Transplantation of Progenitor Cells and Regeneration Enhancement in Acute Myocardial Infarction (TOPCARE-AMI)

Umbilical cord blood derived endothelial progenitor cells for tissue engineering of vascular grafts

BACKGROUND

A substantial limitation regarding present pediatric cardiac surgery is the lack of appropriate materials for the repair of congenital defects. To address this shortcoming, tissue engineering is a scientific field that aims at in vitro fabrication of living autologous grafts with the capacity of growth, repair, and regeneration. Here we focused on tissue engineered vascular grafts using human umbilical cord blood derived endothelial progenitor cells (EPCs), as a noninvasive cell source for pediatric applications.

METHODS

EPCs were isolated from 20 ml fresh human umbilical cord blood by Ficoll gradient centrifugation and cultured in endothelial basal medium containing growth factors. After proliferation and differentiation cells were analyzed by immunohistochemistry and seeded onto three-dimensional (3D) biodegradable vascular scaffolds (porosity > 95%, n = 22). Twenty-four hours after seeding the vascular grafts were positioned into a pulse-duplicator-in vitro system and grown for 48 hours under biomimetic conditions. A second group was grown 6 days statically and an additional 6 days biomimetically. Controls were cultured statically. Analysis of the grafts included immunohistochemistry, histology, and scanning electron microscopy.

RESULTS

Preseeding differentiated EPCs indicated constant endothelial phenotypes including acetylated low-density lipoprotein, cluster of differentiation 31, von Willebrand factor, and endothelial nitric oxide synthetase. Seeded EPCs established favorable cell-to-polymer attachment and proliferation into the 3D tubular scaffolds. Both conditioned and static cellular constructs demonstrated positive staining for cluster of differentiation 31, von Willebrand factor, and expression of endothelial nitric oxide synthase.

CONCLUSIONS

Human umbilical cord derived EPCs indicated exceptional growth characteristics used for tissue engineering of vascular grafts. These cells demonstrated a constant endothelial phenotype and related functional features. Based on these results EPCs seem to be a promising autologous cell source with regard to cardiovascular tissue engineering, particularly for the repair of congenital defects.

In vitro differentiation characteristics of cultured human mononuclear cells—implications for endothelial progenitor cell biology

Endothelial progenitor cells (EPCs) have been implicated in the pathogenesis and treatment of cardiovascular disease. By use of quantitative uptake of DiLDL and lectin staining, EPCs have been characterized reliably. However, the exact nature and function of this cell population still remains poorly defined. In an attempt to further clarify the cell surface characteristics of EPCs, mononuclear cells (MNCs) were isolated from human blood and cell surface expression patterns were defined by FACS analysis before and after differentiation for 1-10 days in cell culture. "Classical" double staining for DiLDL and Ulex europaeus increases to 89.2 /- 0.05 after 10 days in culture. Looking at EPC-specific markers by FACS analysis, 0.18 +/- 0.11% of freshly isolated MNCs express CD34, 0.13 +/- 0.08% CD133, 0.59 +/-0.51% VEGFr2, 0.01 +/- 0.02% CD34/VEGFr2, 0.09 +/- 0.05% CD34/CD133, 0.58 +/- 0.13% CD34/CD31, and 0.02 +/- 0.01% CD34/CD146, respectively. Induction of the endothelial phenotype is evidenced by positive staining for VEGFr2, CD146, and CD31, and occurs in co-expression with stem cell markers in less than 2 +/- 0.52% of cultured cells. Expression of CD34 increases to 0.38 +/- 0.10% after 10 days, whereas the CD133(+) cell population shows an initial peak at 24h (0.29 +/- 0.18%) before decreasing to 0.15 +/- 0.02% at day 10. EPCs co-expressing CD34/CD133 increase to 0.19 +/- 0.09% after 10 days, and EPCs double-positive for CD34/VEGFr2 increase to 1.45 +/- 1.03%. Looking at leukocyte, lymphocyte, and monocyte lineage markers, 56.27 +/- 0.15% of freshly isolated MNCs express CD45, 7.13 +/- 0.02% CD14, and 38.65 +/- 0.01% CD3. Over the 10-day culture period, expression of CD45 decreases to 28.48 +/- 0.18%, CD3 to 23.11 +/- 0.02%, and CD14 to 0.09 +/- 0.02%. Cells co-expressing CD3/CD45 decrease from 38.88 +/- 0.33% to 24.86 +/- 2.49% after 10 days in culture. These findings extend present knowledge by showing that human MNCs differentiate at a very low rate to EPCs, while a majority of the cultured cell population remain committed to the leukocyte or lymphocyte lineage. Careful surface marker analysis might be necessary when using in vitro EPC differentiation systems.

