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World's Tiniest Test Tubes Get Teensiest
Corks
Scientists have found a way to "cork" infinitesimally
small nano test tubes. The goal is a better way to deliver
drugs, for example, for cancer treatment. Scientists
want to fill the teeny tubes with drugs and inject them
into the body, where they will seek diseased or cancerous
cells, uncork and spill their therapeutic contents in
the right place.
"After making the nano test tubes, we saw the potential
for them to be used for drug delivery vehicles, but
because they are open at one end it would be like trying
to ship wine in a bottle without a cork," said
University of Florida chemistry professor Charles Martin.
"You have to cork it, which is what we have accomplished."
While chemotherapy works against many cancers, it can
cause severe side effects such as nausea, temporary
hair loss and blood disease. To make the chemo hit only
the cancerous cells, Martin and scientists elsewhere
have spent recent years experimenting with drug-carrying
nanotubes or nanoparticles.
"Nano" stems from nanotechnology, the fast-growing
science of making objects or devices that approach molecular
dimensions. One nanometer equals one-billionth of a
meter.
The goal of the nano test tubes is a
better way to deliver drugs
The approach makes sense for attacking
diseased cells while bypassing healthy ones, but it
also poses challenges. For one thing, the nanotubes
must recognize their target, a problem scientists are
attacking by tweaking their chemistry to make it respond
to the unique chemistry of cancer cells. The tubes also
must be biologically benign. Martin says a method for
making nanotubes he pioneered, template synthesis, allows
manufacturers to use biodegradable material, such as
the polylactides that compose biodegradable sutures.
Additionally, the tubes also had to be closed at one
end to form the classic test tube shape, a problem Martin
and his group solved in research published in 2004.
To "cork" the test tubes in the latest research,
the researchers applied an amino chemical group to the
mouth of the tubes and an aldehyde chemical group to
the corks. The two groups are complementary, so they
bond with one another.
Billions of nanotubes could fit on a postage stamp.
So, said Martin, "we don't put individual caps
in each nanotube the way corking machines do for bottles."
Instead, the scientists immerse a small mesh that holds
millions of amino-modified nanotubes, all precisely
lined up in a grid pattern, into a solution imbued with
millions of the corks. Brownian motion - what happens
when minute particles immersed in a fluid move about
randomly - takes care of the rest. The corks simply
float around, then slip into the mouths of the tubes
as they encounter them.
The diameter of the tubes is about 80 nanometers, or
80-billionths of a meter. Even though they are tiny,
each tube can hold about 5 million drug molecules. "Each
tube packs a real punch in terms of the number of drug
molecules it can deliver," Martin said.
Sang Bok Lee, an assistant professor of chemistry and
biochemistry at the University of Maryland, works on
similar research. He said scientists have proposed capping
the tubes using chemical interactions between the drugs
and the tubes. But that might not work because the tube
could leak before it reaches its target.
"I strongly agree that Professor Martin's proposed
strategy will be one of the ideal solutions for the
problem of controlling drug uptake and release,"
he said in an e-mail.
The UF scientists aren't there yet. There's no easy
way to unlock the amino chemical group from the aldehyde
chemical group. So while Martin says there are some
promising possibilities, he and his colleagues have
their next job cut out for them: figuring out how to
uncork the tubes.
Visit www.ufl.edu
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