Xintong Wang

Combinatorial Polymer Electrospun Matrices Promote Physiologically-Relevant Cardiomyogenic Stem Cell Differentiation

Myocardial infarction results in extensive cardiomyocyte death which can lead to fatal arrhythmias or congestive heart failure. Delivery of stem cells to repopulate damaged cardiac tissue may be an attractive and innovative solution for repairing the damaged heart. Instructive polymer scaffolds with a wide range of properties have been used extensively to direct the differentiation of stem cells. In this study, we have optimized the chemical and mechanical properties of an electrospun polymer mesh for directed differentiation of embryonic stem cells (ESCs) towards a cardiomyogenic lineage. A combinatorial polymer library was prepared by copolymerizing three distinct subunits at varying molar ratios to tune the physicochemical properties of the resulting polymer: hydrophilic polyethylene glycol (PEG), hydrophobic poly(ε-caprolactone) (PCL), and negatively-charged, carboxylated PCL (CPCL). Murine ESCs were cultured on electrospun polymeric scaffolds and their differentiation to cardiomyocytes was assessed through measurements of viability, intracellular reactive oxygen species (ROS), α-myosin heavy chain expression (α-MHC), and intracellular Ca2+ signaling dynamics. Interestingly, ESCs on the most compliant substrate, 4%PEG-86%PCL-10%CPCL, exhibited the highest α-MHC expression as well as the most mature Ca2+ signaling dynamics. To investigate the role of scaffold modulus in ESC differentiation, the scaffold fiber density was reduced by altering the electrospinning parameters. The reduced modulus was found to enhance α-MHC gene expression, and promote maturation of myocyte Ca2+ handling. These data indicate that ESC-derived cardiomyocyte differentiation and maturation can be promoted by tuning the mechanical and chemical properties of polymer scaffold via copolymerization and electrospinning techniques.

Poly(ε-caprolactone)–carbon nanotube composite scaffolds for enhanced cardiac differentiation of human mesenchymal stem cells

AIM To evaluate the efficacy of electrically conductive, biocompatible composite scaffolds in modulating the cardiomyogenic differentiation of human mesenchymal stem cells (hMSCs). MATERIALS & METHODS Electrospun scaffolds of poly(ε-caprolactone) with or without carbon nanotubes were developed to promote the in vitro cardiac differentiation of hMSCs. RESULTS Results indicate that hMSC differentiation can be enhanced by either culturing in electrically conductive, carbon nanotube-containing composite scaffolds without electrical stimulation in the presence of 5-azacytidine, or extrinsic electrical stimulation in nonconductive poly(ε-caprolactone) scaffolds without carbon nanotube and azacytidine. CONCLUSION This study suggests a first step towards improving hMSC cardiomyogenic differentiation for local delivery into the infarcted myocardium.

Development of 3D Microvascular Networks Within Gelatin Hydrogels Using Thermoresponsive Sacrificial Microfibers.

A 3D microvascularized gelatin hydrogel is produced using thermoresponsive sacrificial poly(N-isopropylacrylamide) microfibers. The capillary-like microvascular network allows constant perfusion of media throughout the thick hydrogel, and significantly improves the viability of human neonatal dermal fibroblasts encapsulated within the gel at a high density.

Oligoproline-derived nanocarrier for dual stimuli-responsive gene delivery

Gene therapy is a promising method for the treatment of vascular disease; however, successful strategies depend on the development of safe and effective delivery technologies with specific targeting to a diseased point of vasculature. Reactive oxygen species (ROS) are overproduced by vascular smooth muscle cells (VSMCs) at critical stages of atherosclerosis progression. Therefore, ROS were exploited as a stimulus for vascular targeted gene delivery in this study. A combination of bio-conjugation methods and controlled reverse addition-fragmentation chain-trasfer (RAFT) polymerization was utilized to synthesize a new ROS-cleavable, pH-responsive mPEG113-b-CP5K-b-PDMAEMA42-b-P(DMAEMA22-co-BMA40-co-PAA24) (PPDDBP) polymer as a nanocarrier for plasmid DNA (pDNA) delivery. The ros degradability of PPDDBP polymers was confirmed by SIN-1-mediated cleavage of CP5K peptide linkers through a shift in GPC chromatogram with an appearance of mPEG shoulder peak and an increase in zeta potential (ζ). The polyplex nanocarrier also demonstrated effective PDNA loading, serum stability, and hemocompatibility, indicating its excellent performance under physiological conditions. The polyplexes demonstrated ideal pH responsiveness for endosomal escape and effective ROS responsiveness for improved targeting in an in vitro model of pathogenic VSMCs in terms of both uptake and expression of reporter gene. These data suggest this novel nanocarrier polyplex system is a promising gene delivery tool for preventing or treating areas of high ROS, such as atherosclerotic lesions.