Stem cells and cardiovascular and renal disease: today and tomorrow

The traditional view that organs have only limited regenerative capacity has been challenged in recent years as adult bone marrow stem cells as well circulating progenitor cells have been identified to retain the plasticity to participate in neovascularization, a process so far believed not to be possible after birth. An organ that is damaged by ischemia causes the release of cytokines; these act via the flowing blood and stimulate the bone marrow, which then mobilizes progenitor cells to the blood and directs them to adhere to and migrate into the damaged organ. Thus, these progenitor cells most likely constitute a natural repair mechanism that counteracts degenerative or aging processes. On the basis of encouraging experimental data, first clinical trials have been established to demonstrate the safety and the feasibility of progenitor cell therapy in case of peripheral artery disease or myocardial infarction. Trials investigating injection of bone marrow or circulating progenitor cells into the coronary artery after an acute myocardial infarction not only demonstrates safety of the procedure but also gave hints toward efficacy. Nevertheless, these findings have to be validated by subsequent larger, prospective, randomized, controlled trials. There are also potential topics in nephrology, where modification of progenitor cell activity might be of benefit, such as renal ischemic disease, glomerular disease, and renal transplant vasculopathy. Finding a way to integrate the principle of progenitor cell action into therapeutic efforts might provide a completely new therapeutic strategy that not only attempts to retard disease progression but furthermore targets to regenerate damaged organs.

Treatment with granulocyte colony-stimulating factor for mobilization of bone marrow cells in patients with acute myocardial infarction

BACKGROUND

This study was undertaken to evaluate the hypothesis that treatment with granulocyte colony-stimulating factor (G-CSF) to mobilize bone marrow cells (BMCs) is feasible and safe and promotes neovascularization and myocardial function in patients with acute myocardial infarction.

METHODS

Fourteen patients in the treatment group and 9 patients in the control group were enrolled in this prospective, nonrandomized, open-label study. Forty-eight hours after successful recanalization and stent implantation, the patients of the treatment group received 10 microg/kg body weight per day G-CSF subcutaneously for mean treatment duration of 7.0 +/- 1.0 days. Nine patients fulfilled the entry criteria but refused participation and served therefore as control group. In both groups, regional wall motion and perfusion was evaluated with electrocardiogram-gated sestamibi single-photon emission computed tomography imaging and ejection fraction with radionuclidventriculography before discharge and after 3 months.

RESULTS

No severe side effects of G-CSF treatment were observed. There was a significant improvement of the regional wall motion and perfusion within the treatment group (P < .0001) and between the treatment and control group (P < .05 and P < .01, respectively). Ejection fraction in the treatment group increased from 0.40 +/- 0.11 to 0.48 +/- 0.13 (P < .01), whereas in the control group, ejection fraction increased from 0.40 +/- 0.13 to 0.43 +/- 0.13 (P = .049). A control angiography of the treatment group after 12.4 +/- 6.6 months showed an in-stent restenosis in 1 patient.

CONCLUSION

In patients with acute myocardial infarction, treatment with G-CSF to mobilize BMCs is feasible and safe and seems to be effective under clinical conditions. The therapeutic effect might be attributed to BMC-associated promotion of myocardial regeneration and neovascularization.

Therapeutic potential of endothelial progenitor cells in cardiovascular diseases

Endothelial dysfunction and cell loss are prominent features in cardiovascular disease. Endothelial progenitor cells (EPCs) originating from the bone marrow play a significant role in neovascularization of ischemic tissues and in re-endothelialization of injured blood vessels. Several studies have shown the therapeutic potential of EPC transplantation in rescue of tissue ischemia and in repair of blood vessels and bioengineering of prosthetic grafts. Recent small-scale trials have provided preliminary evidence of feasibility, safety, and efficacy in patients with myocardial and critical limb ischemia. However, several studies have shown that age and cardiovascular disease risk factors reduce the availability of circulating EPCs (CEPCs) and impair their function to varying degrees. In addition, the relative scarcity of CEPCs limits the ability to expand these cells in sufficient numbers for some therapeutic applications. Priority must be given to the development of strategies to enhance the number and improve the function of CEPCs. Furthermore, alternative sources of EPC such as chord blood need to be explored. Strategies for improvement of cell adhesion, survival, and prevention of cell senescence are also essential to ensure therapeutic viability. Genetic engineering of EPCs may be a useful approach to developing these cells into efficient therapeutic tools. In the clinical arena there is pressing need to standardize the protocols for isolation, culture, and therapeutic application of EPC. Large-scale multi-center randomized trials are required to evaluate the long-term safety and efficacy of EPC therapy. Despite these hurdles, the outlook for EPC-based therapy for cardiovascular disease is promising.

Bone marrow stem cell transplantation for cardiac repair

Cardiomyocytes respond to physiological or pathological stress only by hypertrophy and not by an increase in the number of functioning cardiomyocytes. However, recent evidence suggests that adult cardiomyocytes have the ability, albeit limited, to divide to compensate for the cardiomyocyte loss in the event of myocardial injury. Similarly, the presence of stem cells in the myocardium is a good omen. Their activation to participate in the repair process is, however, hindered by some as-yet-undetermined biological impediments. The rationale behind the use of adult stem cell transplantation is to supplement the inadequacies of the intrinsic repair mechanism of the heart and compensate for the cardiomyocyte loss in the event of injury. Various cell types including embryonic, fetal, and adult cardiomyocytes, smooth muscle cells, and stable cell lines have been used to augment the declining cardiomyocyte number and cardiac function. More recently, the focus has been shifted to the use of autologous skeletal myoblasts and bone marrow-derived stem cells. This review is a synopsis of some interesting aspects of the fast-emerging field of bone marrow-derived stem cell therapy for cardiac repair.

