Restore Heart Function Research Articles

Alpha lipoic acid–loaded electrospun fibrous patch films protect heart in acute myocardial infarction mice by inhibiting oxidative stress

Oxidative stress, characterized by excessive accumulation of reactive oxygen species (ROS), is involved in acute myocardial infarction (AMI)-related pathological processes and vascular reperfusion therapy injury. Alpha lipoic acid (LA) exhibits excellent antioxidant properties, however, its application is limited by inherent characteristics, including rapid clearance and extensive volume distribution. In this study, we hypothesized that scavenging cardiac ROS using adequately delivered LA could promote heart repair. Here, we report a new strategy for dynamic-release LA to treat AMI disease. In particular, this involves using poly(lactic-co-glycolic) (PLGA) copolymers as carriers to form a thin film (LA@PLGA) via electrospinning technology to achieve controlled release of LA, which essentially blocking local ROS production in damaged hearts. The drug-loading capacity and capsulation efficiency of this compound film could be regulated by determining the dose proportions of LA and PLGA. The incubation of LA@PLGA showed strong anti-oxidative activity and anti-apoptosis effect in hydrogen peroxide–administered primary cardiomyocytes. Patching LA@PLGA on the infarcted cardiac surfaces of AMI mice dramatically improved heart functions and reduced cardiac fibrosis throughout ventricular remodeling process. Importantly, the attenuation of detrimental pathologies was observed, including oxidative stress, senescence, DNA damage, cytokine-related processes, apoptosis, and ferroptosis. These results suggest that PLGA-carried LA can reduce ROS damage and restore heart function after myocardial damage, demonstrating a great potential for LA drugs in treating AMI disease.

Potential of graphene-based nanomaterials for cardiac tissue engineering.

Cardiovascular diseases are the primary cause of death worldwide. Despite significant advances in pharmacological treatments and surgical interventions to restore heart function after myocardial infarction, it can progress to heart failure due to the restricted inherent potential of adult cardiomyocytes to self-regenerate. Hence, the evolution of new therapeutic methods is critical. Nowadays, novel approaches in tissue engineering have assisted in restoring biological and physical specifications of the injured myocardium and, hence, cardiac function. The incorporation of a supporting matrix that could mechanically and electronically support the heart tissue and stimulate the cells to proliferate and regenerate will be advantageous. Electroconductive nanomaterials can facilitate intracellular communication and aid synchronous contraction via electroactive substrate creation, preventing the issue of arrhythmia in the heart. Among a wide range of electroconductive materials, graphene-based nanomaterials (GBNs) are promising for cardiac tissue engineering (CTE) due to their outstanding features including high mechanical strength, angiogenesis, antibacterial and antioxidant properties, low cost, and scalable fabrication. In the present review, we discuss the effect of applying GBNs on angiogenesis, proliferation, and differentiation of implanted stem cells, their antibacterial and antioxidant properties, and their role in improving the electrical and mechanical properties of the scaffolds for CTE. Also, we summarize the recent research that has applied GBNs in CTE. Finally, we present a concise discussion on the challenges and prospects.

Breast milk mesenchymal stem cells abate cisplatin-induced cardiotoxicity in adult male albino rats via modulating the AMPK pathway

Myocardial injury influenced by cisplatin (Cis) is a compelling reason to hunt out a treatment modality to overcome such a threat in cisplatin-treated patients. Breast Milk mesenchymal stem cells (Br-MSCs) are a non-invasive, highly reproducible source of stem cells. Herein, we investigate Br-MSCs' role in cardiotoxicity induced by cisplatin. Rats were divided into; control, Cis-treated (received 12 mg/kg single intraperitoneal injection), BrMSCs-treated (received single intraperitoneal injection of 0.5 ml sterilized phosphate-buffered saline containing 2 × 107 cells of Br-MSCs); metformin-treated (received 250 mg/kg/day orally) and BrMSCs + metformin + Cis treated groups. At the experiment end, serum creatine kinase (CK-MB) and cardiac troponin T (cTnT) activates were estimated, cardiac malondialdehyde (MDA), superoxide dismutase (SOD), interleukin-1ß (IL-1ß), tumor necrosis factor-α (TNF-α) levels were measured, cardiac expression of Bax and Bcl-2 and AMP-activated protein kinase (AMPK), as well as heart histopathology, were evaluated. Study results showed that Cis explored acute cardiotoxicity evidenced by deteriorated cardiac indices, induction of oxidative stress, and inflammation with myocardium histological alterations. Treatment with Br-MSCs restored heart function and structure deteriorated by Cis injection. The antioxidant/anti-inflammatory/anti-apoptotic results of Br-MSCs were supported by AMPK activation denoting their protective role against cisplatin-induced cardiac injury. These results were superior when metformin was added to the treatment protocol.

