Liver Scaffolds Support Survival and Metabolic Function of Multilineage Neonatal Allogenic Cells.

Organ scaffold bioengineering is currently limited by the inability to effectively repopulate the scaffold with appropriately distributed functional cells. We examined the feasibility of a decellularized liver scaffold to support the growth and function of multilineage allogenic cells derived from either adult or neonatal liver cells. Cell slurries from neonatal and adult rat livers containing hepatocytes, cholangiocytes, and endothelial cells were introduced into decellularized adult rat liver scaffolds via the bile duct. Recellularized grafts were perfused with cell growth medium through the portal vein for 7 days. Concurrently, the same cell slurries were incubated on culture dishes. Albumin levels were measured from graft perfusates and cell culture media. Immunofluorescent assays were used to verify the colocalization of cholangiocytes, hepatocytes, endothelial cells, and Kupffer cells in the recellularized grafts by using anti-CK7, anti-hepatocyte antigen, anti-CD34, and anti-CD68, respectively. More robust albumin production was detected in the perfusate of scaffolds recellularized with a neonatal liver cell slurry compared with those with an adult liver cell slurry. The perfusates from all recellularized grafts showed increasing albumin concentration over 7 days; higher levels were detected in the constructs compared with the cell culture. Scaffolds seeded with a neonatal liver cell slurry showed the presence of hepatocytes, cholangiocytes, endothelial cells, and Kupffer cells. Results demonstrated the superiority of neonatal allogenic cells over adult cells of the same origin, possibly because of their pluripotent behavior. Liver bio-scaffolds supported the growth of four different liver cell lines. Recellularized grafts exhibited preserved functionality as demonstrated by albumin production, and constructs seeded with a neonatal cell slurry demonstrated proliferation on Ki-67 assay, thus representing a promising model for a transplantable construct.

Recellularization via the bile duct supports functional allogenic and xenogenic cell growth on a decellularized rat liver scaffold.

Recent years have seen a proliferation of methods leading to successful organ decellularization. In this experiment we examine the feasibility of a decellularized liver construct to support growth of functional multilineage cells. Bio-chamber systems were used to perfuse adult rat livers with 0.1% SDS for 24 hours yielding decellularized liver scaffolds. Initially, we recellularized liver scaffolds using a human tumor cell line (HepG2, introduced via the bile duct). Subsequent studies were performed using either human tumor cells co-cultured with human umbilical vein endothelial cells (HUVECs, introduced via the portal vein) or rat neonatal cell slurry (introduced via the bile duct). Bio-chambers were used to circulate oxygenated growth medium via the portal vein at 37C for 5-7 days. Human HepG2 cells grew readily on the scaffold (n = 20). HepG2 cells co-cultured with HUVECs demonstrated viable human endothelial lining with concurrent hepatocyte growth (n = 10). In the series of neonatal cell slurry infusion (n = 10), distinct foci of neonatal hepatocytes were observed to repopulate the parenchyma of the scaffold. The presence of cholangiocytes was verified by CK-7 positivity. Quantitative albumin measurement from the grafts showed increasing albumin levels after seven days of perfusion. Graft albumin production was higher than that observed in traditional cell culture. This data shows that rat liver scaffolds support human cell ingrowth. The scaffold likewise supported the engraftment and survival of neonatal rat liver cell slurry. Recellularization of liver scaffolds thus presents a promising model for functional liver engineering.