Myocyte Derived Cardiac Spheroids for Post Infarct Cardiac Regeneration

Burford, Evans J

29 January 2014

Research has shown that autologous progenitor-like cardiac spheroids, when delivered to an infarcted heart, are able to restore mechanical function. These spheroids are made by isolating and expanding autologous cardiac progenitor cells. Though these results are promising, the process for creating cardiac spheroids is inefficient and time consuming, requiring a large amount of cardiac tissue. For every 10,000 cardiac myocytes in the heart there is only one cardiac progenitor cell; requiring a large amount of initial tissue. This clinical limitation could be overcome if cardiac myocytes, which are more abundant than cardiac progenitor cells, could be used to make cardiac spheroids. Research has shown that mesenchymal stem cells when co-cultured with adult cardiac myocytes cause the cardiac myocytes to behave like a progenitor cell. We found that, when co-cultured with mesenchymal stem cells, cardiac mycoytes could be made to form cardiac spheroid bodies. This was done by isolating adult myocytes from rat hearts and co-culturing them with human mesenchymal stem cells. After two weeks, cultures were observed to form spheroid bodies and the number of spheroids formed were compared to a pure myocyte control. Cardiac specific staining confirmed that the spheroids were made from the myocytes. It was also found that the mesenchymal stem cells, when co-cultured in the same well with the myocytes, form significantly more spheroids than myocytes treated with stem cell conditioned media. Further, no other cell type present in the co-cultures are able to create spheroid bodies when co-cultured with mycoytes or stem cells. The ability to create cardiac spheroid like bodies from adult myocytes offers a way to overcome the limitations of the time needed and the large quantity of autologous cardiac tissue required to currently make these types of bodies.