Abstract GS102: Injection Of Human IPSC-derived Cardiac Cells Promote Cardiac Repair After Infarction In Nonhuman Primates

Introduction: Injection of induced pluripotent stem cell-derived cardiomyocytes has been reported as a promising approach to regenerate loss myocardium and restore heart function after ischemic injury. However, immaturity of the transplanted cardiomyocytes and their poor survival rates caused by limited blood supply remain as major hurdles for clinical translation. Hypothesis: We tested the hypothesis that co-culture of human induced pluripotent stem cell (hiPSC)-derived cardiomyocytes (CMs) with hiPSC-derived endothelial cells (ECs) promotes CM maturation in vitro, and that co-transplantation of both hiPSC-CMs and hiPSC-ECs facilitates hiPSC-CM muscularization in myocardial ischemic injured mice and non-human primates. Methods and Results: We examined the therapeutic effect of co-transplantation of hiPSC-CMs and hiPSC-ECs in NOD-SCID mice undergoing myocardial infarction (N = 14 / group). Mice receiving co-transplantation had an improvement in ejection fraction compared to control (4.2 ± 1.2 % vs -8.4 ± 0.9 %, P < 0.0001), and even those receiving high-dose (-0.3 ± 0.9 %, P = 0.052) and low-dose (-2.4 ± 1.1 %, P = 0.001) hiPSC-CMs alone treatment. Moreover, less arrhythmic events were observed in co-transplantation using three-lead electrogram. To be more clinically relevant, we first showed in healthy non-human primates (N = 4) that hiPSC-CM engraftment, maturation, and integration was achieved when co-transplanted with hiPSC-ECs. Furthermore, we then examined the therapeutic effect of co-transplantation of hiPSC-CMs and hiPSC-ECs in rhesus macaques undergoing ischemia-reperfusion surgery (N = 3 / group). Consistent with the mouse model, co-transplantation in rhesus macaques significantly improved the ejection fraction (10 ± 1.3 % vs -1.8 ± 2.2 %, P = 0.010), accompanied by a reduced infarct size compared to control (16 ± 1.1 % vs 23 ± 3.3 %, P = 0.091). Conclusions: This study demonstrates the beneficial effects of co-transplantation of hiPSC-CMs with hiPSC-ECs, promoting hiPSC-CM maturation, enhancing neovascularization, and improving cardiac function in both mouse and non-human primate hearts. Delivery of this combined cell therapy holds promise for future clinical translation.

Phosphorylation regulation of cardiac proteins in Babesia microti infected mice in an effort to restore heart function