Current Status of Cellular Therapy for Ischemic Heart Disease

Cellular therapy for acute myocardial infarction and ischemic cardiomyopathy has entered clinical trials across the globe. Early promising results have now provided the justification for larger randomized and blinded trials to address the efficacy of cellular therapy. A variety of fresh or cultured autologous cells have been delivered by catheter-guided endocardial, catheter-guided intracoronary, catheter-guided transvenous, and direct epicardial routes. This review will summarize the clinical data and highlight salient basic science data that support the ongoing efforts to identify the optimal cellular therapy both for acute myocardial infarction and chronic ischemic cardiomyopathy patients.

A regenerative role for bone marrow following experimental colitis: contribution to neovasculogenesis and myofibroblasts

BACKGROUND & AIMS

Bone marrow (BM) cells form differentiated adult lineages within nonhematopoietic tissues, with a heightened propensity with increasing regenerative pressure dictated by disease. We have previously shown that BM cells engraft into the gut and contribute substantially to the subepithelial intestinal myofibroblast population in the lamina propria. To investigate the reparative capacity of BM in inflammatory bowel disease (IBD), a well-established model of experimental colitis was used.

METHODS

Lethally irradiated female mice were rescued by a BM transplant from male donors. Colitis was induced 6 weeks posttransplantation by injection of trinitrobenzene sulfonic acid (TNBS), and tissues were analyzed 1-14 days later. Donor-derived cells were detected by in situ hybridization using a Y chromosome-specific probe, and their phenotype was determined by immunohistochemistry.

RESULTS

TNBS-induced colitis was manifest as patchy lesions that increased in severity between days 1 and 8, and the mucosa gradually regenerated between days 8 and 14. The contribution of BM to intestinal myofibroblasts was significantly increased in regions of colitis compared with noninflamed regions. Furthermore, BM-derived endothelial cells, pericytes, and vascular smooth muscle cells were frequently interspersed throughout blood vessels, suggesting that these cells facilitate angiogenesis in tissue repair, substantiated by a significant increase in the incidence of BM-derived vascular smooth muscle cells in colitic compared with noninflamed regions. Blood vessels formed entirely from BM-derived cells were also seen, suggesting a role for BM in neovasculogenesis.

CONCLUSIONS

Our data show that BM contributes to multiple intestinal cell lineages in colitis, with an important function in tissue regeneration and vasculogenesis after injury.

Human umbilical cord blood mononuclear cells for the treatment of acute myocardial infarction

Cell transplantation is a new treatment to improve cardiac function in hearts that have been damaged by myocardial infarction. We have investigated the use of human umbilical cord blood mononuclear progenitor cells (HUCBC) for the treatment of acute myocardial infarction. The control group consisted of 24 normal rats with no interventions. The infarct + vehicle group consisted of 33 rats that underwent left anterior descending coronary artery (LAD) ligation and after 1 h were given Isolyte in the border of the infarction. The infarct + HUCBC group consisted of 38 rats that underwent LAD ligation and after 1 h were given 10(6) HUCBC in Isolyte directly into the infarct border. Immunosuppression was not given to any rat. Measurements of left ventricular (LV) ejection fraction, LV pressure, dP/dt, and infarct size were determined at baseline and 1, 2, 3, and 4 months. The ejection fraction in the controls decreased from 88+/-3% to 78+/-4% at 4 months (p = 0.03) as a result of normal aging. Following infarction in the infarct + vehicle group, the ejection fraction decreased from 87+/-4% to 51+/-3% between 1 and 4 months (p < 0.01). In contrast, the ejection fraction of the infarcted + HUCBC-treated rat hearts decreased from 87+/-4% to 63+/-3% at 1 month, but progressively increased to 69+/-6% at 3 and 4 months, which was different from infarct + vehicle group rats (p < 0.02) but similar to the controls. At 4 months, anteroseptal wall thickening in infarct + HUCBC group was 57.9+/-11.6%, which was nearly identical to the control anteroseptal thickening of 59.2+/-8.9%, but was significantly greater than the infarct + vehicle group, which was 27.8+/-7% (p < 0.02). dP/dt(max) increased by 130% in controls with 5.0 microg of phenylephrine (PE)/min (p < 0.001). In the infarct + vehicle group, dP/dt(max) increased by 91% with PE (p = 0.01). In contrast, in the infarct + HUCBC group, dP/dt(max) increased with PE by 182% (p < 0.001), which was significantly greater than the increase in dP/dt(max) in the infarct + vehicle group (p = 0.03) and similar to the increase in the controls. Infarct sizes in the infarct + HUCBC group were smaller than the infarct + vehicle group and averaged 3.0+/-2.8% for the infarct + HUCBC group versus 22.1+/-5.6% for infarct + vehicle group at 3 months (p < 0.01); at 4 months they averaged 9.2+/-2.0% for infarct + HUCBC group versus 40.0+/-9.2% for the infarct + vehicle group (p < 0.001). The present experiments demonstrate that HUCBC substantially reduce infarction size in rats without requirements for immunosuppression. As a consequence, LV function measurements, determined by LV ejection fraction, wall thickening, and dP/dt, are significantly greater than the same measurements in rats with untreated infarctions.

