Abstract
Adult and pluripotent stem cells represent a ready supply of cellular raw materials that can be used to generate the functionally mature cells needed to replace damaged or diseased heart tissue. However, the use of stem cells for cardiac regenerative therapies is limited by the low efficiency by which stem cells are differentiated in vitro to cardiac lineages as well as the inability to effectively deliver stem cells and their derivatives to regions of damaged myocardium. In this review, we discuss the various biomaterial-based approaches that are being implemented to direct stem cell fate both in vitro and in vivo. First, we discuss the stem cell types available for cardiac repair and the engineering of naturally and synthetically derived biomaterials to direct their in vitro differentiation to the cell types that comprise heart tissue. Next, we describe biomaterial-based approaches that are being implemented to enhance the in vivo integration and differentiation of stem cells delivered to areas of cardiac damage. Finally, we present emerging trends of using stem cell-based biomaterial approaches to deliver pro-survival factors and fully vascularized tissue to the damaged and diseased cardiac tissue.
Keywords: stem cell, pluripotent stem cell, biomaterials, cardiac regeneration
Introduction
Cardiovascular diseases are the leading causes of morbidity and mortality in the United States. Every 43 seconds an American experiences a myocardial infarction (MI), which can lead to the death of up to 1 billion cardiomyocytes in the left ventricle, translating to approximately 50 g of muscle mass.1–3 Unlike in some model organisms such as zebrafish, the mammalian heart has limited regenerative capacity.4 As a result, cardiac injury triggers a pathologic adaptive cascade resulting in tissue remodeling, myocyte hypertrophy, and eventual catastrophic heart failure.5,6 Current therapeutic strategies such as surgical, endovascular, and pharmacological interventions6–9 are merely palliative in nature and do not adequately address the true cause of heart failure – the loss of functional myocytes and supporting cardiac tissue.10 As such, heart transplantation is the only effective treatment option to replace damaged or diseased myocardium. However, the limited number of available donors and complications from immune rejection of transplanted organs make cardiac transplants impractical for the vast number of people affected by heart failure and disease.
Over the past several years, the integration of stem cell biology with biomaterials science has resulted in the development of several promising strategies for the regeneration of various tissues and organs.11 In this review, we discuss the extent to which biomaterial-based approaches are aiding myocardial regenerative medicine efforts in the following ways: (i) improving the in vitro differentiation of stem cells to cardiomyocytes and (ii) guiding the delivery and integration of transplanted stem cells. We then speculate on the future of biomaterial-based approaches for stem cell myocardial tissue engineering.
Stem Cell Types for Cardiac Repair
Although a variety of mature cell types isolated from primary and fetal tissue sources have been used to repair the damaged cardiac tissue in animal models and clinical trials,12,13 this review focuses on the development of stem cell-based biomaterial approaches for myocardium regenerative purposes. Broadly speaking, stem cells are defined by two common characteristics: (i) the ability to self-renew or proliferate indefinitely and (ii) the potential to differentiate into one or more specialized cell types. As such, stem cells can be categorized into two types, which have differing differentiation potentials: (i) pluripotent stem cells [PSCs; including embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs)], which can give rise to hundreds of cell types that comprise the adult body, and (ii) adult stem cells, which can only differentiate into a small subset of specialized mature cells. The characteristics, advantages, and limitations of each of these cell sources for cardiac regenerative medicine purposes are summarized in Table 1.
Table 1.
STEM CELL | ADVANTAGES | DISADVANTAGES | CLINICAL TRIALS |
---|---|---|---|
Embryonic stem cells (ESCs) | Robust in vitro expansion Broad differentiation potential |
Potential tumor formation upon in vivo transplantation Potential for immune rejection Ethical issues associated with derivation |
NCT02057900: Transplantation of human embryonic stem cell-derived progenitors in severe heart failure |
Induced pluripotent stem cells (iPSC) | Robust in vitro expansion Broad differentiation potential Limited ethical issues Ability to generate patient-specific therapies |
Potential tumor formation upon in vivo transplantation Use of oncogenes for derivation Genetic and epigenetic instability |
None reported |
Bone-marrow derived mesenchymal stem cells (MSCs) | Limited ethical issues Ability to generate autologous therapies |
Limited in vitro expansion Difficult to isolate Limited cardiac differentiation potential |
NCT00279175: REPAIR-AMI: intracoronary progenitor cells in acute myocardial infarction NCT00684021: Use of adult autologous stem cells in treating people who have had a heart attack (the TIME study) NCT00877903: Prochymal® (human adult stem cells) intravenous infusion following acutemyocardial infarction (AMI) |
Adipose derived stem cells (ADSCs) | Easy to isolate Robust in vitro expansion Limited ethical issues Ability to generate autologous therapies |
Limited cardiac differentiation potential |
NCT01556022: Safety and feasibility trial of adipose-derived regenerative cells in the treatment of chronic myocardial ischemia (ATHENA) NCT02052427: Safety and efficacy of adipose-derived regenerative cells in the treatment of chronic myocardial ischemia (ATHENA II) NCT01449032: MesenchYmal STROMAL CELL therapy in patients with chronic myocardial ischemia (MyStromalCell Trial) |
Cardiac progenitor cells (CPCs) | Robust in vitro expansion Broad cardiac differentiation potential Limited ethical issues Ability to generate autologous therapies |
Difficult to isolate Lack of consensus on purification methods |
NCT00474461: Cardiac stem cell infusion in patients with ischemic cardiomyopathy (SCIPIO) NCT00893360: CArdiosphere-derived aUtologous stem CElls to reverse ventricUlar dySfunction (CADUCEUS) |
Pluripotent stem cells
PSCs, which include ESCs and iPSCs, have the potential to differentiate into hundreds of specialized cell types that comprise the fully mature adult body. Although there are some slight genetic and epigenetic differences between ESCs and iPSCs,14,15 both the cells have the ability to provide the raw material that is necessary for cardiac tissue engineering. There are a wide variety of protocols used to generate cardiomyocytes from PSC through the temporal addition of growth factors that mimic in vivo cardiac development.16–26
Embryonic stem cells
ESCs are derived from the inner cell mass of a preimplantation embryo. The first ESCs were isolated from mouse embryos by two independent groups in the early 1980s.27,28 In 1998, Thomson led a group of researchers who developed for the first time methods to isolate and propagate human ESCs (hESCs).29 This seminal discovery ushered in a new era of regenerative medicine where hESCs could be used for the generation of functionally mature human cells, including cardiac tissue.