A temperature-sensitive, self-adhesive hydrogel to deliver iPSC-derived cardiomyocytes for heart repair

Induced pluripotent stem cells (iPSCs) from patients’ somatic tissues provide a viable source to create autologous cardiomyocytes (CMs) for potential cardiac-related cell therapies. However, a gap between the generation of iPSC-derived cardiomyocytes (iPSC-CMs) and the successful intra-cardiac engraftment of the cells to restore heart function remains to be bridged. Clinical data reporting engraftment of cells within human heart tissue has not been without its challenges, with significant cell loss from the site of delivery due to the physical stress of the cardiac cycle and the hostile inflammatory response within the infarct zone.[1–3] Hydrogels have been proven to support the survival of multiple cell types and have served as a platform for cell transplantation.[4, 5] Yet the use of tissue-adhesive, temperature-sensitive hydrogels to deliver iPSC-derived cardiomyocytes to infarcted heart remains to be explored. Therefore, we developed a polymer hydrogel to encapsulate, deliver, and integrate iPSC-CMs into infarcted myocardium to restore heart function. A temperature-sensitive biodegradable copolymer (polyethylene glycol-co-poly-e-caprolactone (PEG-PCL)) was synthesized [6] and conjugated with a collagen-binding peptide (SYIRIADTNIT). [7] The polymer was soluble in aqueous solutions at room temperature and underwent solution-to-gel transition at 37°C (Fig. 1 a,b).[6] As the peptide-modified polymer had a strong affinity to collagen I in vitro (Fig. 1c), it was expected that it would significantly increase the binding of the hydrogel to an infarcted heart, thus immobilizing iPSC-CMs within the damaged myocardium. Functional, beating cardiomyocytes were derived from patient fibroblast-derived iPSCs using a “Matrigel sandwich” method.[8] Cardiac differentiation was confirmed by fluorescence-activated cell sorting (FACS) and by immunostaining with known cardiac markers cardiac troponin T (cTNT), ryanodine receptor 2 (RYR) and α-actinin (Fig. 1f). The iPSC-CMs encapsulated in the polymer hydrogel at 37°C for two weeks maintained their viability (Fig. 1g) and cardiac phenotype, as evidenced by strong expression of troponin T and Nkx2.5 (Fig. 1h); thus, PEG-PCL does not appear to have obvious toxic effects on iPSC-CMs. Fig. 1 PEG-PCL copolymer was (a) dissolved in PBS at RT and (b) gelled at 37°C within 5 min (Sol-gel transition). Collagen-binding study was performed by adding peptide-modified polymer to collagen-coated surface at 37°C, and unbound polymer ... Engraftment of iPSC-CMs into infarcted myocardium using the peptide-modified hydrogel and its impact on infarcted heart function and structure were assessed with a rat myocardial infarction (MI) model. All animal surgery and animal care were approved by the Institutional Animal Care and Use Committee (IACUC) at Vanderbilt University (protocol: M/12/074). The left anterior descending (LAD) coronary artery of nude rats was ligated to induce MI. At 30 minutes post-MI, iPSC-CMs alone, or modified copolymer solution with or without iPSC-CMs (2–4 million/rat) were injected around the infarct border zone. A negative control group received the LAD ligation and phosphate-buffered saline (PBS) injection without cells or copolymer. At two weeks post-injection, heart dimensions and functional output were assessed by echocardiography. All groups had ventricular dilation and reduced fractional shortening (FS) (Fig. 2). However, rats treated with iPSC-CM-encapsulated copolymer demonstrated significantly less decline in FS (Δ= −6.37±0.49%) compared to other groups (Δ= −12.77±2.04%, −11.44±2.04% and −12.65±1.53% for PBS control, iPSC-CM only, and polymer only groups, respectively (Fig. 2a). p=0.016 vs. PBS, p=0.021 vs. iPSC-CM only, and p=0.005 vs. polymer only). Overall, the iPSC-CM plus polymer group demonstrated 50.1%, 28.2% and 49.6% improvement in LV systolic function over PBS, iPSC-CM only and polymer only groups (Fig. 2b). Moreover, rats treated with iPSC-CM plus polymer demonstrated a trend toward less LV enlargement (Δ= 15.07±3.24%) compared to other groups (Δ=24.44±3.99%, 25.02±2.03% and 23.17±4.51% for PBS control, iPSC-CM only, and polymer only groups, respectively; Fig. 2c) although this reached statistical