L. Frenguelli

Rapid production of human liver scaffolds for functional tissue engineering by high shear stress oscillation-decellularization

The development of human liver scaffolds retaining their 3-dimensional structure and extra-cellular matrix (ECM) composition is essential for the advancement of liver tissue engineering. We report the design and validation of a new methodology for the rapid and accurate production of human acellular liver tissue cubes (ALTCs) using normal liver tissue unsuitable for transplantation. The application of high shear stress is a key methodological determinant accelerating the process of tissue decellularization while maintaining ECM protein composition, 3D-architecture and physico-chemical properties of the native tissue. ALTCs were engineered with human parenchymal and non-parenchymal liver cell lines (HepG2 and LX2 cells, respectively), human umbilical vein endothelial cells (HUVEC), as well as primary human hepatocytes and hepatic stellate cells. Both parenchymal and non-parenchymal liver cells grown in ALTCs exhibited markedly different gene expression when compared to standard 2D cell cultures. Remarkably, HUVEC cells naturally migrated in the ECM scaffold and spontaneously repopulated the lining of decellularized vessels. The metabolic function and protein synthesis of engineered liver scaffolds with human primary hepatocytes reseeded under dynamic conditions were maintained. These results provide a solid basis for the establishment of effective protocols aimed at recreating human liver tissue in vitro.

Increasing the accuracy of proteomic typing by decellularisation of amyloid tissue biopsies

Diagnosis and treatment of systemic amyloidosis depend on accurate identification of the specific amyloid fibril protein forming the tissue deposits. Confirmation of monoclonal immunoglobulin light chain amyloidosis (AL), requiring cytotoxic chemotherapy, and avoidance of such treatment in non-AL amyloidosis, are particularly important. Proteomic analysis characterises amyloid proteins directly. It complements immunohistochemical staining of amyloid to identify fibril proteins and gene sequencing to identify mutations in the fibril precursors. However, proteomics sometimes detects more than one potentially amyloidogenic protein, especially immunoglobulins and transthyretin which are abundant plasma proteins. Ambiguous results are most challenging in the elderly as both AL and transthyretin (ATTR) amyloidosis are usually present in this group. We have lately described a procedure for tissue decellularisation which retains the structure, integrity and composition of amyloid but removes proteins that are not integrated within the deposits. Here we show that use of this procedure before proteomic analysis eliminates ambiguity and improves diagnostic accuracy. Significance Unequivocal identification of the protein causing amyloidosis disease is crucial for correct diagnosis and treatment. As a proof of principle, we selected a number of cardiac and fat tissue biopsies from patients with various types of amyloidosis and show that a classical procedure of decellularisation enhances the specificity of the identification of the culprit protein reducing ambiguity and the risk of misdiagnosis.

Development of human liver extracellular matrix hydrogel for three dimensional cell culture and cell transplantation

Introduction: It is increasingly evident that the currently available in vivo and in vitro methodologies for disease modelling are sub-optimal in recapitulating the complexity of human pathophysiology, as confirmed by the high failure rate of drug candidates due to lack of efficacy and safety. Moreover, hepatocyte transplantation has been tested as an alternative to liver transplantation for the treatment of liver diseases, but its applicability is hampered by the limited source of hepatocytes and poor hepatocyte engraftment. Aims: to develop human liver ECM hydrogels as novel in vitro platform for target identification/drug screening and for cell transplantation. Methods: Human livers unsuitable for transplantation were decellularized. The resulting ECM scaffold was then lyophilized and the resultant liver ECM powder was solubilised and mixed with three different biomaterials such as agarose, inert bio-ink or a synthetic thermo-responsive copolymer for hydrogel development. Samples were bioengineered with human hepatic cell lines (HepG2, LX2 or SNU-449), stem cells (IPSCs) or human primary hepatocytes. Validation of the hepatocellular carcinoma (HCC) model was investigated through treatment of SNU-449 samples with Sorafenib and TGF-β1. Furthermore, HepG2 bioengineered hydrogels were implanted for 3 weeks in immune-deficient mice. Samples were analysed by histology, immunofluorescence, immunohistochemistry, viability assays, gene expression and metabolic activity. Results: Bioengineered human liver ECM-based hydrogels with human liver cells showed an increase in cell survival, engraftment, proliferation and functionality compared to agarose, inert bio-ink or synthetic thermo-responsive copolymer. Viability assays of SNU-499 cells, upon Sorafenib treatment, revealed differences between 2D and 3D modelling in HCC. Implanted HepG2 ECM-hydrogels, retrieved from mice, showed that cells were still alive and engrafted. In vitro, ECM hydrogels combined with synthetic thermo-responsive copolymer showed the highest cell viability, better reproducibility, required less ECM volume and a smaller number of cells compared to ECM hydrogels combined with agarose or inert bio-ink. Conclusion: This study describes the development and the technical validation of human liver ECM hydrogels for in vitro and in vivo applications.