Several groups have reported the differentiation of mouse ESCs (mESCs)30–32 and hESCs33–36 to cardiomyocytes that express well-organized sarcomeric proteins and display synchronous contractile activity. Further genetic and molecular analyses of in vitro derived cardiomyocytes have revealed that these cells display properties similar to early-stage, fetal cardiomyocytes, thereby potentially limiting their therapeutic potential.37 In fact, several studies have evaluated the potential of ESC-derived cardiomyocytes in repairing the damaged cardiac tissue in animal models of MI. As such, these studies have shown that transplanted cardiomyocytes derived from both mESCs38,39 and hESCs23,40–42 integrate with host tissue and can lead to the improvement of cardiac function. However, there remains considerable debate as to whether these transplanted cells suppress43 or induce44,45 cardiac arrhythmias in injured hearts. Finally, additional hurdles such as complications associated with immune rejection and ethical issues may limit the clinical application of cardiomyocytes derived from hESCs.46 Despite these challenges, there are ongoing clinical trials assessing the feasibility and safety of a transplantation of hESC-derived cardiac-committed progenitor cells derived in patients with severe heart failure (ClinicalTrials.gov Identifier: NCT02057900).
Induced pluripotent stem cells
IPSCs are PSCs generated through the reprograming of somatic cells into a pluripotent state. IPSCs were first generated by Yamanaka’s group in 2006 from mouse fibroblasts47 and then in 2007 from human fibroblasts.48 Because generation of human induced pluripotent stem cells (hiPSCs) does not involve the destruction of human embryos, they are not subject to the same ethical considerations as hESCs. HiPSCs have an additional advantage that they do not generate an immune response in the recipient from which they were derived, although recently this has been subject to a considerable debate.49,50 Additionally, cardiomyocytes generated from patient-specific cells can be used to provide important insights in disease pathology, progression, and mechanism, as well as an unlimited source of cells, and to enable the development of compounds and the screening of potential drugs.51–53
Adult stem cells
Tissue-specific adult stem cells are more limited in their differentiation potential compared to PSCs. Additionally, unlike PSCs, which can be propagated in culture indefinitely, adult stem cells are difficult to maintain and expand in vitro, Within the body, adult stem cells are located in complex microenvironments, called niches, which tightly regulate their self-renewal and differentiation.54 Adult stem cells have been isolated from a variety of tissues, including the mammary glands (mammary stem cells),55 the base of the crypt of the intestinal epithelium (intestinal stem cells),56 basal layer of the epidermis (epidermal stem cells),57 Subventricular zone of the lateral ventricle and the subgranular zone of the hippocampus in the central nervous system (neural stem cells),58 the bulge region of the epithelial stem cells in the hair follicle,59 the basal layer of the seminiferous tubules (germline stem cells),60 under the basal lamina of myofibers (muscle satellite cells),61 and the bone marrow (hematopoietic stem cells).62 The following three additional adult stem cell populations have been widely used in cardiac tissue engineering applications: (i) mesenchymal stem cells (MSCs), (ii) adipose-derived stem cells (ADSCs), and (iii) cardiac progenitor cells (CPCs).
Bone marrow-derived MSCs
MSCs are derived from the nonhematopoietic stromal component of the bone marrow.63,64 Most commonly, MSCs are isolated using fluorescence-or magnetic-activated cell sorting with a combination of positive (eg, CD13, CD29, CD44, CD73, CD90, CD105, STRO-1) and negative (eg, CD3, CD14, CD15, CD28, CD33, CD34, CD45, HLA-DR) selection markers.65,66 Several groups have shown that MSCs have the potential to differentiate into a variety of nonmarrow cells such as bone, cartilage, connective tissue fat, and endothelial cells.67 However, the existence and differentiation potential of MSCs has been somewhat controversial as some studies suggest that MSCs and fibroblasts are identical.68 Nonetheless, several groups have reported the in vitro directed differentiation of MSCs to cardiomyocyte-like cells through a variety of approaches, including incubation with media that has been conditioned on primary ventricular cardiomyocytes69 and addition of chemical factors such as the DNA methylation inhibitor 5-azacytidine.70,71 Although cells generated using these methods express early cardiomyocyte markers such as cardiac myosin heavy chain (MHC), cardiac troponin T (cTnT), and connexin 43, in-depth electrophysiological and functional analyses of such resultant populations have yet to be reported.
