Monday, August 31, 2020

CBC CORONA VIRUS VACCINE TRACKER.

How close are we to a vaccine for COVID-19?

A look at the different vaccines under development, and where they are in the pipeline

Total number of vaccine candidates

Pre-clinical evaluation
142
Phase 1
11
Phase 2
13
Phase 3
6
Approved*
1
*Russia approved a vaccine before Phase 3 testing.
Note: This section has been changed so each candidate is only included in its latest stage of development.
An effective vaccine against the coronavirus that causes COVID-19 is everyone's hope for a real return to normal life. More than 100 teams of scientists around the world are working to develop and test a vaccine against the virus SARS-CoV-2 as quickly as possible. They're employing a huge variety of strategies and technologies, including some that have never been used in an approved vaccine before.
"It's a very fascinating and kind of impressive effort," said Dr. Lynora Saxinger, an infectious disease specialist at the at the University of Alberta in Edmonton.
"It's absolutely crucial."
Even in countries that have had a devastating number of deaths from COVID-19, there is nowhere close to a level of "herd immunity" within the population preventing the disease from spreading exponentially if we go back to normal levels of social interaction, she said.

How far are we from the first SARS-CoV-2 vaccine?

Typically, it takes an average of more than 10 years for a vaccine to get from pre-clinical development (including animal testing) through three phases of clinical (human) trials to market registration.
The process has been fast-tracked for COVID-19. The first human vaccine trials began in March, just two months after the virus and disease were identified. And different phases of human trials are being run in an overlapping fashion instead of one at time — for example, Phase 2 might begin just a few weeks after the start of a six-month Phase 1 trial. 
Still, officials, including the World Health Organization, have reassured the public that no steps will be skipped. That’s why Russia drew fierce criticism when it announced in mid-August that it was granting regulatory approval to a vaccine developed by Gamaleya Research Institute of Epidemiology after less than two months of human testing, with only two incomplete Phase 1 trials registered with the WHO.
Canada has a notably large number of vaccine candidates registered with the World Health Organization — at least eight.