BackgroundBabesia is a common protozoan parasite that infects red blood cells. In mice infected with Babesia microti, the red blood cells were lysed, resulting in decreased oxygen-carrying capacity. To compensate for low blood oxygen levels, stress on the heart was greatly increased. Babesiosis induces a variety of pathologies; meanwhile, heart tissues initiate self-repair responses to babesiosis-induced tissue damage to restore heart function.MethodsTo discover the molecular mechanisms of the damage and self-repair in the heart after B. microti infection in mice, we investigated the changes in protein expression and phosphorylation modification levels in heart tissues at 0, 5, 8, 11, and 19 days post-infection using data-independent acquisition (DIA) quantitative proteomics.ResultsThe numbers of global proteins we identified were 1934, 1966, 1984, 1989, and 1955 and of phosphopeptides were 5118, 5133, 5130, 5133, and 5140 at 0, 5, 8, 11, and 19 days, respectively, in heart cells after infection with B. microti. The results showed that after B. microti infection the differentially expressed proteins in mice mainly include fibrinogen α (Fgα), fibrinogen β (Fgβ), Serpina1b, Serpina1c, cathepsin Z, cytochrome c oxidases (COXs), RPS11, and RPS20. The proteins with phosphorylation changes mainly include 20-kDa light chain of myosin II (MLC20), myosin light chain kinase (MLCK), mitogen-activated protein kinase 14 (MAPK14), and Akt1. These proteins were mainly involved in coagulation processes, cell apoptosis, oxidative phosphorylation, and ribosomes.ConclusionsThe coagulation cascade-related proteins, apoptosis-related proteins, oxidative phosphorylation-related proteins, and other types of proteins are all involved in the damage and self-repair process in the heart after B. microti infection. These results offer a wealth of new targets for further exploration into the causes of heart disease induced by Babesia infection and are of great significance for novel drug development and new opportunities for targeted therapies.Graphical

Ischemic tolerance and cardiac repair in the spiny mouse (Acomys)

Ischemic heart disease and by extension myocardial infarction is the primary cause of death worldwide, warranting regenerative therapies to restore heart function. Current models of natural heart regeneration are restricted in that they are not of adult mammalian origin, precluding the study of class-specific traits that have emerged throughout evolution, and reducing translatability of research findings to humans. Here, we present the spiny mouse (Acomys spp.), a murid rodent that exhibits bona fide regeneration of the back skin and ear pinna, as a model to study heart repair. By comparing them to ordinary mice (Mus musculus), we show that the acute injury response in spiny mice is similar, but with an associated tolerance to infarction through superior survivability, improved ventricular conduction, and near-absence of pathological remodeling. Critically, spiny mice display increased vascularization, altered scar organization, and a more immature phenotype of cardiomyocytes, with a corresponding improvement in heart function. These findings present new avenues for mammalian heart research by leveraging unique tissue properties of the spiny mouse.

Lymphatic Clearance of Immune Cells in Cardiovascular Disease.

Recent advances in our understanding of the lymphatic system, its function, development, and role in pathophysiology have changed our views on its importance. Historically thought to be solely involved in the transport of tissue fluid, lipids, and immune cells, the lymphatic system displays great heterogeneity and plasticity and is actively involved in immune cell regulation. Interference in any of these processes can be deleterious, both at the developmental and adult level. Preclinical studies into the cardiac lymphatic system have shown that invoking lymphangiogenesis and enhancing immune cell trafficking in ischaemic hearts can reduce myocardial oedema, reduce inflammation, and improve cardiac outcome. Understanding how immune cells and the lymphatic endothelium interact is also vital to understanding how the lymphatic vascular network can be manipulated to improve immune cell clearance. In this Review, we examine the different types of immune cells involved in fibrotic repair following myocardial infarction. We also discuss the development and function of the cardiac lymphatic vasculature and how some immune cells interact with the lymphatic endothelium in the heart. Finally, we establish how promoting lymphangiogenesis is now a prime therapeutic target for reducing immune cell persistence, inflammation, and oedema to restore heart function in ischaemic heart disease.

Overexpression of miR-145 in Bone Marrow Mesenchymal Stem Cells Improves Myocardial Injury in Rats

Ischemia/reperfusion injury (IRI) causes myocardial damage. Bone marrow mesenchymal stem cells (BMSCs) exert protection on damaged hearts. We studied the effect of BMSCs with highly expressed miR-145 on repairing damaged heart caused by IRI in rats. SD rats were selected to isolate BMSCs which were assigned into negative control group, BMSCs group or miR-145-BMSCs (transfected with a lentivirus carrying pLVX-miR-145) followed by analysis of cell proliferation and apoptosis, and level of miR-145, Bcl2, Bax and VEGF by qRT-PCR. BMSCs overexpressing miR-145 showed elevated proliferation and decreased apoptotic activity. The cardiac function of miR-145-BMSCs and BMSCs rats was improved significantly, Bcl-2 and VEGF expression was enhanced, and Bax was decreased with more significant improvement in miR-145-BMSCs group. miR-145 overexpression has a regulatory effect on the biological behavior of BMSCs, and upregulates Bcl-2, VEGF and other key factors to repair the heart damage caused by IRI and restore heart function.

