Enhanced engraftment and repairing ability of human adipose-derived stem cells, conveyed by pharmacologically active microcarriers continuously releasing HGF and IGF-1, in healing myocardial infarction in rats.

One of the main cause of ineffective cell therapy in repairing the damaged heart is the poor yield of grafted cells. To overcome this drawback, rats with 4-week-old myocardial infarction (MI) were injected in the border zone with human adipose-derived stem cells (ADSCs) conveyed by poly(lactic-co-glycolic acid) microcarriers (PAMs) releasing hepatocyte growth factor (HGF) and insulin-like growth factor-1 (IGF-1) (GFsPAMs). According to treatments, animals were subdivided into different groups: MI_ADSC, MI_ADSC/PAM, MI_GFsPAM, MI_ADSC/GFsPAM, and untreated MI_V. Two weeks after injection, a 31% increase in ADSC engraftment was observed in MI_ADSC/PAM compared with MI_ADSC (p < 0.05). A further ADSC retention was obtained in MI_ADSC/GFsPAM with respect to MI_ADSC (106%, p < 0.05) and MI_ADSC/PAM (57%, p < 0.05). A 130% higher density of blood vessels of medium size was present in MI_ADSC/GFsPAM compared with MI_ADSC (p < 0.01). MI_ADSC/GFsPAM also improved, albeit slightly, left ventricular remodeling and hemodynamics with respect to the other groups. Notably, ADSCs and/or PAMs, with or without HGF/IGF-1, trended to induce arrhythmias in electrically driven, Langendorff-perfused, hearts of all groups. Thus, PAMs releasing HGF/IGF-1 markedly increase ADSC engraftment 2 weeks after injection and stimulate healing in chronically infarcted myocardium, but attention should be paid to potentially negative electrophysiological consequences.

Restored perfusion and reduced inflammation in the infarcted heart after grafting stem cells with a hyaluronan-based scaffold.

The aim of this study is to investigate the blood perfusion and the inflammatory response of the myocardial infarct area after transplanting a hyaluronan-based scaffold (HYAFF(®) 11) with bone marrow mesenchymal stem cells (MSCs). Nine-week-old female pigs were subjected to a permanent left anterior descending coronary artery ligation for 4 weeks. According to the kind of the graft, the swine subjected to myocardial infarction were divided into the HYAFF(®) 11, MSCs, HYAFF(®) 11/MSCs and untreated groups. The animals were killed 8 weeks after coronary ligation. Scar perfusion, evaluated by Contrast Enhanced Ultrasound echography, was doubled in the HYAFF(®) 11/MSCs group and was comparable with the perfusion of the healthy, non-infarcted hearts. The inflammation score of the MSCs and HYAFF(®) 11/MSCs groups was near null, revealing the role of the grafted MSCs in attenuating the cell infiltration, but not the foreign reaction strictly localized around the fibres of the scaffold. Apart from the inflammatory response, the native tissue positively interacted with the HYAFF(®) 11/MSCs construct modifying the extracellular matrix with a reduced presence of collagene and increased amount of proteoglycans. The border-zone cardiomyocytes also reacted favourably to the graft as a lower degree of cellular damage was found. This study demonstrates that the transplantation in the myocardial infarct area of autologous MSCs supported by a hyaluronan-based scaffold restores blood perfusion and almost completely abolishes the inflammatory process following an infarction. These beneficial effects are superior to those obtained after grafting only the scaffold or MSCs, suggesting that a synergic action was achieved using the cell-integrated polymer construct.

Localization of mesenchymal stem cells grafted with a hyaluronan-based scaffold in the infarcted heart.

