In silico evaluation of cell therapy in acute versus chronic infarction: role of automaticity, heterogeneity and Purkinje in human.
Leto Luana RiebelZhinuo Jenny WangHector Martinez-NavarroCristian TrovatoJulia CampsLucas Arantes BergXin ZhouRuben DosteRafael Sachetto OliveiraRodrigo Weber Dos SantosJacopo BiasettiBlanca RodriguezPublished in: Scientific reports (2024)
Human-based modelling and simulation offer an ideal testbed for novel medical therapies to guide experimental and clinical studies. Myocardial infarction (MI) is a common cause of heart failure and mortality, for which novel therapies are urgently needed. Although cell therapy offers promise, electrophysiological heterogeneity raises pro-arrhythmic safety concerns, where underlying complex spatio-temporal dynamics cannot be investigated experimentally. Here, after demonstrating credibility of the modelling and simulation framework, we investigate cell therapy in acute versus chronic MI and the role of cell heterogeneity, scar size and the Purkinje system. Simulations agreed with experimental and clinical recordings from ionic to ECG dynamics in acute and chronic infarction. Following cell delivery, spontaneous beats were facilitated by heterogeneity in cell populations, chronic MI due to tissue depolarisation and slow sinus rhythm. Subsequent re-entrant arrhythmias occurred, in some instances with Purkinje involvement and their susceptibility was enhanced by impaired Purkinje-myocardium coupling, large scars and acute infarction. We conclude that homogeneity in injected ventricular-like cell populations minimises their spontaneous beating, which is enhanced by chronic MI, whereas a healthy Purkinje-myocardium coupling is key to prevent subsequent re-entrant arrhythmias, particularly for large scars.
Keyphrases
- cell therapy
- single cell
- stem cells
- heart failure
- liver failure
- drug induced
- mesenchymal stem cells
- respiratory failure
- endothelial cells
- aortic dissection
- risk factors
- blood pressure
- intensive care unit
- mass spectrometry
- cardiovascular events
- induced pluripotent stem cells
- molecular docking
- atomic force microscopy
- congenital heart disease
- coronary artery disease
- functional connectivity
- high speed
- pluripotent stem cells