Functional Maturation of Human iPSC-based Cardiac Microphysiological Systems with Tunable Electroconductive Decellularized Extracellular Matrices

Human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) offer tremendous potential for use in engineering human tissues for regenerative therapy and drug screening. However, differentiated cardiomyocytes are phenotypically immature, reducing assay reliability when translating in vitro results to clinical studies and precluding hiPSC-derived cardiac tissues from therapeutic use in vivo. To address this, we have developed hybrid hydrogels comprised of decellularized porcine myocardial extracellular matrix (dECM) and reduced graphene oxide (rGO) to provide a more instructive microenvironment for proper cellular and tissue development. A tissue-specific protein profile was preserved post-decellularization, and through the modulation of rGO content and degree of reduction, the mechanical and electrical properties of the hydrogels could be tuned. Engineered heart tissues (EHTs) generated using dECM-rGO hydrogel scaffolds and hiPSC-derived cardiomyocytes exhibited significantly increased twitch forces at 14 days of culture and had increased the expression of genes that regulate contractile function. Similar improvements in various aspects of electrophysiological function, such as calcium-handling, action potential duration, and conduction velocity, were also induced by the hybrid biomaterial. We also demonstrate that dECM-rGO hydrogels can be used as a bioink to print cardiac tissues in a high-throughput manner, and these tissues were utilized to assess the proarrhythmic potential of cisapride. Action potential prolongation and beat interval irregularities was observed in dECM-rGO tissues at clinical doses of cisapride, indicating that the enhanced maturation of these tissues corresponded well with a capability to produce physiologically relevant drug responses.

[1]  S. BielawskiKevin,et al.  Real-Time Force and Frequency Analysis of Engineered Human Heart Tissue Derived from Induced Pluripotent Stem Cells Using Magnetic Sensing. , 2016 .

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

[3]  K. Bolotin,et al.  Three-dimensional graphene foams promote osteogenic differentiation of human mesenchymal stem cells. , 2013, Nanoscale.

[4]  Y. S. Zhang,et al.  Reduced Graphene Oxide-GelMA Hybrid Hydrogels as Scaffolds for Cardiac Tissue Engineering. , 2016, Small.

[5]  Eloi Marijon,et al.  State-of-the-art Paper Prevalences, Patterns, and the Potential of Early Disease Detection , 2022 .

[6]  A. Khera,et al.  Forecasting the Future of Cardiovascular Disease in the United States: A Policy Statement From the American Heart Association , 2011, Circulation.

[7]  Sangeeta N Bhatia,et al.  Assessing porcine liver-derived biomatrix for hepatic tissue engineering. , 2004, Tissue engineering.

[8]  Wei-Zhong Zhu,et al.  Structural and functional maturation of cardiomyocytes derived from human pluripotent stem cells. , 2013, Stem cells and development.

[9]  Xuan Guan,et al.  Nanopatterned Human iPSC-Based Model of a Dystrophin-Null Cardiomyopathic Phenotype , 2015, Cellular and molecular bioengineering.

[10]  Gregory F. Lewis,et al.  High-throughput cardiac safety evaluation and multi-parameter arrhythmia profiling of cardiomyocytes using microelectrode arrays. , 2015, Toxicology and applied pharmacology.

[11]  D. Atsma,et al.  Progressive increase in conduction velocity across human mesenchymal stem cells is mediated by enhanced electrical coupling. , 2006, Cardiovascular research.

[12]  A. Camm,et al.  Relationships between preclinical cardiac electrophysiology, clinical QT interval prolongation and torsade de pointes for a broad range of drugs: evidence for a provisional safety margin in drug development. , 2003, Cardiovascular research.

[13]  N. Sniadecki,et al.  Afterload promotes maturation of human induced pluripotent stem cell derived cardiomyocytes in engineered heart tissues. , 2018, Journal of molecular and cellular cardiology.

[14]  Mark Van Dyke,et al.  The influence of extracellular matrix derived from skeletal muscle tissue on the proliferation and differentiation of myogenic progenitor cells ex vivo. , 2009, Biomaterials.

[15]  B. Kay,et al.  Molecular basis of human cardiac troponin T isoforms expressed in the developing, adult, and failing heart. , 1995, Circulation research.

[16]  Adam J Engler,et al.  Embryonic cardiomyocytes beat best on a matrix with heart-like elasticity: scar-like rigidity inhibits beating , 2008, Journal of Cell Science.

