Tuesday, October 27, 2020

A great little video explaining vaccines today.

Look up this great little video...https://edhub.ama-assn.org/jn-learning/video-player/18547208   
(Transcript)

Researchers are racing towards the goal of delivering a safe and effective vaccine that could curb the COVID-19 pandemic. And production scale-up for some of the vaccine candidates has already started. Consider the US government's Operation Warp Speed:

[Robert Redfield, MD:] You know I spent time in the military, so I like that concept of focusing on a mission. And the mission is to have a vaccine available to the American public by January 2021. We're on an accelerated course here that I've not witnessed before.

One of the reasons why this vaccine search is breaking records is because most of the frontrunners--and nearly all the vaccines in the Warp Speed portfolio--are based on next-generation technologies that can be developed and scaled up more quickly than conventional vaccines. These new technologies are genetic vaccines and viral vector vaccines.

These technologies--also called platforms--have been in development for decades. A lot of the investment in them has specifically focused on their potential to combat emerging infectious diseases. And COVID-19 is putting that potential to the test. Let's take a look at how they work, and how they're different from conventional vaccines.

In these pictures from 1953, (locate the video above) the scientists are developing an influenza vaccine. They're injecting viruses into fertilized eggs, which are then incubated to allow the virus to replicate within the eggs. Growing the virus is necessary for developing live attenuated virus and whole inactivated virus vaccines--these are the two classic approaches where the virus is either weakened or killed. These approaches are still in use today, although different cell cultures are most often used instead of eggs.

But since those photos were taken, huge advancements in the field of vaccinology have introduced multiple other approaches to developing vaccines. Here are the major types of vaccines being deployed against COVID-19. Unlike the two classic vaccines, these four types, which include the next-generation platforms as well as more conventional approaches, don't require researchers to handle any of the actual virus.

[Anthony S. Fauci, MD:] The Chinese, when they made the diagnosis and showed it was a coronavirus, they put the sequence up on a public database. So today you don't need the virus in hand. All you need is a sequence.

This is that published sequence for SARS-CoV-2. Because of previous research into SARS-1 and MERS, researchers knew that they could focus initial attention on the S protein, also known as the spike.

The spike is the protein that studs the surface of the SARS-CoV-2 virus. It's also necessary for viral entry into human cells. So a vaccine that exposes the immune system to just the spike should induce a protective immune response. And that's the strategy behind the majority of COVID-19 vaccine candidates, which use both next-generation and more conventional approaches. The scientific way to put this is that the spike is the target antigen in these vaccines.

Where the next-generation vaccine platforms differ from those more conventional vaccines is how the immune system is exposed to the spike, or the antigen. Conventional vaccines contain the antigen itself. Now compare this to genetic vaccines:

[Paul A. Offit, MD:] You can take just really to the genetic material, either as messenger RNA or DNA, that then codes for that spike protein. So the person makes the protein. You're not giving them the protein. You're giving them the genetic material that then instructs them how to make that spike protein, to which they make an antibody response that hopefully is protective.

Two types of genetic vaccines are being investigated for COVID-19: mRNA and DNA. mRNA needs to reach the cytoplasm of host cells, while DNA needs to enter the nucleus. Then this genetic material gets taken up by the cell's machinery, and the cell expresses the spike protein. These spike proteins are then recognized by the immune system, hopefully stimulating a protective response.

These two candidates in the Warp Speed portfolio are mRNA vaccines. This one was developed by Moderna and the NIH, and was the first candidate to enter clinical trials in the US, with this one from Pfizer and BioNTech following not long after. Naked mRNA cannot easily cross cell membranes passively, and it's very susceptible to degradation. So in both of those vaccines, the mRNA coding for the spike is encased in small carrier molecules called lipid nanoparticles. Both of these candidates are currently in Phase 3 trials.

Now let's look at viral vector vaccines.

The basic idea is that you take another virus and replace its genetic payload with the sequence coding for the antigen, in this case the spike protein. The goal is to induce immunity against the target antigen--the added genetic cargo. But these vaccines may also induce immunity to the vector itself. The viruses used as vectors are attenuated, or weakened, so they cannot cause disease. A lot of different viruses have been developed as vectors, and they can be broadly categorized into two buckets: replication-defective and replication-competent.

Let's start with replication-defective vectors. A very popular choice among the potential COVID-19 vaccines is adenoviruses, like these two candidates, which are both in phase 3 clinical trials. Adenoviruses are common pathogens that typically cause mild cold or flu-like symptoms. This candidate, which was developed by the University of Oxford and AstraZeneca, uses a chimpanzee adenovirus 5, while this candidate from Johnson & Johnson, uses a human adenovirus 26. In both vaccines the adenovirus vector carries the DNA coding for the spike to the host cells, but it doesn't display it on its surface. Once the virus infects a host cell, it delivers the DNA to the nucleus; the cell's machinery then expresses the spike using this DNA, similarly to what we saw with genetic vaccines. And because these adenovirus vectors are replication-defective, after the virus infects a cell, no more viruses are produced.

Now let's take a look at replication-competent virus vectors. This Warp Speed vaccine that's being developed by Merck in partnership with IAVI is an example; it uses recombinant vesicular stomatitis virus. In humans, wild-type VSV is usually asymptomatic or causes a mild flu-like illness. The researchers replaced part of its RNA sequence with RNA coding for the spike. Unlike the adenoviruses, this rVSV vector does display the spike on its surface. After the rVSV infects a host cell, again the cell's machinery expresses the spike; but because rVSV is replication competent, this platform mimics a real viral attack more closely.

