From: Spudboy100@aol.com
Date: Sat Mar 04 2000 - 09:52:22 MST
http://news.bbc.co.uk/hi/english/sci/tech/newsid_665000/665338.stm
Researchers have shown that cells can be "trained" to grow, one by one, along
a chemical trail.
This feat, conducted at Nottingham University, in the UK, is an important
step towards the goal of growing all tissues to order in the lab.
One day scientists believe they will be able persuade nerve cells to grow
again to repair spinal injuries. It might even be possible to take cells from
your bloodstream and coax them into growing a new organ for transplantation.
These are just two of the tantalising possibilities that are envisioned for
the interdisciplinary science of cell engineering. Scientists are anxious to
stress that it will be many years into the future before any such advances
are realised.
But understanding of the body's most basic units is increasing at a rapid
rate and it is not unreasonable to think that we could build organs and other
structures with cells in the same way that we build somewhat larger
structures with bricks and girders.
Synthetic materials
Dr Kevin Shakesheff, of the School of Pharmaceutical Sciences at Nottingham,
told BBC News Online: "Our own bodies are achieving amazing feats in
materials production every day. They produce materials that are far more
complex and perfectly formed than any current synthetic materials."
Dr Shakesheff is finding out how cells work by redesigning the extra-cellular
matrix, the scaffold that surrounds the cells and acts like a 'glue' to stick
the cells together.
"Our own cells produce a natural scaffold that provides a support structure
that holds tissues together. It is a complex mixture of biological molecules
that are organised into fibres and networks."
Not only is this scaffold a remarkable mechanical structure, it also
transmits data as well. "Incredibly, this structure not only supports the
cells but also signals to them, telling them how to repair damaged regions,"
the Nottingham researcher said.
Experimenting with cells, Dr Shakesheff and his colleagues have been able
show that they will line up along a chemical trail laid on a flat surface,
even when the trail is only as wide as a single cell. It is, believe the
researchers, just the beginning.
Donor shortages
"Being able to grow organs would mean we could be much more efficient in our
use of animal tissue in research. For example, if we could take one liver and
engineer the cells so that it would form 1000 identical mini-livers in the
laboratory, we could use small amounts of tissue to test thousands of drug
molecules.
"Ultimately, it would be wonderful to be able to take one donated human liver
and grow many engineered livers. Then we could overcome the problem of donor
shortages for liver transplantation."
Artificial organs grown using cell engineering are in the future. But before
that cell engineering is already providing some benefits for patients. Skin
grown in the lab is already available and used to treat burns victims or to
aid the healing of ulcers.
In the US, it has been possible to repair cartilage, a simple tissue that
contains only one type of cell and no blood vessels.
"It's exciting to work at the interface between biology and materials
science," Dr Shakesheff said.
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