SCIENTISTS GROW LEG MUSCLE FROM CELLS IN A DISH
A team of researchers
from Italy, Israel and the United Kingdom has succeeded in generating mature,
functional skeletal muscles in mice using a new approach for tissue
engineering. The scientists grew a leg muscle starting from engineered cells
cultured in a dish to produce a graft. The subsequent graft was implanted close
to a normal, contracting skeletal muscle where the new muscle was nurtured and
grown. In time, the method could allow for patient-specific treatments for a
large number of muscle disorders.
The results are
published in EMBO Molecular Medicine.
The scientists used
muscle precursor cells -- mesoangioblasts -- grown in the presence of a
hydrogel (support matrix) in a tissue culture dish. The cells were also
genetically modified to produce a growth factor that stimulates blood vessel
and nerve growth from the host. Cells engineered in this way express a protein
growth factor that attracts other essential cells that give rise to the blood
vessels and nerves of the host, contributing to the survival and maturation of
newly formed muscle fibres. After the graft was implanted onto the surface of
the skeletal muscle underneath the skin of the mouse, mature muscle fibres
formed a complete and functional muscle within several weeks. Replacing a
damaged muscle with the graft also resulted in a functional artificial muscle
very similar to a normal Tibialis anterior.
Tissue engineering of
skeletal muscle is a significant challenge but has considerable potential for
the treatment of the various types of irreversible damage to muscle that occur
in diseases like Duchenne muscular dystrophy. So far, attempts to re-create a
functional muscle either outside or directly inside the body have been
unsuccessful. In vitro-generated artificial muscles normally do not
survive the transfer in vivo because the host does not create
the necessary nerves and blood vessels that would support the muscle's
considerable requirements for oxygen.
"The morphology
and the structural organisation of the artificial organ are extremely similar
to if not indistinguishable from a natural skeletal muscle," says Cesare
Gargioli of the University of Rome, one of the lead authors of the study.
In future,
irreversibly damaged muscles could be restored by implanting the patient's own
cells within the hydrogel matrix on top of a residual muscle, adjacent to the
damaged area. "While we are encouraged by the success of our work in
growing a complete intact and functional mouse leg muscle we emphasize that a
mouse muscle is very small and scaling up the process for patients may require
significant additional work," comments EMBO Member Giulio Cossu, one of
the authors of the study. The next step in the work will be to use larger
animal models to test the efficacy of this approach before starting clinical
studies.
Comments
Post a Comment