A tissue-engineered scale model of the heart ventricle

Laboratory studies of the heart use cell and tissue cultures to dissect heart function yet rely on animal models to measure pressure and volume dynamics. Here, we report tissue-engineered scale models of the human left ventricle, made of nanofibrous scaffolds that promote native-like anisotropic myocardial tissue genesis and chamber-level contractile function. Incorporating neonatal rat ventricular myocytes or cardiomyocytes derived from human induced pluripotent stem cells, the tissue-engineered ventricles have a diastolic chamber volume of ~500 µl (comparable to that of the native rat ventricle and approximately 1/250 the size of the human ventricle), and ejection fractions and contractile work 50–250 times smaller and 104–108 times smaller than the corresponding values for rodent and human ventricles, respectively. We also measured tissue coverage and alignment, calcium-transient propagation and pressure–volume loops in the presence or absence of test compounds. Moreover, we describe an instrumented bioreactor with ventricular-assist capabilities, and provide a proof-of-concept disease model of structural arrhythmia. The model ventricles can be evaluated with the same assays used in animal models and in clinical settings.Scale models of the human left ventricle made of tissue-engineered nanofibrous scaffolds and primary rat cardiomyocytes or human-stem-cell-derived cardiomyocytes enable the study of contractile function and the modelling of structural arrhythmia.

[1]  A K Capulli,et al.  Fibrous scaffolds for building hearts and heart parts. , 2016, Advanced drug delivery reviews.

[2]  Gordana Vunjak-Novakovic,et al.  Advanced maturation of human cardiac tissue grown from pluripotent stem cells , 2018, Nature.

[3]  Andrew D McCulloch,et al.  Laminar fiber architecture and three-dimensional systolic mechanics in canine ventricular myocardium. , 1999, American journal of physiology. Heart and circulatory physiology.

[4]  Luke P. Lee,et al.  Human iPSC-based Cardiac Microphysiological System For Drug Screening Applications , 2015, Scientific Reports.

[5]  Esther Novosel,et al.  Vascularization is the key challenge in tissue engineering. , 2011, Advanced drug delivery reviews.

[6]  A. McCulloch,et al.  Laminar fiber architecture and three-dimensional systolic mechanics in canine ventricular myocardium. , 1999, The American journal of physiology.

[7]  A. McCulloch,et al.  Relating myocardial laminar architecture to shear strain and muscle fiber orientation. , 2001, American journal of physiology. Heart and circulatory physiology.

[8]  Milica Radisic,et al.  Distilling complexity to advance cardiac tissue engineering , 2016, Science Translational Medicine.

[9]  M. C. Morales,et al.  Influence of age, growth, and sex on cardiac myocyte size and number in rats , 1990, The Anatomical record.

[10]  Pál Pacher,et al.  Measurement of cardiac function using pressure–volume conductance catheter technique in mice and rats , 2008, Nature Protocols.

[11]  Wolfram-Hubertus Zimmermann,et al.  Development of a Biological Ventricular Assist Device: Preliminary Data From a Small Animal Model , 2007, Circulation.

[12]  M. Goumans,et al.  Defined Engineered Human Myocardium With Advanced Maturation for Applications in Heart Failure Modeling and Repair , 2017, Circulation.

[13]  Johan U. Lind,et al.  Instrumented cardiac microphysiological devices via multimaterial three-dimensional printing , 2016 .

[14]  Kevin E Healy,et al.  In vitro cardiac tissue models: Current status and future prospects. , 2016, Advanced drug delivery reviews.

[15]  Herbert Schulz,et al.  Human Engineered Heart Tissue: Analysis of Contractile Force , 2016, Stem cell reports.

[16]  M. Radisic,et al.  Strategies and Challenges to Myocardial Replacement Therapy , 2016, Stem cells translational medicine.

[17]  Kevin D. Costa,et al.  Advancing functional engineered cardiac tissues toward a preclinical model of human myocardium , 2014, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[18]  Felix Chua,et al.  Passive Stiffness of Myocardium From Congenital Heart Disease and Implications for Diastole , 2010, Circulation.

