Decellularization of the Human Liver to Generate Native Extracellular Matrix for Use in Automated Functional Assays with Stellate Cells.

With the incidence of liver disease on the rise globally, increasing numbers of patients are presenting with advanced hepatic fibrosis and significant mortality risk. The demand far outstrips possible transplantation capacities, and thus there is an intense drive to develop new pharmacological therapies that stall or reverse liver scarring. Recent late-stage failures of lead compounds have highlighted the challenges of resolving fibrosis, which has developed and stabilized over many years and varies in nature and composition from individual to individual. Hence, preclinical tools are being developed in both the hepatology and tissue engineering communities to elucidate the nature, composition, and cellular interactions of the hepatic extracellular niche in health and disease. In this protocol, we describe strategies for decellularizing cirrhotic and healthy human liver specimens and show how these can be used in simple functional assays to detect the impact on stellate cell function. Our simple, small-scale approach is translatable to diverse lab settings and generates cell-free materials which could be used for a variety of in vitro analyses as well as a scaffold for repopulating with key hepatic cell populations.

The Contribution of Liver Sinusoidal Endothelial Cells to Clearance of Therapeutic Antibody.

Many chronic inflammatory diseases are treated by administration of "biological" therapies in terms of fully human and humanized monoclonal antibodies or Fc fusion proteins. These tools have widespread efficacy and are favored because they generally exhibit high specificity for target with a low toxicity. However, the design of clinically applicable humanized antibodies is complicated by the need to circumvent normal antibody clearance mechanisms to maintain therapeutic dosing, whilst avoiding development of off target antibody dependent cellular toxicity. Classically, professional phagocytic immune cells are responsible for scavenging and clearance of antibody via interactions with the Fc portion. Immune cells such as macrophages, monocytes, and neutrophils express Fc receptor subsets, such as the FcγR that can then clear immune complexes. Another, the neonatal Fc receptor (FcRn) is key to clearance of IgG in vivo and serum half-life of antibody is explicitly linked to function of this receptor. The liver is a site of significant expression of FcRn and indeed several hepatic cell populations including Kupffer cells and liver sinusoidal endothelial cells (LSEC), play key roles in antibody clearance. This combined with the fact that the liver is a highly perfused organ with a relatively permissive microcirculation means that hepatic binding of antibody has a significant effect on pharmacokinetics of clearance. Liver disease can alter systemic distribution or pharmacokinetics of antibody-based therapies and impact on clinical effectiveness, however, few studies document the changes in key membrane receptors involved in antibody clearance across the spectrum of liver disease. Similarly, the individual contribution of LSEC scavenger receptors to antibody clearance in a healthy or chronically diseased organ is not well characterized. This is an important omission since pharmacokinetic studies of antibody distribution are often based on studies in healthy individuals and thus may not reflect the picture in an aging or chronically diseased population. Therefore, in this review we consider the expression and function of key antibody-binding receptors on LSEC, and the features of therapeutic antibodies which may accentuate clearance by the liver. We then discuss the implications of this for the design and utility of monoclonal antibody-based therapies.