Despite the lack of in vitro analysis of the cardiac differentiation potential of MSCs, several studies have reported the transplantation of MSCs or MSC-derived cardiac cells in animal models of cardiac damage.72–77 For example, in a study performed by Orlic et al, isolated MSCs were injected into the ventricular portion of an infarcted heart.78 The engrafted MSCs generated de novo myocardium and ameliorated the outcome of coronary artery disease in the treated animals. Along similar lines, transplantation of MSC-derived cardiac cells into a cryoinjury-derived scar in the left ventricle resulted in the repair of scar tissue and improved cardiac function.70
Because of the promising results observed in preclinical animal models of cardiac injury and disease, numerous clinical trials have been performed to examine the ability of MSCs to ameliorate or reverse the effects of tissue damage caused by MI. Overall, the results of these clinical trials have been met with mixed success.79 Some trials have demonstrated that autologous MSC transplantation leads to improved ventricular function and survival in patients several years after transplantation.80 On the other hand, recent studies have not shown significant improvement of ventricular function after either intracoronary81 or transendocardial82 delivery of autologous MSCs in patients with acute MI81 or ischemic cardiomyopathy.82
Adipose-derived stem cells
ADSCs have been isolated using cell sorting approaches from a variety of sources, including human white and brown adipose tissues.83,84 Similar to MSCs, ADSCs have the ability to undergo osteogenesis, chondrogenesis, and adipogenesis. However, ADSCs may be advantageous over MSCs as a source of material for cell-based therapies because of relative ease of their isolation and ability for their long-term in vitro expansion. Several groups have examined the in vitro ability of ADSCs to differentiate into cardiomyocytes.85–87 For example, Planat-Bénard et al demonstrated that the addition of 5-azacytidine to ADSC cultures resulted in cells that expressed cardiac-specific markers such as GATA4, NKX2.5, ANP, MLC2v, and MLC2a.85 Additionally, ultrastructural and electrophysiological analyses revealed the presence of functional atrial, ventricular, and nodal cardiomyocytes. Similarly, other groups have shown that modulation of soluble signaling pathways such as Wnt/β-catenin87 and vascular endothelial growth factor88 enhances the cardiac differentiation of ADSCs. On the other hand, some argue that ADSCs lack inherent cardiac differentiation potential89 and that only through direct fusion with primary cardiomyocytes can ADSCs display cardiomyocyte-like phenotypes.90
In subsequent studies in animal models of cardiac damage, delivery of ADSCs through direct intramyocardial injection91 or indirectly through intravenous92 or intracoronary93 injections has resulted in the repair of damaged myocardial tissue and improved cardiac function. A clinical trial examining the effects of transendocardial injections of ADSCs in patients with nonrevascularizable ischemic myocardium demonstrated that ADSC-treated patients showed significant improvements in total left ventricular mass and reductions in inducible ischemia. Additionally, these studies revealed that ADSCs preserved ventricular function, myocardial perfusion, and exercise capacity in ischemic patients.94 Additional ongoing clinical trials are examining the safety and efficacy of ADSCs in patients with chronic myocardial ischemia (ClinicalTrials.gov Identifiers: NCT02052427, NCT01556022, and NCT01449032).
Cardiac progenitor cells
Several studies over the past decade have demonstrated the existence of a CPC population that can contribute to cardiac tissue homeostasis and repair.46,95–98 CPCs can be isolated from functionally mature cardiac tissue using a variety of cell surface markers, including c-Kit,95 Sca-1,96 CD31,97 Flk-1,99 Flt1+/Flt4+,98 or on the ability to efflux Hoechst dye.100 Although there is a lack of consensus of the specific markers that should be used to isolate CPCs from primary tissue,101 CPCs share the following common characteristics: (i) express early cardiac markers (eg, GATA4, NKX2.5), (ii) can be expanded in vitro through modulation of various pathways such as Wnt/β-catenin102,103 and FGF104 signaling, and (iii) are capable of generating the three major cell types that comprise the myocardium – cardiomyocytes, smooth muscle, and endothelial cells. As it relates to in vitro generation of cardiomyocytes, treatment of CPCs with 5-azacytidine or other signaling molecules such as TGF-β results in cells that express cardiomyocyte-related sarcomeric proteins (eg, β-MHC, a-actinin), contract spontaneously, and display action potentials that resemble those of mature cardiomyocytes.97,99,105 Although CPCs robustly differentiate into cardiomyocytes in vitro, there is considerable debate to the extent to which endogenous CPCs contribute to cardiomyocytes in the heart.106–110
The therapeutic potential of CPCs has been extensively studied in animal models of cardiac damage and disease. For example, Dawn et al demonstrated that intravascular injection of CPCs results in increased cardiac mass and ventricular function during hypertrophy or ischemia.111 Along similar lines, it has been reported that in aortic stenosis112 and ischemic heart failure,113 the activation of endogenous CPCs results in myocyte formation and myocardial regeneration.
There are several early clinical trials that are examining the ability of CPCs to ameliorate the effects of cardiac injury and disease. In one such trial, autologous CPCs were delivered through intracoronary injections in patients with postinfarction left ventricular dysfunction.114 Patients examined one year after treatment showed a significant increase in ventricular function and decrease in infarct size. In a similar study, autologous CPCs isolated from endomyocardial biopsies were infused into the infarct-related artery of patients who suffered an MI.115
Classes of Biomaterials for Stem Cell Cardiac Muscle Repair
A variety of biomaterial scaffolds have been used for the in vitro generation of stem cell-derived cardiac tissue and the in vivo delivery of stem cells to damaged myocardium. These biomaterials can be classified into the following categories (Table 2).
Table 2.