A continuum model and simulations for large deformation of anisotropic fiber–matrix composites for cardiac tissue engineering

Cardiac patch therapies promise to restore heart function and lower the risk of heart failure after heart attack. Fiber–matrix engineered tissue scaffolds have gained significant attention due to their tunable micro-structures, providing nonlinear mechanical properties similar to native anisotropic heart tissues. Mechanical properties of engineered scaffolds directly affect the stress fields generated inside and around the tissue scaffolds and have significant impact on the tissue functionality. Currently, biomedical cardiac patches are designed through experimentation and there exists a need for an accurate model that will allow micro-structural design optimization and analysis of effectiveness of the implanted patches. We have developed a three-dimensional large strain continuum model that can predict nonlinear, anisotropic mechanical response of engineered tissue scaffolds that have two orientation families of fibers inside a bulk hydrogel matrix. We have validated the predictive capability of our continuum model for the fiber–matrix composite using selected experiments and a suite of detailed finite element analysis that incorporated the micro-structural details of the composites. Comparing the continuum model predictions (1 element) against the representative volume micro-structural geometry finite element simulations (with greater than 4,00,000 elements), we show that the proposed model can accurately predict nonlinear mechanical behavior of highly anisotropic tissue scaffolds in both the longitudinal and transverse directions, as a function of the critical design parameters inter-fiber angle and fiber spacing. We show that the model can also capture native heart tissue’s anisotropic large strain mechanical response. We implemented our model in the finite element software Abaqus by writing a user material subroutine UANISOHYPER and demonstrated its predictive abilities by conducting a full three-dimensional analysis of engineered tissue patch application on an infarcted heart.

Heart Regeneration in the Leopard Gecko ( Eublepharis macularius ): a Comparison of Spontaneous Repair and Regrowth Following Two Different Injury Models

Across vertebrates, non-lethal injuries to the heart are resolved in one of two ways: scar formation or regeneration. Injury to the mammalian heart results in the permanent loss of contractile muscle cells (cardiomyocytes) and formation of a non-contractile fibrous scar. In contrast, species such as zebrafish and salamander are capable regenerating damaged or lost cardiomyocytes, thus restoring heart function. Previous work has shown that the cellular processes involved in heart regeneration, such as cell death and proliferation, appear to be conserved across teleost fish and salamanders. Whether similar the cellular processes are involved in heart regeneration in reptiles remains largely unexplored. Here, we characterize heart regeneration in the lizard Eublepharis macularius (the leopard gecko, hereafter ‘gecko’), following two different injury models: a physical puncture (cardiocentesis) and a cryolesion. Cardiocentesis is a penetrating wound that creates a small-scale lesion as a needle passed through the body wall into the heart ventricle. A cryolesion requires opening the body cavity to expose the heart, and then placing a pre-cooled probe directly on the ventricle. This results in the destruction of ~30% of the ventricle. Both injury models were tolerated by geckos, and normal movement and feeding behaviours were resumed within days. To characterize the cellular events involved in heart repair, we used serial histology and immunostaining for markers of cell death (Terminal deoxynucleotidyl transferase dUTP nick end labeling) or cell proliferation (proliferating cell nuclear antigen), each with markers for cardiomyocytes (alpha-smooth muscle actin, myosin heavy chain), and fibroblasts/endocardial cells (Vimentin). Within the first 1-3 days, both injury models are characterized by localized cell death and a loss in cardiomyocytes at the wound site. Over the next two weeks, injured hearts no longer show evidence of cell death. Simultaneously, there is an increase in cell proliferation by populations of cardiomyocytes bordering the wound site and by non-cardiomyocytes within the wound bed itself. Cardiocentesis injuries were resolved within 14 days, while cryoinjuries were resolved within 60 days. Ultimately, both injury models demonstrate the return of mature cardiomyocytes and the near-perfect restoration of the original architecture of the ventricular wall. Overall, our findings reveal that the cellular responses involved in gecko heart regeneration are conserved across different injury models but the duration of repair varies with the magnitude of the injury.

