COVID-19

Research says Omicron lasts much longer on surfaces than other variants – but disinfecting still works.

We can’t say whether longer Omicron survivability on surfaces relates to a greater risk of infection. But it is of public health significance to know that wiping down surfaces and hand sanitising with disinfectants are effective methods of killing live virus.



Research says Omicron lasts much longer on surfaces than other variants – but disinfecting still works.

We can’t say whether longer Omicron survivability on surfaces relates to a greater risk of infection. But it is of public health significance to know that wiping down surfaces and hand sanitising with disinfectants are effective methods of killing live virus.


First published: April 2022.


One of the many challenges over the course of the past two years has been in understanding the importance of the different routes of transmission of the SARS-CoV-2 virus that causes COVID. Understanding the role of the different infection pathways plays a vital role in prioritising what we should be doing to prevent disease.

The World Health Organization advises COVID transmission mainly occurs during close personal contact and via aerosols in poorly ventilated or crowded spaces. But the WHO also acknowledges people can become infected by touching their eyes, nose or mouth after coming into contact with contaminated objects or surfaces.

Xtra | How does COVID-19 spread between people?

“We know that the disease is caused by the SARS-CoV-2 virus, which spreads between people in several different ways.

  • Current evidence suggests that the virus spreads mainly between people who are in close contact with each other, for example at a conversational distance. The virus can spread from an infected person’s mouth or nose in small liquid particles when they cough, sneeze, speak, sing or breathe. Another person can then contract the virus when infectious particles that pass through the air are inhaled at short range (this is often called short-range aerosol or short-range airborne transmission) or if infectious particles come into direct contact with the eyes, nose, or mouth (droplet transmission).
  • The virus can also spread in poorly ventilated and/or crowded indoor settings, where people tend to spend longer periods of time. This is because aerosols can remain suspended in the air or travel farther than conversational distance (this is often called long-range aerosol or long-range airborne transmission).
  • People may also become infected when touching their eyes, nose or mouth after touching surfaces or objects that have been contaminated by the virus. 

Further research is ongoing to better understand the spread of the virus and which settings are most risky and why.”

(Source: WHO)


Over time we’ve seen a reduced emphasis on preventing surface transmission and a greater focus on preventing person-to-person and aerosol transmission. This focus reflects how our understanding of transmission pathways has improved but it is still important to understand as much as we can about surface transmission.

Japanese research – published online and not yet reviewed by expert peers – examines how long the SARS-CoV-2 virus survives on skin and plastic. It investigates differences in survivability between the original Wuhan strain of the virus and subsequent variants – Alpha, Beta, Gamma, Delta and Omicron. The study claims to be the first to include Omicron in such side-by-side comparisons.

The researchers report SARS-COV-2 variants are able to survive on skin and plastic more than twice as long as the original Wuhan strain.

Of particular interest, the Omicron variant was found to survive on plastic for 193.5 hours and on skin for 21.1 hours. What’s inferred is that this longer survival on these surfaces contributes to Omicron’s increased infectivity, because there’s more likelihood of picking up viable virus from surfaces. But is that really likely?

The study has yielded interesting results, but has limitations that mean understanding the significance of these findings to the real world is difficult.

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How much virus?

The most important limitation of the study, and one that is shared with similar survivability studies published earlier in the pandemic, is generalising survival times in the laboratory to survival times in the real world. The main reason for this is the lack of a clear rationale for the decision on the amount of virus added to the surfaces tested.

This is important because the ability to detect viable virus on a surface over time is hugely influenced by the amount of virus seeded on the surface in the first place. Theoretically – and not to suggest the researchers in this study did this – you could contrive any survival time in the laboratory if you deposit enough virus at the outset.

How the amount of virus used in this study relates to how much virus might be deposited on a real-world surface by an infected person is not clear from the preprint article.



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The laboratory versus the real world

It’s also worth noting the study was completed under highly controlled laboratory conditions. It is reasonable to speculate real-world conditions would be harsher and more changeable – in terms of temperature and humidity – which may reduce virus survival times considerably.

On the plus side, researchers used the same set of conditions when assessing all variants so comparisons of survival times are likely to be a good indicator of relative environmental stability. Therefore the increased survival time of the Omicron variant compared to other variants is likely to indicate mutations that make it more resilient. This could contribute to its increased infectiousness – but the extent of any increase in the amount of surface transmission, the relative contribution of surface transmission to Omicron infections, and what causes this enhanced environmental stability are key questions that were beyond the scope of the study.

A secondary finding of the study suggests that in vitro (in other words, in test tubes or culture dishes) the Omicron variant was slightly more resistant to the disinfectant properties of ethanol than the Wuhan strain. But an evaluation on human skin in the laboratory demonstrated that a 15-second exposure to 35% alcohol was equally effective at inactivating the virus, regardless of the strain.

So the good news is that all of the variants seemed equally vulnerable to alcohol-based disinfectants when used on skin.

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In terms of which findings from this study are of public health significance, confirmation of the effectiveness of disinfectants may be the most important. At times criticised as hygiene theatre, disinfecting retains an important role in infection control practices.

Let’s be clear. These results don’t prove that we’re at increased risk of picking up the Omicron variant from surfaces. But what it does do is confirm that wiping down surfaces and hand sanitising with disinfectants are effective methods of killing any live virus that may be lurking there.

PMP Magazine





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— AUTHOR —

Dr Hassan Vally, Epidemiologist with experience in the analysis and interpretation of health data. Associate Professor, Faculty of Health, School of Health & Social Dev, Deakin University.
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