BIOMATERIAL | KEY APPLICATIONS | |||
---|---|---|---|---|
IN VITRO | IN VIVO | |||
ADULT STEM CELLS | PLURIPOTENT STEM CELLS | ADULT STEM CELLS | PLURIPOTENT STEM CELLS | |
Extracellular matrix protein (ECMP) | Van Dijk et al (2008): Laminin facilitated the CM differentiation of ADSCs Santiago et al (2009): Identified collagen type I as optimal matrix for cardiac commitment of MSCs |
Baharvard et al (2005): Cardiogel enchanced the differentiation of ESCs to CMs Zhang et al (2012): Matrigel™ sandwich promotes CM preparations of high purity and yield |
Maureira et al (2012): Repair of chronic MI with autologous MSCs seeded in collagen scaffolds Araña et al (2014): Epicardial delivery of collagen patches seeded with ADSCs in model of chronic MI |
Kofidis et al (2004): Matrigel™–based scaffold to deliver ESCs to the damaged ventricular areas of post-MI heart |
Decellularized matrices | French et al (2012): Decellularized ventricular ECM enhance CPC maintenance, expansions, and differentiation | De Quach et al (2010): Decellularized matrix promotes cardiac differentiation of ESCs Duan et al (2011): Composite hydrogel comprised of collagen type I and decellularized heart matrix differentiates ESCs to CMs |
N/A | Lesman et al (2010): Decellularized matrices seeded with ESC-derived CMs integrated with host coronary vasculature upon transplantation to the heart |
Natural materials | Di Felice et al (2013): Silk scaffold enchances cardiac commitment of CPCs Liu et al (2013): Chitosan substrates enchanced the cardiomyogenic potential of CPCs |
Schaaf et al (2011): Fibrin scaffold used to generate highly functionalized heart tissue from ESCs Zhang et al (2013): 3-D fibrin scaffolds enhance the functional maturation of ESC-derived CMs |
Guo et al (2011): Transplantation of MSCs in fibrin improves cardiac function after MI Sun et al (2014): Embedded ADSCs in fibrin scaffolds led to improved ventricular function in model of acute MI |
Lü et al (2010): Injection of temperature-responsive chitosan hydrogel improve myocardial performance in MI hearts Habib et al (2011): Transplantation of ESC-derived CMs in silk matrix increased ventricular performance in a MI model |
Synthetic polymer-based materials | Crowder et al (2013): PCL carbon nanotube composite scaffolds were to enhance cardiac differentiation of MSCs Tran et al (2013): Emulsion electrospun PLCL scaffolds enhanced cardiomyogenic differentiation of MSCs |
Gupta et al (2011): Combinatorial identification of 4% PEF-86% PCL-10% PCL as optimal substrate for cardiac differentiation of PSCs Lee et al (2014): Graphene enhances the cardiomyogenic differentiation of ESCs |
Fukuhara et al (2005): MSC-seeded PGA scaffolds enhanced angiogenesis and improved function of the infracted heart Jin et al (2009): Transplantation of MSCs with PLCL scaffolds reduced scar size and improved cardiac function in animal model of MI |
Chen et al (2010): Elastomeric patch derived from PGS for delivery of ESC to the heart |
Extracellular matrix protein-based biomaterials
Extracellular matrix protein (ECMP)-based biomaterials are attractive scaffolds for cardiac tissue engineering and regeneration because they retain their inherent biological activity to support cell adhesion, survival, and differentiation. These biomaterials include those isolated from animal sources, such as Matrigel™ and Geltrex™, and those from purified or recombinant sources, such as collagen, laminin, fibronectin, and vitronectin.116–118 ECMP-based biomaterials are biocompatible and can be proteolytically degraded into nontoxic by-products. In addition, the degradation rate of ECMP-based materials is highly variable and dependent upon several factors such as implantation location and extent of material cross-linking.119 As an example, biomaterials composed of gelatin, a denatured derivative of collagen, have a higher degradation rate than collagen itself.119
Decellularized matrices
Although ECMP-based materials can be used as stem cell substrates, they do not readily mimic the complexity and architecture of native tissue. On the other hand, it has been demonstrated that decellularized matrices, which can be readily obtained through the detergent treatment of intact cardiac tissue,120 retain the complex mixture of collagens, elastin, and glycosaminoglycans that comprise in vivo tissue.121 As such, these decellularized matrices, which maintain the composition and structure of in vivo tissue, have gained a wide use in cardiac regenerative medicine purposes.121 Similar to ECMP-based biomaterials, decellularized matrices are degraded in vivo into safe by-products.122
Natural biomaterial scaffolds
Several naturally occurring biomaterials have been used for in vitro and in vivo cardiac regenerative medicine purposes. These naturally occurring materials are advantageous because they contain the proteins, polysaccharides, and other cell adhesive domains that are found in native tissue. Naturally occurring biomaterials that have been used in cardiac tissue engineering include silk fibroin (biodegradable polypeptide secreted from worms and insects), chitosan (polysaccharide-based material isolated from crustacean shells), fibrin (generated through the polymerization of the protein fibrinogen isolated from blood plasma), alginate (polysaccharide-based material obtained from brown algae), and agarose (polysaccharide-based material obtained from red algae).123–130 The physicochemical properties of these natural biomaterials can be manipulated, so that they can be naturally degraded within days to weeks after implantation.119,124,131 As such, when implanted in vivo, these materials will persist long enough to promote integration with the native tissue but degrade quickly enough not to disrupt mechanical coupling that is critical to myocardial function.132
Synthetic polymer-based materials
Several synthetic polymer-based materials have been used for cardiac regenerative medicine purposes.133 Compared to ECMPs and decellularized scaffolds, polymer-based materials are easily fabricated and tunable, thereby allowing iterative engineering of materials for specific stem cell responses. Polymers that have been used for stem cell-based cardiac tissue engineering include poly(ethylene glycol) (PEG), poly(lactic acid) (PLA), poly(caprolactone) (PCL), poly(l-lactide-co-caprolactone) (PLCL), poly(glycolide-co-caprolactone) (PGCL), poly(glycerol sebacate) (PGS), and polyurethane (PU).134–140 While some polymer-based biomaterials such as PGS,141,142 PLCL,143 and PGCL144 biodegrade into nontoxic natural metabolites over the course of several weeks or months,143 other polymer-based materials can release potentially harmful by-products of degradation. For example, it has been demonstrated that PU-based biomaterials can oxidize, thereby leading to post-implantation complications.145 To that end, modifications, such as coating PU-based materials with an antioxidant layer, have been shown to reduce adverse degradation effects in vivo.145
Application of Biomaterials to Aid in Vitro Differentiation of Stem Cells to Cardiac Tissue
The development of reproducible and efficient methods for differentiating stem cells to functionally mature cardiomyocytes in vitro is a necessary step for the application of these cells for disease modeling, drug screening, and regenerative medicine purposes. In this section, we will review the current biomaterial-based approaches that are being implemented to guide the differentiation of adult stem cells and PSCs toward cardiomyocytes.