Adult 'endothelial progenitor cells'. Renewing vasculature

During embryogenesis, endothelial progenitor cells participate in the initial processes of primitive blood vessel formation (vasculogenesis). It has become evident that progenitors to vascular endothelial cells also exist in the adult. Endothelial progenitors normally reside in the adult bone marrow but may become mobilized into circulation by cytokine or angiogenic growth factor signals from the periphery, enter extravascular tissue, and promote de novo vessel formation by virtue of physically integrating into vessels and/or supplying growth factors (adult vasculogenesis). For that reason, autologous endothelial progenitors, mobilized in situ or transplanted, has become a major target of therapeutic revascularization approaches to ischemic disease and endothelial injury. Moreover, endothelial progenitors represent a potential target of strategies to block tumor growth.

Closed-chest cell injections into mouse myocardium guided by high-resolution echocardiography

The mouse is an important model for the development of therapeutic stem cell/bone marrow cell implantation to treat ischemic myocardium. However, its small heart size hampers accurate implantation into the left ventricular (LV) wall. Precise injections have required surgical visualization of the heart, which is subject to complications and is impractical for delayed or repeated injections. Furthermore, the thickness of the myocardium is comparable to the length of a needle bevel, so surgical exposure does not prevent inadvertent injection into the LV cavity. We describe the use of high-resolution echocardiography to guide nonsurgical injections accurately into the mouse myocardial wall. We optimized this system by using a mixture of ultrasound contrast and fluorescent microspheres injected into the myocardium, which enabled us to interpret the ultrasound image of the needle during injection. Quantitative dye injection studies demonstrated that guided closed-chest injections and open-chest injections deliver comparable amounts of injectate to the myocardium. We successfully used this system in a mouse myocardial infarction model to target the injection of labeled cells to a region adjacent to the infarct. Intentional injection of tracer into the LV cavity resulted in a small accumulation in the myocardium, suggesting that non-guided cell injections into mouse hearts may appear to be successful even if the majority of the injectate is lost in the chamber. The use of this system will allow more precise cellular implantation into the mouse myocardium by accurately guiding injections to desired locations, confirming successful implantation of cells, in a clinically relevant time frame.

Circulating endothelial progenitor cells are reduced in peripheral vascular complications of type 2 diabetes mellitus

OBJECTIVES

We sought to establish whether a reduction in endothelial progenitor cells (EPCs) has a putative role in peripheral vascular disease (PVD) of type 2 diabetic patients.

BACKGROUND

Peripheral vascular disease is a common and severe complication of diabetes mellitus. Impaired collateralization of diabetic vasculopathy has been extensively shown, but causes leading to its pathogenesis are not fully understood. Recently, EPCs have been found to contribute to vascular repair and angiogenesis. Diabetes has been associated with low levels of circulating EPCs, but no data are available in the literature on the relationship between EPCs and PVD in diabetes.

METHODS

Flow cytometric analysis was used to quantify circulating progenitor cells (CPCs, CD34+) and EPCs (CD34+KDR+) in 51 patients and 17 control subjects.

RESULTS

The CPCs and EPCs from diabetic patients were reduced by 33% and 40%, respectively, compared with healthy subjects (p < 0.001). An inverse correlation was found between the number of EPCs and the values of fasting glucose (r = -0.49, p = 0.006). Peripheral vascular disease was associated with a 47% reduction in EPCs (p < 0.0001) and EPC levels directly correlated with the ankle-brachial index (r = 0.70, p = 0.01). The subgroup of diabetic patients with PVD also had reduced CPCs by 32% (p = 0.037), whereas patients with ischemic foot lesions had the lowest levels of both EPCs and CPCs (p = 0.02).

CONCLUSIONS

Our data demonstrate decreased EPC levels in diabetic patients and, for the first time, show that PVD is associated with an extensively low number of EPCs. Depletion of circulating EPCs in diabetic patients may be involved in the pathogenesis of peripheral vascular complications.

Endothelial progenitor cells functional characterization

Increasing evidence suggests that circulating progenitor cells contribute to postnatal neovascularization. These cells home to sites of ischemia, adopt an endothelial phenotype, and contribute to new blood vessel formation. Hence, the identity of the circulating cells that contribute to neovascularization is not entirely clear. Bone-marrow-derived hematopoietic progenitor cells can give rise to endothelial cells and contribute to endothelial recovery and new capillary formation after ischemia. However, nonhematopoietic stem cells within the bone marrow and adipose-tissue-derived cells, as well as cardiac and neural progenitor cells, also differentiate to endothelial cells. Progenitor cells from the different sources may be useful to augment therapeutic vascularization. The present review article summarizes the different subtypes of (endothelial) progenitor cells that can give rise to endothelial cells, enhance neovascularization, and may be suitable for therapeutic neovascularization.