cardiac myocyte

cardiac regeneration

Cardiac spheroids

Role of cardiac perivascular cells in cardiac repair

Baily, James Edward

January 2015

Ischaemic heart disease accounts for approximately 7 million deaths worldwide on a yearly basis and this figure is only set to rise as life expectancy in developing countries increases. Although no longer considered a post mitotic organ, the adult heart demonstrates only a very limited capacity for regeneration. Consequently ischaemic injury results in massive loss of contractile cardiomyocytes with damaged myocardium replaced by a non-contractile and poorly conductive collagen scar. This in turn often leads to the development of heart failure. Enhancing or supplementing the myocardial regenerative capacity of the heart is thus a key goal in the development of effective therapies for the treatment of cardiac infarction. Several stem cell populations of non-cardiac origin have been investigated for their capacity to contribute to myocardial repair when therapeutically transplanted into injured hearts. Recent efforts have focused on the “next generation” of donor cells, endogenous cardiac progenitor cells, as these are thought to be better adapted to survival in the cardiac environment and to possess enhanced cardiomyocyte differentiation potential. Pericytes, proposed as the source of the elusive mesenchymal stem cells (MSC) within multiple tissues, are a potential new cell type for use in regenerative medicine. This study tests the hypothesis that pericytes and another perivascular progenitor population, the adventitial cell, from foetal cardiac tissue will positively contribute to the repair of the myocardium post injury. Staining of human foetal ventricular myocardium confirmed the presence of large numbers of both cell types with pericytes tightly associated with capillaries and adventitial cells primarily located in the outer, adventitial layer of muscular arteries. CD146+ CD34- pericytes and CD146- CD34+ adventitial cells were isolated by FACS and expanded in culture. On examination of gene and protein expression both populations stably expressed a similar panel of pericyte markers, MSC markers and cardiac transcription factors as well as c-kit, a cardiac progenitor cell candidate marker. Co-culture with neo-natal rat cardiomyocytes induced expression of an additional cardiac progenitor marker Isl-1 and a mature cardiomyocyte marker ANP in adventitial cells but not pericytes. Labelled, co-cultured, perivascular progenitors readily adhered to rat cells but did not appear to contract independently. De-methylation of perivascular progenitors prior to co-culture resulted in expression of sarcomeric proteins and spontaneous cytoplasmic calcium fluctuations in both populations but more commonly in pericytes. This suggests that cardiac perivascular cells contain a minor sub-population capable of cardiomyocyte differentiation. When these populations were injected into the infarcted hearts of NOD/SCID mice, the animals treated with adventitial cells had significantly reduced cardiac function at 21 days post-surgery on ultrasound examination. An increased scar area and a non-significant trend towards increased scar length and a decreased wall thickness were also observed. Transplanted cells of both groups were detected in low numbers 21 days after injection. Adventitial cells were retained much more readily and in both populations retained cells exhibited three key morphologies: fibroblast type; macrophage type; and cardiomyocyte type. The majority of cells adopted a fibroblast type morphology, lesser numbers a macrophage like morphology and only rare cells a cardiomyocyte like morphology. Both fibroblast and cardiomyocyte type cells had single, human nuclear antigen positive nuclei suggesting true differentiation rather than cell fusion and pericytes exhibited an enhanced ability to differentiate into cardiomyocytes. This supports the in-vitro findings of a minor pro-cardiomyogenic subset within the perivascular cell population. As a result of these findings the starting hypothesis was modified to propose that perivascular cells play a significant role in cardiac fibrosis, largely mediated through expression of surface integrin receptors. This was tested using mice expressing fluorescent proteins under the control of the PDGFR-β promoter and mice in which the αv integrin subunit, common to 5 integrin receptors, had been deleted on the surface of PDGFR-β+ cells. Immunostaining and flow cytometry revealed the PDGFR-β expression to be tightly restricted to perivascular cells and co-expressed with the fibroblast markers, vimentin, PDGFR-α, CD90.2 and CD34 in a subset of cells. Cardiac fibroblasts isolated from reporter mouse hearts revealed strong expression of PDGFR-α and CD34 but PDGFR-β expression in only approximately 20% of the population on flow cytometry. Following angiotensin II induced cardiac hypertrophy and fibrosis approximately 50% of fibroblasts expanding the interstitium were PDGFR-β+. Genetic deletion of the αv integrin subunit on PDGFR-β+ cells resulted in a reduction in cardiac interstitial collagen content of about 50% compared to wild type controls. These findings suggest that the cardiac perivascular PDGFR-β+ population is heterogeneous with a sub-population likely to be fibroblasts or fibroblast progenitors and that the development of cardiac interstitial fibrosis is in part modulated by integrin receptor expression on these cells. In summary this study provides evidence of the existence of a pro-fibrotic progenitor population, which co-express pericyte and MSC markers, within the cardiac perivascular niche. These cells contribute to cardiac fibrosis both on transplantation and endogenously following cardiac injury with the latter mediated via αv integrin expression. Within the perivascular progenitor population however there also appears to be a minor subset of pro-cardiomyogenic cells which are able to adopt a cardiomyocyte phenotype both in-vitro and in-vivo.

616.1

Synergistically Therapeutic Effects of VEGF165 and Angiopoietin-1 on Ischemic Rat Myocardium

Liu, Xiang, Chen, Yijiang, Zhang, Fumin, Chen, Lizhen, Ha, Tuanzhu, Gao, Xiang, Li, Chuanfu

24 April 2007

Purpose: The aim of this study was to determine whether the combination of 2 angiogenic growth factor, vascular endothelial growth factor 165(VEGF165) and angiopoietin-1 (Ang1), could increase angiogenesis and cardiomyocyte(CM) proliferation in an infarcted myocardium. Methods: Myocardial ischemia was induced in rats by ligation of the left anterior descending (LAD) coronary artery. Replication-deficient adenoviruses encoding VEGF165 (Ad-VEGF165), Ang1 (Ad-Ang1) or enhanced green fluorescence protein (Ad-EGFP) was injected into the ischemic myocardium immediately. Bromodexyuridine (BrdU) was administered intraperitoneally 1 week after ligation. One week later, the hearts were harvested and sectioned for hematoxylin-eosin (HE) and immunohistochemistry to evaluate densities of capillary, arteriole and double labelled BrdU(+) CM. M-mode echocardiography was used to evaluate the cardiac function. Results: Ang1 significantly increased collateral vessel formation. Both VEGF165 and Ang1 significantly increased densities of capillary and arteriole, as well as the number of double labelled BrdU(+) CM, and improved cardiac function. Conclusion: Our results suggest that the combination of VEGF165 and Ang1 can increase both myocardial angiogenesis and CM proliferation following myocardial ischemia in rats, leading to improved cardiac function.