ECMP-based biomaterials
ECMP-based materials have been used as matrices for the cardiac differentiation of a variety of stem cell types. Cardiogel, a naturally occurring extracellular matrix (ECM) containing a complex mixture of laminin and fibronectin isolated from cardiac fibroblasts,146 has been used to direct the differentiation of MSCs to cardiomyocytes.147 ECMPs from both purified and recombinant sources have also been used as natural biomaterials for the generation of cardiomyocytes from stem cell populations. For example, Santiago et al examined the effect of individual ECMPs, including collagens type I, III, IV, laminin, and fibronectin, on the cardiac commitment of MSCs.148 The authors found that collagen can be remodeled to form fibrils that guide the differentiation of MSCs into cells representative of cardiac muscle.148 Along similar lines, Miskon et al reported that differentiation of MSCs on collagen type I matrix elevated expression of cardiomyocyte-related genes in the resultant populations.149 Likewise, Tan et al reported that MSCs differentiated on collagen V matrices had higher expression of cardiac-related genes such as GATA4, NKX2.5, and cTnT compared to cells differentiated on collagen I matrices.150 In fact, cardiac cells generated on collagen V matrices prevented chamber dilation and improved contractile function when injected into the injured myocardium of animals subject to an MI.150 On the other hand, other nonfibrillar ECMPs such as laminin have been shown to facilitate the differentiation of ADSCs toward cardiomyocytes.151
The differentiation of hESCs toward cardiomyocytes has been achieved by culture on gelatin,21,152,153 cardiogel,154 and Matrigel™,155 a gelatinous protein mixture secreted by mouse sarcoma cells, which consists mainly of collagen, laminin, and entactin.156 In another line of investigation, Burridge and colleagues investigated the use of defined ECMP-based matrices for the cardiac differentiation of hiPSCs.157 While there was no difference in cardiomyocyte differentiation efficiency between recombinant laminin, fibronectin, and vitronectin matrices, recombinant laminin substrates did aid in the adhesion and survival of iPSC-derived cardiomyocytes.
Three-dimensional (3-D) architecture has been incorporated into ECMP-based materials to improve the generation of cardiomyocytes from PSCs. In one such study, hESCs and hiPSCs were differentiated between a Matrigel matrix sandwich. Differentiation of cells in this system resulted in cardiomyocyte preparations of high purity (up to 98%) and yield (up to 11 cardiomyocytes for each input PSC).19 Additionally, the cardiomyocyte populations were functionally mature and displayed action potentials typical of nodal, atrial, and ventricular cardiomyocytes. More recently, polydimethylsiloxane (PDMS) templates were used to engineer collagen-based 3-D, self-assembled scaffolds, termed biowires, for the generation of cardiomyocytes from hESCs and hiPSCs.158 Differentiation of PSCs in these scaffolds resulted in aligned cardiac tissue with a high degree of ultrastructural organization, enhanced conduction velocity, and improved calcium handling and electrophysiological characteristics when compared to cardiomyocytes generated using conventional approaches.
Decellularized matrices
Decellularized matrices have been implemented to enhance the cardiac differentiation of MSCs, ADSCs, and CPCs. For example, decellularized ventricular ECMs have been used to enhance CPC maintenance, expansion, and differentiation.9 In another study, decellularized full thickness ventricular matrices were repopulated with MSCs and human umbilical vein endothelial cells to engineer fully vascularized cardiac tissue.159
Likewise, decellularized heart ECMs have been used for in vitro generation of cardiomyocytes from hESCs and mESCs.120,160 In fact, these native tissue matrices increased the sarcomeric organization and enhanced the maturation of hESC-derived cardiomyocytes when compared to conventional cell culture coatings such as gelatin or collagen.120 Hybrid materials consisting of ECMPs and decellularized cardiac ECM have also been used to direct the differentiation of hESCs to cardiomyocytes.161 For example, composite hydrogels composed of collagen type I and decellularized matrix from porcine heart were used to efficiently differentiate hESCs to cardiomyocytes.161 Interestingly, decellularized hydrogels with a high collagen content promoted the function and contractile activities of cardiomyocytes compared with low collagen content or pure collagen gels.161
Natural biomaterial scaffolds
Silk fibroin substrates have been used extensively for the cardiac differentiation of adult stem cell populations. In one such study, silk fibroin nanometric nets were fabricated and seeded with CPCs.162 After three weeks of culture, CPCs differentiated into cells that expressed high levels of cardiac- and sarcomeric-related proteins.162 In fact, these scaffolds not only induced alignment of the cardiomyocyte populations but also synthesis of titin, a protein critical to sarcomere assembly.
