11 on candidate progenitors in pancreatic ducts It is of interes

11 on candidate progenitors in pancreatic ducts. It is of interest that peribiliary glands have the highest density at the hepato-pancreatic ampulla and common hepatic duct at the hilum, sites at which cholangiocarcinomas typically occur.31 The common embryologic origin of intestine and biliary tree opens new perspectives on certain pathologies such as ulcerative colitis and sclerosing cholangitis or in the similarities between colorectal adenocarcinoma and cholangiocarcinoma.32 Comparisons of progenitor stem/populations in biliary tree versus pancreas could provide explanations for the known distinctions in regenerative capacity Midostaurin of liver versus pancreas and

could reveal if, as we suspect, organogenesis of liver and pancreas is ongoing throughout CCI-779 in vitro life. These speculations are to be addressed with future studies. Biliary tree tissue is available from fetal, neonatal, pediatric, and adult organs, including surgical materials (e.g., from cholecystectomy), tissue routinely discarded from donor livers (gallbladder, cystic ducts, periampular region), or pancreata (periampular region, bile duct) rejected for use in transplantation and made available for research. Thus, the extrahepatic biliary tree is an ideal and available source of stem/progenitor cells useful

for regenerative medicine programs for liver, bile duct, and pancreas, including for treatment of diabetes. Additional Supporting Information may be found in the online 上海皓元 version of this article. “
“The unique ability of the liver to regenerate itself has fascinated biologists for years and has made it the prototype for mammalian organ regeneration. Harnessing

this process has great potential benefit in the treatment of liver failure and has been the focus of intense research over the past 50 years. Not only will detailed understanding of cell proliferation in response to injury be applicable to other dysfunction of organs, it may also shed light on how cancer develops in a cirrhotic liver, in which there is intense pressure on cells to regenerate. Advances in molecular techniques over the past few decades have led to the identification of many regulatory intermediates, and pushed us onto the verge of an explosive era in regenerative medicine. To date, more than 10 clinical trials have been reported in which augmented regeneration using progenitor cell therapy has been attempted in human patients. This review traces the path that has been taken over the last few decades in the study of liver regeneration, highlights new concepts in the field, and discusses the challenges that still stand between us and clinical therapy. It is now well accepted that there are two physiological forms of regeneration in the liver as responses to different types of liver injury (Fig. 1).

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