[17]  Atsushi Nakano,et al.  A Single CRISPR-Cas9 Deletion Strategy that Targets the Majority of DMD Patients Restores Dystrophin Function in hiPSC-Derived Muscle Cells. , 2016, Cell stem cell.

[18]  Michael Regnier,et al.  Substrate stiffness increases twitch power of neonatal cardiomyocytes in correlation with changes in myofibril structure and intracellular calcium. , 2011, Biophysical journal.

[19]  Jae-Young Choi,et al.  Efficient Reduction of Graphite Oxide by Sodium Borohydride and Its Effect on Electrical Conductance , 2009 .

[20]  M J Bissell,et al.  How does the extracellular matrix direct gene expression? , 1982, Journal of theoretical biology.

[21]  J. Stinstra,et al.  On the Passive Cardiac Conductivity , 2005, Annals of Biomedical Engineering.

[22]  Xuetao Sun,et al.  Biowire platform for maturation of human pluripotent stem cell-derived cardiomyocytes. , 2016, Methods.

[23]  P. Lijnen The effect of membrane cholesterol content on ion transport processes in plasma membranes. , 1997, Cardiovascular research.

[24]  N. Sniadecki,et al.  Micropost arrays for measuring stem cell-derived cardiomyocyte contractility. , 2016, Methods.

[25]  R. Lazzara,et al.  Spontaneous adverse event reports of serious ventricular arrhythmias, QT prolongation, syncope, and sudden death in patients treated with cisapride: An ongoing independent case review , 2000 .

[26]  Yiming Wu,et al.  Developmental Control of Titin Isoform Expression and Passive Stiffness in Fetal and Neonatal Myocardium , 2004, Circulation research.

[27]  Christopher H. Fry,et al.  Abnormal Action Potential Conduction in Isolated Human Hypertrophied Left Ventricular Myocardium , 1997, Journal of cardiovascular electrophysiology.

[28]  Chamber compliance and myocardial stiffness in left ventricular hypertrophy. , 1982, European heart journal.

[29]  Sean P. Palecek,et al.  Directed cardiomyocyte differentiation from human pluripotent stem cells by modulating Wnt/β-catenin signaling under fully defined conditions , 2012, Nature Protocols.

[30]  B. Hong,et al.  Graphene enhances the cardiomyogenic differentiation of human embryonic stem cells. , 2014, Biochemical and biophysical research communications.

[31]  Zhaoxia Jin,et al.  Fabrication, mechanical properties, and biocompatibility of graphene-reinforced chitosan composites. , 2010, Biomacromolecules.

[32]  A. Van der Laarse,et al.  The effect of membrane cholesterol content on ion transport processes in plasma membranes , 1997 .

[33]  Shu‐hong Li,et al.  A Conductive Polymer Hydrogel Supports Cell Electrical Signaling and Improves Cardiac Function After Implantation into Myocardial Infarct , 2015, Circulation.

[34]  Tu Hong,et al.  Membrane cholesterol mediates the cellular effects of monolayer graphene substrates , 2018, Nature Communications.

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

[36]  M. Sheetz,et al.  Local force and geometry sensing regulate cell functions , 2006, Nature Reviews Molecular Cell Biology.

[37]  R. Bialecki,et al.  Excess membrane cholesterol alters calcium channels in arterial smooth muscle. , 1989, The American journal of physiology.

[38]  Sung Gap Im,et al.  Electroconductive Nanopatterned Substrates for Enhanced Myogenic Differentiation and Maturation , 2016, Advanced healthcare materials.

[39]  R. Broderick,et al.  Cholesterol-induced changes in rabbit arterial smooth muscle sensitivity to adrenergic stimulation. , 1989, The American journal of physiology.

[40]  A. DeMaria,et al.  Safety and Efficacy of an Injectable Extracellular Matrix Hydrogel for Treating Myocardial Infarction , 2013, Science Translational Medicine.

[41]  L. Samuelson,et al.  Troponin I isoform expression is developmentally regulated in differentiating embryonic stem cell‐derived cardiac myocytes , 1996, Developmental dynamics : an official publication of the American Association of Anatomists.

[42]  R. Stevens,et al.  High-Resolution Crystal Structure of an Engineered Human β2-Adrenergic G Protein–Coupled Receptor , 2007, Science.

[43]  H. Jongsma,et al.  Heptanol-induced decrease in cardiac gap junctional conductance is mediated by a decrease in the fluidity of membranous cholesterol-rich domains , 1993, The Journal of Membrane Biology.

[44]  F. Guinea,et al.  The electronic properties of graphene , 2007, Reviews of Modern Physics.