Unchain my heart: the scientific foundations of cardiac repair

In humans, the biological limitations to cardiac regenerative growth create both a clinical imperative--to offset cell death in acute ischemic injury and chronic heart failure--and a clinical opportunity; that is, for using cells, genes, and proteins to rescue cardiac muscle cell number or in other ways promote more efficacious cardiac repair. Recent experimental studies and early-phase clinical trials lend credence to the visionary goal of enhancing cardiac repair as an achievable therapeutic target.

Ponce de Leon's Fountain: stem cells and the regenerating heart

Despite current pharmacologic and whole organ transplantation strategies, advanced heart failure remains a common and deadly disease. Limited availability of donor organs for use in orthotopic heart transplantation has prompted the examination of alternative therapies, including cell transfer strategies. Stem cell populations have been identified in virtually all postnatal tissues with the exception of the heart, and these stem cells function in the maintenance and regeneration of the respective tissues. Recent studies challenge preexisting notions regarding cardiac repair and suggest that the heart is capable of limited regeneration through the activation of resident cardiac stem cells or the recruitment of stem cell populations from other tissues such as the bone marrow. This review highlights animal models that have the capacity for myocardial regeneration and examines potential sources of stem cell populations that may participate in tissue regeneration. While some authors view these cell-based strategies as a Fountain of Youth for the myopathic heart, future studies will decipher the regulatory mechanisms of stem cell populations and serve as a prelude to stem cell-based strategies.

Therapeutic angiogenesis and vasculogenesis for tissue regeneration

Therapeutic angiogenesis/vasculogenesis holds promise for the cure of ischaemic disease. The approach postulates the manipulation of spontaneous healing response by supplementation of growth factors or transplantation of vascular progenitor cells. These supplements are intended to foster the formation of arterial collaterals and promote the regeneration of damaged tissues. Angiogenic factors are generally delivered in the form of recombinant proteins or by gene transfer using viral vectors. In addition, new non-viral methods are gaining importance for their safer profile. The association of growth factors with different biological activity might offer distinct advantages in terms of efficacy, yet combined approaches require further optimization. Alternatively, substances with pleiotropic activity might be considered, by virtue of their ability to target multiple mechanisms. For instance, some angiogenic factors not only stimulate the growth of arterioles and capillaries, but also inhibit vascular destabilization triggered by metabolic and oxidative stress. Transplantation of endothelial progenitor cells was recently proposed for the treatment of peripheral and myocardial ischaemia. Progenitor cells can be transplanted either without any preliminary conditioning or after ex vivo genetic manipulation. Delivery of genetically modified progenitor cells eliminates the drawback of immune response against viral vectors and makes feasible repeating the therapeutic procedure in case of injury recurrence. It is envisioned that these new approaches of regenerative medicine will open unprecedented opportunities for the care of life-threatening diseases.

Monitoring of Bone Marrow Cell Homing Into the Infarcted Human Myocardium

Background— Intracoronary transfer of autologous bone marrow cells (BMCs) promotes recovery of left ventricular systolic function in patients with acute myocardial infarction. Although the mechanisms of this effect remain to be established, homing of BMCs into the infarcted myocardium is probably a critical early event.

Methods and Results— We determined BMC biodistribution after therapeutic application in patients with a first ST-segment–elevation myocardial infarction who had undergone stenting of the infarct-related artery. Unselected BMCs were radiolabeled with 100 MBq 2-[ 18 F]-fluoro-2-deoxy- d -glucose ( 18 F-FDG) and infused into the infarct-related coronary artery (intracoronary; n=3 patients) or injected via an antecubital vein (intravenous; n=3 patients). In 3 additional patients, CD34-positive (CD34 + ) cells were immunomagnetically enriched from unselected BMCs, labeled with 18 F-FDG, and infused intracoronarily. Cell transfer was performed 5 to 10 days after stenting. More than 99% of the infused total radioactivity was cell bound. Nucleated cell viability, comparable in all preparations, ranged from 92% to 96%. Fifty to 75 minutes after cell transfer, all patients underwent 3D PET imaging. After intracoronary transfer, 1.3% to 2.6% of 18 F-FDG–labeled unselected BMCs were detected in the infarcted myocardium; the remaining activity was found primarily in liver and spleen. After intravenous transfer, only background activity was detected in the infarcted myocardium. After intracoronary transfer of 18 F-FDG–labeled CD34-enriched cells, 14% to 39% of the total activity was detected in the infarcted myocardium. Unselected BMCs engrafted in the infarct center and border zone; homing of CD34-enriched cells was more pronounced in the border zone.

Conclusions— 18 F-FDG labeling and 3D PET imaging can be used to monitor myocardial homing and biodistribution of BMCs after therapeutic application in patients.