Candidate vaccines in clinical trials

Note: Because of changes to the World Health Organization candidate vaccine document, we are no longer tracking phases that are completed and in progress. Instead we are marking each phase that the candidate has entered.
Developer
Pre-clinicalevaluation
Phase 1Phase 2Phase 3Approved
Sinovac Inactivated
Complete
Complete
Complete
Complete
Not started
Beijing Institute of Biological Products/Sinopharm Inactivated
Complete
Complete
Complete
Complete
Not started
Wuhan Institute of Biological Products/Sinopharm Inactivated
Complete
Complete
Complete
Complete
Not started
University of Oxford/AstraZeneca Non-replicating viral vector
Complete
Complete
Complete
Complete
Not started
BioNTech/Fosun Pharma/Pfizer RNA
Complete
Complete
Complete
Complete
Not started
Moderna/NIAID RNA
Complete
Complete
Complete
Complete
Not started
CureVac RNA
Complete
Complete
Complete
Not started
Not started
Bharat Biotech Inactivated
Complete
Complete
Complete
Not started
Not started
Institute of Medical Biology, Chinese Academy of Medical SciencesInactivated
Complete
Complete
Complete
Not started
Not started
Anhui Zhifei Longcom/Institute of Microbiology, Chinese Academy of Sciences Protein subunit
Complete
Complete
Complete
Not started
Not started
Kentucky Bioprocessing Protein subunit
Complete
Complete
Complete
Not started
Not started
Novavax Protein subunit
Complete
Complete
Complete
Not started
Not started
CanSino Biologics/Beijing Institute of Biotechnology Non-replicating viral vector
Complete
Complete
Complete
Not started
Not started
Janssen Non-replicating viral vector
Complete
Complete
Complete
Not started
Not started
Arcturus/Duke-NUS RNA
Complete
Complete
Complete
Not started
Not started
Cadila Healthcare DNA
Complete
Complete
Complete
Not started
Not started
Genexine Consortium DNA
Complete
Complete
Complete
Not started
Not started
Inovio/International Vaccine Institute DNA
Complete
Complete
Complete
Not started
Not started
Osaka University/AnGes/Takara Bio DNA
Complete
Complete
Complete
Not started
Not started
Clover Inc./GSK/Dynavax Protein subunit
Complete
Complete
Not started
Not started
Not started
Medigen Vaccine Biologics Protein subunit
Complete
Complete
Not started
Not started
Not started
Instituto Finlay de Vacunas Protein subunit
Complete
Complete
Not started
Not started
Not started
Vaxine Pty Ltd/Medytox Protein subunit
Complete
Complete
Not started
Not started
Not started
University of Queensland Protein subunit
Complete
Complete
Not started
Not started
Not started
Medicago  Virus-like particles
Complete
Complete
Not started
Not started
Not started
Gamaleya Research Institute Non-replicating viral vector
Complete
Complete
Not started
Not started
Complete
ReiThera Non-replicating viral vector
Complete
Complete
Not started
Not started
Not started
Merck/Themis Bioscience/Institut Pasteur Replicating viral vector
Complete
Complete
Not started
Not started
Not started
Imperial College London RNA
Complete
Complete
Not started
Not started
Not started
People's Liberation Army Academy of Military Sciences/Walvax BiotechRNA
Complete
Complete
Not started
Not started
Not started
Mediphage Bioceuticals/University of Waterloo  DNA
Complete
Not started
Not started
Not started
Not started
University of Manitoba  Non-replicating viral vector
Complete
Not started
Not started
Not started
Not started
VIDO-InterVac, University of Saskatchewan  Protein subunit
Complete
Not started
Not started
Not started
Not started
University of Alberta  Protein subunit
Complete
Not started
Not started
Not started
Not started
University of Manitoba  Replicating viral vector
Complete
Not started
Not started
Not started
Not started
Western University  Replicating viral vector
Complete
Not started
Not started
Not started
Not started
Entos Pharmaceuticals  DNA
Complete
Not started
Not started
Not started
Not started
IMV Inc.  Protein subunit
Complete
Not started
Not started
Not started
Not started
With data from the World Health Organisation

Multiple vaccines on the horizon?

Most vaccine candidates that make it to preclinical testing never make it to market (about 94 per cent fail, a 2013 study found). But in this case, with so many different vaccines under development, there may still end up being multiple vaccines for the coronavirus, possibly using different strategies, Saxinger predicts.
There are a number of potential advantages if that happens:
  • They'd be using different ingredients and manufacturing facilities and wouldn't be competing for resources — allowing for more vaccine production.
  • Different vaccines have different pros and cons. Some vaccines require more doses to be effective than others, while ease of manufacturing, testing and distribution varies.
  • Some vaccines may be more suitable for some populations than others, due to factors such as age or genetics.
Stephen Barr is associate professor of microbiology and immunology who is part of a COVID-19 vaccine development team at at Western University in London, Ont. He noted that the "best" vaccine in the end may not be best for everybody. "But the second one might be, for those that don't respond, right? So it's always good to have these backup vaccines as well or vaccines that can be used in parallel around the world."
Many teams are working on a COVID-19 vaccine using technologies that have been in development for decades, but have never yet been approved for wide-scale human use, such as DNA, RNA, and viral-vector vaccines. Many of those candidates are considered very promising, garnering huge amounts of funding and billions of preorders from some countries. In August, Canada announced deals to reserve millions of doses of RNA vaccines from Moderna and Pfizer.

Vaccine types:

Whole virus vaccines

These are the most traditional types of vaccine. They've been used for a long time, and most of us have had these kinds of vaccines.

