Development and characterisation of a large diameter decellularised vascular allograft

The aims of this study were to develop a biological large diameter vascular graft by decellularisation of native human aorta to remove the immunogenic cells whilst retaining the essential biomechanical, and biochemical properties for the ultimate benefit of patients with infected synthetic grafts. Donor aortas (n = 6) were subjected to an adaptation of a propriety decellularisation process to remove the cells and acellularity assessed by histological analysis and extraction and quantification of total DNA. The biocompatibility of the acellular aortas was determined using standard contact cytotoxicity tests. Collagen and denatured collagen content of aortas was determined and immunohistochemistry was used to determine the presence of specific extracellular matrix proteins. Donor aortas (n = 6) were divided into two, with one half subject to decellularisation and the other half retained as native tissue. The native and decellularised aorta sections were then subject to uniaxial tensile testing to failure [axial and circumferential directions] and suture retention testing. The data was compared using a paired t-test. Histological evaluation showed an absence of cells in the treated aortas and retention of histoarchitecture including elastin content. The decellularised aortas had less than 15 ng mg¯¹ total DNA per dry weight (mean 94% reduction) and were biocompatible as determined by in vitro contact cytotoxicity tests. There were no gross changes in the histoarchitecture [elastin and collagen matrix] of the acellular aortas compared to native controls. The decellularisation process also reduced calcium deposits within the tissue. The uniaxial tensile and suture retention testing revealed no significant differences in the material properties (p > 0.05) of decellularised aorta. The decellularisation procedure resulted in minimal changes to the biological and biomechanical properties of the donor aortas. Acellular donor aorta has excellent potential for use as a large diameter vascular graft

In Support of a Patient-Driven Initiative and Petition to Lower the High Price of Cancer Drugs

Comment in Lowering the High Cost of Cancer Drugs--III. [Mayo Clin Proc. 2016] Lowering the High Cost of Cancer Drugs--I. [Mayo Clin Proc. 2016] Lowering the High Cost of Cancer Drugs--IV. [Mayo Clin Proc. 2016] In Reply--Lowering the High Cost of Cancer Drugs. [Mayo Clin Proc. 2016] US oncologists call for government regulation to curb drug price rises. [BMJ. 2015

von Willebrand protein facilitates platelet incorporation in polymerizing fibrin.

von Willebrand protein was found to promote the incorporation of platelets into evolving fibrin thrombi. Using formalin-treated or fresh platelets, both the initial rate and extent of platelet incorporation into polymerizing fibrin were dependent on von Willebrand protein. von Willebrand protein was incorporated into evolving fibrin thrombi in parallel with platelets. Soluble fibrin monomer covalently linked to acrylonitrile beads (Matrex 102) bound von Willebrand protein specifically and saturably with an apparent approximate dissociation constant (KD) of 15 micrograms/ml. Glycocalicin, the water-soluble proteolytic fragment of glycoprotein Ib, bound to fibrin monomer in this system specifically and saturably, as well, with an apparent approximate KD of 5 micrograms/ml, but only in the presence of saturating concentrations of von Willebrand protein. These data demonstrate that the initial rate and extent of platelet incorporation into evolving fibrin thrombi are dependent on von Willebrand protein; von Willebrand protein serves as a link between polymerizing fibrin and platelet surface glycoprotein Ib; and von Willebrand protein binds to fibrin monomer and is thereby able to bind to platelet surface glycoprotein Ib in the absence of ristocetin