3D bioprinted functional and contractile cardiac tissue constructs.

Bioengineering of a functional cardiac tissue composed of primary cardiomyocytes has great potential for myocardial regeneration and in vitro tissue modeling. However, its applications remain limited because the cardiac tissue is a highly organized structure with unique physiologic, biomechanical, and electrical properties. In this study, we undertook a proof-of-concept study to develop a contractile cardiac tissue with cellular organization, uniformity, and scalability by using three-dimensional (3D) bioprinting strategy. Primary cardiomyocytes were isolated from infant rat hearts and suspended in a fibrin-based bioink to determine the priting capability for cardiac tissue engineering. This cell-laden hydrogel was sequentially printed with a sacrificial hydrogel and a supporting polymeric frame through a 300-µm nozzle by pressured air. Bioprinted cardiac tissue constructs had a spontaneous synchronous contraction in culture, implying in vitro cardiac tissue development and maturation. Progressive cardiac tissue development was confirmed by immunostaining for α-actinin and connexin 43, indicating that cardiac tissues were formed with uniformly aligned, dense, and electromechanically coupled cardiac cells. These constructs exhibited physiologic responses to known cardiac drugs regarding beating frequency and contraction forces. In addition, Notch signaling blockade significantly accelerated development and maturation of bioprinted cardiac tissues. Our results demonstrated the feasibility of bioprinting functional cardiac tissues that could be used for tissue engineering applications and pharmaceutical purposes. STATEMENT OF SIGNIFICANCE Cardiovascular disease remains a leading cause of death in the United States and a major health-care burden. Myocardial infarction (MI) is a main cause of death in cardiovascular diseases. MI occurs as a consequence of sudden blocking of blood vessels supplying the heart. When occlusions in the coronary arteries occur, an immediate decrease in nutrient and oxygen supply to the cardiac muscle, resulting in permanent cardiac cell death. Eventually, scar tissue formed in the damaged cardiac muscle that cannot conduct electrical or mechanical stimuli thus leading to a reduction in the pumping efficiency of the heart. The therapeutic options available for end-stage heart failure is to undergo heart transplantation or the use of mechanical ventricular assist devices (VADs). However, many patients die while being on a waiting list, due to the organ shortage and limitation of VADs, such as surgical complications, infection, thrombogenesis, and failure of the electrical motor and hemolysis. Ultimately, 3D bioprinting strategy aims to create clinically applicable tissue constructs that can be immediately implanted in the body. To date, the focus on replicating complex and heterogeneous tissue constructs continues to increase as 3D bioprinting technologies advance. In this study, we demonstrated the feasibility of 3D bioprinting strategy to bioengineer the functional cardiac tissue that possesses a highly organized structure with unique physiological and biomechanical properties similar to native cardiac tissue. This bioprinting strategy has great potential to precisely generate functional cardiac tissues for use in pharmaceutical and regenerative medicine applications.

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

[2]  Vladimir Mironov,et al.  Organ printing: tissue spheroids as building blocks. , 2009, Biomaterials.

[3]  Megan L. McCain,et al.  Ensembles of engineered cardiac tissues for physiological and pharmacological study: heart on a chip. , 2011, Lab on a chip.

[4]  K. Y. Ye,et al.  Encapsulation of Cardiomyocytes in a Fibrin Hydrogel for Cardiac Tissue Engineering , 2011, Journal of visualized experiments : JoVE.

[5]  N. Sharpe,et al.  Left ventricular remodeling after myocardial infarction: pathophysiology and therapy. , 2000, Circulation.

[6]  Jonathan A. Bernstein,et al.  Using iPS cells to investigate cardiac phenotypes in patients with Timothy Syndrome , 2011, Nature.

[7]  Patrizia Camelliti,et al.  Adult human heart slices are a multicellular system suitable for electrophysiological and pharmacological studies. , 2011, Journal of molecular and cellular cardiology.

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

[9]  Yong Chen,et al.  3D printing of soft lithography mold for rapid production of polydimethylsiloxane-based microfluidic devices for cell stimulation with concentration gradients , 2015, Biomedical microdevices.

[10]  Visar Ajeti,et al.  Myocardial Tissue Engineering With Cells Derived From Human-Induced Pluripotent Stem Cells and a Native-Like, High-Resolution, 3-Dimensionally Printed Scaffold , 2017, Circulation research.

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

[12]  G. Jung,et al.  3D-Printed Microfluidic Device for the Detection of Pathogenic Bacteria Using Size-based Separation in Helical Channel with Trapezoid Cross-Section , 2015, Scientific Reports.

[13]  E. Ballestar,et al.  Notch signaling is essential for ventricular chamber development. , 2007, Developmental cell.