Risk factors for coronary artery disease, circulating endothelial progenitor cells, and the role of HMG-CoA reductase inhibitors

Recent studies suggest that postnatal neovascularization relies not exclusively on sprouting of preexisting vessels ("angiogenesis"), but also involves the contribution of bone marrow-derived circulating endothelial progenitor cells (EPCs). EPCs can be isolated from peripheral blood or bone marrow mononuclear cells, CD34(+) or CD133(+) hematopoietic progenitors. Infusion of EPCs was shown to promote postnatal neovascularization of ischemic tissue after myocardial infarction in animal models and initial clinical trials. Moreover, circulating endothelial precursor cells can home to denuded arteries after balloon injury and contribute to endothelial regeneration, thereby limiting the development of restenosis. Thus, circulating endothelial cells may exert an important function as endogenous repair mechanism to maintain the integrity of the endothelial monolayer and to promote ischemia-induced neovascularization. However, risk factors for coronary artery disease, such as diabetes, hypercholesterolemia, and hypertension are associated with impaired number and function of EPC in patients with coronary artery disease. Therapeutically, the reduction of EPC number and the decreased functional activity in patients with coronary artery disease was counteracted by 3-hydroxy-3-methylglutaryl coenzymeA (HMG-CoA) reductase inhibitors (statins), vascular endothelial growth factor (VEGF), estrogen, or exercise. At the molecular level, these factors are well established to activate the phosphatidyl-inositol-3-kinase (PI3K)-Akt-dependent activation of the endothelial nitric oxide synthase (eNOS), suggesting that the PI3K-Akt-eNOS signaling pathway may be involved in the transduction of atheroprotective factors. Taken together, the balance of atheroprotective and proatherosclerotic factors may influence EPC levels and their functional capacity to improve neovascularization and endothelial regeneration.

Use of granulocyte-colony stimulating factor during acute myocardial infarction to enhance bone marrow stem cell mobilization in humans: clinical and angiographic safety profile

AIMS

There is increasing evidence that stem cell (SC) mobilization to the heart and their differentiation into cardiac cells is a naturally occurring process. We sought to assess the safety and feasibility of granulocyte-colony stimulating factor (G-CSF) administration in humans to enhance SC mobilization and left ventricle (LV) injury repair during myocardial infarction (MI).

METHODS AND RESULTS

Twenty patients with STEMI (mean age, 61+/-10 years), of whom 14 were submitted to primary percutaneous coronary intervention, were randomized to G-CSF (5 microg/kg/day s.c. for 4 consecutive days) or placebo. At entry and then at months 3 and 6, (99m)Tc-sestamibi gated-SPECT was performed to estimate extension of perfusion defect (PD) and LV function. The study drug was well tolerated and induced a significant increase of white blood count, CD34(+) cells, and CD34(+) cells coexpressing AC133 and VEGFR-2. At follow-up, treated and placebo groups did not differ for the angiographic coronary late loss and showed a similar pattern of PD recovery, whereas in the former at 6 months LVEF and especially LVEDV tended to be relatively higher (P=0.068) and lower (P=0.054), respectively.

CONCLUSION

G-CSF administration in acute MI patients was feasible and did not lead to any clinical or angiographic adverse events and resulted in CD34(+) and CD34(+)AC133(+)VEGFR2(+) cell mobilization.

Therapeutical potential of blood-derived progenitor cells in patients with peripheral arterial occlusive disease and critical limb ischaemia

AIMS

Despite considerable advances in the therapy of patients with peripheral arterial occlusive disease (PAOD) and critical limb ischaemia (CLI), a substantial number remain, in whom amputation has to be considered the only and final option. Recent evidence from animal models of hind limb ischaemia suggests that neovascularization induced by circulating blood-derived progenitor cells (CPCs) may permit limb salvage. It remains unclear, however, whether an intra-arterial application of autologous CPCs in patients with infrapopliteal PAOD and CLI is safe, feasible, and of potentially beneficial effects.

METHODS AND RESULTS

Seven patients with critical PAOD were treated with an intra-arterial infusion of autologous CPCs (39+/-24 x 10(6)) isolated from peripheral blood. Pre-interventional stimulation with G-CSF and CPC application was well tolerated. Twelve weeks after CPC administration, the pain-free walking distance increased from 6+/-13 to 195+/-196 m. A significant increase in the ankle-brachial index, transcutaneous O(2), flow-dependent vasodilation, flow reserve in response to adenosine, and endothelium-dependent vasodilation was observed.

CONCLUSION

These preliminary data in a small series of patients with CLI without surgical or interventional options indicate that CPC application is safe, feasible, and may improve both functional and clinical indices.

[Cell transplantation in heart failure management]

