Abstract
Objectives/purposeHigh-touch surfaces are a critical reservoir in the spread of nosocomial infections. Although disinfection and infection control protocols are well developed, they lack the ability to passively reduce the pathogenic load of high-touch surfaces. Copper and its alloys have been suggested as a surface that exhibit continuous biocidal effects. Antimicrobial studies on these surfaces are prevalent, while virucidal studies are not as well explored. The goal of this study was to first determine the virucidal activity of a copper–nickel–zinc alloy and to then examine the effect of soiling and virus preparation on virucidal activity.MethodsA baculovirus vector was used as an easily quantifiable model of an infectious enveloped animal cell virus. Droplets containing virus were deposited on surfaces and allowed to stay wet using humidity control or were dried onto the surface. Virus was then recovered from the surface and assayed for infectivity. To examine how the composition of the droplet affected the survival of the virus, 3 different soiling conditions were tested. The first two were recommended by the United States Environmental Protection Agency and the third consisted of cell debris resulting from virus amplification.ResultsA copper–nickel–zinc alloy was shown to have strong virucidal effects for an enveloped virus. Copper, nickel, and zinc ions were all shown to leach from the alloy surface and are the likely cause of virucidal activity by this surface. Virucidal activity was achieved under moderate soiling but lost under high soiling generated by routine virus amplification procedures. The surface was able to repeatably inactivate dried virus droplets under moderate soiling conditions, but unable to do so for virus droplets kept wet using high humidity.ConclusionIon leaching was associated with virucidal activity in both wet and dried virus conditions. Soiling protected the virus by quenching metal ions, and not by inhibiting leaching. The composition of the solution containing virus plays a critical role in evaluating the virucidal activity of surfaces and surface coatings.
Highlights
Nosocomial infections are a large burden on heath-care systems, with the American Center for Disease Control (CDC) estimating one in every 25 patients acquiring one
Nickel, and zinc ions were all shown to leach from the alloy surface and are the likely cause of virucidal activity by this surface
Virucidal activity was achieved under moderate soiling but lost under high soiling generated by routine virus amplifi‐ cation procedures
Summary
Nosocomial infections are a large burden on heath-care systems, with the American Center for Disease Control (CDC) estimating one in every 25 patients acquiring one. Walji et al Antimicrob Resist Infect Control (2021) 10:133 cost-estimate of preventable nosocomial infections ($5.7–$6.8 billion) was comparable to the cost for treating stroke, complications from diabetes, or chronic obstructive pulmonary disease [1] These types of infections are known to occur through medical devices or environmental transmission, and strategies have been developed to reduce them. A newer avenue is to design surfaces that are biocidal against key pathogens This method may add initial costs, but it does allow for greater consistency and has potential to decrease costs incurred in treatment of nosocomial infections. Development of these surfaces does not endeavour to displace established cleaning and disinfection procedures, but to supplement them and create a comprehensive defence against environmental transmission
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