Inactivated virus

In this case, the virus is grown in large quantities in cells, and then killed, often with a chemical, which is usually formaldehyde, but heat or radiation can also be used. Two kinds of flu vaccines are made this way, grown in either chicken eggs or mammalian cells.
Pros
  • Unlike live virus vaccines, it can even be given to people with weakened immune systems.
Cons
  • It doesn't lead to as strong an immune response as a live virus. Several doses, including boosters at regular intervals, are usually necessary.
  • It requires the virus to be grown in large quantities and that can take time and may not be as easy to scale up as other kinds of vaccines.
Clinical trials and Canadian candidates
Developer
Pre-clinicalevaluation
Phase 1Phase 2Phase 3Approved
Sinovac
Complete
Complete
Complete
Complete
Not started
Beijing Institute of Biological Products/Sinopharm
Complete
Complete
Complete
Complete
Not started
Wuhan Institute of Biological Products/Sinopharm
Complete
Complete
Complete
Complete
Not started
Bharat Biotech 
Complete
Complete
Complete
Not started
Not started
Institute of Medical Biology, Chinese Academy of Medical Sciences
Complete
Complete
Complete
Not started
Not started
All candidate vaccines in clinical trials

Live, attenuated virus

In this case, viruses are also grown in cells, but instead of being killed they're genetically "weakened" so they can't infect cells and reproduce as effectively. Traditionally, this was done by getting the virus to grow in and adapt to an environment different than the one they normally infect. That's the approach used for vaccines such as varicella (chicken pox) or yellow fever. The SARS-CoV-2 vaccine candidates of this type use a high-tech genetic engineering approach called "codon deoptimization," where the virus is rebuilt from scratch, incorporating targeted mutations that weaken it. None of these vaccine prototypes for COVID-19 have made it to human trials.
Pros
  • Similar to real infection and usually provides long-lasting protection — sometimes lifelong — after one dose.
Cons
  • May not be suitable for people with weakened immune systems, long-term health problems, or people who've had organ transplants.
  • Live viruses need to be refrigerated, making them more difficult to transport and unusable in countries without access to refrigeration.
  • The virus must be grown in large quantities. That can take time and it may not be easy to scale up.
Clinical trials and Canadian candidates
There are currently no candidates in clinical trials for this vaccine type.
All candidate vaccines in clinical trials

Vaccines that target part of a virus

These types of vaccines don't contain entire viruses. They present parts of viruses, such as proteins or sugars, to your immune system to help it learn to recognize the virus and build an immune response.
In the case of SARS-CoV-2, the part of the virus that's typically targeted is the spike or "S" protein — the projections on its outer coat that make it look like a crown under a microscope ("corona" means "crown.") That's the protein the virus uses to bind to human cells, allowing it to enter. 
What varies among different vaccine candidates is the way they make the spike protein and get it into the body — it may be injected directly, transported by a "carrier" virus that doesn't cause disease, or it may be manufactured by the human body itself using instructions encoded in DNA or RNA.

Protein subunit

With this type of vaccine, the protein is made outside the body. Traditionally, this was done by breaking whole viruses into pieces using detergent or a solvent such as ether. However, this can now be done with "recombinant" genetic technology, where the gene for a protein is inserted into another organism to grow the protein in large quantities. 
Pros
  • Can be produced more quickly than live vaccines.
Cons
  • Doesn't generate as strong an immune response as whole virus vaccines. A compound called an adjuvant needs to be included to boost a patient's immune response.
  • Can't be scaled up as quickly as production of RNA or DNA vaccines.
Clinical trials and Canadian candidates
Developer
Pre-clinicalevaluation
Phase 1Phase 2Phase 3Approved
Anhui Zhifei Longcom/Institute of Microbiology, Chinese Academy of Sciences
Complete
Complete
Complete
Not started
Not started
Kentucky Bioprocessing
Complete
Complete
Complete
Not started
Not started
Novavax
Complete
Complete
Complete
Not started
Not started
Clover Inc./GSK/Dynavax
Complete
Complete
Not started
Not started
Not started
Medigen Vaccine Biologics
Complete
Complete
Not started
Not started
Not started
Instituto Finlay de Vacunas
Complete
Complete
Not started
Not started
Not started
Vaxine Pty Ltd/Medytox
Complete
Complete
Not started
Not started
Not started
University of Queensland
Complete
Complete
Not started
Not started
Not started
VIDO-InterVac, University of Saskatchewan 
Complete
Not started
Not started
Not started
Not started
University of Alberta 
Complete
Not started
Not started
Not started
Not started
IMV Inc. 
Complete
Not started
Not started
Not started
Not started
All candidate vaccines in clinical trials