A tunable self-healing ionic hydrogel with microscopic homogeneous conductivity as a cardiac patch for myocardial infarction repair

Conductive hydrogel is a potential therapeutic tool to treat damaged heart muscles in myocardial infarction (MI). However, it is still a quite challenge to optimize the fabrication of a therapeutic hydrogel patch that sustains favorable biocompatibility, electronic and mechanical stability under a complicated MI microenvironment. Herein, a tunable self-healing ionic hydrogel (POG1) was developed through the introduction of a biocompatible polyacrylic acid (PAA, FDA-approved) into the hydrogel matrix. The fabricated POG1 hydrogel possessed suitable stretchable (>500% strain) and compressive (>85% strain) properties, comparable modulus with mammalian heart (30–500 kPa, Young's modulus), self-healable, and highly stable conductivity during large deformations (~50% compress strain, ~150% tensile strain). Specifically, the established PAA nano-channels inside of POG1 endowed the hydrogel with microscopic ultra-homogeneous conductivity. Compared to those seeded in the electronic conductors-embedded (PPy, CNT, rGO) hydrogels, the cardiomyocytes (CMs) seeded in the POG1 hydrogel exhibited more significantly oriented sarcomeres. This POG1 engineered cardiac patch (ECP) also exerted robust benefits in attenuating left ventricular remodeling and restoring heart function after implantation in vivo. This paper highlighted a previously unexplored strategy for a biocompatible ionic conductive hydrogel ECP with an excellent MI repair function.

Cardiotoxicity in HER2-positive breast cancer patients.

Due to the recent advances in diagnosis and management of patients with HER2-positive breast cancer, especially through novel HER2-targeted agents, cardiotoxicity becomes an emerging problem. Although chemotherapy significantly increases survival, the risk of cardiovascular disease development is high and still underestimated and could imply treatment discontinuation. Frequently, due to lack of rigorous diagnosis strategies, cardiotoxicity assessment is delayed, and, moreover, the efficacy of current therapy options in restoring heart function is questionable. For a comprehensive risk assessment, it is vital to characterize the clinical spectrum of HER2-targeted agents and anthracyclines, as well as their pathogenic pathways involved in cardiotoxicity. Advanced cardiovascular multimodal imaging and circulating biomarkers plays primary roles in early assessing cardiotoxicity and also in guiding specific preventive measures. Even though the knowledge in this field is rapidly expanding, there are still questions that arise regarding the optimal approach in terms of timing and methods. The aim of the current review aims to providean overview of currently available data.

Lymphoangiocrine signals promote cardiac growth and repair.

Recent studies suggested a beneficial role of lymphatics in restoring heart function after cardiac injury1–6. Here we report that in mice lymphatics promote cardiac growth, repair and cardio-protection. We show that a lymphoangiocrine signal produced by lymphatic endothelial cells (LECs) controls cardiomyocyte (CM) proliferation and survival during heart development, improves neonatal cardiac regeneration and is cardioprotective after myocardial infarction (MI). Embryos devoid of LECs develop smaller hearts as a consequence of reduced CM proliferation and increased CM apoptosis. Culturing primary mouse CMs in LEC-conditioned media increases CM proliferation and survival, indicating that LECs produce lymphoangiocrine signals controlling CM homeostasis. Characterization of the LEC secretome identified Reelin as a key player responsible for such function. Moreover, we report that LEC-specific Reln-null embryos also develop smaller hearts, that Reelin is required for efficient heart repair and function following neonatal MI, and that cardiac delivery of REELIN using collagen patches improves adult heart function after MI through a cardioprotective effect. These results identify a lymphoangiocrine role of LECs during cardiac development and injury response, and Reelin as an important mediator of this function.

Human Induced Pluripotent Stem Cell-Derived Cardiomyocytes, in Contrast to Adipose Tissue-Derived Stromal Cells, Efficiently Improve Heart Function in Murine Model of Myocardial Infarction.

