Isolated small intestinal segments support auxiliary livers with maintenance of hepatic functions.

We determine here the functional integrity of auxiliary livers in containers fashioned from the small intestine. Liver microfragments from dipeptidyl peptidase 4 (DPP4)-deficient rats were transplanted into syngeneic normal animals with isolated intestinal segments characterized by mucosal denudation but intact vascular supply. Transplanted liver fragments were restored to confluent tissue with normal hepatic architecture and development of DPP4-positive vessels, indicating angiogenesis and revascularization. Auxiliary liver units expressed multiple hepatotrophic and angiogenic genes, and transplanted tissues remained intact for up to the 6-week duration of the studies with neither ischemic injury nor significant hepatocellular proliferation. Hepatic metabolic, transport and synthetic functions were preserved in auxiliary livers, including uptake and biliary excretion of (99m)Tc-mebrofenin in syngeneic recipients of liver from F344 rats, as well as secretion of albumin in allografted Nagase analbuminemic rats. This ability to produce functionally competent auxiliary livers in vascularized intestinal segments offers therapeutic potential for liver disease and genetic deficiency.

Heterotopic auxiliary liver in an isolated and vascularized segment of the small intestine in rats.

BACKGROUND: Development of an auxiliary liver is of interest for treating several conditions. To examine whether an isolated intestinal segment will support development of a heterotopic auxiliary liver, we studied the fate of liver microfragments in rats. METHODS: Small intestinal segments with intact circulation were created, and the small intestinal mucosa was removed. The intestinal segments were filled with autologous liver microfragments, and animals were studied for various periods. RESULTS: Initially, liver microfragments were engulfed by a serosanguineous exudate enriched in polymorphonuclear leukocytes, suggesting an early granulation-type response. Transplanted liver fragments were subsequently reorganized and showed morphologic integrity with typical hepatic lobular organization. Transplanted tissue contained healthy hepatocytes with abundant glycogen content. Transplanted liver remained intact in the small intestine for up to 40 days, although at later times portal fibrosis and bile ductular proliferation were apparent, despite the absence of cholestasis or hepatocellular abnormalities. In contrast, instillation of liver microfragments in the peritoneal cavity led to rapid loss of tissue integrity and phagocytotic clearance of transplanted tissue. CONCLUSIONS: Small intestinal segments denuded of the mucosal layer can support heterotopically transplanted liver. Further development of this auxiliary liver system will provide insights into mechanisms concerning neo-organogenesis and into potential therapeutic applications of heterotopic liver in specific diseases.