BACKGROUND: Permanence of grafted stem cells in the infarcted myocardial area has been suggested to be favored by tissue engineering strategies, including the application of a scaffold as a cell support. However, an estimation of how many cells remain localized in the site of transplantation has never been done. The aim of this work was to investigate the localization of mesenchymal stem cells (MSCs) grafted with a well cell-adhesive polymer in the scar region of the infarcted heart. MATERIALS AND METHODS: Rat MSCs were engineered in a hyaluronan-based scaffold (HYAFF(®)11) for 3 wk. The hearts of donor rats were also explanted, subjected to coronary artery ligation, and grafted into the abdomen of syngeneic rats. Two wk after coronary ligation a small dish of the HYAFF(®)11/MSC construct was introduced into a pouch created in the ventricular wall of the infarct area and left for 2 wk. RESULTS: Under ex vivo conditions, MSCs tightly adhered to the hyaluronan fibers and secreted abundant extracellular matrix. In contrast, HYAFF(®)11 was not more surrounded by the engrafted MSCs 2 wk after construct transplantation. Most MSCs migrated near the border zone of the infarcted area close to the coronary vessels. Moreover, the infarcted region of the heart was enriched in capillaries and the degree of fibrosis was attenuated. CONCLUSIONS: Two wk after transplantation most MSCs grafted in the infarcted myocardium with HYAFF(®)11 had left the scaffold and moved to the border zone. Nevertheless, this treatment increased the myocardial vascularization and reduced the degree of fibrosis in the scar area.

Comparison between stem cells harvested from wet and dry lipoaspirates.

Adipose-derived stem cells (ASC) are usually isolated from lipoaspirates, but it is not known if the anesthetic solution injected into adipose tissue affects cell yield and functions. Two different samples were drawn from the abdominal region of female subjects. In the first, a physiological solution containing lidocaine/adrenaline was injected (wet liposuction, WL), while in the contralateral area, the sample was collected without injecting any solution (dry liposuction, DL). The aspirates were processed to investigate the yield of the stromal-vascular fraction (SVF) cells and ASC frequency, growth rate, apoptosis, and differentiation potential. The solid dried mass of fresh WL isolates was lower than that of DL isolates (p < 0.01) due to the presence, in the former, of a liquid solution. As a consequence, the amount of WL-SVF cells was 18.7% lower than those obtained from DL (p < 0.01); this difference was also observed under culture conditions. In addition, the number of colony-forming unit-fibroblasts (CFU-Fs) obtained from 1 × 10(3) SVF cells was 25.5% lower in WL-aspirates than DL-aspirates (p < 0.05) owing, at least in part, to the observed presence of ASC [corrected] in the liquid solution of the WL isolates. After WL and DL, no differences were observed in ASC growth rate, apoptosis, or differentiation potential toward adipogenic, osteogenic, and endothelial cell lineages. In conclusion, WL yields about 40% fewer ASC than DL due to the combined effect of tissue dilution and the reduced frequency of ASC in the SVF. The main biological features of ASC are suitable for cell-based therapies.

Local activation or implantation of cardiac progenitor cells rescues scarred infarcted myocardium improving cardiac function.

Ischemic heart disease is characterized chronically by a healed infarct, foci of myocardial scarring, cavitary dilation, and impaired ventricular performance. These alterations can only be reversed by replacement of scarred tissue with functionally competent myocardium. We tested whether cardiac progenitor cells (CPCs) implanted in proximity of healed infarcts or resident CPCs stimulated locally by hepatocyte growth factor and insulin-like growth factor-1 invade the scarred myocardium and generate myocytes and coronary vessels improving the hemodynamics of the infarcted heart. Hepatocyte growth factor is a powerful chemoattractant of CPCs, and insulin-like growth factor-1 promotes their proliferation and survival. Injection of CPCs or growth factors led to the replacement of approximately 42% of the scar with newly formed myocardium, attenuated ventricular dilation and prevented the chronic decline in function of the infarcted heart. Cardiac repair was mediated by the ability of CPCs to synthesize matrix metalloproteinases that degraded collagen proteins, forming tunnels within the fibrotic tissue during their migration across the scarred myocardium. New myocytes had a 2n karyotype and possessed 2 sex chromosomes, excluding cell fusion. Clinically, CPCs represent an ideal candidate cell for cardiac repair in patients with chronic heart failure. CPCs may be isolated from myocardial biopsies and, following their expansion in vitro, administered back to the same patients avoiding the adverse effects associated with the use of nonautologous cells. Alternatively, growth factors may be delivered locally to stimulate resident CPCs and promote myocardial regeneration. These forms of treatments could be repeated over time to reduce progressively tissue scarring and expand the working myocardium.