Virus-like particles

These are a special class of subunit vaccines, where the proteins are self-assembled into artificial particles that are intended to look like viruses to the human immune system. They bind to and enter cells like a virus, which is different from the way individual protein subunits do.
Some vaccines on the market that use VLPs include vaccines for HPV (human papilloma virus) and Hepatitis B.
Pros
  • Produce a stronger immune response than regular subunit vaccines.
  • Production is much faster than for traditional vaccines.
Cons
  • Ensuring stability and purification can add to production time.
  • Can be hard to produce in large quantities.
Clinical trials and Canadian candidates
Developer
Pre-clinicalevaluation
Phase 1Phase 2Phase 3Approved
Medicago 
Complete
Complete
Not started
Not started
Not started
All candidate vaccines in clinical trials

Non-replicating viral vector

Viral vectors are "carrier" viruses that don't cause the disease you're vaccinating against, such as COVID-19, but can be engineered to carry a piece of viruses such as SARS-CoV-2. Non-replicating viral vectors are viruses that have been genetically engineered so they can't replicate and cause disease. Then they're further modified to produce the protein for the disease you want, such as the coronavirus spike protein, and injected into the body to provoke an immune response.
The viruses used by COVID-19 vaccine candidates include adenoviruses, MVA (modified vaccinia ankara, a weakened pox virus), parainfluenza and rabies.
Pros
  • Generates more powerful immune response than subunit proteins.
  • Some don't have to be stored at very low temperatures (according to China-based company CanSino), so they're viable for use in resource-limited tropical areas.
Cons
  • People who have already been exposed to the viral vector, such as adenovirus, may be resistant.
  • Harder to scale up than protein or DNA because a virus still needs to be grown.
  • Because each virus can only infect one cell, large quantities of the virus need to be grown and injected, adding to production time.
Clinical trials and Canadian candidates
Developer
Pre-clinicalevaluation
Phase 1Phase 2Phase 3Approved
University of Oxford/AstraZeneca
Complete
Complete
Complete
Complete
Not started
CanSino Biologics/Beijing Institute of Biotechnology
Complete
Complete
Complete
Not started
Not started
Janssen
Complete
Complete
Complete
Not started
Not started
Gamaleya Research Institute
Complete
Complete
Not started
Not started
Complete
ReiThera
Complete
Complete
Not started
Not started
Not started
University of Manitoba 
Complete
Not started
Not started
Not started
Not started
All candidate vaccines in clinical trials

Replicating viral vector

These are "carrier" viruses that can replicate in the body, but are either weakened or don't cause any symptoms in humans. Like non-replicating viral vectors, they're modified to produce a protein from the virus you want to protect against, such as the spike protein from SARS-CoV-2.
The replicating viral vectors used in COVID-19 vaccine candidates include weakened versions of influenza and measles, as well viruses that cause animal diseases such as horsepox and VSV (Vesicular stomatitis virus).
Pros
  • Closely mimics a real infection and induces a stronger, more widespread immune response.
  • Because it can replicate, much less virus needs to be injected as a vaccine to induce a good response.
  • That also means less needs to be grown to produce the vaccine, cutting the cost, time and labour needed compared to whole virus and non-replicating viral vector vaccines.
Cons
  • Requires more testing before approval than protein or nucleic acid-based vaccines, adding to development time.
  • Needs to be stored and transported at cool temperatures to keep the virus alive, which may make it harder to distribute in warmer parts of the developing world.
Clinical trials and Canadian candidates
Developer
Pre-clinicalevaluation
Phase 1Phase 2Phase 3Approved
Merck/Themis Bioscience/Institut Pasteur
Complete
Complete
Not started
Not started
Not started
University of Manitoba 
Complete
Not started
Not started
Not started
Not started
Western University 
Complete
Not started
Not started
Not started
Not started
All candidate vaccines in clinical trials