Cell therapies are extensively tested to restore heart function after myocardial infarction (MI). Survival of any cell type after intracardiac administration, however, may be limited due to unfavorable conditions of damaged tissue. Therefore, the aim of this study was to evaluate the therapeutic effect of adipose-derived stromal cells (ADSCs) and human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) overexpressing either the proangiogenic SDF-1α or anti-inflammatory heme oxygenase-1 (HO-1) in a murine model of MI. ADSCs and hiPSCs were transduced with lentiviral vectors encoding luciferase (Luc), GFP and either HO-1 or SDF-1α. hiPSCs were then differentiated to hiPSC-CMs using small molecules modulating the WNT pathway. Genetically modified ADSCs were firstly administered via intracardiac injection after MI induction in Nude mice. Next, ADSCs-Luc-GFP and genetically modified hiPSC-CMs were injected into the hearts of the more receptive NOD/SCID strain to compare the therapeutic effect of both cell types. Ultrasonography, performed on days 7, 14, 28 and 42, revealed a significant decrease of left ventricular ejection fraction (LVEF) in all MI-induced groups. No improvement of LVEF was observed in ADSC-treated Nude and NOD/SCID mice. In contrast, administration of hiPSC-CMs resulted in a substantial increase of LVEF, occurring between 28 and 42 days after MI, and decreased fibrosis, regardless of genetic modification. Importantly, bioluminescence analysis, as well as immunofluorescent staining, confirmed the presence of hiPSC-CMs in murine tissue. Interestingly, the luminescence signal was strongest in hearts treated with hiPSC-CMs overexpressing HO-1. Performed experiments demonstrate that hiPSC-CMs, unlike ADSCs, are effective in improving heart function after MI. Additionally, long-term evaluation of heart function seems to be crucial for proper assessment of the effect of cell administration.

Stem Cells and Their Cardiac Derivatives for Cardiac Tissue Engineering and Regenerative Medicine.

Significance: Heart failure is among the leading causes of morbidity worldwide with a 5-year mortality rate of ∼50%. Therefore, major efforts are invested to reduce heart damage upon injury or maintain and at best restore heart function. Recent Advances: In clinical trials, acellular constructs succeeded in improving cardiac function by stabilizing the infarcted heart. In addition, strategies utilizing stem-cell-derived cardiomyocytes have been developed to improve heart function postmyocardial infarction in small and large animal models. These strategies range from injection of cell-laden hydrogels to unstructured hydrogel-based and complex biofabricated cardiac patches. Importantly, novel methods have been developed to promote differentiation of stem-cell-derived cardiomyocytes to prevascularized cardiac patches. Critical Issues: Despite substantial progress in vascularization strategies for heart-on-the-chip technologies, little advance has been made in generating vascularized cardiac patches with clinically relevant dimensions. In addition, proper electrical coupling between engineered and host tissue to prevent and/or eliminate arrhythmia remains an unresolved issue. Finally, despite advanced approaches to include hierarchical structures in cardiac tissues, engineered tissues do not generate forces in the range of native adult cardiac tissue. Future Directions: It involves utilizing novel materials and advancing biofabrication strategies to generate prevascularized three-dimensional multicellular constructs of clinical relevant size; inclusion of hierarchical structures, electroconductive materials, and biologically active factors to enhance cardiomyocyte differentiation for optimized force generation and vascularization; optimization of bioreactor strategies for tissue maturation. Antioxid. Redox Signal. 35, 143-162.

The piRNA CHAPIR regulates cardiac hypertrophy by controlling METTL3-dependent N6-methyladenosine methylation of Parp10 mRNA

PIWI-interacting RNAs (piRNAs) are abundantly expressed during cardiac hypertrophy. However, their functions and molecular mechanisms remain unknown. Here, we identified a cardiac-hypertrophy-associated piRNA (CHAPIR) that promotes pathological hypertrophy and cardiac remodelling by targeting METTL3-mediated N6-methyladenosine (m6A) methylation of Parp10 mRNA transcripts. CHAPIR deletion markedly attenuates cardiac hypertrophy and restores heart function, while administration of a CHAPIR mimic enhances the pathological hypertrophic response in pressure-overloaded mice. Mechanistically, CHAPIR-PIWIL4 complexes directly interact with METTL3 and block the m6A methylation of Parp10 mRNA transcripts, which upregulates PARP10 expression. The CHAPIR-dependent increase in PARP10 promotes the mono-ADP-ribosylation of GSK3β and inhibits its kinase activity, which results in the accumulation of nuclear NFATC4 and the progression of pathological hypertrophy. Hence, our findings reveal that a piRNA-mediated RNA epigenetic mechanism is involved in the regulation of cardiac hypertrophy and that the CHAPIR-METTL3-PARP10-NFATC4 signalling axis could be therapeutically targeted for treating pathological hypertrophy and maladaptive cardiac remodelling.

