Your search keyword '"Max J Cumberland"' showing total 6 results

1. Generation of a human iPSC-derived cardiomyocyte/fibroblast engineered heart tissue model [version 2; peer review: 1 approved, 2 approved with reservations]

Author

Chris Denning, Andrew P Holmes, Katja Gehmlich, Nguyen T N Vo, Paulus Kirchhof, Jonas Euchner, Amar J Azad, and Max J Cumberland

Subjects

Engineered Heart Tissue (EHT), 3D cardiac model, induced pluripotent stem cell derived cardiomyocytes (iPSC-CM), induced pluripotent stem cell derived cardiac fibroblasts (iPSC-CF), cardiac co-culture, cardiac fibrosis, eng, Medicine, Science

Abstract

Animal models have proven integral to broadening our understanding of complex cardiac diseases but have been hampered by significant species-dependent differences in cellular physiology. Human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) have shown great promise in the modelling of cardiac diseases despite limitations in functional and structural maturity. 3D stem cell-derived cardiac models represent a step towards mimicking the intricate microenvironment present in the heart as an in vitro model. Incorporation of non-myocyte cell types, such as cardiac fibroblasts, into engineered heart tissue models (EHTs) can help better recapitulate the cell-to-cell and cell-to-matrix interactions present in the human myocardium. Integration of human-induced pluripotent stem cell-derived cardiac fibroblasts (hiPSC-CFs) and hiPSC-CM into EHT models enables the generation of a genetically homogeneous modelling system capable of exploring the abstruse structural and electrophysiological interplay present in cardiac pathophysiology. Furthermore, the construction of more physiologically relevant 3D cardiac models offers great potential in the replacement of animals in heart disease research. Here we describe efficient and reproducible protocols for the differentiation of hiPSC-CMs and hiPSC-CFs and their subsequent assimilation into EHTs. The resultant EHT consists of longitudinally arranged iPSC-CMs, incorporated alongside hiPSC-CFs. EHTs with both hiPSC-CMs and hiPSC-CFs exhibit slower beating frequencies and enhanced contractile force compared to those composed of hiPSC-CMs alone. The modified protocol may help better characterise the interplay between different cell types in the myocardium and their contribution to structural remodelling and cardiac fibrosis.

Published

2024

2. Generation of a human iPSC-derived cardiomyocyte/fibroblast engineered heart tissue model [version 1; peer review: 1 approved, 2 approved with reservations]

Author

Chris Denning, Andrew P Holmes, Katja Gehmlich, Nguyen T N Vo, Paulus Kirchhof, Jonas Euchner, Amar J Azad, and Max J Cumberland

Subjects

Engineered Heart Tissue (EHT), 3D cardiac model, induced pluripotent stem cell derived cardiomyocytes (iPSC-CM), induced pluripotent stem cell derived cardiac fibroblasts (iPSC-CF), cardiac co-culture, cardiac fibrosis, eng, Medicine, Science

Abstract

Animal models have proven integral to broadening our understanding of complex cardiac diseases but have been hampered by significant species-dependent differences in cellular physiology. Human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) have shown great promise in the modelling of cardiac diseases despite limitations in functional and structural maturity. 3D stem cell-derived cardiac models represent a step towards mimicking the intricate microenvironment present in the heart as an in vitro model. Incorporation of non-myocyte cell types, such as cardiac fibroblasts, into engineered heart tissue models (EHTs) can help better recapitulate the cell-to-cell and cell-to-matrix interactions present in the human myocardium. Integration of human-induced pluripotent stem cell-derived cardiac fibroblasts (hiPSC-CFs) and hiPSC-CM into EHT models enables the generation of a genetically homogeneous modelling system capable of exploring the abstruse structural and electrophysiological interplay present in cardiac pathophysiology. Furthermore, the construction of more physiologically relevant 3D cardiac models offers great potential in the replacement of animals in heart disease research. Here we describe efficient and reproducible protocols for the differentiation of hiPSC-CMs and hiPSC-CFs and their subsequent assimilation into EHTs. The resultant EHT consists of longitudinally arranged iPSC-CMs, incorporated alongside hiPSC-CFs. EHTs with both hiPSC-CMs and hiPSC-CFs exhibit slower beating frequencies and enhanced contractile force compared to those composed of hiPSC-CMs alone. The modified protocol may help better characterise the interplay between different cell types in the myocardium and their contribution to structural remodelling and cardiac fibrosis.