RNA

With RNA vaccines, what's injected into the body is simply the genetic instructions to make a viral protein such as the spike protein. Cells in your body then use the instructions to make the protein inside the body for your immune cells to see and respond to.
Pros
  • No virus is needed to make the vaccine, cutting production time compared to conventional vaccines.
Cons
  • Don't always produce a strong immune response compared to whole viruses, and may require adjuvants.
Clinical trials and Canadian candidates
Developer
Pre-clinicalevaluation
Phase 1Phase 2Phase 3Approved
BioNTech/Fosun Pharma/Pfizer
Complete
Complete
Complete
Complete
Not started
Moderna/NIAID
Complete
Complete
Complete
Complete
Not started
CureVac
Complete
Complete
Complete
Not started
Not started
Arcturus/Duke-NUS
Complete
Complete
Complete
Not started
Not started
Imperial College London
Complete
Complete
Not started
Not started
Not started
People's Liberation Army Academy of Military Sciences/Walvax Biotech
Complete
Complete
Not started
Not started
Not started
All candidate vaccines in clinical trials

DNA

This is very similar to the RNA vaccines, except that DNA is used instead of RNA. It's often delivered as a ring of DNA called a plasmid.
That enters the cell, and the cell produces the virus protein. 
Pros
  • Quick and relatively inexpensive to manufacture in large quantities.
  • Shelf stable and doesn't require freezing in storage and transport.
  • Easy to switch to different gene/virus, and you can combine multiple in single vial.
Cons
  • Requires adjuvants for a good response.
Clinical trials and Canadian candidates
Developer
Pre-clinicalevaluation
Phase 1Phase 2Phase 3Approved
Cadila Healthcare
Complete
Complete
Complete
Not started
Not started
Genexine Consortium
Complete
Complete
Complete
Not started
Not started
Inovio/International Vaccine Institute
Complete
Complete
Complete
Not started
Not started
Osaka University/AnGes/Takara Bio
Complete
Complete
Complete
Not started
Not started
Mediphage Bioceuticals/University of Waterloo 
Complete
Not started
Not started
Not started
Not started
Entos Pharmaceuticals 
Complete
Not started
Not started
Not started
Not started
All candidate vaccines in clinical trials

Lots of Canadian candidates

As mentioned earlier, Canada currently has at least seven vaccine candidates under development, with Canadian involvement in the development of some others. Saxinger said that maximizes the impact of the expertise we have, from work on diseases such as Ebola, SARS and MERS.
Developing and producing vaccines here at home could also give Canada more control over when Canadians can get the vaccine, and who can be prioritized, given that there will likely be huge demand for the vaccine from countries around the world.
"I don't think we want to rely on others, hoping they will remember us," said Volker Gerdts, director and CEO of VIDO-Intervac at the University of Saskatchewan in Saskatoon, one of the Canadian teams developing a SARS-CoV-2 vaccine. The current race for a vaccine underscores why it's important for countries like Canada to be self-sufficient, he added.