[19]  Gang Wang,et al.  Modeling the mitochondrial cardiomyopathy of Barth syndrome with iPSC and heart-on-chip technologies , 2014 .

[20]  C. Pc,et al.  The human subject: an integrative animal model for 21(st) century heart failure research. , 2015 .

[21]  K. Nicolay,et al.  Small animal cardiovascular MR imaging and spectroscopy. , 2015, Progress in nuclear magnetic resonance spectroscopy.

[22]  S. Sheehy,et al.  The contribution of cellular mechanotransduction to cardiomyocyte form and function , 2012, Biomechanics and Modeling in Mechanobiology.

[23]  A. Barrett,et al.  Comparative chronotropic activity of β‐adrenoceptive antagonists , 1970 .

[24]  Ronald A. Li,et al.  Bioengineering an electro-mechanically functional miniature ventricular heart chamber from human pluripotent stem cells. , 2018, Biomaterials.

[25]  Kevin Kit Parker,et al.  Structural Phenotyping of Stem Cell-Derived Cardiomyocytes , 2015, Stem cell reports.

[26]  Eva Wagner,et al.  Physiologic force-frequency response in engineered heart muscle by electromechanical stimulation. , 2015, Biomaterials.

[27]  Lil Pabon,et al.  Engineering Adolescence: Maturation of Human Pluripotent Stem Cell–Derived Cardiomyocytes , 2014, Circulation research.

[28]  Y. Rudy,et al.  Basic mechanisms of cardiac impulse propagation and associated arrhythmias. , 2004, Physiological reviews.

[29]  R. Cohen,et al.  Power spectrum analysis of heart rate fluctuation: a quantitative probe of beat-to-beat cardiovascular control. , 1981, Science.

[30]  Fu Siong Ng,et al.  Processing and analysis of cardiac optical mapping data obtained with potentiometric dyes. , 2012, American journal of physiology. Heart and circulatory physiology.

[31]  S. Brew,et al.  All Six Modules of the Gelatin-binding Domain of Fibronectin Are Required for Full Affinity* , 2003, The Journal of Biological Chemistry.

[32]  Sean P Sheehy,et al.  Controlling the contractile strength of engineered cardiac muscle by hierarchal tissue architecture. , 2012, Biomaterials.

[33]  D. Buxton,et al.  Building a bioartificial heart: Obstacles and opportunities , 2017, The Journal of thoracic and cardiovascular surgery.

[34]  Martin Biel,et al.  Comprehensive multilevel in vivo and in vitro analysis of heart rate fluctuations in mice by ECG telemetry and electrophysiology , 2015, Nature Protocols.

[35]  Catherine Theodoropoulos,et al.  New approaches in small animal echocardiography: imaging the sounds of silence. , 2011, American journal of physiology. Heart and circulatory physiology.

[36]  E Ruoslahti,et al.  RGD and other recognition sequences for integrins. , 1996, Annual review of cell and developmental biology.

[37]  Lior Gepstein,et al.  Controlling the Cellular Organization of Tissue‐Engineered Cardiac Constructs , 2004, Annals of the New York Academy of Sciences.

[38]  Kumaraswamy Nanthakumar,et al.  Biowire: a New Platform for Maturation of Human Pluripotent Stem Cell Derived Cardiomyocytes Pubmed Central Canada , 2022 .

[39]  I. Karakikes,et al.  Human induced pluripotent stem cell-derived cardiomyocytes: insights into molecular, cellular, and functional phenotypes. , 2015, Circulation research.

[40]  B Buis,et al.  Continuous measurement of left ventricular volume in animals and humans by conductance catheter. , 1984, Circulation.

[41]  E. T. van der Velde,et al.  Continuous stroke volume and cardiac output from intra-ventricular dimensions obtained with impedance catheter. , 1981, Cardiovascular research.

[42]  Thomas Eschenhagen,et al.  Human engineered heart tissue as a model system for drug testing. , 2016, Advanced drug delivery reviews.

