper components and eight control rooms were standardly equipped. In addition to significantly reducing local bacterial burden, it was reported that the introduction of copper alloys in the study rooms suppressed the microbial burden recovered from components in nearby control rooms. The paper notes: ‘It is suggested that this may be a result of suppressed cross contamination.’
In discussing one of the best-known pieces of research—a multi-centre US study looking at the impact of antimicrobial copper surfaces in ICUs—it quotes the conclusion that introducing only six copper items into each study room resulted in a 58% reduction in infections. These surfaces comprised less than 10% of the room’s total touch surface area.
The cost perspective
The final issue addressed is perceptions of cost surrounding antimicrobial copper surfaces. The review observes that ‘the initial cost of outfitting a copper alloy room may be perceived as an issue. However, the extra cost can quickly be recovered because infections are expensive to treat.’
An example of research exploring this subject is described, based on the number of infections antimicrobial copper could prevent in the ICU environment. Clinical researchers stated ‘the extra cost of copper components was recaptured in less than two months.’
In its conclusions, the paper notes ‘there is ample evidence currently available to encourage hospitals and other patient treatment centers to adopt the use of antimicrobial copper alloys as part of their infection control protocols… Antimicrobial copper alloys may also have intangible benefits, such as demonstrating to patients that your organization cares about their wellbeing.’
It further observes that the copper alloy components used in the referenced studies were fabricated from 100% solid metal. ‘The copper alloy was not applied as a coating, which can wear off, or introduced as particles in a proprietary plastic matrix that makes up less than 5% of the surface area.’
A final area of interest is that ‘the greatest potential benefit of wider use of antimicrobial copper alloys to control infection has the potential to inhibit the emergence of new antibiotic-resistant strains.’ Based on reports from the US CDC, the ‘abuse and overuse’ of antibiotics is a major contributing factor in the emergence of resistant bacteria. Also to be considered in this process is the role of horizontal gene transfer, a major cause of the spread of multidrug resistance in bacteria. This is ‘essentially blocked by copper surface killing because the bacteria die rapidly with few to no survivors.’
The review finishes by saying that ‘consideration should be given to deploying components made from solid metal antimicrobial copper alloys as an additional tool in the fight to reduce hospital-acquired infection.'
Click here to read the full review paper.
- Intrinsic bacterial burden associated with intensive care unit hospital beds: Effects of disinfection on population recovery and mitigation of potential infection risk
Hubert H. Attaway III, Sarah Fairey, Lisa L. Steed, Cassandra D. Salgado, Harold T. Michels, Michael G. Schmidt. American Journal of Infection Control, December 2012, Volume 40, Issue 10, Pages 907–912
- Copper Continuously Limits the Concentration of Bacteria Resident on Bed Rails within the Intensive Care Unit
Michael G Schmidt, PhD; Hubert H Attaway III, MS; Sarah E Fairey, BS; Lisa L Steed, PhD; Harold T Michels, PhD; Cassandra D Salgado, MD, MS Infection Control and Hospital Epidemiology, Vol. 34, No. 5
- Copper Surfaces Reduce the Microbial Burden in Out-Patient Infectious Disease Practice
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- Potential effectiveness of copper surfaces in reducing health care–associated infection rates in a pediatric intensive and intermediate care unit: A nonrandomized controlled trial
Bettina von Dessauer Maria S. Navarrete, Dona Benadof, Carmen Benavente, Michael G. Schmidt. American Journal of Infection Control. doi:10.1016/j.ajic.2016.03.053
- Copper Surfaces Reduce the Rate of Healthcare-Acquired Infections in the Intensive Care Unit
Cassandra D Salgado, MD; Kent A Sepkowitz, MD; Joseph F John, MD; J Robert Cantey, MD; Hubert H Attaway, MS; Katherine D Freeman, DrPH; Peter A Sharpe, MBA; Harold T Michels, PhD; Michael G Schmidt, PhD. ICHE, Vol. Vol. 34, No. 5, 2013., Infection Control and Hospital Epidemiology , Vol. 34, No. 5, Special Topic Issue: The Role of the Environment in Infection Prevention (May 2013), pp. 479-486
- From Laboratory Research to a Clinical Trial: Copper Alloy Surfaces Kill Bacteria and Reduce Hospital-Acquired Infections
Michels, H.T. 2015. Health Environments Research & Design Journal. 1–16
- Horizontal Transfer of Antibiotic Resistance Genes on Abiotic Touch Surfaces: Implications for Public Health
Sarah L. Warnes, Callum J Highmore, and C William Keevil, Centre for Biological Sciences, University of Southampton, Highfield Campus, Southampton, UK. doi: 10.1128/mBio.00489-12 27 November 2012 mBio vol. 3 no. 6 e00489-12
Copper and copper alloys are engineering materials that are durable, colourful and recyclable and are widely available in various product forms suitable for a range of manufacturing purposes. Copper and its alloys offer a suite of materials for designers of functional, sustainable and cost-effective products.
Copper and certain copper alloys have intrinsic antimicrobial properties (so-called ‘Antimicrobial Copper’) and products made from these materials have an additional, secondary benefit of contributing to hygienic design. Products made from Antimicrobial Copper are a supplement to, not a substitute for standard infection control practices. It is essential that current hygiene practices are continued, including those related to the cleaning and disinfection of environmental surfaces.