Effects of Lipids and Lipoproteins on Mesenchymal Stem Cells Used in Cardiac Tissue Regeneration.

Mesenchymal stem cells (MSCs) have two characteristics of interest for this paper: the ability to self-renew, and the potential for multiple-lineage differentiation into various cells. MSCs have been used in cardiac tissue regeneration for over a decade. Adult cardiac tissue regeneration ability is quite low; it cannot repair itself after injury, as the heart cells are replaced by fibroblasts and lose function. It is therefore important to search for a feasible way to repair and restore heart function through stem cell therapy. Stem cells can differentiate and provide a source of progenitor cells for cardiomyocytes, endothelial cells, and supporting cells. Studies have shown that the concentrations of blood lipids and lipoproteins affect cardiovascular diseases, such as atherosclerosis, hypertension, and obesity. Furthermore, the MSC lipid profiles, such as the triglyceride and cholesterol content, have been revealed by lipidomics, as well as their correlation with MSC differentiation. Abnormal blood lipids can cause serious damage to internal organs, especially heart tissue. In the past decade, the accumulated literature has indicated that lipids/lipoproteins affect stem cell behavior and biological functions, including their multiple lineage capability, and in turn affect the outcome of regenerative medicine. This review will focus on the effect of lipids/lipoproteins on MSC cardiac regenerative medicine, as well as the effect of lipid-lowering drugs in promoting cardiomyogenesis-associated MSC differentiation.

SUN-100 Exosome-packaged sonic hedgehog in cardiomyocyte plays a central role in type 2 cardiorenal syndrome

Cardiorenal syndrome type 2 (CRS2) is characterized by chronic abnormalities in cardiac function causing progressive chronic kidney disease (CKD). However, the mediators connecting heart and kidney remains largely unknown. In this study, we provide evidence supporting that exosomes containing Shh generated by injured cardiomyocyte plays a vital role in mediating cardiorenal connection in mouse model of transverse aortic constriction (TAC). Four weeks after TAC, mice were randomized into three groups: 1) sham control; 2) TAC mice; 3) TAC mice injected daily with cyclopamine (CPN), a specific inhibitor of hedgehog signaling. At 8 weeks after TAC, all animals were sacrificed. Urine, blood, heart and kidney tissues were collected for analysis. Another set of mice were randomized into three groups after 4 weeks of TAC: 1) sham control mice injected with pcDNA3 plasmid; 2) TAC mice injected with pcDNA3 plasmid; 3) TAC mice injected with shRab27a plasmid, a small GTPases implicated in regulating exosome biogenesis and secretion. These mice were injected with pcDNA3 or shRab27a plasmids once a week for three weeks beginning at 4 weeks after TAC. At 8 weeks after TAC, all animals were sacrificed. Urine, blood, heart and kidney tissues were collected for analysis. Exosomes were isolated from TAC mice serum and CRS2 patients’ serum, and incubated with normal rat kidney interstitial fibroblast (NRK-49F) cells. At 8 weeks after TAC, cardiac hypertrophy and fibrosis were prominent, as evidenced by increased expression of β-myosin heavy chain, α-actin and fibronectin. Echocardiography also revealed an impaired cardiac function in TAC mice. These cardiac lesions were accompanied by an upregulation of Shh and increased production of exosomes in cardiac tissue. Electron microscopy confirmed abundant exosomes derived from the injured cardiomyocytes in the heart of TAC mice. Blockade of Shh signaling by CPN ameliorated cardiac injury and restored heart function. Moreover, TAC mice also developed kidney injury secondary to chronic heart failure, manifested by proteinuria, kidney fibrosis, podocyte injury, and renal upregulation of Shh. CPN mitigated all these lesions in the kidneys. Notably, serum derived from TAC mice or CRS patients was able to induce renal interstitial fibroblast activation in vitro, indicating the circulating factors as mediators of cardiorenal connection. Furthermore, exosomes isolated from TAC serum was sufficient to cause fibroblast activation and matrix production. Furthermore, blockade of exosome biogenesis and secretion by knockdown of Rab27a expression not only protected against cardiac hypertrophy and fibrosis but also ameliorated renal fibrotic lesions. These studies demonstrate that heart-derived, circulating exosomes are a unique and effective vehicle to deliver Shh into the kidney after TAC. Targeting exosome generation and secretion or inhibition of Shh signaling could be novel therapeutic strategies for protecting both heart and kidney in cardiorenal syndrome.