Polysaccharide-based scaffolds have also been implemented for cardiac differentiation of stem cell populations.163–165 For example, Liu et al demonstrated that chitosan substrates enhanced the cardiomyogenic potential of ADSCs when compared to cells cultured on standard tissue culture polystyrene substrates.163 In a related study, chitosan elevated intracellular calcium levels in differentiating ADSCs, thereby significantly upregulating the expression of cardiac marker genes GATA4, NKX2.5, and MYH6.164 Along similar lines, another polysaccharide-based material, alginate, preserved the cardiac differentiation potential of CPCs.166
Composite biomaterials have also been investigated for their effect on the cardiac differentiation potential of MSCs.167,168 To that end, Yang et al found that MSCs more efficiently differentiated to cardiac cells when cultured on hybrid substrates consisting of silk fibroin and hyaluronic acid when compared to cells differentiated only on silk fibroin matrices.168 The same group found that by incorporating the polysaccharide chitosan into these silk fibroin/hyaluronic acid scaffolds significantly elevated the cardiomyogenic differentiation of MSCs.
Fibrin-based scaffolds have been widely used for the cardiac differentiation of PSCs.169–171 As an example, highly functionalized heart tissue was engineered by differentiating hESCs in a fibrin substrate.170 Specifically, differentiated cells displayed highly organized and oriented networks of sarcomeres, as well as electrophysiological properties indicative of mature cardiomyocytes. Additional studies have demonstrated that the effect of fibrin on the cardiac differentiation of mESCs and hESCs is improved in a 3-D culture system.169,171 For instance, Zhang et al investigated the effects of dimensionality of fibrin constructs on the structural and functional maturation of hESC-derived cardiomyocytes.171 Compared to cardiomyocytes generated in two-dimensional fibrin substrates, cardiomyocytes generated in 3-D scaffolds exhibited significantly higher conduction velocities, longer sarcomeres, and elevated expression of genes involved in cardiac contractile function.171
Synthetic polymer-based materials
A variety of polymer-based materials have been engineered for the differentiation of adult stem populations toward the cardiac lineage. In a recent work, PU, 3-hydroxybutryate-co-4-hydroxybutryate [P(3HB-co-4HB)], and polypropylene carbonate (PPC) substrates were studied for their ability to support the adhesion and cardiac differentiation of MSCs.172 The authors found that substrates composed of PU and P(3HB-co-4HB) permitted optimal cell growth and cardiac differentiation. In another study, PCL carbon nanotube composite scaffolds were used to enhance cardiac differentiation of MSCs.173 Moreover, MSCs cultured on the composite scaffolds inherently assumed an elongated morphology allowing the cells to be more receptive to cardiac inducing factors. Additional PCL-based copolymer scaffolds have been used as an effective means to direct the cardiac differentiation of MSCs. For example, differentiation of MSCs on PLA-co-PCL scaffolds resulted in elevated expression of cardiac-related genes, alpha actinin, and MHC.174 Finally, composite scaffolds consisting of polymers and ECMPs have been used for the cardiogenic differentiation of MSCs.175 MSCs differentiated on PGS-collagen hybrid scaffolds more efficiently differentiated to cardiomyocyte-like cells than cells differentiated on substrates that only contained collagen.175
Synthetic polymer-based materials have also been used for the derivation of mature cardiac cells from CPCs. PGS has been used to develop biomimetic substrates that guide the adhesion, growth, and differentiation of CPCs.176 Along similar lines, PEG has been used to generate in vitro CPC niches to control their function and fate.177 These highly anisotropic substrates augmented CPC adhesion, migration, and proliferation. In turn, these substrates enhanced the differentiation of CPCs to mature cardiomyocytes through a nanotopography response mediated via p190RhoGAP.
Along similar lines, synthetic polymer-based substrates have been used for the cardiac differentiation of PSCs. As an example, the culture of hESCs on graphene-based polymer scaffolds enhanced their cardiomyogenic differentiation compared with differentiation on Matrigel substrates.178 In an effort to precisely tune the polymer physicochemical properties required for cardiac differentiation of mESCs, Gupta et al prepared a combinatorial polymer library by copolymerizing PEG, PCL, and carboxylated PCL (CPCL) and used electrospinning to develop scaffolds to mimic the ECM network.179 Through measurement of a-myosin heavy chain (a-MHC) expression and calcium (Ca2+) signaling dynamics, the authors observed that the most compliant substrate tested, 4%PEG–86%PCL–10%CPCL, allowed for the most efficient cardiac differentiation of mESCs. Additionally, by altering the elastic modulus of the 4%PEG–86%PCL–10%CPCL substrates, the authors were able to further promote maturation of mESC-derived cardiomyocytes.
Hybrid scaffolds consisting of polymers, ECMPs, and other materials have been implemented as an effective means to direct the fate of hESCs toward cardiomyocytes. For example, poly(lactic-co-glycolic acid) (PLGA) and collagen scaffolds were fabricated using electrospinning methods to precisely control the fiber diameters to mimic the ECM of in vivo cardiac tissue.180 Differentiation of hESCs to cardiomyocytes on the composite PLGA/collagen scaffolds was found to be more efficient than on the substrates composed solely of PLGA or collagen.
Biomaterial-Based Methods for the In Vivo Delivery of Stem Cell Populations to Repair Cardiac Tissue
Current methods of stem cell delivery for cardiac regenerative purposes are inadequate as the integration and survival of transplanted cells is low, thereby reducing their therapeutic potential.181,182 As such, biomaterial scaffolds have emerged as a promising approach to effectively deliver stem cells to damaged cardiac tissue. The following design considerations must be taken into account when implementing biomaterial-based approaches for the delivery of stem cells to repair cardiac tissue: (i) provide the appropriate strength and elasticity to withstand contraction and relaxation (or cyclic stretch) of the myocardium, (ii) capable of biodegrading without the generation of any toxic products once new tissue is formed, and (iii) conducive to support the contraction, proliferation, and differentiation of stem cells and their derivatives. In this section, we will review the various biomaterial-based approaches that are being used to deliver stem cells to repair injured or diseased myocardium.
