Vascular endothelial growth factor-releasing scaffolds enhance vascularization and engraftment of hepatocytes transplanted on liver lobes.

Hepatocyte transplantation within porous scaffolds (HT) is being explored as a treatment strategy for end-stage liver diseases and enzyme deficiencies. One of the main issues in this approach is the limited viability of transplanted cells because vascularization of the scaffold site is either too slow or insufficient. We now address this by enhancing scaffold vascularization before cell transplantation via sustained delivery of vascular endothelial growth factor (VEGF), and by examining the liver lobes as a platform for transplanting donor hepatocytes in close proximity to the host liver.

Liver tissue engineering within alginate scaffolds: effects of cell-seeding density on hepatocyte viability, morphology, and function.

Tissue engineering with three-dimensional biomaterials represents a promising approach for developing hepatic tissue to replace the function of a failing liver. Herein, we address cell seeding and distribution within porous alginate scaffolds, which represent a new type of porous biomaterial for tissue engineering. The hydrophilic nature of the alginate scaffold as well as its pore structure and interconnectivity enabled the efficient seeding of hepatocytes into the scaffolds, that is, 70-90% of the initial cells depending on the seeding method.

Selective separation of cis-trans geometrical isomers of beta-carotene via CO2 supercritical fluid extraction.

We investigated a novel method for the selective separation of beta-carotene isomers from a freeze-dried powder of the algae Dunaliella bardawil using supercritical fluid extraction. The separation method relies on the different dissolution rate of the 9Z and all-E isomers of beta-carotene in SC-CO(2). At first, the equilibrium solubility of the two isomers in SC-CO(2) was determined at the extraction conditions of 44.