Skin-derived micro-organs induce angiogenesis in rabbits.

We have recently reported an alternative cell therapy approach to induce angiogenesis. The approach is based on small organ fragments--micro-organs (MOs)--whose geometry allows preservation of the natural epithelial/mesenchymal interactions and ensures appropriate diffusion of nutrients and gases to all cells. We have shown that lung-derived MOs, when implanted into hosts, transcribe a wide spectrum array of angiogenic factors and can induce an angiogenic response that can rescue experimentally induced ischemic regions in mice.

Development of a scaled up liver device incorporating cryo-preserved pig liver micro-organs.

Background/aims: Currently there is no effective therapy for most patients with fulminant or end stage liver disease.

Methods: Pig liver micro-organs (LMOs), which preserve liver micro-architecture and ensure a maximal 150-200mum distance from a source of nutrients and gases have been prepared and a method to cryo-preserve them has been developed. A new scaled-up extra-corporeal liver device termed aLIVE-H in which LMOs are exposed to liver-like hemodynamic conditions has also been developed.

Liver micro-organs transcribe albumin and clotting factors and increase survival of 92% hepatectomized rats.

Background/aims: Currently there is no effective non-surgical therapy for most patients with fulminant or end stage chronic liver disease.

Methods: We have prepared rat liver micro-organs (LMOs), which preserve the liver micro-architecture and ensure that no cell is more than 150 microm away from a source of nutrients and gases. The function of LMOs has been evaluated in vitro and in a new extra-corporeal liver device termed aLIVE in which LMOs are exposed to liver-like hemodynamic conditions.