[45]  Didier Y. R. Stainier,et al.  Cardiac troponin T is essential in sarcomere assembly and cardiac contractility , 2002, Nature Genetics.

[46]  N. Koratkar,et al.  Enhanced mechanical properties of nanocomposites at low graphene content. , 2009, ACS nano.

[47]  Nenad Bursac,et al.  Tissue-engineered cardiac patch for advanced functional maturation of human ESC-derived cardiomyocytes. , 2013, Biomaterials.

[48]  S. Viskin,et al.  The QT interval: too long, too short or just right. , 2009, Heart rhythm.

[49]  Gordana Vunjak-Novakovic,et al.  Shortcomings of Animal Models and the Rise of Engineered Human Cardiac Tissue. , 2017, ACS biomaterials science & engineering.

[50]  Milica Radisic,et al.  Influence of substrate stiffness on the phenotype of heart cells , 2010, Biotechnology and bioengineering.

[51]  K. Bielawski,et al.  Real-Time Force and Frequency Analysis of Engineered Human Heart Tissue Derived from Induced Pluripotent Stem Cells Using Magnetic Sensing. , 2016, Tissue engineering. Part C, Methods.

[52]  I. Georgakoudi,et al.  Young developmental age cardiac extracellular matrix promotes the expansion of neonatal cardiomyocytes in vitro. , 2014, Acta biomaterialia.

[53]  Daniela S Hauser,et al.  Cardiovascular parameters in anaesthetized guinea pigs: a safety pharmacology screening model. , 2005, Journal of pharmacological and toxicological methods.

[54]  J. Caldwell,et al.  Carbon nanotubes instruct physiological growth and functionally mature syncytia: nongenetic engineering of cardiac myocytes. , 2013, ACS nano.

[55]  L Hartley,et al.  Nkx-2.5: a novel murine homeobox gene expressed in early heart progenitor cells and their myogenic descendants. , 1993, Development.

[56]  C. Enger,et al.  Serious ventricular arrhythmias among users of cisapride and other QT‐prolonging agents in the United States , 2002, Pharmacoepidemiology and drug safety.

[57]  Tal Dvir,et al.  Nanowired three dimensional cardiac patches , 2011, Nature nanotechnology.

[58]  S. Heymans,et al.  Mutations in MYH7 reduce the force generating capacity of sarcomeres in human familial hypertrophic cardiomyopathy. , 2013, Cardiovascular research.

[59]  C. Stamm,et al.  Human cardiac extracellular matrix supports myocardial lineage commitment of pluripotent stem cells. , 2015, European journal of cardio-thoracic surgery : official journal of the European Association for Cardio-thoracic Surgery.

[60]  Seeram Ramakrishna,et al.  Polypyrrole-contained electrospun conductive nanofibrous membranes for cardiac tissue engineering. , 2011, Journal of biomedical materials research. Part A.

[61]  Ali Khademhosseini,et al.  Gold Nanocomposite Bioink for Printing 3D Cardiac Constructs , 2017, Advanced functional materials.

[62]  T. Hisada,et al.  Screening system for drug-induced arrhythmogenic risk combining a patch clamp and heart simulator , 2015, Science Advances.

[63]  Kerry A. Daly,et al.  Biologic scaffold composed of skeletal muscle extracellular matrix. , 2012, Biomaterials.

[64]  J. Jacot,et al.  The Effect of Substrate Stiffness on Cardiomyocyte Action Potentials , 2016, Cell Biochemistry and Biophysics.

[65]  A. DeMaria,et al.  Catheter-deliverable hydrogel derived from decellularized ventricular extracellular matrix increases endogenous cardiomyocytes and preserves cardiac function post-myocardial infarction. , 2012, Journal of the American College of Cardiology.

[66]  P. Doevendans,et al.  The human adult cardiomyocyte phenotype. , 2003, Cardiovascular research.

[67]  Doris A Taylor,et al.  Perfusion-decellularized matrix: using nature's platform to engineer a bioartificial heart , 2008, Nature Medicine.

[68]  Charles E. Murry,et al.  Growth of Engineered Human Myocardium With Mechanical Loading and Vascular Coculture , 2011, Circulation research.

[69]  Adam J. Engler,et al.  Mesenchymal stem cell injection after myocardial infarction improves myocardial compliance , 2006 .

[70]  C. January,et al.  Kv11.1 (ERG1) K+ Channels Localize in Cholesterol and Sphingolipid Enriched Membranes and Are Modulated by Membrane Cholesterol , 2007, Channels.