This is the same platform that Merck used to develop a vaccine for Ebola, which was approved by the FDA last year. But so far that Ebola vaccine is the only viral vector vaccine that has gotten FDA approval. Adenovirus vectors, which are much further ahead in COVID-19 trials, have never been used in an FDA-approved vaccine, and there are likewise no FDA-approved vaccines that use DNA or mRNA platforms.

So despite the investment in these approaches, and the media attention they've been getting, it's far from certain they will curb COVID-19.

[Paul A. Offit, MD:] I think the reason that you hear the most about the mRNA vaccine or the DNA vaccine or these replication-defective adenovirus vaccines is because they're the easiest to make. So I think that's why you hear about them first, but I just would want to warn people that, you know, what you want is you want the best and safest vaccine, which may not necessarily be the first vaccines.

And the only way to find out is through rigorous trials. Before COVID-19 hit, these platforms were extensively studied in animal models, and some candidates were tested in phase 1 and 2 trials, but until now phase 3 data has been lacking.

[Paul A. Offit, MD:] This is the -- if the proof is in the pudding, the pudding is a phase three trial, a large, prospective, placebo-controlled, safety and efficacy trial.

And platforms do not save time in clinical trials. No matter the approach, rigorous safety and efficacy testing is required. The safety standard for vaccines is very high compared to other interventions, because vaccines are potentially given to millions of healthy people.

If the phase 3 trials are done correctly, there will be enough data about both safety and efficacy in diverse demographic groups to allow health officials, doctors and individuals to make informed decisions. Until that data has been adequately analyzed, it's too early to say which approaches, either novel or conventional, are the safest and most effective.

A handful of vaccines are already in phase 3 trials, so some data will be available soon; and at that point--not before--we might find out if these next-generation platforms have lived up to their potential for combating emerging infectious diseases. 

Immunizations

How Are Vaccines Made and Why Do They Work? 

In their book Vaccines: What Every Parent Should Know, Dr. Paul Offit and Dr. Louis Bell take the complex question of how vaccines are made and answer it in a way we can all understand:

Vaccines are made by taking viruses or bacteria and weakening them so that they can’t reproduce (or replicate) themselves very well or so that they can’t replicate at all. Children given vaccines are exposed to enough of the virus or bacteria to develop immunity, but not enough to make them sick. There are four ways that viruses and bacteria are weakened to make vaccines:

  • Change the virus blueprint (or genes) so that the virus replicates poorly. This is how the measles, mumps, rubella, and varicella vaccines are made. The virus blueprint is changed  by a technique called cell culture adaptation [adapting a virus   to grow in specialized cells grown in the lab instead of the cells it normally grows in]. Because viruses can still, to some extent, make copies of themselves after cell culture adaptation (and therefore are still alive), they are often referred to as live, attenuated (or weakened) viruses.

  • Destroy the virus blueprint (or genes) so that the virus can’t replicate at all. This is how the “killed” polio vaccine (or polio shot) is made. Vaccine virus is made by treating polio virus  with the chemical formaldehyde. This treatment permanently destroys the polio genes so  that the virus can no longer replicate.

  • Use only a part of the virus or bacteria. This is how the Hib, hepatitis B, and (in part) pertussis vaccines are made.    Because the viral or bacterial genes are not present in the vaccine, the viruses or bacteria can’t replicate.

  • Take the toxin that is released from the bacteria, purify it, and kill it so it can’t do any harm. Some bacteria cause disease  not by replicating but by manufacturing harmful proteins  called toxins. For example, bacteria like diphtheria, tetanus, and pertussis (whooping cough) all cause disease by producing toxins. To make vaccines against these bacteria, toxins are purified and killed with chemicals (such as formaldehyde). Again, because bacterial genes are not part of the vaccine, bacteria can’t replicate.

Vaccine Boosters

Because the immune response from some vaccines may decrease over time, vaccines known as “boosters” are sometimes given  to restore the immune response against that particular germ. Protective immunity lasts longer when boosters are given.

Tetanus boosters, for example, are recommended every 10 years starting at age 10 or 11. A study published in May 2002 by the Annals of Internal Medicine revealed that millions of Americans are vulnerable to tetanus and diphtheria infections because their booster shots have not been kept up to date.

On other fronts in the vaccine field, scientists are trying to find new ways of producing vaccines, particularly using biotechnology and genetic engineering. These new methods would make it unnecessary to produce large quantities of the dangerous pathogens to make vaccines.

Passive Immunity

In addition to natural or “vaccine-induced” immunity to diseases, there is also “passive” immunity. Passive immunity occurs when someone is injected directly with large quantities of antibodies that are ready to immediately fight a specific virus or bacteria.

These antibodies go to work immediately against any antigen or pathogen. There is no waiting period, as is needed by some vaccines, before sufficient antibodies are produced. However, protection from these antibody injections is temporary. Once the antibodies are cleared from the body, no new antibodies are made.

Doctors use this approach to treat people who have been exposed to hepatitis B, hepatitis A and rabies. Babies born to mothers with hepatitis B are immediately treated with hepatitis B antibodies (called HBIG or hepatitis B immune globulin) and  simultaneously immunized against hepatitis B   to prevent any infection that might have occurred during the birth process.

Next Page: Monitoring Vaccines for Safety

Previous Page: The Immune System vs. Germs

 

Important disclaimer: The information on pkids.org is for educational purposes only and should not be considered to be medical advice. It is not meant to replace the advice of the physician who cares for your child. All medical advice and information should be considered to be incomplete without a physical exam, which is not possible without a visit to your doctor.

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