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Ever since bacteria existed, viruses have also existed.
They have been Evolutionarily competing for billions of
years. Today, this means that every bacterium you can
find will have viral enemies specialized to attack that
bacterium.
Human diseases can be sorted into various categories,
of
which the two biggest categories are diseases caused by
bacteria, and diseases caused by viruses (because
human
bodies are mostly made of living cells, and the prime
target of viruses are living cells).
Now it happens that viruses are often so specialized that
they cannot attack organisms that fall outside a certain
range. And so a human is in no danger of catching a
disease caused by the tobacco mosaic virus, for
example.
It also happens that ordinary bacterial cells are even-
more-
different from human cells, than are plant cells different
from human cells (look up "prokaryotes" and
"eukaryotes"
some time). This means we can be quite sure that a
virus
that targets a particular ordinary bacterium is not going
to
be a threat to human cells.
Therefore, suppose you catch a disease caused by a
bacterium, such as tuberculosis. What we need to do is
find the perfectly natural and already-existing viruses
that
target that bacteria. If we need to tweak them a bit to
make the viruses more effective against that bacteria,
using already-existing genetic-engineering techniques,
fine; we know how to do that.
It is possible we might also want to add a special marker
to the viruses, so that the human immune system won't
target them. It depends on how fast the immune-
response
is; the viruses only need enough time in the body to
locate
and invade the disease-causing bacteria.
So, we simply dose the patient with the viruses, and in
reasonably short order the disease-causing bacterium
will
be overcome by its natural enemies, and the patient will
be cured.
Old viruses
http://www.microbio...oldest-virus-known/
For anyone interested. [Vernon, Apr 05 2013]
Common organisms
http://www.eolss.ne...C03/E6-51-04-03.pdf
There is stuff here about prokaryotes, eukaryotes, archaea, and viruses [Vernon, Apr 05 2013]
Genetic Engineering
http://www.ucsusa.o...ing-techniques.html
We are manipulating viruses in various ways right now. [Vernon, Apr 05 2013]
Tuberculosis
http://textbookofba...t/tuberculosis.html
More info about that bacterium. [Vernon, Apr 05 2013]
More About Viral Range
http://www.independ...solved-2125675.html
The AIDS virus targets a particular human cell. Some people have variant DNA such that this cell cannot be targeted by AIDS.... [Vernon, Apr 05 2013]
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Annotation:
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Only them? Why not medical practitioners
everywhere else? Please keep in mind that this Idea
is mostly about FINDING useful bacteriophages,
simply because we can be sure they exist. |
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I was going to say what [Bigsleep] said, but what
[Bigsleep] said. |
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Using 'phage as antibacterials crops up every few
years, and always fizzles out. I'm not sure why,
but I would guess that: |
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(a) most phage have evolved to infect bacteria in
the environment. Killing off bacteria in a human
host is probably a dead-end for the phage. |
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(b) just 'adding a marker' to the phage to elude
the immune system is unlikely to be
straightforward. |
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(c) //make the viruses more effective against that
bacteria, using already-existing genetic-
engineering techniques, fine; we know how to do
that.// No, we don't. |
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(d) It's pretty straightforward for a bacterium to
evolve resistance to phage, because phage
infection and replication is a complex business. It
happens readily on a Petri dish - you almost
immediately get phage-resistant bacteria. |
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starts humming it's the Phage of Aquarius... |
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I also saw a documentary about Russian (or was it Georgian?) use of bacteriophage therapy. Probably the same one. |
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The reasons given for its limited use elsewhere were 1) squeamishness (the assumption that the public would be put off by the idea of being deliberately exposed to viruses) and greed (it is relatively cheap, and would cut into the profits of the established medical industries - although the level of hypocrisy there is quite staggering). |
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It was also suggested that bacteriophages are particularly useful for infections that are isolated from the circulatory system, and therefore hard to reach with systemic antibiotics, whereas antibiotics may be more effective for systemic infections. |
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By the way, I once read a metapedagogical article describing a demonstration of the selection, multiplication, and isolation of bacteriophages, able to be carried out by a competent high school biology teacher in an afternoon. You need little more than a bacteria culture, an incubator, a sub-micron filter, and a fly. |
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