We generated a animal model of bile acid malabsorption using rats that
underwent resection of the distal 25% of their small intestine (ileum).
This resulted in significant losses of bile acids with the fecal
excretions in these animals. We subsequently harvested ileal stem cell
clusters from neonatal donors, removed the mucosa from a segment of
proximal intestine (jejunum) and implanted the stem cell clusters into
the debrided segment of jejunum. After four weeks the animals had
developed a functional "neo-mucosa". We inserted the "neo-ileal"
segment into continuity as a substitute ileum. Postoperative
measurements of fecal bile acid excretion showed that we were able to
reverse the malabsorption syndrome in this model. This was the first
reported neo-mucosa-based treatment of a malabsorption syndrome in
vivo. We subsequently studied different biodegradable PGA and PLLA
scaffoldings to generate bioengineered intestinal mucosa. We implanted
these materials into omentum of rats and were able to identify a PGA/
PLLA hybrid material on which engraftment rates of 36 % of the
available surface area could be achieved. Most recently we developed a
novel technique that permits direct observation of cell-biomaterial
interactions after implantation into omentum or intestine in vivo. This
method will help to optimize engraftment conditions for stem cell
clusters on biomaterials.
Key words:
Problems or questions regarding this site should be directed to
the organiser