Date: Fri 23-Apr-1999
Date: Fri 23-Apr-1999
Publication: Hea
Author: CURT
Quick Words:
replacement-body-parts
Full Text:
HEALTH MONITOR: Researchers Take Big Step Toward Growing Replacement Body
Parts
By Paul Recer
Associated Press
WASHINGTON, DC -- In what may be a major step toward learning how to grow
replacement body parts, researchers in Baltimore have isolated from adult bone
marrow a master cell that can be induced to grow bone or cartilage.
A study published today in the journal Science reports that researchers at
Osiris Therapeutics extracted a single mesenchymal stem cell from bone marrow
and then grew it into a colony of more than a million cells that could be
directed to produce either bone, cartilage or fat.
If the technique proves successful, researchers predict that precursor cells
for bone could be used to replace tissue lost to cancer, osteoporosis, injury
or dental disease.
Experts said the study is an important achievement for the new and rapidly
expanding field of stem cell research.
"The fact that they can [isolate] a precursor cell like that, and direct it to
produce specific cell types, is quite an advance," said Dr James A. Thomson of
the University of Wisconsin, a noted pioneer in stem cell research. "It may be
that such cells can eventually be used for therapy and that would be quite
exciting." The study using adult stem cells is important also because it
avoids the controversy of using stem cells from embryos, said Dr Mark F.
Pittenger, who led the team of Osiris researchers.
Stem cells are the body's building blocks. Some, such as pluripotent stem
cells, come only from embryos and their use in research is opposed by many
people. Other stem cells, such as the mesenchymal cells used by Osiris, are
produced in adults.
But only the pluripotent stem cells from embryos are thought to be capable of
growing into any tissue in the body. The mesenchymal stem cells are the parent
lines for bone, cartilage, fat, tendon and muscle.
The Osiris work helps move stem cell research from the laboratory toward the
clinic, said Dr David J. Anderson, a Howard Hughes Medical Institute stem cell
researcher at the California Institute of Technology.
"If you want to use stem cells to replace damaged tissue, you have to first
know how to differentiate those cells in the lab dish before you put them into
a patient," he said.
In their work, Osiris researchers led by Pittenger grew a single mesenchymal
stem cell through more than 20 generations to create about a million cells.
The researchers then altered the culture medium and added proteins that caused
the specimens to grow into cell families, or lineages, that would produce
bone, tendon or fat, Pittenger said. Other work under way may lead to
producing muscle cell lines.
"We've arrived at conditions that allow us a very strong degree of control,"
said Pittenger. "When we direct these cells to the [cartilage] lineage, almost
all of the cells grow to that lineage."
That means it's very likely that researchers will eventually be able to inject
specific types of cells into patients, which then would grow into replacement
bone, tendon or muscle, he said.
Laboratory research on animals is already underway and human studies may be
possible in three years, he said.
Research in rabbits and dogs already has shown that gaps in leg bone caused by
surgery, such as for cancer, can be filled in with tissue grown in the body
from stem cells.
Animal studies also are underway to determine if stem cells injected into the
heart can replace scar tissue caused by heart attack.
Congress has banned federal financing of research using human embryos, and
some lawmakers oppose a National Institutes of Health plan to possibly pay for
embryonic stem cell research.
But Thomson, one of the first to isolate stem cells from human embryos, said
that although researchers have proven that some types of stem cells can be
obtained from adults, there is still a scientific need for embryonic stem cell
research. There are no known adult stem cells for some critical organs, such
as kidney, heart and lung, he noted. If replacements are to be grown for these
parts, Thomson said, it would require embryonic stem cell research.