Abstract
Cardiovascular disease is a major cause of death globally. This has led to significant efforts to develop new anti-thrombotic therapies or re-purpose existing drugs to treat cardiovascular diseases. Due to difficulties of obtaining healthy human blood vessel tissues to recreate in vivo conditions, pre-clinical testing of these drugs currently requires significant use of animal experimentation, however, the successful translation of drugs from animal tests to use in humans is poor. Developing humanised drug test models that better replicate the human vasculature will help to develop anti-thrombotic therapies more rapidly. Tissue-engineered human blood vessel (TEBV) models were fabricated with biomimetic matrix and cellular components. The pro- and anti-aggregatory properties of both intact and FeCl3-injured TEBVs were assessed under physiological flow conditions using a modified parallel-plate flow chamber. These were perfused with fluorescently labelled human platelets and endothelial progenitor cells (EPCs), and their responses were monitored in real-time using fluorescent imaging. An endothelium-free TEBV exhibited the capacity to trigger platelet activation and aggregation in a shear stress-dependent manner, similar to the responses observed in vivo. Ketamine is commonly used as an anaesthetic in current in vivo models, but this drug significantly inhibited platelet aggregation on the injured TEBV. Atorvastatin was also shown to enhance EPC attachment on the injured TEBV. The TEBV, when perfused with human blood or blood components under physiological conditions, provides a powerful alternative to current in vivo drug testing models to assess their effects on thrombus formation and EPC recruitment.
Highlights
Introduction iationsCardiovascular diseases are among the leading causes of mortality and morbidity worldwide
Consistent with our previous findings, it was possible to generate tissue-engineered intimal layers (TEILs), TEML, and Tissue-engineered human blood vessel (TEBV) constructs with human umbilical vein endothelial cells (HUVECs) and human cardiac artery smooth muscle cells (HCASMCs) showing typical normal cellular morphology when grown atop (HUVECs) or within (HCASMCs) the collagen hydrogel scaffold using our previously published layer-by-layer fabrication technique [18]
The layer-by-layer assembly of human blood vessel models provides a convenient and reliable research tool to investigate the interaction of blood components, such as platelets and circulated progenitor cells, with a blood vessel
Summary
Cardiovascular diseases are among the leading causes of mortality and morbidity worldwide. These are caused by aberrant platelet activation caused by endothelial dysfunction and exposure of plasma to collagen- and tissue factor-rich atherosclerotic plaques. Most studies assessing the effect of drugs on cardiovascular disease rely on animal models to predict and explain their effects in humans [1]. Different animal species have been used to evaluate certain features of cardiovascular disease, such as zebrafish, pigs, rabbits, and rodents. Mice have become the animal of choice for disease modelling given their genetic similarity to humans, their fast breeding rate, and well-established methods for creating genetic knock-outs [2,3]. Intravital microscopy allows the real-time examination of thrombus formation on artificial vessel injuries in response to ferric chloride
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