In 30 years if we have a Great stroke association pushing this line of research we might have some useful therapy for strokies.
http://www.alphagalileo.org/ViewItem.aspx?ItemId=128826&CultureCode=en
Scientists have used sugar-coated scaffolding to move a step closer
to the routine use of stem cells in the clinic and unlock their huge
potential to cure diseases from Alzheimer’s to diabetes.
Stem cells have the unique ability to turn into any type of human
cell, opening up all sorts of therapeutic possibilities for some of the
world’s incurable diseases and conditions. The problem facing scientists
is how to encourage stem cells to turn into the particular type of cell
required to treat a specific disease.
But researchers at the University of Manchester’s School of Materials
and Faculty of Life Sciences have developed a web-like scaffold, coated
with long-sugar molecules, that enhances stem-cell cultures to do just
this. The scaffold is formed by a process known as ‘electrospinning’,
creating a mesh of fibres that mimic structures that occur naturally
within the body.
The team’s results – presented in the Journal of Biological Chemistry
- are particularly promising, as the sugar molecules are presented on
the surface of the fibres, retaining structural patterns important in
their function. The sugars are also ‘read’ by the stem cells grown on
the surface, stimulating and enhancing the formation of neuronal cell
types.
Lead author Dr Catherine Merry, from Manchester’s Stem Cell
Glycobiology group, said: “These meshes have been modified with long,
linear sugar molecules, which we have previously shown play a
fundamental role in regulating the behaviour of stem cells. By combining
the sugar molecules with the fibre web, we hoped to use both
biochemical and structural signals to guide the behaviour of stem cells,
in a similar way to that used naturally by the body. This is the Holy
Grail of research into developing new therapeutics using stem cell
technology.”
The group anticipate that the combination of the sugar molecules with
the fibre web will aid both the growth of stem cells and the formation
of different cell types from the stem cell population.
Possible applications include tissue engineering, where the meshes
could support cells differentiating to form bone, liver or blood
vessels, for example. The meshes also have potential therapeutic
implications in the treatment of diseases such as multiple
osteochondroma (MO), a rare disease creating bony spurs or lumps caused
by abnormal production of these sugar molecules.
Co-author Professor Tony Day, from Manchester’s Wellcome Trust Centre
for Cell-Matrix Research, said: "This cross-faculty collaboration
provides exciting new possibilities for how we might harness the
adhesive interactions of extracellular matrix to manipulate stem cell
behaviour and realise their full therapeutic potential."
The study was funded by the Medical Research Council and Engineering
and Physical Sciences Research Council Human Frontiers Scientific
Programme.
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