ECMP-based biomaterials
Collagen-based scaffolds have been widely implemented as an efficient means to deliver stem cells to damaged myocardial tissue.183–186 In fact, it has been reported that the use of collagen as a stem cell delivery vehicle significantly reduced the localization and engraftment of transplanted cells to other organs and uninjured myocardium.183 Collagen-based matrices have been used to deliver MSCs to damaged cardiac tissue in animal models of MI. For example, a patch consisting of autologous MSCs seeded in a collagen scaffold that was engrafted into the epicardial surface of a chronic MI scar led to enhanced angiogenesis and significantly improved cardiac function.184 In a related study, Simpson et al demonstrated that the delivery of MSCs using such methods led to elevated ventricular remodeling and function compared to MSCs delivered through direct injection.185 Addition of glycosaminoglycans to these MSC seeded collagen scaffolds has led to improved cell retention, neovascularization, and tissue repair.187
The use of collagen scaffolds for cell delivery has not been limited to use with only MSCs. Araña et al examined the effect of collagen patches seeded with ADSCs on cardiac function in models of chronic MI.188 The delivery of ADSCs in collagen substrates led to increased cell engraftment as well as improvement in cardiac function, myocardial remodeling, and revascularization. Moreover, the level of fibrosis, a factor that critically impairs cardiac recovery in chronic MI, was significantly reduced in animals that received ADSC seeded collagen patches.
Matrigel™ has been used as a substrate to deliver PSCs and their derivatives to sites of cardiac damage. Kofidis et al used Matrigel™ scaffolds to deliver undifferentiated mESCs to the damaged ventricular areas of a postinfarcted heart.189 Overall, the mESC seeded scaffold engrafted within the injured area and prevented ventricular wall thinning. Importantly, no signs of teratoma formation were reported, and the engrafted cells remained viable and expressed high levels of the cardiomyocyte-related proteins, connexin 43 and alpha-sarcomeric actin.
Decellularized matrices
Because of the ability to match the biochemical properties of native heart tissue, decellularized matrices are emerging as a promising approach to deliver stem cells to regions of cardiac damage. Additionally, it has been shown that when delivered to the in vivo heart tissue, these scaffolds have the potential to promote stem cell differentiation, cardiac regeneration, and angiogenesis.190 Lesman and colleagues used decellularized matrices and hESC-derived cardiomyocytes as the basis for the engineering of 3-D tissue-engineered cardiac muscle.191 Upon transplantation to the heart, the engineered muscle formed cardiac tissue grafts and integrated with the host coronary vasculature. In the future, such engineered tissue could be used to ameliorate or reverse the effects of cardiac damage.
Natural biomaterial scaffolds
Fibrin-based scaffolds have been effectively used to improve adult stem cell engraftment and survival in cardiac regenerative medicine applications. Embedding ADSCs in fibrin scaffolds leads to improved ventricular function and remodeling in a model of acute MI when compared to direct ADSC implantation.192 Along similar lines, Guo et al demonstrated that the delivery of CPCs in fibrin matrices promoted their survival, engraftment, and cardiomyogenic differentiation in an animal model of MI.193 In turn, improved myocardial tissue repair and cardiac function were observed in animals that received CPCs delivered in fibrin scaffolds compared to the animals that received CPCs or fibrin alone.
Polysaccharide containing matrices have been broadly used as adult stem cell delivery vehicles. Encapsulation of MSCs194–196 or ADSCs197 in alginate enhanced retention and survival of MSCs in several animal models of MI. As such, alginate encapsulation facilitated paracrine effects, such as increased angiogenesis and decreased scaring, and improved cardiac function.195 Similarly, Wang and colleagues demonstrated that delivery of ADSCs in chitosan hydrogels to regions of the heart that had been damaged by MI enhanced cell survival and increased differentiation to cardiomyocytes.165 Moreover, cell delivery in chitosan prevented adverse matrix remodeling, elevated angiogenesis, and preserved cardiac function. Interestingly, a direct comparison of alginate and chitosan matrices revealed that the delivery of ADSCs in alginate scaffolds improved cell retention in the infarcted heart when compared to chitosan scaffolds.198 In order to leverage the beneficial effects of both alginate and chitosan, Ceccaldi et al examined the efficacy of MSCs seeded in composite scaffolds that comprised various alginate/chitosan ratios in ameliorating the effects of acute MI.199 The authors found that an alginate/chitosan ratio of 40/60 led to the highest improvement in cardiac function and attenuation of fibrosis.