Inducing Endogenous Cardiac Regeneration: Can Biomaterials Connect the Dots?

Heart failure (HF) after myocardial infarction (MI) due to blockage of coronary arteries is a major public health issue. MI results in massive loss of cardiac muscle due to ischemia. Unfortunately, the adult mammalian myocardium presents a low regenerative potential, leading to two main responses to injury: fibrotic scar formation and hypertrophic remodeling. To date, complete heart transplantation remains the only clinical option to restore heart function. In the last two decades, tissue engineering has emerged as a promising approach to promote cardiac regeneration. Tissue engineering aims to target processes associated with MI, including cardiomyogenesis, modulation of extracellular matrix (ECM) remodeling, and fibrosis. Tissue engineering dogmas suggest the utilization and combination of two key components: bioactive molecules and biomaterials. This chapter will present current therapeutic applications of biomaterials in cardiac regeneration and the challenges still faced ahead. The following biomaterial-based approaches will be discussed: Nano-carriers for cardiac regeneration-inducing biomolecules; corresponding matrices for their controlled release; injectable hydrogels for cell delivery and cardiac patches. The concept of combining cardiac patches with controlled release matrices will be introduced, presenting a promising strategy to promote endogenous cardiac regeneration.

Exosomes from mesenchymal stem cells overexpressing MIF enhance myocardial repair.

Accumulating evidence has shown that mesenchymal stem cell (MSC)-derived exosomes (exo) mediate cardiac repair following myocardial infarction (MI). Macrophage migration inhibitory factor (MIF), a proinflammatory cytokine, plays a critical role in regulating cell homeostasis. This study aimed to investigate the cardioprotective effects of exo secreted from bone marrow-MSCs (BM-MSCs) overexpressing MIF in a rat model of MI. MIF plasmid was transducted in BM-MSCs. Exo were isolated from the supernatants of BM-MSCs and MIF-BM-MSCs, respectively. The morphology of mitochondria in neonatal mice cardiomyocytes (NRCMs) was determined by MitoTracker staining. The apoptosis of NRCMs was examined by deoxynucleotidyl transferase-mediated dUTP nick end-labeling. BM-MSC-exo and MIF-BM-MSC-exo were intramuscularly injected into the peri-infarct region in a rat model of MI. The heart function of rats was assessed by echocardiography. The expression of MIF was greatly enhanced in MIF-BM-MSCs compared with BM-MSCs. Both BM-MSC-exo and MIF-BM-MSC-exo expressed CD63 and CD81. NRCMs treated with MIF-BM-MSC-exo exhibited less mitochondrial fragmentation and cell apoptosis under hypoxia/serum deprivation (H/SD) challenge than those treated with BM-MSC-exo via activating adenosine 5'-monophosphate-activated protein kinase signaling. Moreover, these effects were partially abrogated by Compound C. Injection of BM-MSC-exo or MIF-BM-MSC-exo greatly restored heart function in a rat model of MI. Compared with BM-MSC-exo, injection of MIF-BM-MSC-exo was associated with enhanced heart function, reduced heart remodeling, less cardiomyocyte mitochondrial fragmentation, reactive oxygen species generation, and apoptosis. Our study reveals a new mechanism of MIF-BM-MSC-exo-based therapy for MI and provides a novel strategy for cardiovascular disease treatment.