angiopoietin-1

cardiac regeneration

gene therapy

myocardial infarction

VEGF165

Surgery

MicroRNA Mediated Proliferation of Adult Cardiomyocytes to Regenerate Ischemic Myocardium

Pandey, Raghav

15 December 2017

No description available.

Biology

Cardiomyocytes

Cardiac regeneration

microRNAs

Heart disease

Cardiovascular

Cardiovascular diseases

Development of therapeutic systems to treat the infarcted heart

Gray, Warren Dale

08 June 2015

Cardiovascular disease is the leading cause of morbidity and mortality in developed nations, and heart disease is predicted to remain the leading killer for the foreseeable future. Acute myocardial infarctions—nearly 1.1 million annually occurring in the U.S. alone—are the major cardiovascular disease subgroup. Current treatments for myocardial infarction are limited to interventions that serve to mitigate the initial insult, but clinical applications to protect or regenerate damaged myocardium are lacking. This dissertation examines three therapeutic systems to treat the infarcted heart. First, the decoration of a polymeric nanoparticle with N-acetylglucosamine for the uptake of anti-­apoptotic therapeutics to ameliorate cardiomyocyte cell death. Second, novel dendrimeric structure architecture to allow for regio­selected decoration of ligands to induce angiogenesis. Third, exosomes secreted from hypoxic cardiac progenitor cells as a naturally derived therapeuticfor angiogenesis and anti-fibrosis, and to provide bio-inspired clues for future therapies.

Myocardial infarction

Cardiac protection

Cardiac regeneration

Angiogenesis

Therapeutic system

Nanoparticle

Dendrimer

Exosome

Hypoxia

N-acetylglucosamine

Gata4-Dependent Differentiation of c-Kit+ Derived Endothelial Cells Underlies Artefactual Cardiomyocyte Regeneration in the Heart

Maliken, Bryan D., B.A.

29 October 2018

No description available.

Molecular Biology

Angiogenesis

Cardiac Regeneration

Gata4

c-Kit Progenitor Cell

Lineage Tracing

Cardiogenic differentiation of induced pluripotent stem cells for regeneration of the ischemic heart

Buccini, Stephanie M.

January 2013

No description available.

Physiological Psychology

iPS cells

myocardial infarction

cardiomyocyte differentiation

angiogenesis

mesenchymal stem cells

cardiac regeneration

Tissue engineering strategies for cardiac regeneration

Hurley, Jennifer R.

January 2011

No description available.

Biomedical Research

tissue engneering

cardiac regeneration

fibroblasts

peptide nanofibers

angiogenesis

matrix remodeling

DIRECTION OF INDUCED PLURIPOTENT STEM CELL DIFFERENTIATION BY ENDOTHELIAL CELL SECRETOME

DiVincenzo, Lola S.

07 August 2015

No description available.

Biomedical Research

Biology

stem cells

induced pluripotent stem cells

regenerative therapy

cardiac regeneration

myocardial infarction

exosome

Cardiac Regeneration Following Myocardial Infarction in a Rat Model of Diabetic Cardiomyopathy

Denby, Elisabeth D.

January 2016

No description available.

Biomedical Research

diabetic cardiomyopathy

myocardial infarction

tissue engineering

cardiac regeneration

matrix metalloprotease

nanofibers