Abstract
Despite improvements over the past 30 years, 10-year pediatric heart transplantation survival rates remain low and mechanical support is both expensive and relatively unavailable. In contrast to isolated cell therapies, implantable engineered cardiac tissues (ECTs) recover myocardial mass and function, creating the opportunity for cardiac recovery rather than replacement. Our ECT research has progressed from using embryonic avian and rodent cell compositions to human induced pluripotent stem cell (h-iPSC)-derived, multiple cell lineage formulations with the goal of clinical translation. We generate ECTs from h-iPSC-derived cardiomyocytes (CM), endothelial cells (EC), and vascular mural cells (MC) in both linear (15 × 1 mm) and large format (LF, 20 × 20 mm) geometries using rodent-derived and human-compatible reagents. H-iPSC ECTs undergo rapid gel compaction and begin intrinsic beating by day 3. CM fraction at ECT formation is approximately 60%. The ECT maximum capture rates increased during in vitro culture up to 28 days and in response to optogenetic pacing (OP) using AAV-ChIEF from day 7 to 14. ECT relaxation times decreased, force-frequency relations became more neutral, and beat-to-beat hysteresis decreased with prolonged culture or OP. H-iPSC-derived ECTs generated using human collagen I and human compatible MaxGel have comparable structural and functional features to rodent-derived ECTs. Linear and LF-ECTs implanted onto xenotolerant infarcted rat hearts survived, engrafted, improved ejection fraction, normalized regional echo strain, and reduced scar area at 4 weeks. Thus, these h-iPSC ECT compositions show promise as a strategy for pediatric myocardial recovery.
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Keywords
- Cardiomyocytes
- Cardiac repair and regeneration
- Engineered cardiac tissues
- Induced pluripotent stem cells
1 Introduction
Despite dramatic progress in the surgical management and survival of infants with complex congenital heart defects, myocardial injury following cardiac surgery and progressive cardiac dysfunction results in significant morbidity and mortality. There are currently many cardiac “cellular therapies” undergoing pre-clinical and clinical trials in adults. There have been small, encouraging clinical trials using stem cells in infants with hypoplastic left heart syndrome in Japan [1,2,3] that have led to similar trials in the United States [4,5,6]. It is clear that injected or implanted cells do not survive and that functional improvement occurs via paracrine mechanisms that impact angiogenesis and/or remodeling. Rapid advances in tissue engineering over the past two decades have resulted in the generation of functional, multicellular, 3D cardiac tissues with the potential for translation to human cardiac repair and regeneration [7,8,9,10,11,12,13,14]. This chapter provides a concise overview of some of the key issues in the generation, maturation, and translation of these engineered cardiac tissues (ECTs) and related work in our laboratory.
2 Continued Expansion of Engineered Cardiac Tissues (ECTs)
Following the initial description of 3D-reconstituted heart tissue using embryonic chick CM [7], CM species used to generate ECTs include chicken, mouse, and rat embryonic and post-natal CM, and a range of embryonic stem cells and induced pluripotent stem cells from rodents and human cell lines [8,9,10,11,12,13,14,15,16]. While initial formulations used a combination of cells, matrix factors, and collagen, additional compositions have utilized fibrin rather than collagen to reduce the effect of matrix stimulated inflammation [17] and tunable matrix compositions [18]. ECTs became increasingly popular as in vitro platforms for drug toxicology models [19] as well as for in vitro models for cardiac genetic disease modeling and repair [20].
3 Human Induced Pluripotent Stem Cell (H-iPSC) Linear ECTs
While cells from multiple vertebrate species have been used to investigate ECT structural and functional maturation and to model cardiomyopathies, it is clear that human cells are required for clinical trials and future therapies. H-iPSCs can be differentiated to cardiac lineages and produced in the quantities required for pre-clinical and future clinical trials. Multiple studies have validated the ability of h-iPSC-derived CM to mature and form implantable cell sheets [21]. To advance this paradigm, we developed and validated methods to generate linear (15 mm length × 1 mm diameter) ECTs from human iPSCs-derived CV lineages (h-iPSC-ECTs) [11]. We found that the coexistence of EC and MC vascular lineages with CMs within the 3D ECT compositions promoted tissue maturation (Fig. 54.1). Furthermore, we demonstrated the therapeutic potential of h-iPSC ECTs in an immune-tolerant rat myocardial infarction (MI) model showing the improvement of cardiac function with regenerated myocardium and enhanced angiogenesis [11].