[43]  Elisabetta A. Matsumoto,et al.  Biomimetic 4D printing. , 2016, Nature materials.

[44]  Josue A. Goss,et al.  Design and Fabrication of Fibrous Nanomaterials Using Pull Spinning , 2017 .

[45]  Karl-Ludwig Laugwitz,et al.  Patient-specific induced pluripotent stem-cell models for long-QT syndrome. , 2010, New England Journal of Medicine.

[46]  Nobuyuki Magome,et al.  Electrospun nanofibers as a tool for architecture control in engineered cardiac tissue. , 2011, Biomaterials.

[47]  H. Reichenspurner,et al.  Myocardial tissue engineering for cardiac repair. , 2016, The Journal of heart and lung transplantation : the official publication of the International Society for Heart Transplantation.

[48]  E. Entcheva,et al.  Electrospun fine-textured scaffolds for heart tissue constructs. , 2005, Biomaterials.

[49]  Kevin E. Healy,et al.  Miniaturized iPS-Cell-Derived Cardiac Muscles for Physiologically Relevant Drug Response Analyses , 2016, Scientific Reports.

[50]  Robert W. Mills,et al.  Bioengineering Human Myocardium on Native Extracellular Matrix. , 2016, Circulation research.

[51]  Jonathan W. Valvano,et al.  Accuracy considerations in catheter based estimation of left ventricular volume , 2010, 2010 Annual International Conference of the IEEE Engineering in Medicine and Biology.

[52]  A. Kleber,et al.  Patterned growth of neonatal rat heart cells in culture. Morphological and electrophysiological characterization. , 1991, Circulation research.

[53]  Thomas Mattair,et al.  Obstacles and Opportunities , 1993 .

[54]  M. Endoh Force-frequency relationship in intact mammalian ventricular myocardium: physiological and pathophysiological relevance. , 2004, European journal of pharmacology.

[55]  Eun Jung Lee,et al.  Engineered cardiac organoid chambers: toward a functional biological model ventricle. , 2008, Tissue engineering. Part A.

[56]  Johan U. Lind,et al.  Production of Synthetic, Para-Aramid and Biopolymer Nanofibers by Immersion Rotary Jet-Spinning , 2017 .

[57]  H. Suga,et al.  Assessment of systolic and diastolic ventricular properties via pressure-volume analysis: a guide for clinical, translational, and basic researchers. , 2005, American journal of physiology. Heart and circulatory physiology.

[58]  Sung-Jin Park,et al.  Instrumented cardiac microphysiological devices via multi-material 3D printing , 2016, Nature materials.

[59]  Jason A Burdick,et al.  Engineering on the straight and narrow: the mechanics of nanofibrous assemblies for fiber-reinforced tissue regeneration. , 2009, Tissue engineering. Part B, Reviews.

[60]  M. Radisic,et al.  Maturing human pluripotent stem cell-derived cardiomyocytes in human engineered cardiac tissues. , 2016, Advanced drug delivery reviews.

[61]  M. Marber,et al.  Advancements in pressure–volume catheter technology – stress remodelling after infarction , 2013, Experimental physiology.

[62]  M. Böhm,et al.  Antiadrenergic effect of carbachol but not of adenosine on contractility in the intact human ventricle in vivo. , 1994, Journal of the American College of Cardiology.

[63]  Irene Georgakoudi,et al.  Optical metrics of the extracellular matrix predict compositional and mechanical changes after myocardial infarction , 2016, Scientific Reports.

[64]  P. Simpson,et al.  Differentiation of Rat Myocytes in Single Cell Cultures with and without Proliferating Nonmyocardial Cells: Cross‐Striations, infrastructure, and Chronotropic Response to Isoproterenol , 1982, Circulation research.

[65]  Veniamin Y. Sidorov,et al.  I-Wire Heart-on-a-Chip I: Three-dimensional cardiac tissue constructs for physiology and pharmacology. , 2017, Acta biomaterialia.