significance only in comparison to the iPSC-CM group (p=0.032). Overall, iPSC-CM plus polymer group demonstrated 38.3%, 39.8% and 35.0% less LV enlargement over PBS, iPSC-CM only and polymer only groups, suggesting that iPSC-CM encapsulated in polymer curtailed adverse ventricular remodeling better than other treatment modalities. Fig. 2 The effects of hydrogel-encapsulated iPSC-CMs on left ventricle function and remodeling. (a–c) Echocardiography was performed before the ligation of rat LAD coronary arteries (baseline) and again 2 weeks post-delivery (n=5 rats per group). (a, ... Histological examination of the hearts was performed, and the LV anterior free wall thickness was measured using ImageJ and averaged from 3 randomly selected regions in each rat heart. Result demonstrated that, in addition to LV chamber enlargement, the LAD ligation resulted in dramatic thinning and significant fibrosis of the LV anterior free wall at two weeks in control groups (Fig. 2e). In contrast, heart injected with polymer-encapsulated iPSC-CMs had smaller LV chamber, thicker LV free wall and less fibrosis (Fig. 2e). Overall, hearts in the iPSC-CM plus polymer group were significantly thicker than all other groups; the average LV anterior wall thickness of cell plus polymer group was 2.46±0.06mm, compared with 0.48±0.07, 0.35±0.05 and 0.39±0.02mm in PBS, cell only and polymer only groups, respectively (Fig. 2d, p<0.001). In summary, implantation of iPSC-CMs encapsulated in polymer hydrogel was much more effective at limiting adverse LV remodeling and preserving cardiac function after MI than other treatment modalities. Importantly, as implantation of iPSC-CMs or polymer alone did not elicit as favorable outcomes as the iPSC-CMs plus polymer group, we attribute the latter group’s synergistic effects to enhanced survival of transplanted iPSC-CMs in vivo. Consistent with this notion, staining for human nuclei confirmed the presence of iPSC-CMs, delivered with the polymer hydrogel, in the peri-infarct region of the host rat myocardium at 2 weeks (Fig. 2f); moreover, the implanted cells maintained their cardiac phenotype, as demonstrated by positive staining of cardiac α-actinin (Fig. 2f). By contrast, no human nuclei were detected in hearts of control groups at 2 weeks. In conclusion, we describe a temperature-sensitive, collagen-binding hydrogel based system to deliver human iPSC-derived cardiomyocytes to improve cardiac structure and function in infarcted rat heart. Moreover, our studies indicate that the beneficial effects of encapsulating iPSC-CMs in hydrogel are mediated through enhanced survival of transplanted iPSC-CMs in vivo. While future studies are needed to demonstrate long-term functional engraftment of transplanted cells, our study illustrates a promising biomaterial-based approach to overcome a commonly recognized obstacle to the potentially revolutionary cell-based approaches to repair failing hearts: survival of donor cells in the infarcted heart.

Stem cell therapy for chronic heart failure: an updated appraisal

Introduction: Significant advances have been made to understand the mechanisms involved in cardiac cell-based therapies. The early translational application of basic science knowledge has led to several animal and human clinical trials. The initial promising beneficial effect of stem cells on cardiac function restoration has been eclipsed by the inability of animal studies to translate into sustained clinical improvements in human clinical trials. Areas covered: In this review, the authors cover an updated overview of various stem cell populations used in chronic heart failure. A critical review of clinical trials conducted in advanced heart failure patients is proposed, and finally promising avenues for developments in the field of cardiac cell-based therapies are presented. Expert opinion: Several questions remain unanswered, and this limits our ability to understand basic mechanisms involved in stem cell therapeutics. Human studies have revealed critical unresolved issues. Further elucidation of the proper timing, mode delivery and prosurvival factors is imperative, if the field is to advance. The limited benefits seen to date are simply not enough if the potential for substantial recovery of nonfunctioning myocardium is to be realized.