[71]  David J. Mooney,et al.  Harnessing Traction-Mediated Manipulation of the Cell-Matrix Interface to Control Stem Cell Fate , 2010, Nature materials.

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

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

[74]  B. R. Jewell,et al.  Calcium‐ and length‐dependent force production in rat ventricular muscle , 1982, The Journal of physiology.

[75]  Christy L Haynes,et al.  Cytotoxicity of graphene oxide and graphene in human erythrocytes and skin fibroblasts. , 2011, ACS applied materials & interfaces.

[76]  Brenda M Ogle,et al.  Spatial and temporal analysis of extracellular matrix proteins in the developing murine heart: a blueprint for regeneration. , 2013, Tissue engineering. Part A.

[77]  Yang Xu,et al.  Cytotoxicity effects of graphene and single-wall carbon nanotubes in neural phaeochromocytoma-derived PC12 cells. , 2010, ACS nano.

[78]  Deok‐Ho Kim,et al.  Printing three-dimensional tissue analogues with decellularized extracellular matrix bioink , 2014, Nature Communications.

[79]  A. Khademhosseini,et al.  Carbon-nanotube-embedded hydrogel sheets for engineering cardiac constructs and bioactuators. , 2013, ACS nano.

[80]  Jennifer M. Singelyn,et al.  Naturally derived myocardial matrix as an injectable scaffold for cardiac tissue engineering. , 2009, Biomaterials.

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

[82]  Bin Duan,et al.  State-of-the-Art Review of 3D Bioprinting for Cardiovascular Tissue Engineering , 2016, Annals of Biomedical Engineering.

[83]  D. Weber,et al.  Xenogeneic extracellular matrix as an inductive scaffold for regeneration of a functioning musculotendinous junction. , 2010, Tissue engineering. Part A.

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

[85]  Serge Richard,et al.  Prediction of the risk of Torsade de Pointes using the model of isolated canine Purkinje fibres , 2005, British journal of pharmacology.

[86]  Elisa Cimetta,et al.  Soft substrates drive optimal differentiation of human healthy and dystrophic myotubes. , 2010, Integrative biology : quantitative biosciences from nano to macro.

[87]  Jane Y. Zhao,et al.  Skeletal muscle regeneration by extracellular matrix biological scaffold: a case report. , 2018, Journal of wound care.

[88]  H. Ruohola-Baker,et al.  Dystrophin-deficient cardiomyocytes derived from human urine: new biologic reagents for drug discovery. , 2014, Stem cell research.

[89]  J. Chun,et al.  Sphingosine 1-phosphate receptor-1 in cardiomyocytes is required for normal cardiac development. , 2016, Developmental biology.

[90]  B. Darpö,et al.  Spectrum of drugs prolonging QT interval and the incidence of torsades de pointes , 2001 .

[91]  M. Hori,et al.  GATA-4 regulates cardiac morphogenesis through transactivation of the N-cadherin gene. , 2003, Biochemical and biophysical research communications.

[92]  D. Atsma,et al.  The effect of sarcolemmal cholesterol content on intracellular calcium ion concentration in cultured cardiomyocytes. , 1994, Archives of biochemistry and biophysics.

[93]  Dajun Chen,et al.  Enhanced Mechanical Properties of Graphene-Based Poly(vinyl alcohol) Composites , 2010 .

[94]  R. Lazzara,et al.  Spontaneous Adverse Event Reports of Serious Ventricular Arrhythmias, QT Prolongation, Syncope, and Sudden Death in Patients Treated with Cisapride , 2002, Journal of cardiovascular pharmacology and therapeutics.

[95]  Deok‐Ho Kim,et al.  Conductive Silk-Polypyrrole Composite Scaffolds with Bioinspired Nanotopographic Cues for Cardiac Tissue Engineering. , 2018, Journal of materials chemistry. B.

[96]  Tal Dvir,et al.  Coiled fiber scaffolds embedded with gold nanoparticles improve the performance of engineered cardiac tissues. , 2014, Nanoscale.

[97]  David Tweedie,et al.  Differentiation of Pluripotent Embryonic Stem Cells Into Cardiomyocytes , 2002, Circulation research.

[98]  A. Murphy,et al.  Troponin I isoform expression in human heart. , 1991, Circulation research.

[99]  Chwee Teck Lim,et al.  Origin of enhanced stem cell growth and differentiation on graphene and graphene oxide. , 2011, ACS nano.