4 Generation and Characterization of Large Format H-iPSC ECTs
Larger-format ECTs have been described using pre-vascularization, stacking cell sheets, scalable scaffolds, and bioprinting [12, 22]. Building on our success with linear h-iPSC ECTs and guided by initial works from the Bursac lab using polydimethylsiloxane (PDMS) molds, we fabricated a range of mold geometries from 0.5 mm thick PDMS sheets to generate a novel large-format hiPSC-ECT (LF-ECT, Fig. 54.2). As with our linear h-iPSC ECTs, these h-iPSC LF-ECTs undergo gel compaction, spontaneously and then synchronously beat, develop CM alignment along the internal bundle long axis, and survive in vivo implantation to recover myocardial function in an immune-tolerant rodent MI model [12]. Though unpublished, we have scaled this LF-ECT geometry to 30 × 30 mm, suitable for large animal pre-clinical studies.
5 Optogenetic Pacing of H-iPSC ECTs
One of the barriers to h-iPSC-derived ECT clinical translation is the relative electrophysiologic and contractile immaturity of h-iPSC-derived CMs. Strategies to mature CM within tissue-engineered structures include cyclic mechanical loading and electric field stimulation. As a novel approach, we designed proof-of-principle experiments to transfect h-iPSC-derived ECTs with a desensitization-resistant, chimeric channel rhodopsin, ChR (ChIEF) protein and then optically pace (OP) ECTs to accelerate maturation. We transfected h-iPSC ECTs using an AAV-packaged ChIEF and then verified OP by whole-cell patch clamp. ECTs were then chronically OP (C-OP) above their intrinsic beat rates in vitro from day 7 to 14. C-OP resulted in improved ECT electrophysiological properties and subtle changes in the expression of some cardiac relevant genes though active force generation and histology were unchanged (Fig. 54.3). These results validate the feasibility of a novel C-OP paradigm for non-invasive and scalable OP-induced ECT maturation strategies.
6 Incorporating Human Compatible Biomaterials into H-iPSC ECTs
An additional barrier to the clinical translation of h-iPSC-derived ECTs is the qualification of all reagents for human use as required by the FDA. Therefore, we revised our h-iPSC ECT formulation to replace rodent-derived Matrigel with human-derived and clinically acceptable MaxGel and replaced rodent type with human type I collagen. These experiments required multiple variations in composition but ultimately resulted in a human compatible h-iPSC-derived linear ECT with structural and functional features equivalent or better than ECTs formulated with rodent-derived matrix reagents (Fig. 54.4). While higher cost, these experiments provide additional insights for the formulations required for h-iPSC translation to humans.
7 Future Directions and Clinical Implications
Clearly, biological repair and replacement of lost myocardium using h-iPSCs that can form myocardium (versus skeletal muscle) are feasible, and clinical trials to determine safety and feasibility in adult heart failure patients should occur in the near future. It is important to note that many adult stem cell trials have shown statistically and clinically significant improvements in heart failure patients, and studies using stem cells have shown encouraging results for children with congenital heart disease [1,2,3,4]. The use of isolated cells, or the exosomes extracted from cells, may represent a much simpler therapeutic product to manufacture, verify, and distribute for future clinical therapy compared to the complexities of generating engineered tissues (multi-layer cell sheets and ECTs). Translation of these more complex formulations will require the engagement of biotechnology and biopharma companies with expertise in semi-automated manufacturing techniques and complex biologic quality controls not available in academic environments. Fortunately, every innovation in CV care for infants and children has been shown to also be valuable for the treatment of the much larger adult market. Therefore, the opportunities to translate h-iPSC ECTs towards infants and children with significant myocardial injury and heart failure remain encouraging.
References
Tsilimigras DI, Oikonomou EK, Moris D, et al. Stem cell therapy for congenital heart disease: a systematic review. Circulation. 2017;136(24):2373–85.
Sano T, Ousaka D, Goto T, et al. Impact of cardiac progenitor cells on heart failure and survival in single ventricle congenital heart disease. Circ Res. 2018;122:994. https://doi.org/10.1161/CIRCRESAHA.117.312311.
ClinicalTrials.gov. NCT01829750: Cardiac Progenitor Cell Infusion to Treat Univentricular Heart Disease (PERSEUS). Phase I study to investigate the efficacy of intracoronary infusion of cardiac progenitor cells in patients with univentricular heart disease. Dr. Hidemasa Oh, PI.
Kaushal S, Wehman B, Pietris N, et al. Study design and rationale for ELPIS: a phase I/IIb randomized pilot study of allogeneic human mesenchymal stem cell injection in patients with hypoplastic left heart syndrome. Am Heart J. 2017;192:48–56.
ClinicalTrials.gov. NCT01883076: Autologous Umbilical Cord Blood Cells for HLHS. Phase I study to determine the safety and feasibility of injections of autologous umbilical cord blood (UCB) cells into the right ventricle of Hypoplastic Left Heart Syndrome (HLHS) children undergoing a scheduled Glenn surgical procedure. Dr. Tim Nelson, PI.
