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Biofisika
dari gigitan ular: bagaimana ular
berbisa melakukan penyuntikkan racun ke luka korban ?
Biophysics of snakebites: How do venomous snakes inject venom into
victim's wound?
Date:
May 16, 2011
Source:
Technische Universitaet Muenchen
Summary:
Most snakes do not inject venom into their victims
bodies using hollow fangs, contrary to common misconceptions. The fact is that
most snakes and many other venomous reptiles have no hollow fangs. Physicists
have now uncovered the tricks these animals use to force their venom under the
skin of their victims
........................
Most snakes do not inject venom into their victims bodies
using hollow fangs, contrary to common misconceptions. The fact is that most
snakes and many other venomous reptiles have no hollow fangs. Physicists have
now uncovered the tricks these animals use to force their venom under the skin
of their victims.
For years
Professor Leo von Hemmen, a biophysicist at the TU Muenchen, and Professor
Bruce Young, a biologist at the University of Massachusetts Lowell, have been
researching the sense of hearing in snakes. While discussing the toxicity of
their snakes, it dawned on them that only few snakes inject their venom into
their victims' bodies using hollow fangs. Yet, even though the vast majority of
venomous reptiles lack hollow fangs, they are effective predators.
Only around
one seventh of all venomous snakes, like the rattlesnake, rely on the trick
with the hollow fang. The vast majority has developed another system. A typical
representative of this class is the mangrove pit viper, Boiga dendrophila.
Using its twin fangs, it punches holes into the skin of its victims. The venom
flows into the wound between the teeth and the tissue. But there is an even
easier way: many fangs simply have a groove the venom flows along to enter the
wound.
The
researchers asked themselves how this simple method could be so successful from
an evolutionary perspective, considering that bird feathers, for example,
should be able to easily brush away any venom flowing along an open groove. To
get to the bottom of this mystery, they investigated the surface tension and
viscosity of various snake venoms. The measurements showed that snake venom is
amazingly viscous.
The surface
tension is high, about the same as that of water. As a result, the surface
energy pulls the drops into the fang grooves, where they then spread out. In
the course of evolution, snakes have adapted to their respective preferred prey
using a combination of optimal fang groove geometry and venom viscosity. Snakes
that prey on birds developed deeper grooves to keep the viscous venom from
being brushed away by bird feathers.
The
researchers also found an answer to the question of how snakes manage to ferry
the venom well under the skin of their prey. After all, only there can it
unfold its deadly effect. Here too, snakes developed a trick in the course of
evolution: When a snake attacks, the fang grooves and the surrounding tissue
form a canal. Just like blotting paper, the tissue sucks the venom through this
canal. And snake venom has a very special property to facilitate this effect: Just
like ketchup, which becomes significantly more fluid upon shaking, the sheer
forces that arise from the suction cause the venom to become less viscous,
allowing it to flow through the canal quickly as a result of the surface
tension.
Scientists
refer to substances with these characteristics as non-Newtonian fluids. These
have a very practical consequence for snakes: As long as there is no prey in
sight, the venom in the groove remains viscous and sticky. When the snake
strikes, the venomous "tears" flow along the groove -- just like wine
along a glass -- and into the wound, where the venom takes its lethal effect.
The German
Federal Ministry for Education and Research funded portions of this work via
the Bernstein Center for Computational Neuroscience Munich. Professor van
Hemmen is a member of the Excellence Cluster Cognition for Technical Systems
(CoTeSys).
Story
Source:
The above
story is based on materials provided by Technische Universitaet Muenchen. Note: Materials may be edited
for content and length.
Journal
Reference:
- Bruce Young, Florian Herzog, Paul Friedel, Sebastian Rammensee, Andreas Bausch, J. van Hemmen. Tears of Venom: Hydrodynamics of Reptilian Envenomation. Physical Review Letters, 2011; 106 (19) DOI: 10.1103/PhysRevLett.106.198103
