Novel Coronavirus, COVID-19 and How to Deal with the Virus
in the Indoor Environment
Chin S. Yang, Ph.D., and Ching-Yi Tsai, Ph.D.
A novel (new) coronavirus (SARS-CoV-2)
that causes the coronavirus disease 2019 (COVID-19) was first reported from
China in November of 2019. The symptoms of the disease are similar to pneumonia
which include fever, cough, and shortness of breath. It has now spread to more
than 100 countries, including the United States, causing a pandemic.
Because the virus is new, our current
understanding about the virus is largely based on what is known from similar
coronaviruses, such as SARS, MERS, and common human coronaviruses. COVID-19 is
a new disease, and there is more to learn about how it spreads among
individuals and in the community and the severity of illness it causes.
It is now known that COVID-19 is spread
person-to-person, directly or indirectly. The spread appears to occur mainly
through close contact with one another (within about 6 feet) or respiratory
droplets produced when an infected person coughs or sneezes. A person can be
infected with COVID-19 by touching contaminated surfaces and then touching
their mucous membranes of the nose, eyes, or mouth, but this is not thought to be
the primary way the virus spreads. A recent review revealed that the SARS
virus, which is genetically about 80% similar to the new coronavirus, can
persist on inanimate surfaces like glass, metal, plastic, paper or wood for up
to 9 days at room temperature.
A recent study in the US and published
in the New England Journal of Medicine found that aerosol and fomite
transmission of SARS-CoV-2 is plausible, since the virus can remain infectious
in aerosols for hours and on surfaces up to days. These findings are similar to
those with SARS.
Preliminary data suggests that older
adults (50 years or older) or persons with underlying health conditions (i.e.,
cardiovascular disease, diabetes, chronic respiratory disease, hypertension,
and cancer) are at an increased risk for severe illness or death from this virus.
However, people of all ages have been reportedly infected. There are currently
no vaccines or therapeutic treatments available for COVID-19. Frequent hand
washing and avoiding events with large groups of people can minimize individual
exposure to the virus. Early containment and prevention for further spread are
crucial in stopping the outbreak and to control this novel infectious threat.
In the event that an indoor environment
is exposed or contaminated by the virus, there is no direct testing available.
We recommend that the environment be cleaned, and surfaces sanitized or
disinfected. Surface treatments can be accomplished by using several common disinfectants.
The following cleaning/sanitizing agents/disinfectants are known to be very effective
against SARS virus, which is genetically about 80% similar to the new coronavirus
(SARS-CoV-2). The sanitizers/disinfectants are:
1. Alcohols, including rubbing alcohol or isopropyl alcohol
containing at least 60%, can inactivate the virus particles by denaturing the
viral proteins. However, alcohols are flammable and should only be used in
great care and should not be used in large scale sanitization.
2. The second disinfectant is hydrogen peroxides. A review of
scientific literature suggests that 0.5% hydrogen peroxide can inactivate SARS
virus within one minute. Common hydrogen peroxide sanitizer available in drug
stores is 3% hydrogen peroxide.Some mold remediation
contractors may have equipment and capability to apply hydrogen peroxide by
fogging.
3. The third option is sodium hypochlorite solutions or similar
chlorine-releasing compounds. It was reported that 0.1% sodium hypochlorite
solution can inactivate SARS particles within one minute. Sodium hypochlorite
is the active ingredient in household bleach. Commercial bleach solutions
usually contain 5-6% sodium hypochlorite. Chlorinereleasing
compounds and solutions should always be used with the greatest caution. Chlorine
gas is toxic and can be lethal. Never mix bleach solutions with acids, alkali,
or other cleaning agents, such as ammonia or Windex.
As always, know your sanitizers and
disinfectants. Read instruction labels on the disinfectant containers or MSDSs,
if they are available, before using them. These disinfectants should only be
used and applied by professionals when used in large scales.
In an indoor environment where
contamination is suspected, sanitization with selected sanitizers/disinfectants
is recommended. Fogging, surface wiping, or a combination of both is useful.
Fogging may reach areas where wiping is difficult to reach. However, wiping on
surfaces where frequent human contacts likely occur is also very important.
After sanitization and disinfection
treatments, post-treatment is verified by swab sampling to test for bacterial
and fungal spores as surrogates to the virus. There are no specific testing
methods available for the virus obtained from environmental samples. Bacterial and
fungal spores are more resistant to the sanitizer/disinfectant treatment than
the virus. If the sanitizer/disinfectant treatment can eradicate bacteria and fungal spores on the surfaces, the probability
of the virus being inactivated is probably greater than 95%.
Our senior microbiologist, Dr. Ching-Yi
Tsai, was a member of the Taiwanese team that identified and completed whole
genome sequences of SARS virus in patients in Taiwan. She helped to determine
the replication and pathogenesis of SARS coronavirus. If you have any questions
concerning the new coronavirus, SARS-CoV-2 or COVID-2019, you can reach her at
856-767-8300 or chingyi.tsai@prestige-em.com. Prestige is currently researching
a RT-PCR method for the detection of the virus from the environment.
References:
Kampf, G., D. Todt,
S. Pfaender, and E. Steinmann. Persistence of
coronaviruses on inanimate surfaces and their inactivation with biocidal agents.
Journal of Hospital Infection . February 2020. https://www.journalofhospitalinfection.com/article/S0195-6701(20)30046-3/pdf
Ong,
Sean W. X., Yian K Tan, Po Y. Chia, Tau H. Lee, Oon T. Ng, Michelle S. Y. Wong, and Kalisvar
Marimuthu. 2020. Air, Surface Environmental, and
Personal Protective Equipment Contamination by Severe Acute Respiratory
Syndrome Coronavirus 2 (SARS-CoV-2) From a Symptomatic Patient. JAMA.
March 2020.
https://jamanetwork.com/journals/jama/fullarticle/2762692
Van Doremalen1, N., Trenton Bushmaker, Dylan H. Morri, Myndi G. Holbrook, Amandine Gamble, Brandi N. Williamson, Azaibi Tamin, Jennifer L.
Harcourt, Natalie J. Thornburg, Susan I. Gerber, James O. Lloyd-Smith, Emmie de
Wit, Vincent J. Munster. Aerosol and surface stability of HCoV-19 (SARS-CoV-6
2) compared to SARS-CoV-1. The New England Journal of Medicine. March
2020.
https://www.nejm.org/doi/full/10.1056/NEJMc2004973
Yeh, S.H., H.Y. Wang, C.Y. Tsai, C.L. Kao, J.Y. Yang, H.W.
Liu, I.J. Su, S.F. Tsai, D.S. Chen, P.J. Chen & National Taiwan University SARS
Research Team. Characterization of SARS coronavirus genomes in Taiwan: Molecular
epidemiology and genome evolution. 2004.
Proc. Natl. Acad. Sci. USA 101:2542-2547.
Date:
March 23, 2020
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