ClinicalTrials.gov. NCT02781922: Cardiac Stem/Progenitor Cell Infusion in Univentricular Physiology (APOLLON Trial). The purpose of this study is to evaluate the efficacy and safety of intracoronary injection of autologous cardiac stem cells (JRM-001) after reconstructive surgery in pediatric patients with functional single ventricle Japan Regenerative Medicine Co., Ltd, PI.
Eschenhagen T, Fink C, Remmers U, et al. Three-dimensional reconstitution of embryonic cardiomyocytes in a collagen matrix: a new heart muscle model system. FASEB J. 1997;11(8):683–94.
Tobita K, Liu LJ, Janczewski AM, et al. Engineered early embryonic cardiac tissue retains proliferative and contractile properties of developing embryonic myocardium. Am J Physiol Heart Circ Physiol. 2006;291(4):H1829–37.
Fujimoto KL, Clause KC, Liu LJ, et al. Engineered fetal cardiac graft preserves its cardiomyocyte proliferation within post-infarcted myocardium and sustains cardiac function. Tissue Eng Part A. 2011;17(5–6):585–96.
Tulloch NL, Muskheli V, Razumova MV, et al. Growth of engineered human myocardium with mechanical loading and vascular coculture. Circ Res. 2011;109:47–59.
Masumoto H, Nakane T, Tinney JP et al 2016 The potential of three-dimensional engineered cardiac tissues composed of multiple human iPS cell-derived cardiovascular cell lineages for cardiac regeneration. Sci Rep 6:29933. YouTube: https://www.youtube.com/watch?v=dDUtxP-zcP0.
Nakane T, Masumoto H, Tinney JP, et al. Development of a large-format engineered cardiac tissue from human induced pluripotent stem cells-derived multiple lineage cardiac cells. Sci Rep. 2017;7:45641.
Kowalski WJ, Yuan FP, Nakane T, et al. Quantification of cardiomyocyte alignment from 3D confocal microscopy of engineered tissue. Microsc Microanal. 2017;23:826–42.
Fujita B, Zimmermann WH. Myocardial tissue engineering for regenerative applications. Curr Cardiol Rep. 2017;19(9):78. Review.
Tiburcy M, Hudson JE, Balfanz P, et al. Defined engineered human myocardium with advanced maturation for applications in heart failure modeling and repair. Circulation. 2017;135(19):1832–47.
Li RA, Keung W, Cashman TJ, et al. Bioengineering an electro-mechanically functional miniature ventricular heart chamber from human pluripotent stem cells. Biomaterials. 2018;163:116–27.
Conradi L, Schmidt S, Neofytou E, et al. Immunobiology of fibrin-based engineered heart tissue. Stem Cells Transl Med. 2015;4(6):625–31.
Williams C, Budina E, Stoppel WL, et al. 3rd Cardiac extracellular matrix-fibrin hybrid scaffolds with tunable properties for cardiovascular tissue engineering. Acta Biomater. 2015;14:84–95.
Feric NT, Radisic M. Towards adult-like human engineered cardiac tissue: maturing human pluripotent stem cell-derived cardiomyocytes in human engineered cardiac tissues. Adv Drug Deliv Rev. 2016;96:110–34.
Long C, Li H, Tiburcy M, Rodriguez-Caycedo C, et al. Correction of diverse muscular dystrophy mutations in human engineered heart muscle by single-site genome editing. Sci Adv. 2018;4(1):eaap9004.
Masumoto H, Ikuno T, Takeda M, et al. Human iPS cell-engineered cardiac tissue sheets with cardiomyocytes and vascular cells for cardiac regeneration. Sci Rep. 2014;4:6716. https://doi.org/10.1038/srep06716.
Miyagawa S, Domae K, Yoshikawa Y, et al. Phase I clinical trial of autologous stem cell-sheet transplantation therapy for treating cardiomyopathy. J Am Heart Assoc. 2017;6(4). pii: e003918) https://doi.org/10.1161/JAHA.116.003918.
Acknowledgments
This research was funded by the Kosair Charities Pediatric Heart Research Endowment Fund. All h-iPSCs used for this research were provided under a materials transfer agreement between the University of Louisville Research Foundation and the Center for iPS Cell Research and Application, Kyoto University. The authors acknowledge the collaborative support of Dr. Jun K. Yamashita, Principal Investigator, Department of Cell Growth and Differentiation, Center for iPS Cell Research and Application, Kyoto University.
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Ye, F. et al. (2020). Progress in the Generation of Multiple Lineage Human-iPSC-Derived 3D-Engineered Cardiac Tissues for Cardiac Repair. In: Nakanishi, T., Baldwin, H., Fineman, J., Yamagishi, H. (eds) Molecular Mechanism of Congenital Heart Disease and Pulmonary Hypertension. Springer, Singapore. https://doi.org/10.1007/978-981-15-1185-1_54
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