Abstract
Cardiovascular disease is the leading cause of death worldwide. Although investment in drug discovery and development has been sky-rocketing, the number of approved drugs has been declining. Cardiovascular toxicity due to therapeutic drug use claims the highest incidence and severity of adverse drug reactions in late-stage clinical development. Therefore, to address this issue, new, additional, replacement and combinatorial approaches are needed to fill the gap in effective drug discovery and screening. The motivation for developing accurate, predictive models is twofold: first, to study and discover new treatments for cardiac pathologies which are leading in worldwide morbidity and mortality rates; and second, to screen for adverse drug reactions on the heart, a primary risk in drug development. In addition to in vivo animal models, in vitro and in silico models have been recently proposed to mimic the physiological conditions of heart and vasculature. Here, we describe current in vitro, in vivo, and in silico platforms for modelling healthy and pathological cardiac tissues and their advantages and disadvantages for drug screening and discovery applications. We review the pathophysiology and the underlying pathways of different cardiac diseases, as well as the new tools being developed to facilitate their study. We finally suggest a roadmap for employing these non-animal platforms in assessing drug cardiotoxicity and safety.
Highlights
The cardiovascular system, with its broad interdependence with circulation, blood vessels and blood constituents, as well as renal and nervous systems, is especially complex to model [1]
Motivated by a native cardiac niche, we developed Biowire [246], by seeding cardiac cells encapsulated in a hydrogel into a PDMS microwell, where the cardiac cell suspension selforganized around a suture template situated in the middle of the microwell
It would be ideal to establish a mechanistic approach first, to assess and evaluate new tyrosine kinase inhibitors (TKIs) efficacy, especially on signaling networks in CMs, as well as to identify new mechanisms of action to minimize accompanying cardiotoxicity. These can be addressed by the quantitative systems pharmacology (QSP) approach, where large-scale measurements are combined with mechanism-based mathematical modelling [336]
Summary
The cardiovascular system, with its broad interdependence with circulation, blood vessels and blood constituents, as well as renal and nervous systems, is especially complex to model [1]. We describe current platforms for in vitro, in vivo, and in silico modelling of healthy and pathological cardiac tissues as well as their pros and cons for drug screening and discovery applications To this end, we first briefly review the pathophysiology of different cardiovascular diseases (CVDs) and current knowledge about their underlying pathways, as well as the new tools being developed to facilitate their study. The occupation of sub-endothelial space with a high concentration of modified lipoprotein leads to lipoprotein spillover into resident ECs, SMCs and macrophages, and as a result a series of inflammatory reactions are initiated. ECs and SMCs take up modified lipoproteins and undergo phenotypic and metabolic changes leading to atherosclerotic plaque accumulation These cells attract additional inflammatory cells with chemokines, cytokine secretion, and expression of adhesion molecules, thereby further amplifying atherosclerosis progression [38]. Microvessels are crucial in supplying oxygen and nutrients during the repair process, motivating extensive tissue engineering efforts focused on revascularization [47]
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