[14]  Tse Nga Ng,et al.  Scalable printed electronics: an organic decoder addressing ferroelectric non-volatile memory , 2012, Scientific Reports.

[15]  Gordana Vunjak-Novakovic,et al.  Engineered microenvironments for human stem cells. , 2008, Birth defects research. Part C, Embryo today : reviews.

[16]  M. Nemir,et al.  Jagged1 intracellular domain-mediated inhibition of Notch1 signalling regulates cardiac homeostasis in the postnatal heart , 2015, Cardiovascular research.

[17]  James J. Yoo,et al.  Complex heterogeneous tissue constructs containing multiple cell types prepared by inkjet printing technology. , 2013, Biomaterials.

[18]  J. Epstein,et al.  Coordinating tissue interactions: Notch signaling in cardiac development and disease. , 2012, Developmental cell.

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

[20]  D. Diamond,et al.  Advances in three-dimensional rapid prototyping of microfluidic devices for biological applications. , 2014, Biomicrofluidics.

[21]  Andreas Hess,et al.  Engineered heart tissue grafts improve systolic and diastolic function in infarcted rat hearts , 2006, Nature Medicine.

[22]  N. Gude,et al.  Notch signaling and cardiac repair. , 2012, Journal of molecular and cellular cardiology.

[23]  Dong-Woo Cho,et al.  3D printed complex tissue construct using stem cell-laden decellularized extracellular matrix bioinks for cardiac repair. , 2017, Biomaterials.

[24]  Kevin Kit Parker,et al.  Generation of Functional Ventricular Heart Muscle from Mouse Ventricular Progenitor Cells , 2009, Science.

[25]  Ali Khademhosseini,et al.  Micro- and nanoscale control of the cardiac stem cell niche for tissue fabrication. , 2009, Tissue engineering. Part B, Reviews.

[26]  T. Okano,et al.  Composite Cell Sheets: A Further Step Toward Safe and Effective Myocardial Regeneration by Cardiac Progenitors Derived From Embryonic Stem Cells , 2010, Circulation.

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

[28]  Milica Radisic,et al.  Challenges in cardiac tissue engineering. , 2010, Tissue engineering. Part B, Reviews.

[29]  Gordon G. Wallace,et al.  Biofabrication: an overview of the approaches used for printing of living cells , 2013, Applied Microbiology and Biotechnology.

[30]  N. Bursac,et al.  Controlling the structural and functional anisotropy of engineered cardiac tissues , 2014, Biofabrication.

[31]  Stefan Wagner,et al.  Murine and human pluripotent stem cell-derived cardiac bodies form contractile myocardial tissue in vitro. , 2013, European heart journal.

[32]  M. V. van Amerongen,et al.  Features of cardiomyocyte proliferation and its potential for cardiac regeneration , 2008, Journal of cellular and molecular medicine.

[33]  Wesley R. Legant,et al.  Microfabricated tissue gauges to measure and manipulate forces from 3D microtissues , 2009, Proceedings of the National Academy of Sciences.

[34]  M. Nemir,et al.  Functional role of Notch signaling in the developing and postnatal heart. , 2008, Journal of molecular and cellular cardiology.

[35]  Anthony Atala,et al.  3D bioprinting of tissues and organs , 2014, Nature Biotechnology.

[36]  Euan A. Ashley,et al.  Patient-Specific Induced Pluripotent Stem Cells as a Model for Familial Dilated Cardiomyopathy , 2012, Science Translational Medicine.

[37]  Savas Tasoglu,et al.  Bioprinting: Functional droplet networks. , 2013, Nature materials.

[38]  L. Greensmith,et al.  Characterization and optimization of a simple, repeatable system for the long term in vitro culture of aligned myotubes in 3D , 2012, Journal of cellular biochemistry.

[39]  N. Jones Science in three dimensions: The print revolution , 2012, Nature.

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

[41]  David A. Hutchins,et al.  A Simple, Low-Cost Conductive Composite Material for 3D Printing of Electronic Sensors , 2012, PloS one.

[42]  James J. Yoo,et al.  A 3D bioprinting system to produce human-scale tissue constructs with structural integrity , 2016, Nature Biotechnology.

[43]  N. Cooper,et al.  Gene expression profiles in engineered cardiac tissues respond to mechanical loading and inhibition of tyrosine kinases , 2013, Physiological reports.

[44]  Mark D. Huffman,et al.  Heart disease and stroke statistics--2013 update: a report from the American Heart Association. , 2013, Circulation.

[45]  Kam W Leong,et al.  Pluripotent stem cell-derived cardiac tissue patch with advanced structure and function. , 2011, Biomaterials.

[46]  Megan L. McCain,et al.  A tissue-engineered jellyfish with biomimetic propulsion , 2012, Nature Biotechnology.