Heart failure is becoming a major issue for public health in western countries and the effect of currently available therapies is limited. Therefore cell transplantation was developed as an alternative strategy to improve cardiac structure and function. This review describes the multiple cell types and clinical trials considered for use in this indication. Most studies have been developed in models of post-ischemic heart failure. The transplantation of fetal or neonatal cardiomyocytes has proven to be functionally successful, but ethical as well as immunological and technical reasons make their clinical use limited. Recent reports, however, suggested that adult autologous cardiomyocytes could be prepared from stem cells present in various tissues (bone marrow, vessels, adult heart itself, adipose tissue). Alternatively, endothelial progenitors originating from bone marrow or peripheral blood could promote the neoangiogenesis within the scar tissue. Hematopietic stem cells prepared from bone marrow or peripheral blood have been proposed but their differentiation ability seems limited. Finally, the transplantation of skeletal muscle cells (myoblasts) in the infarcted area improved myocardial function, in correlation with the development of skeletal muscle tissue in various animal models. The latter results paved the way for the development of a first phase I clinical trial of myoblast transplantation in patients with severe post-ischemic heart failure. It required the scale-up of human cell production according to good manufacturing procedures, started in june 2000 in Paris and was terminated in november 2001, and was followed by several others. The results were encouraging and prompted the onset of a blinded, multicentric phase II clinical trial for skeletal muscle cells transplantation. Meanwhile, phase I clinical trials also evaluate the safeness and efficacy of various cell types originating from the bone marrow or the peripheral blood. However, potential side effects related to the biological properties of the cells or the delivery procedures are being reported. High quality clinical trials supported by strong pre-clinical data will help to evaluate the role of cell therapy as a potential treatment for heart failure.

Granulocyte colony stimulating factor/macrophage colony stimulating factor improves postinfarct ventricular function by suppression of border zone remodelling in rats

1. The aim of the present study was to examine the effects of mobilization of bone marrow cells by granulocyte colony stimulating factor (G-CSF) and macrophage colony stimulating factor (M-CSF) on ventricular function after myocardial infarction (MI). 2. After ligation of the left coronary artery, rats were divided into a vehicle control group (MI group) and a CSF-treated group (MI-CSF group). Rats in the MI-CSF group received a combination of G-CSF (50 microg/kg per day) and M-CSF (10(6) IU/kg per day) for 5 days after MI. Two weeks after MI, hearts were isolated and perfused with a Krebs' buffer and their functional responses to step-wise elevation of left ventricular end-diastolic pressure (LVEDP) were assessed. In histological analysis, proliferating cells and bone marrow-derived cells were identified by antibodies against Ki-67 and c-kit and organization of collagen was examined by picrosirius red staining. The mRNA levels of transforming growth factor (TGF)-beta(1), collagen type I and collagen type III were measured by quantitative reverse transcription-polymerase chain reaction. 3. Numbers of Ki-67- and c-kit-positive cells in the infarct border zone after MI were increased by CSF treatment, but few of those cells were stained by anti-alpha-sarcomeric actin. The levels in mRNA of TGF-beta1 and collagen type I in the infarct border zone were higher in the CSF-treated group compared with the MI group. Although CSF treatment did not reduce ventricular hypertrophy or infarct size at 2 weeks after MI, it did significantly improved the response of left ventricular developed pressure to step-wise elevation of LVEDP. This effect was mimicked by treatment with M-CSF alone. The functional improvement by CSF treatment was correlated with suppression of enlargement of the infarct-non-infarct border associated with infarct expansion. Collagen fibres in the border zone were thicker and orientated more orderly in the CSF-treated group than in the untreated group. 4. The results suggest that G-CSF/M-CSF treatment improves contractile function of the ventricle after infarction, presumably by acceleration of infarct repair and suppression of remodelling in the border zone.

Mesenchymal stem cells: biological characteristics and potential clinical applications

Mesenchymal stem cells (MSC) are clonogenic, non-hematpoietic stem cells present in the bone marrow and are able to differentiate into multiple mesoderm-type cell lineages, for example, osteoblasts, chondrocytes, endothelial-cells and also non-mesoderm-type lineages, for example, neuronal-like cells. Several methods are currently available for isolation of the MSC based on their physical and physico-chemical characteristics, for example, adherence to plastics or other extracellular matrix components. Because of the ease of their isolation and their extensive differentiation potential, MSC are among the first stem cell types to be introduced in the clinic. Several studies have demonstrated the possible use of MSC in systemic transplantation for systemic diseases, local implantation for local tissue defects, as a vehicle for genes in gene therapy protocols or to generate transplantable tissues and organs in tissue engineering protocols. Before their widespread use in therapy, methods allowing the generation of large number of cells without affecting their differentiation potential as well as technologies that overcome immunological rejection (in case allogenic transplantation) must be developed.

The role of stem cells in cardiac regeneration

After myocardial infarction, injured cardiomyocytes are replaced by fibrotic tissue promoting the development of heart failure. Cell transplantation has emerged as a potential therapy and stem cells may be an important and powerful cellular source. Embryonic stem cells can differentiate into true cardiomyocytes, making them in principle an unlimited source of transplantable cells for cardiac repair, although immunological and ethical constraints exist. Somatic stem cells are an attractive option to explore for transplantation as they are autologous, but their differentiation potential is more restricted than embryonic stem cells. Currently, the major sources of somatic cells used for basic research and in clinical trials originate from the bone marrow. The differentiation capacity of different populations of bone marrow-derived stem cells into cardiomyocytes has been studied intensively. The results are rather confusing and difficult to compare, since different isolation and identification methods have been used to determine the cell population studied. To date, only mesenchymal stem cells seem to form cardiomyocytes, and only a small percentage of this population will do so in vitro or in vivo. A newly identified cell population isolated from cardiac tissue, called cardiac progenitor cells, holds great potential for cardiac regeneration. Here we discuss the potential of the different cell populations and their usefulness in stem cell based therapy to repair the damaged heart.

