get 2019-nCoV by touching a surface
According to the United States Centers for Disease Control and Prevention (CDC) it’s “currently unclear if a person can get 2019-nCoV by touching a surface or object that has the virus on it and then touching their own mouth, nose, or possibly their eyes.”
In fact, not a lot is known about the COVID-19 virus at all, so researchers are turning to similar coronaviruses, like SARS and MERS, for answers.
Reviewing the literature on all available human and veterinary viruses within this family, encompassing 22 studies, researchers have found that the human pathogens can persist on surfaces and remain infectious at room temperature for up to nine days. (To put that in perspective, the measles virus can live on contaminated surfaces for up to two hours.)
Granted, that’s the upper end of a coronavirus lifespan, but on average, researchers say this family of viruses can survive between four and five days on various materials like aluminium, wood, paper, plastic and glass.
Some of the veterinary coronaviruses – the ones that can only infect animals – could even persist for longer than 28 days.
“Low temperature and high air humidity further increase their lifespan,” says physician Günter Kampf at the Greifswald University Hospital.
To reduce the spread of coronaviruses in general, the authors of the new study suggest hospitals carefully disinfect surfaces with various solutions made from sodium hypochlorite, hydrogen peroxide, or ethanol.
In their study, they found these particular WHO recommendations to be “very effective” against SARS and MERS.
The results were originally bound for a future textbook, but under the circumstances, the authors felt it was best to publish their findings in advance. They think the results might also extend to the COVID-19 virus.
“Different coronaviruses were analysed, and the results were all similar,” says virologist Eike Steinmann form Leibniz University Hanover.
None of the viruses were 2019-nCoV however, and the team indicated they don’t have data on whether hands can become contaminated with coronavirus after patient contact or after touching contaminated surfaces.
While MERS doesn’t transfer as easily from person to person as other coronaviruses, SARS spreads rather efficiently whenever an infected person sneezes or coughs. If the mucous lands on a surface and is touched by a person later, it can then contaminate them, even if the contact occurs days after the initial exposure.
Given how threatening this could make 2019-nCoV, washing our hands often and making sure to disinfect public areas seems like a harmless price to pay.
“In hospitals, these can be door handles, for example, but also call buttons, bedside tables, bed frames and other objects in the direct vicinity of patients, which are often made of metal or plastic,” explains Kampf.
The study was published in the Journal of Hospital Infection.
“with various solutions made from sodium hypochlorite, hydrogen peroxide, or ethanol.
In their study, they found these particular WHO recommendations to be “very effective” against SARS and MERS.”
That’s all very well and good, but I don’t think anyone would want to spray any of these concoctions on their face, eyes, and hands. As far as contact surfaces are concerned, spraying such a surface with 50 PPM, EIS would, when dried, leave a coating of single silver ions over the surface. Would this coating of silver act to disable virus particles that land on it?
Re-emergence of resistance in different pathogens including viruses are the major cause of human disease and death, which is posing a serious challenge to the medical, pharmaceutical and biotechnological sectors. Though many efforts have been made to develop drug and vaccines against re-emerging viruses, researchers are continuously engaged in the development of novel, cheap and broad-spectrum antiviral agents, not only to fight against viruses but also to act as a protective shield against pathogens attack. Current advancement in nanotechnology provides a novel platform for the development of potential and effective agents by modifying the materials at nanolevel with remarkable physicochemical properties, high surface area to volume ratio and increased reactivity. Among metal nanoparticles, silver nanoparticles have strong antibacterial, antifungal and antiviral potential to boost the host immunity against pathogen attack. Nevertheless, the interaction of silver nanoparticles with viruses is a largely unexplored field. The present review discusses antiviral activity of the metal nanoparticles, especially the mechanism of action of silver nanoparticles, against different viruses such HSV, HIV, HBV, MPV, RSV, etc. It is also focused on how silver nanoparticles can be used in therapeutics by considering their cytotoxic level, to avoid human and environmental risks