Canadian vaccine candidates

Developer
Pre-clinicalevaluation
Phase 1Phase 2Phase 3Approved
Medicago  Virus-like particles
Complete
Complete
Not started
Not started
Not started
Mediphage Bioceuticals/University of Waterloo  DNA
Complete
Not started
Not started
Not started
Not started
University of Manitoba  Non-replicating viral vector
Complete
Not started
Not started
Not started
Not started
VIDO-InterVac, University of Saskatchewan  Protein subunit
Complete
Not started
Not started
Not started
Not started
University of Alberta  Protein subunit
Complete
Not started
Not started
Not started
Not started
University of Manitoba  Replicating viral vector
Complete
Not started
Not started
Not started
Not started
Western University  Replicating viral vector
Complete
Not started
Not started
Not started
Not started
Entos Pharmaceuticals  DNA
Complete
Not started
Not started
Not started
Not started
IMV Inc.  Protein subunit
Complete
Not started
Not started
Not started
Not started
Correction: A previous version of this story said RNA vaccines require adjuvants. In fact, this is not always the case, as RNA itself can act as an adjuvant. 

Note: Because of changes to the World Health Organization candidate vaccine document, we will no longer split Phase 2 and Phase 3 into two stages.

Monday, August 24, 2020

WHAT I WANT!

GENTLE PEOPLE:

 What I want is a government of honest people willing to work for the citizens of Canada.
A democratically elected group of people not beholding to corporate bosses and who honestly want to help their fellow human beings to survive the ride on this planet.
 I do not want people who dominate and control for the sake of dominating and controlling. 
 I do not want people with vested interests running our government. 
 I want gentle and imaginative people willing to create new ideas and concepts liberating our youth from the status quo.

 As a citizen, I need people who have been trained from childhood to be compassionate and caring and highly skilled in avoiding environmentally destructive projects. We do not need billion dollar highways and bridges catering to fossil fuel burning vehicles. What we do need are better schools for the purpose of creating a cleaner and safer environment for everybody! Why not spend several billion dollars on new concept schools?


 Many of our present school buildings continue to represent the industrial status quo of the recent past. Schools were created quickly after world war 11 in order to indoctrinate working-class children to serve industrial and often polluting companies. This made a few corporate bosses very rich very quickly! What if our present leaders ordered the creation of large capacity Green Houses filled with flowering plants and comfortable plexiglass partitioned computer rooms for children to sit and learn Biology and Botany and Science in general. Warm buildings partially covered in Solar Panels. What if we filled sky scrapers with Green Houses filled with plants?


 Many of today's elementary and high school buildings are dangerously old and archaic. Not all but many are square brick and mortar buildings containing rooms with faulty air ventilators and windows that stick. If you think about it, the word "class" explains the thinking of our ancestors. A few centuries ago, schools were the prerogative of the rich and powerful and the buildings they created represented the best architecture of the times. It was high society who placed their children into special schools for learning and for training. The better the schools the more social and economic power they created for the upper class.


 In the past private schools became expensive training grounds for the upper class rich. The poor lower classes were not so lucky. The children of working class people were placed in boxy over-crowded public school buildings and in 1953 some elementary school classes contained as many as Forty Five children per classroom. We became known as the baby boom generation and some of us rebelled against the strict rules and the harsh discipline imposed on us.


 The difficult class curriculums were filled with tests and examinations meant to weed out the slower students and many creative minds did drop out of school. Personal motivation was absent and competition was fostered in the classroom by peer group pressure and by a cruel systemic discipline.  Both the buildings and the old standards of teaching created revolt among the students of the 60's but sadly, both continue to exist today!


 We now live in Canada 2020 and it is passed the time we created something beautiful! It is time we disposed of past dogmas and prejudices and power politics that benefit only a few corporate bosses. After the second World War  many Canadian grade schools and high schools were packed full of children and today I call on all Baby Boomers still alive who attended those schools, to once again revolt and to create a change for the better. Our present schools do not need up-grading, they need total replacement!

P.S. We also need kids to work in the farm fields because we are running out of poor Mexicans!

DO YOU CONSIDER YOURSELF INTELLIGENT? GET OVER IT!

     Do you consider yourself intelligent? If yes, how about explaining the concept of eternity?....... Not easy, is it?  I am a perpetual s...