The application of PSCs and their derivatives for in vivo cardiac repair have benefited from the use of natural biomaterial scaffolds as delivery vehicles. For example, the transplantation of hESC-derived cardiomyocytes in photo-crosslinkable PEGylated-fibrinogen matrices led to increased ventricular performance in a MI model.200 Along similar lines, several studies have demonstrated that fibrin scaffolds loaded with hESC-derived cardiac cells and mESC-derived cardiac cells can reverse the fibrotic effects of MI and lead to improved ventricular function when delivered to regions of cardiac damage.201–203 Finally, the coinjection of mESCs and hESCs in polysaccharide-based scaffolds such as alginate and chitosan in infarcted heart tissue has led to the generation of new myocardium and preservation of cardiac function.204,205
Synthetic polymer-based materials
Owing to the ability to tailor their physicochemical properties, synthetic polymer-based materials have been widely implemented as scaffolds for the in vivo delivery of stem cells for cardiac tissue engineering purposes. For instance, bioengineered polyglycolic acid (PGA) cloths seeded with MSCs have been used to induce angiogenesis and improve function in an infarcted heart.206 In a related study, transplantation of MSCs within PLCL scaffolds reduced scar size and improved cardiac function in an animal model of MI.207 Similarly, MSCs seeded in PLCL scaffolds that were injected into infarcted cardiac tissue migrated to damaged myocardium, augmented neovascularization, and improved ventricular function.208
Several injectable biodegradable hybrid materials have been engineered for cardiac tissue engineering applications. For example, Xu et al developed a hydrogel that comprised thiolated collagen and oligo(acryloyl carbonate)-b-poly(ethylene glycol)-b-oligo(acryloyl carbonate) (OAC-PEG-OAC) for the encapsulation of MSCs to be used for cardiac regeneration purposes.209 As such, these composite hydrogels combined the intrinsic biological activity of collagen and the structural integrity of the OAC-PEG-OAC polymers. When used in an infarction model, these hybrid hydrogels reduced infarct size, increased ventricular wall thickness, and improved cardiac function. In a similar study, the intramyocardial delivery of MSCs in silanized poly(hydroxypropyl) methylcellulose hydrogels attenuated ventricular remodeling and rescued cardiac function in a model of MI.210
Polymer-based scaffolds have also been used for the delivery of PSCs and their derivatives to regions of damaged myocardial tissue. In one such study, a heart patch was engineered from the synthetic elastomer PGS that was seeded with hESC-derived cardiomyocytes.211 Upon suture over the left ventricle, these patches remained intact over a two-week period without any negative impacts on ventricular function. In the future, such patches could be used for stem cell-based cardiac regeneration strategies.
Future Trends and Techniques in Biomaterial-Based Approaches for Stem Cell Myocardial Tissue Engineering
One of the main challenges that need to be addressed to move stem cell-based approaches for cardiac regeneration from bench-to-bedside is enhancing the survival, engraftment, and differentiation of cells in the ischemic or fibrotic host tissue.212 One emerging approach to overcome this hurdle is to engineer biomaterial-based systems for the dual delivery of pro-survival soluble signaling cocktails and stem cells to regions of damaged myocardium. For example, thermosensitive N-isopropylacrylamide (NIPAAm) hydrogels have been engineered to release bFGF for the enhanced differentiation of MSCs into cardiomyocyte-like cells under ischemic conditions.213 Karam and colleagues developed a PLGA-based system that could be used to encapsulate ADSCs along with two cardiac inducing growth factors, hepatocyte growth factor and insulin-like growth factor (IGF-1).213 The authors demonstrated that sustained release of hepatocyte growth factor and IGF-1 enhanced the cardiac differentiation of encapsulated ADSCs. Similarly, encapsulation of CPCs in an alginate hydrogel containing superoxide dismutase, a reactive oxygen species scavenger, prevented doxorubicin-induced apoptosis.214 Finally, biomaterial-based scaffolds loaded with prosurvival and proangiogenic factors such IGF-1 and thymosin β4 have been used to deliver hiPSCs and their derivatives to infarcted cardiac tissue.215 In fact, the use of such scaffolds led to reduced infarct size and the formation new vasculature in the host tissue. In the future, engineered biomaterials to deliver stem cells along with pro-survival drugs may enable sustained tissue preservation and potentially promote regeneration of ischemic cardiac tissue.134
Another emerging approach for the stem cell-based repair of ischemic tissue is the use of biomaterials to develop pre-vascularized tissues that can be delivered via surgery to sites of cardiac injury. To that end, Pagliari et al developed a multistep procedure to engineer pre-vascularized 3-D cardiac bio-substitutes.216 Specifically, MSCs and CPCs were seeded in a highly porous biocompatible gelatin scaffold. Exposure of the scaffold to fluid flow within a modular bioreactor stimulated the formation of VCAM-1-positive vascular cells forming tube-like structures around the scaffold and pores, which contact cTnT expressing cardiomyocytes. One could imagine that in the future such vascularized constructs could interconnect with host vasculature and be used to stimulate repair of damaged in vivo cardiac tissue.
In the future, the ability to effectively move biomaterial approaches for stem cell-based myocardial tissue engineering from bench-to-bedside will require limiting the potential for complications in patients. For example, while recent progress has been made in the directed differentiation of human pluripotent stem cells (hPSCs) to immature myocardial cell types,26 these protocols yield a heterogeneous cell population consisting of nodal-, atrial-, and ventricular-like CM subtypes.36,217 As such, these heterogeneous populations have displayed a high degree of arrhythmogenic properties, thereby potentially limiting their clinical application.44,45 Before such cell types can be used in patients, reproducible methods for the generation of homogenous, subtype-specific CMs need to be developed. Another challenge of stem cell-based cardiac therapies is the high potential for allogenic immune rejection by recipients.218 To that end, continued advances in directed genome modification may allow for the generation of stem cell-derived cardiac tissue that evades allogenic immune responses.219
Footnotes
ACADEMIC EDITOR: Karen Pulford, Editor in Chief
FUNDING: Authors disclose no funding sources.
COMPETING INTERESTS: Authors disclose no potential conflicts of interest.
Paper subject to independent expert blind peer review by minimum of two reviewers. All editorial decisions made by independent academic editor. Upon submission manuscript was subject to anti-plagiarism scanning. Prior to publication all authors have given signed confirmation of agreement to article publication and compliance with all applicable ethical and legal requirements, including the accuracy of author and contributor information, disclosure of competing interests and funding sources, compliance with ethical requirements relating to human and animal study participants, and compliance with any copyright requirements of third parties. This journal is a member of the Committee on Publication Ethics (COPE).
Author Contributions
Contributed to the writing of the manuscript: JC, MN, DAB. Made critical revisions and approved final version: JC, MN, DAB. All authors reviewed and approved of the final manuscript.
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