Involvement of polyamines in apoptosis of cardiac myoblasts in a model of simulated ischemia.

Apoptotic cell death of cardiomyocytes is involved in several cardiovascular diseases including ischemia, hypertrophy, and heart failure. The polyamines putrescine, spermidine, and spermine are polycations absolutely required for cell growth and division. However, increasing evidence indicates that polyamines, cell growth, and cell death can be tightly connected. In this paper, we have studied the involvement of polyamines in apoptosis of H9c2 cardiomyoblasts in a model of simulated ischemia. H9c2 cells were exposed to a condition of simulated ischemia, consisting of hypoxia plus serum deprivation, that induces apoptosis. The activity of ornithine decarboxylase, the rate limiting enzyme of polyamine biosynthesis that synthesizes putrescine, is rapidly and transiently induced in ischemic cells, reaching a maximum after 3 h, and leading to increased polyamine levels. Pharmacological inhibition of ornithine decarboxylase by alpha-difluoromethylornithine (DFMO) depletes H9c2 cardiomyoblasts of polyamines and protects the cells against ischemia-induced apoptosis. DFMO inhibits several of the molecular events of apoptosis that follow simulated ischemia, such as the release of cytochrome c from mitochondria, caspase activation, downregulation of Bcl-xL, and DNA fragmentation. The protective effect of DFMO is lost when exogenous putrescine is provided to the cells, indicating a specific role of polyamine synthesis in the development of apoptosis in this model of simulated ischemia. In cardiomyocytes obtained from transgenic mice overexpressing ornithine decarboxylase in the heart, caspase activation is dramatically increased following induction of apoptosis, with respect to cardiomyocytes from control mice, confirming a proapoptotic effect of polyamines. It is presented for the first time evidence of the involvement of polyamines in apoptosis of ischemic cardiac cells and the beneficial effect of DFMO treatment. In conclusion, this finding may suggest novel pharmacological approaches for the protection of cardiomyocytes injury caused by ischemia.

Antiproliferative effect of sildenafil on human pulmonary artery smooth muscle cells.

Pulmonary arterial hypertension (PAH) is characterized by vasoconstriction and by obstructive changes of the pulmonary vasculature including smooth muscle cell proliferation which leads to medial hypertrophy and subsequent luminal narrowing. Sildenafil, an orally active inhibitor of cGMP phosphodiesterase-type-5, exerts pulmonary vasodilator activity in PAH patients. We evaluated the effects of sildenafil on growth of cultured human pulmonary artery smooth muscle cells (PASMC). The results indicate that sildenafil reduced DNA synthesis stimulated by PDGF and dose dependently inhibited PASMC proliferation. These effects were paralleled by a progressive increase in cGMP content, followed by an accumulation of cAMP. The treatment with 8-bromo-cGMP or dibutyryl-cAMP mimicked all the effects of sildenafil. On the other hand, treatment of PASMC with inhibitors of cGMP-dependent protein kinase (PKG) or cAMP-dependent protein kinase (PKA) reversed the antiproliferative effect of sildenafil. In addition, sildenafil inhibited the phosphorylation of ERK, a converging point for several pathways leading to cell proliferation. This effect was partially reduced by PKG inhibition and completely abolished by PKA inhibition.We conclude that sildenafil exerts an antiproliferative effect on human PASMC that is mediated by an interaction between the cGMP-PKG and the cAMP-PKA activated pathways, leading to inhibition of PDGF-mediated activation of the ERK.