Published

2023

3. Generation of a human iPSC-derived cardiomyocyte/fibroblast engineered heart tissue model [version 2; peer review: 2 approved, 1 approved with reservations]

Author

Max J Cumberland, Jonas Euchner, Amar J Azad, Nguyen T N Vo, Paulus Kirchhof, Andrew P Holmes, Chris Denning, and Katja Gehmlich

Subjects

Method Article, Articles, Engineered Heart Tissue (EHT), 3D cardiac model, induced pluripotent stem cell derived cardiomyocytes (iPSC-CM), induced pluripotent stem cell derived cardiac fibroblasts (iPSC-CF), cardiac co-culture, cardiac fibrosis

Abstract

Animal models have proven integral to broadening our understanding of complex cardiac diseases but have been hampered by significant species-dependent differences in cellular physiology. Human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) have shown great promise in the modelling of cardiac diseases despite limitations in functional and structural maturity. 3D stem cell-derived cardiac models represent a step towards mimicking the intricate microenvironment present in the heart as an in vitro model. Incorporation of non-myocyte cell types, such as cardiac fibroblasts, into engineered heart tissue models (EHTs) can help better recapitulate the cell-to-cell and cell-to-matrix interactions present in the human myocardium. Integration of human-induced pluripotent stem cell-derived cardiac fibroblasts (hiPSC-CFs) and hiPSC-CM into EHT models enables the generation of a genetically homogeneous modelling system capable of exploring the abstruse structural and electrophysiological interplay present in cardiac pathophysiology. Furthermore, the construction of more physiologically relevant 3D cardiac models offers great potential in the replacement of animals in heart disease research. Here we describe efficient and reproducible protocols for the differentiation of hiPSC-CMs and hiPSC-CFs and their subsequent assimilation into EHTs. The resultant EHT consists of longitudinally arranged iPSC-CMs, incorporated alongside hiPSC-CFs. EHTs with both hiPSC-CMs and hiPSC-CFs exhibit slower beating frequencies and enhanced contractile force compared to those composed of hiPSC-CMs alone. The modified protocol may help better characterise the interplay between different cell types in the myocardium and their contribution to structural remodelling and cardiac fibrosis.

Published

2024

4. Chronic activation of human cardiac fibroblasts in vitro attenuates the reversibility of the myofibroblast phenotype

Author

Caitlin Hall, Jonathan P. Law, Jasmeet S. Reyat, Max J. Cumberland, Shaun Hang, Nguyen T. N. Vo, Kavita Raniga, Chris J. Weston, Christopher O’Shea, Jonathan N. Townend, Katja Gehmlich, Charles J. Ferro, Chris Denning, and Davor Pavlovic

Subjects

Medicine, Science

Abstract

Abstract Activation of cardiac fibroblasts and differentiation to myofibroblasts underlies development of pathological cardiac fibrosis, leading to arrhythmias and heart failure. Myofibroblasts are characterised by increased α-smooth muscle actin (α-SMA) fibre expression, secretion of collagens and changes in proliferation. Transforming growth factor-beta (TGF-β) and increased mechanical stress can initiate myofibroblast activation. Reversibility of the myofibroblast phenotype has been observed in murine cells but has not been explored in human cardiac fibroblasts. In this study, chronically activated adult primary human ventricular cardiac fibroblasts and human induced pluripotent stem cell derived cFbs (hiPSC-cFbs) were used to investigate the potential for reversal of the myofibroblast phenotype using either subculture on soft substrates or TGF-β receptor inhibition. Culture on softer plates (25 or 2 kPa Young’s modulus) did not alter proliferation or reduce expression of α-SMA and collagen 1. Similarly, culture of myofibroblasts in the presence of TGF-β inhibitor did not reverse myofibroblasts back to a quiescent phenotype. Chronically activated hiPSC-cFbs also showed attenuated response to TGF-β receptor inhibition and inability to reverse to quiescent fibroblast phenotype. Our data demonstrate substantial loss of TGF-β signalling plasticity as well as a loss of feedback from the surrounding mechanical environment in chronically activated human myofibroblasts.

