Senior Lecturer Supriya Munshaw, a technology transfer expert on the Carey Business School faculty, looks at the process involved in developing a possible vaccine for the coronavirus. 

As an expert in the commercialization of early-stage technologies, especially in the life science and medical device industries, Johns Hopkins Carey Business School Senior Lecturer Supriya Munshaw has monitored news of the vaccine development process during the COVID-19 pandemic.

In the following Q&A, Munshaw offers insights on the likely time frame for a coronavirus vaccine, the steps involved in developing one, the most promising candidates currently in the labs of biotech companies, and why, years after the MERS and SARS outbreaks, a coronavirus vaccine still has not been produced.

QUESTION: Some U.S. government officials are talking about a COVID-19 vaccine being ready in a year to 18 months. And some experts say that’s too soon if it’s going to be a safe vaccine. What do you think is a likely time frame?

SUPRIYA MUNSHAW: A year to 18 months is very optimistic. Typically, a safe and effective vaccine will take anywhere from 10 to 15 years for development if one is starting from scratch. The good news here is that coronaviruses aren’t novel, and there are groups that have already been working on such viruses for a while, especially since the MERS-CoV and SARS-CoV epidemics. So we are not starting from scratch, but even then 18 months is quite optimistic. Given the urgency of the situation, it is most likely that the manufacturer and the FDA will work together to balance the risks and benefits of the vaccine, such that the first vaccine we get may not be the most efficacious as long as it is safe. Since vaccines are given to healthy individuals, the safety requirements are quite high.

What steps are involved in developing a vaccine-like one for COVID-19? What are the particular challenges, and the costs?

As the Centers for Disease Control states on its website, vaccine development begins with an exploratory phase that involves identifying the appropriate antigens, or particles on the virus that can be used to elicit an immune response in the vaccine recipient. This is the basic research stage and can take anywhere from two to four years.

The next stage is pre-clinical studies, where the response to the identified antigen is observed in animal studies and in cell and tissue cultures, taking up to two years.

Next, we move on to the clinical trial stage, wherein Phase I the vaccine candidate is tested in a small group of people (about 20 to 30) to ensure safety, followed by Phase II, where a larger group of individuals (typically hundreds to thousands) is tested for safety, dosage, and administration. Finally, in Phase III the manufacturer would test the vaccine on thousands of people and look for the incidence of disease in their large sample. It takes time to recruit people, find sites for clinical trials, and establish protocols. Once all that is done, these large vaccine trials can go on for anywhere between one to five years, because you are waiting to see if your vaccinated group has a lower incidence of disease than your placebo group.

Again, given the urgency of this situation, a surrogate endpoint may be used such that the effectiveness of the vaccine is measured in the type and length of immune response it can elicit. But even then, you’re talking one to two for this last phase alone. Also, one must remember that there is a high failure rate at each stage, so just because we found an antigen at the exploratory phase doesn’t mean it will end up being a vaccine.

Another important aspect is scaling and manufacturing. Regulatory approval does not mean that enough vaccines can be manufactured quickly enough and then be available for the entire population. We often have flu vaccine shortages, even after planning those vaccines in advance.

Is it correct that a coronavirus vaccine has never been developed? And if that’s so, why wasn’t one developed after the MERS and SARS outbreaks of the past two decades?

There are currently no vaccines to protect against any of the coronaviruses. But the research that was done during the previous epidemics may have shortened at least the exploratory and pre-clinical stages for the COVID-19 vaccine. That’s why we already have vaccine candidates in Phase I. The MERS-CoV vaccine is still under development, but the disease is primarily contained in the Arab peninsula. And since SARS-CoV disappeared, a vaccine is no longer necessary.

Are there ways to speed up the vaccine-development process through a coordinated effort between public and private entities?

The Coalition for Epidemic Preparedness Innovations (CEPI) is coordinating a majority of the efforts of vaccine discovery throughout the globe. They arrange funding, partnerships, and collaboration efforts between governments, pharmaceutical companies, and research organizations to speed up this process. For example, they brought together Moderna, the biotech company with a lead vaccine candidate in Phase I trials, and the National Institute of Allergy and Infectious Diseases (NIAID) to conduct the trial.

What are the most promising vaccine candidates right now?

Several companies are working on vaccine candidates. For vaccines, we have candidates from Moderna, Inovio, CanSino Biologics, and Shenzen Genoimmune Medical Institute in the lead in Phase I trials. The others are in preclinical or exploratory stages. Interestingly, a trial is about to begin in Australia to test the effectiveness of the BCG vaccine against COVID-19. We know this vaccine is already safe, so that’s taken care of. It will be interesting to see if it is efficacious.

Do you see a coronavirus vaccination (once developed) becoming an annual occurrence, like influenza vaccinations?

It depends on how long the virus lasts and how fast it mutates. The SARS-CoV disappeared before a vaccine was ever developed. There are several hypotheses why this happened, but no one knows exactly why. The social distancing and isolation measures taken during that time probably played an important role in curbing the spread.

In terms of its mutation rate, influenza has lasted and has a very high mutation rate, so the virus changes rapidly, and several strains are often in circulation. So every year a vaccine is made after predictions are made of the strains that will likely be around that year. Even then, influenza vaccines don’t confer 100-percent protection, only because it is difficult to predict every single mutation.

 

 

 

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