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After successfully treating four Ebola patients last year, Emory University in Atlanta is now leading a government-funded project that will use blood from survivors of the deadly virus to test a novel way of treating infectious disease.
Faster and cheaper
Traditional vaccines boost the immune system's response to infections. The new project will inject people with genetic material, such as DNA or RNA, in hopes of spurring a person's own cells to make specific antibodies capable of fighting Ebola or other pathogens.
"The person's body is the factory," said Dr. James Crowe of Vanderbilt University, one of the collaborators on the project. "It's a cool idea."
Experts say the method, if proven to be safe and effective, would be faster and cheaper than conventional drug production and could potentially be used to treat illnesses such as seasonal flu or malaria.
Read: Ebola vaccine trials begin in Liberia
Antibodies are typically grown in large vats of mammal cells or in some cases, tobacco plants, such as Mapp Biopharmaceutical's experimental Ebola treatment ZMapp.
The Defence Advanced Research Projects Agency (DARPA), the Pentagon's elite research arm, has awarded Emory up to $10.8 million over three years to direct the project.
It will include research teams at the U.S. Centres for Disease Control and Prevention, the U.S. Army Medical Research Institute of Infectious Diseases (USAMRIID), and several academic research labs including the University of Wisconsin-Madison, Rockefeller University, Vanderbilt and Scripps Research Institute.
Getting access to blood samples from survivors of the current Ebola outbreak in West Africa has been challenging, but Emory has a distinct advantage in having treated a small number of patients on U.S. soil.
Two approaches
All four of its former patients agreed to take part in the programme, said Rafi Ahmed, director of the Emory Vaccine Centre, who is leading the effort.
Ahmed and colleagues intend to isolate antibodies made by these patients in response to the Ebola virus, and through a series of experiments in animals, identify the most effective ones for fighting off an Ebola infection.
The approach is unrelated to an experimental treatment provided to several Ebola patients in the United States, which involved transfusions of blood plasma from Ebola survivors.
Read: How will the world prepare for future pandemics like Ebola?
Researchers will take two approaches. In one, they will produce large quantities of Ebola-fighting antibodies that could be infused into patients intravenously, a conventional approach known as passive immunisation.
Protection using this method has a short half life of about two to three weeks, and the antibodies require refrigeration, which is not always available in countries fighting an infectious disease outbreak.
That is why the team is also testing the new method for making protective drugs based on DNA or RNA, rather than the older vaccine technology using killed or weakened viruses to stimulate an immune response, a process that can take several months to manufacture.
"In this method, we are trying to go in as silently as possible," bypassing the immune response, which may not always work, and directly providing the recipe for a highly effective antibody, said Col. Daniel Wattendorf, programme director at DARPA who came up with the new strategy.
Temporary effect
Wattendorf said the effort is based on prior, early stage research with drugmakers Novartis and Sanofi looking at whether they could make vaccines out of ribonucleic acid, or RNA.
"What was particularly intriguing about RNA was that it has no chance of integrating into the human genome," he said. The effect was temporary.
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Initially, the technology was being developed in hopes of protecting soldiers from seasonal flu or germs that cause diarrhoea on the battlefield, but the Ebola outbreak presented an opportunity to accelerate the research.
To succeed, researchers will need to identify an effective delivery system to carry the genetic instructions into the body and learn how to quickly identify the most protective antibodies. The goal is to get the process down to 90 days for most diseases, Wattendorf said.
The group is in the process of characterising several Ebola antibody candidates to find which are the most potent, Ahmed said. At that point, the researchers and DARPA will seek out drug company partners.
Testing in people could begin within two years, with the goal of having a better weapon for the next Ebola outbreak.
Read more:
Ebola: timeline of a ruthless killer
It is the beginning of the endgame for Ebola
WHO needs to repair reputation after bungling Ebola
Image: Blood transfusion from Shutterstock