Published

2023

5. Generation of a human iPSC-derived cardiomyocyte/fibroblast engineered heart tissue model [version 1; peer review: 1 approved, 2 approved with reservations]

Author

Max J Cumberland, Jonas Euchner, Amar J Azad, Nguyen T N Vo, Paulus Kirchhof, Andrew P Holmes, Chris Denning, and Katja Gehmlich

Subjects

Method Article, Articles, Engineered Heart Tissue (EHT), 3D cardiac model, induced pluripotent stem cell derived cardiomyocytes (iPSC-CM), induced pluripotent stem cell derived cardiac fibroblasts (iPSC-CF), cardiac co-culture, cardiac fibrosis

Abstract

Animal models have proven integral to broadening our understanding of complex cardiac diseases but have been hampered by significant species-dependent differences in cellular physiology. Human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) have shown great promise in the modelling of cardiac diseases despite limitations in functional and structural maturity. 3D stem cell-derived cardiac models represent a step towards mimicking the intricate microenvironment present in the heart as an in vitro model. Incorporation of non-myocyte cell types, such as cardiac fibroblasts, into engineered heart tissue models (EHTs) can help better recapitulate the cell-to-cell and cell-to-matrix interactions present in the human myocardium. Integration of human-induced pluripotent stem cell-derived cardiac fibroblasts (hiPSC-CFs) and hiPSC-CM into EHT models enables the generation of a genetically homogeneous modelling system capable of exploring the abstruse structural and electrophysiological interplay present in cardiac pathophysiology. Furthermore, the construction of more physiologically relevant 3D cardiac models offers great potential in the replacement of animals in heart disease research. Here we describe efficient and reproducible protocols for the differentiation of hiPSC-CMs and hiPSC-CFs and their subsequent assimilation into EHTs. The resultant EHT consists of longitudinally arranged iPSC-CMs, incorporated alongside hiPSC-CFs. EHTs with both hiPSC-CMs and hiPSC-CFs exhibit slower beating frequencies and enhanced contractile force compared to those composed of hiPSC-CMs alone. The modified protocol may help better characterise the interplay between different cell types in the myocardium and their contribution to structural remodelling and cardiac fibrosis.

Published

2023

6. Basic Research Approaches to Evaluate Cardiac Arrhythmia in Heart Failure and Beyond

Author

Max J. Cumberland, Leto L. Riebel, Ashwin Roy, Christopher O’Shea, Andrew P. Holmes, Chris Denning, Paulus Kirchhof, Blanca Rodriguez, and Katja Gehmlich

Subjects

heart failure, in vivo cardiac models, human induced pluripotent stem cells, methods, in silico modelling, cardiac arrhythmias, Physiology, QP1-981

Abstract

Patients with heart failure often develop cardiac arrhythmias. The mechanisms and interrelations linking heart failure and arrhythmias are not fully understood. Historically, research into arrhythmias has been performed on affected individuals or in vivo (animal) models. The latter however is constrained by interspecies variation, demands to reduce animal experiments and cost. Recent developments in in vitro induced pluripotent stem cell technology and in silico modelling have expanded the number of models available for the evaluation of heart failure and arrhythmia. An agnostic approach, combining the modalities discussed here, has the potential to improve our understanding for appraising the pathology and interactions between heart failure and arrhythmia and can provide robust and validated outcomes in a variety of research settings. This review discusses the state of the art models, methodologies and techniques used in the evaluation of heart failure and arrhythmia and will highlight the benefits of using them in combination. Special consideration is paid to assessing the pivotal role calcium handling has in the development of heart failure and arrhythmia.

Published

2022