Combined Usage of Stem Cells in End‐Stage Heart Failure Therapies

Remarkable achievements have been made in the clinical application of mechanical circulatory support and cardiac transplantation for patients with end‐stage heart failure. Despite the successes, complications associated with these therapies continue to drive cardiac regenerative research utilizing stem cell based therapies. Multiple stem cell lineages hold clinical promise for cardiac regeneration—mostly through cellular differentiation, cellular fusion, and paracrine signaling mechanisms. Bone marrow‐derived endothelial progenitor cells are among the most intriguing and controversial cell types currently being investigated. Formidable barriers exist, however, in finding the ideal cardiac regenerative stem cell, such as identifying specific lineage markers, optimizing in vitro cellular expansion and improving methods of stem cell delivery. Hybrid approaches of cardiac regeneration using stem cell therapies in conjunction with immunomodulation after cardiac transplantation or with mechanical circulatory support produce cutting edge stem cell technologies. This review summarizes the current knowledge and therapeutic applications of stem cells in patients with end‐stage heart failure, including stem cell therapy after implantation of mechanical circulatory support and cardiac transplantation. J. Cell. Biochem. 115: 1217–1224, 2014.

Polymeric stent materials dysregulate macrophage and endothelial cell functions: Implications for coronary artery stent

BACKGROUND Biodegradable polymers have been applied as bulk or coating materials for coronary artery stents. The degradation of polymers, however, could induce endothelial dysfunction and aggravate neointimal formation. Here we use polymeric microparticles to simulate and demonstrate the effects of degraded stent materials on phagocytic activity, cell death and dysfunction of macrophages and endothelial cells. METHODS Microparticles made of low molecular weight polyesters were incubated with human macrophages and coronary artery endothelial cells (ECs). Microparticle-induced phagocytosis, cytotoxicity, apoptosis, cytokine release and surface marker expression were determined by immunostaining or ELISA. Elastase expression was analyzed by ELISA and the elastase-mediated polymer degradation was assessed by mass spectrometry. RESULTS We demonstrated that poly(D,L-lactic acid) (PLLA) and polycaprolactone (PCL) microparticles induced cytotoxicity in macrophages and ECs, partially through cell apoptosis. The particle treatment alleviated EC phagocytosis, as opposed to macrophages, but enhanced the expression of vascular cell adhesion molecule (VCAM)-1 along with decreased nitric oxide production, indicating that ECs were activated and lost their capacity to maintain homeostasis. The activation of both cell types induced the release of elastase or elastase-like protease, which further accelerated polymer degradation. CONCLUSIONS This study revealed that low molecule weight PLLA and PCL microparticles increased cytotoxicity and dysregulated endothelial cell function, which in turn enhanced elastase release and polymer degradation. These indicate that polymer or polymer-coated stents impose a risk of endothelial dysfunction after deployment which can potentially lead to delayed endothelialization, neointimal hyperplasia and late thrombosis.

Design of Polymeric Culture Substrates to Promote Proangiogenic Potential of Stem Cells

Stem cells are a promising cell source for regenerative medicine due to their differentiation and self-renewal capacities. In the field of regenerative medicine and tissue engineering, a variety of biomedical technologies have been tested to improve proangiogenic activities of stem cells. However, their therapeutic effect is found to be limited in the clinic because of cell loss, senescence, and insufficient therapeutic activities. To address this type of issue, advanced techniques for biomaterial synthesis and fabrication have been approached to mimic proangiogenic microenvironment and to direct proangiogenic activities. This review highlights the types of polymers and design strategies that have been studied to promote proangiogenic activities of stem cells. In particular, scaffolds, hydrogels, and surface topographies, as well as insight into their underlying mechanisms to improve proangiogenic activities are the focuses. The strategy to promote angiogenic activities of hMSCs by controlling substrate repellency is introduced, and the future direction is proposed.