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Scientists in the United States have using the blood of a man who deliberately built up immunity to snakebites by injecting himself with many different kinds of venom more than 800 times over 18 years.

The researchers showed "super antibodies" from the man's blood prevented toxic damage from neurotoxins found in the venoms of 19 different snake species, including mambas and cobras.

The new study may represent a welcome advance in antivenom production. Most current techniques are and involve injecting venom into , then harvesting antibodies from their blood.

Even so, new treatments are only part of the challenge of addressing the huge global problem of snakebites, which kill and maim hundreds of thousands of people around the world each year.

How was this new antivenom made?

describes himself as an "autodidact herpetologist and venom expert." He deliberately immunized himself with increasing doses of a number of snake venoms over an 18-year period, in a risky practice known as "" that we don't recommend. Some issues include: Friede , and immunity can .

Scientists took a small sample of Friede's blood and isolated the antibodies his immune system had developed to counteract the venoms. Next, they determined which of the antibodies were broadly effective against two important types of neurotoxins found in the venoms of , a family of species including cobras, mambas, and taipans.

The next step was to sequence the DNA from Friede's b-cells (a type of immune cell) that produced those two antibodies, then insert the genes responsible into a kind of virus called a bacteriophage. Then, using the modified bacteriophage and as mini factories, the researchers produced lots of the antibodies to use in their work.

How is antivenom usually made?

Antivenom is currently the only specific treatment available for snakebites. It is usually produced by first collecting venom (which is dangerous), then "hyper-immunizing" a domesticated animal (such as a horse) by routinely injecting it with small but increasing doses of that venom.

The horse's blood is extracted and its antibodies purified. The antibodies can then be injected into a snakebite victim, where they stick to toxins. This prevents the toxins from binding to targets in the body, and it also flags them for elimination by the immune system.

Traditional antivenoms have their problems. They can cause a severe allergic response known as an anaphylactic reaction (up to , in some countries). They may also have limited effectiveness due to differences in venom composition in snakes from different regions, or .

Broad-spectrum or "polyvalent" antivenoms are made by injecting horses with mixtures of venom from different species or different populations of snakes. However, the elevated antibody content per dose can increase the risk of adverse reactions.

Another challenge with mixed antivenoms is that some toxins that produce a strong immune response can suppress the production of antibodies against other equally dangerous toxins.

Why has it taken so long to improve antivenom production?

Antivenom production is not presently a very profitable business. The expenses are huge, there is limited economy of scale, the effectiveness of antivenoms can be , and the products have a short shelf-life and may have strict refrigeration requirements.

Snakebite is also a . The people most affected are those least able to afford treatment.

In Australia, the government has been supporting onshore antivenom production .

How else can we treat snakebite?

In the past decade, more precise, ethical, and potentially cost-effective methods of producing snakebite therapeutics have emerged. These include produced in the lab, as well as more conventional drugs.

For example, varespladib is one drug that has progressed to . It works extremely well against a major component found in many snake venoms worldwide.

Hybrid products containing "designer antibodies" and inhibitors like varespladib may be the .

The new "universal elapid antivenom" is in many ways an improvement on traditional antivenoms. However, there are still several deadly toxins present in elapid snake venoms it does not address, such as the coagulotoxin (blood-attacking) found in the venom of eastern brown snakes and taipans.

Why do we need antivenom?

Many people around the world live with the daily threat of being bitten by a venomous snake. Farmers, graziers, children walking barefoot to school, and many rural and remote workers in tropical and subtropical region, are at risk.

The World Health Organization deems snakebite a . It kills one person roughly every four minutes. As many as 2.7 million people are bitten annually, resulting in up to and around 400,000 people permanently maimed.

Will this new medicine reduce snakebite deaths?

When it comes to reducing the number of people who die from snakebite, novel snakebite treatments are undoubtedly important. However, developing new drugs is the relatively easy part of the problem.

A drug is only as good as your capacity to deliver it when and where it's needed. For snakebites, time is short and locations may be remote.

Far more attention and resources need to be devoted to all aspects of health infrastructure in the tropics, including the availability and distribution of life-saving medicines.

Prevention is also critical. Reducing the number of snakebites will reduce the burden on health infrastructure by saving lives and limbs.

To achieve this, we need far more resources devoted to research on snake behavior, snake ecology, human–snake interactions, and public education about snakes. Snakebite is the result of an ecological encounter between two organisms, and we know disappointingly little about the circumstances in which it occurs.

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