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Coronavirus vaccine: Here are the steps it will need to go through during development

Since humans haven't previously been exposed to the novel coronavirus (SARS-CoV-2), our bodies aren't well equipped to deal with being infected by it. A vaccine would allow the body to safely develop an immune response to Covid-19 that could prevent or control infection.
A vaccine must go through six crucial steps. PhotobyTawat/ Shutterstock
But it takes time to develop safe and effective vaccines – usually five to 10 years on average. Despite promising reports about potential coronavirus vaccines being developed worldwide, it could still take an estimated 12-18 months to develop one.

It’s becoming quicker to develop new vaccines than it was in the past as we can build on research from vaccines used for other diseases. During outbreaks, more resources and funding may also become available, which can speed up the process. Products might also be considered for use even before being formally granted licences to control the disease in severely affected areas during emergencies.

The development of a potential novel coronavirus vaccine is being partly led by experts who were already developing vaccines for other coronaviruses. This type of virus was identified as a possible cause of the next big pandemic as the other coronaviruses SARS and MERS have been responsible for two global outbreaks in the last 20 years. Research on vaccines for these coronaviruses was already undergoing clinical trials.

The first new vaccine to enter human trials for Covid-19 was developed by the US firm Moderna Therapeutics. About 35 other companies and academic institutions are also working on Covid-19 vaccines. Most are currently in “pre-clinical testing”, including one being developed by a team of researchers at the University of Oxford. The vaccine candidate was identified in January and is nearing the clinical testing phase.

During development, a vaccine needs to go through the following steps:

1. Basic understanding of the virus



In the past, most studies of human viruses looked at how the virus altered or affected human or animal cells in the lab. Scientists first identify the proteins and sugars on the surface of the viruses or infected cells, then study whether these proteins can be used to produce an immune response.

In the present case, this stage was made easier for researchers after Chinese scientists found and published the genetic sequence of novel coronavirus in January. Researchers worldwide have been able to identify the structure of proteins that make up the virus, create a genetic history of the family of viruses, and determine when the first human was infected. It also enabled diagnostic testing kits to be developed, and lets researchers identify potential treatment options.

2. Vaccine candidates



This may involve isolating the live virus before inactivating or weakening it and then determining whether this modified virus, which is known as a vaccine candidate, might produce immunity in people.

Sometimes the live virus is not part of the process. Instead, its genetic sequence is used to make the vaccine. The genetic sequence can also be used to make recombinant proteins, a vaccine production method that has been used before for vaccines like hepatitis B.

Researchers now know how to manufacture and test the relevant vaccine and check it has been made properly. They even know about likely doses, including how many doses will be needed to build immunity. This background knowledge speeds up the development of each new vaccine made using the same technology.

3. Pre-clinical testing



Initial safety testing is usually carried out in animals to give an idea of responses in humans. These are also used to see how effective the vaccine is at preventing the disease, and allows researchers to adapt the vaccine.

During an outbreak, different research groups often work together to speed up this process.

4. Clinical trials – testing in humans



This step is where many promising potential vaccines fail. There are three phases of a clinical trial:
  1. Testing on a few dozen healthy volunteers, looking at how safe the vaccine is, and if it has any adverse effects;

  2. Testing on several hundred people for efficacy (a “target population” who are ideally those most at risk of the disease);
  3. Testing on several thousand people for efficacy and safety.

Through these phases the vaccine needs to show it’s safe, leads to a strong immune response, and provides effective protection against the virus. During an outbreak, experimental vaccines may be used in severely affected populations if they’re at high risk of disease, before progressing to regulatory approval.

5. Regulatory approvals



If regulators have approved similar products before, approval can be accelerated – although this is not likely for Covid-19. Use of a vaccine before full licensure can be considered in a public health emergency.

6.Production



Once a vaccine has been produced at a small scale and passed safety tests, it can be used in clinical trials. However, significant manufacturing capacity, such as infrastructure, personnel and equipment, will be needed to produce large quantities of a vaccine for use. Quality control is also needed. All of these processes are very carefully monitored. Once licensed, policy must be developed to decide how to prioritise those who should be vaccinated, such as those in the most high-risk groups and locations.

Along the way, if any of these vaccine “candidates” are shown to be unsafe or ineffective, researchers must return to the laboratory to develop a new candidate. This is why vaccine development can be a long and uncertain process.

This article is republished from The Conversation under a Creative Commons license. Read the original article.The Conversation


SOURCE

The Conversation Africa
The Conversation Africa is an independent source of news and views from the academic and research community. Its aim is to promote better understanding of current affairs and complex issues, and allow for a better quality of public discourse and conversation.
Go to: https://theconversation.com/africa

About the author

Samantha Vanderslott, postdoctoral researcher in social sciences, University of Oxford; Andrew Pollard, professor of paediatric infection and immunity, University of Oxford, and Tonia Thomas, vaccine knowledge project manager
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