[66]  Gregory B. Sands,et al.  Three-dimensional transmural organization of perimysial collagen in the heart , 2008, American journal of physiology. Heart and circulatory physiology.

[67]  Kumaraswamy Nanthakumar,et al.  Design and formulation of functional pluripotent stem cell-derived cardiac microtissues , 2013, Proceedings of the National Academy of Sciences.

[68]  Nevan J Krogan,et al.  CRISPR Interference Efficiently Induces Specific and Reversible Gene Silencing in Human iPSCs. , 2016, Cell stem cell.

[69]  Peter Savadjiev,et al.  Heart wall myofibers are arranged in minimal surfaces to optimize organ function , 2012, Proceedings of the National Academy of Sciences.

[70]  G. Whitesides,et al.  Muscular Thin Films for Building Actuators and Powering Devices , 2007, Science.

[71]  K Ann McKibbon,et al.  Current status and future prospects. , 2008, Health information and libraries journal.

[72]  J. Itskovitz‐Eldor,et al.  Molecular characterization and functional properties of cardiomyocytes derived from human inducible pluripotent stem cells , 2009, Journal of cellular and molecular medicine.

[73]  S. Harding,et al.  β1‐ and β2‐adrenoceptor responses in cardiomyocytes derived from human embryonic stem cells: comparison with failing and non‐failing adult human heart , 2008, British journal of pharmacology.

[74]  Jeong-Woo Choi,et al.  Phototactic guidance of a tissue-engineered soft-robotic ray , 2016, Science.

[75]  N. Ziv,et al.  Evolution of Action Potential Propagation and Repolarization in Cultured Neonatal Rat Ventricular Myocytes , 2001, Journal of cardiovascular electrophysiology.

[76]  Praveen Shukla,et al.  Engineered heart tissues and induced pluripotent stem cells: Macro- and microstructures for disease modeling, drug screening, and translational studies. , 2016, Advanced drug delivery reviews.

[77]  W. Zimmermann,et al.  Three-dimensional engineered heart tissue from neonatal rat cardiac myocytes. , 2000, Biotechnology and bioengineering.

[78]  M. Prabhakaran,et al.  Guided orientation of cardiomyocytes on electrospun aligned nanofibers for cardiac tissue engineering. , 2011, Journal of biomedical materials research. Part B, Applied biomaterials.

[79]  Roland N. Emokpae,et al.  Spiral Wave Attachment to Millimeter-Sized Obstacles , 2006, Circulation.

[80]  Donald E Ingber,et al.  Engineered in vitro disease models. , 2015, Annual review of pathology.

[81]  J. Pippin,et al.  The human subject: an integrative animal model for 21(st) century heart failure research. , 2015, American journal of translational research.

[82]  Thomas Boudou,et al.  A microfabricated platform to measure and manipulate the mechanics of engineered cardiac microtissues. , 2012, Tissue engineering. Part A.

[83]  David L. Kaplan,et al.  A 3D aligned microfibrous myocardial tissue construct cultured under transient perfusion. , 2011, Biomaterials.

[84]  I. Efimov,et al.  Arrhythmogenic and metabolic remodelling of failing human heart , 2016, The Journal of physiology.

[85]  Jonathan W. Valvano,et al.  Electrical Conductivity and Permittivity of Murine Myocardium , 2009, IEEE Transactions on Biomedical Engineering.

[86]  A. Kleber,et al.  Slow conduction in cardiac tissue, I: effects of a reduction of excitability versus a reduction of electrical coupling on microconduction. , 1998, Circulation research.

[87]  A. Barrett,et al.  Comparative chronotropic activity of beta-adrenoceptive antagonists. , 1970, British journal of pharmacology.

[88]  N. Bursac,et al.  Cardiomyocyte Cultures With Controlled Macroscopic Anisotropy: A Model for Functional Electrophysiological Studies of Cardiac Muscle , 2002, Circulation research.

[89]  Andre Levchenko,et al.  Nanoscale cues regulate the structure and function of macroscopic cardiac tissue constructs , 2009, Proceedings of the National Academy of Sciences.