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. From a clinical perspective, skin-derived MOs are particularly appealing as they could readily be obtained from a skin biopsy taken from the same target patient. In the present work we have investigated the angiogenesis-inducing capacity of rabbit and human skin-derived micro-organs in vitro and in vivo. Rabbit skin MOs were implanted into homologous adult rabbits and human skin MOs were encapsulated and implanted into xenogenic mice. Skin-derived MOs, as lung-derived MOs, were found to secrete a whole array of angiogenic factors and to induce a powerful angiogenic response when implanted back into animals. We believe the approach presented suggests a novel, efficacious and simple approach for therapeutic angiogenesis.

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. RESULTS: In vitro LMOs maintain normal physiological and biochemical functions including oxygen consumption, glucose metabolism, conversion of ammonia to urea, secretion of albumin and de novo transcription of genes coding for albumin and clotting factors. Inside the aLIVE bioreactor, LMOs also display sustained oxygen consumption, glucose metabolism and transcription of albumin and clotting factors IX and X, when connected both to normal and to 92% hepatectomized rats. Survival of 92% hepatectomized rats was 40% longer following a single 4-h treatment with aLIVE, compared to untreated animals. CONCLUSIONS: An extra-corporeal liver device, aLIVE, which provides key liver functions, has been developed. When tested in 92% hepatectomized rats, aLIVE improved the clinical condition and significantly increased survival time of the treated rats.