Abstract
Coronary heart disease is a leading cause of death. Tissue remodeling and fibrosis results in cardiac pump dysfunction and ischemic heart failure. Cardiac fibroblasts may rebuild damaged tissues when prompted by suitable environmental cues. Here, we use acellular biologic extracellular matrix scaffolds (bioscaffolds) to stimulate pathways of muscle repair and restore tissue function. We show that acellular bioscaffolds with bioinductive properties can redirect cardiac fibroblasts to rebuild microvascular networks and avoid tissue fibrosis. Specifically, when human cardiac fibroblasts are combined with bioactive scaffolds, gene expression is upregulated and paracrine mediators are released that promote vasculogenesis and prevent scarring. We assess these properties in rodents with myocardial infarction and observe bioscaffolds to redirect fibroblasts, reduce tissue fibrosis and prevent maladaptive structural remodeling. Our preclinical data confirms that acellular bioscaffold therapy provides an appropriate microenvironment to stimulate pathways of functional repair. We translate our observations to patients with coronary heart disease by conducting a first-in-human observational cohort study. We show that bioscaffold therapy is associated with improved perfusion of infarcted myocardium, reduced myocardial scar burden, and reverse structural remodeling. We establish that clinical use of acellular bioscaffolds is feasible and offers a new frontier to enhance surgical revascularization of ischemic heart muscle.
Highlights
Coronary heart disease is a leading cause of death
Human cardiac fibroblasts on intact bioscaffolds downregulated selected genes associated with cardiac fibrosis relative to matched cells on neutralized extracellular matrix (ECM) scaffolds
After showing that bioactive scaffolds can provide a pro-reparative microenvironment to redirect cardiac fibroblast phenotype and activity, we explored the ability of this adaptive microenvironment to support post-myocardial infarction (MI) functional recovery
Summary
Coronary heart disease is a leading cause of death. Tissue remodeling and fibrosis results in cardiac pump dysfunction and ischemic heart failure. We use acellular biologic extracellular matrix scaffolds (bioscaffolds) to stimulate pathways of muscle repair and restore tissue function. When human cardiac fibroblasts are combined with bioactive scaffolds, gene expression is upregulated and paracrine mediators are released that promote vasculogenesis and prevent scarring We assess these properties in rodents with myocardial infarction and observe bioscaffolds to redirect fibroblasts, reduce tissue fibrosis and prevent maladaptive structural remodeling. Persistent pro-fibrotic cell activity is maladaptive and results in tissue fibrosis, structural chamber remodeling, and reduced cardiac pump function that can lead to clinical decompensation as end-stage heart failure[4]. Redirecting cardiac fibroblasts toward adaptive repair may help reduce tissue fibrosis and restore microvascular networks within ischemic muscle and in so doing, promote functional recovery
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