Phenotypic characterization and preclinical production of human lineage-negative cells for regenerative stem cell therapy

BACKGROUND

Regenerative stem cell therapy (SCT) is currently being tested in clinical trials. The ideal type and source of cells have not yet been defined. Lineage (Lin) depletion is an experimental procedure capable of enriching all recently recognized SC types with regenerative potency. This study was performed to define a practicable monoclonal antibody (MoAb) cocktail for Lin depletion and to test whether clinical-scale Lin depletion is possible.

STUDY DESIGN AND METHODS

MoAbs (CD2/14/15/19/41/56/glycophorin A) were selected to mark seven mature hematopoietic lineages. Lin7-negative (Lin7NEG) cells were analyzed in peripheral blood (PB, n = 9), mobilized PB (MPB, n = 5), umbilical cord blood (UCB, n = 5), and marrow aspirates (BM, n = 4) by flow cytometry. Preclinical Lin depletion was tested with leukapheresis products from PB following good manufacturing practice (GMP) principles.

RESULTS

Lin7NEG cells comprised 0.23 +/- 0.04, 0.27 +/- 0.03, 0.53 +/- 0.07, and 0.49 +/- 0.03 percent of PB, MPB, UCB, and BM, respectively. Basophils, CD34+, and dendritic cells constituted the major Lin7NEG subpopulations (84 +/- 2, 90 +/- 3, 40 +/- 3, and 80 +/- 3% in PB, MPB, UCB, and BM, respectively). Minor populations included CD7- and CD45- cells. Preclinical CD2/14/15/19/56 (Lin5) depletion after automated red blood cell and platelet reduction resulted in up to a 16.7-fold enrichment of CD34+ and CD34-/Lin5NEG cells.

CONCLUSIONS

A seven-MoAb cocktail is sufficient to label more than 99 percent of nucleated cells in PB, MPB, UCB, and BM. Preclinical Lin depletion can be performed under GMP conditions from PB apheresis procedures.

FOXO-dependent expression of the proapoptotic protein Bim: pivotal role for apoptosis signaling in endothelial progenitor cells

Endothelial progenitor cells (EPCs) contribute to postnatal neovascularization. Risk factors for coronary artery disease reduce the number of EPCs in humans. Since EPC apoptosis might be a potential mechanism to regulate the number of EPCs, we investigated the effects of oxidative stress and HMG-CoA-reductase inhibitors (statins) on EPC apoptosis. Atorvastatin, mevastatin, or VEGF prevented EPC apoptosis induced by H2O2. The antiapoptotic effect was reversed by inhibition of the PI3K/Akt pathway. Forkhead transcription factors (FOXO1, FOXO3a, FOXO4) exert proapoptotic effects and are phosphorylated and, thereby, inactivated by Akt. Therefore, we elucidated the involvement of forkhead transcription factors. Atorvastatin induced the phosphorylation of the predominant forkhead factor FOXO4 in EPCs. In addition, atorvastatin reduced the expression of the proapoptotic forkhead-regulated protein Bim in a PI3K-dependent manner. Consistently, overexpression of FOXO4 activated the Bim promoter as determined by reporter gene expression and stimulated the expression of Bim, resulting in an increased EPC apoptosis. Statins failed to prevent EPC apoptosis induced by overexpression of Bim or nonphosphorylatable FOXO4, suggesting that the protective effects of statins depend on this pathway. In summary, our results show that FOXO-dependent expression of Bim plays a pivotal role for EPC apoptosis. Statins reduce oxidative stress-induced EPC apoptosis, inactivate FOXO4, and down-regulate Bim.

Endothelial-like cells expanded from CD34+ blood cells improve left ventricular function after experimental myocardial infarction

Mobilization and recruitment of endothelial progenitor cells (EPC) contributes to vasculogenesis in vivo. So far, applications for cell therapy are limited by the number of available cells. Expansion of EPC or their progeny may, therefore, facilitate its therapeutic use in ischemic disease. The aim of this study was to expand CD34+ EPC-derived progeny from different sources, characterize them, and investigate their potential for use in therapeutic vasculogenesis. CD34+ cells from G-CSF-mobilized peripheral blood (PB) and cord blood (CB) were isolated using immunomagnetic beads and cultured in endothelial cell medium. Cells were expanded up to 16 (PB) and up to 46 (CB) population doublings, respectively. Immunophenotypic and mRNA expression analyses showed a high degree of similarity between the cultured cells and human umbilical vein endothelial cells (HUVEC). By day 14 after transplantation, transplanted human CD31-positive EPC-derived cells were detected. These cells expressed the proliferation marker Ki67 and formed vessel-like structures in ischemic myocardium. Most strikingly, transplantation of EPC-derived cells improved left ventricular function after experimental ischemia, as shown by echocardiography. In conclusion, cells cultured from CD34+ EPC can be expanded in vitro to clinically relevant numbers. In vivo, these cells proliferate, form vascular structures, and improve left ventricular function after experimental myocardial infarction. Therefore, in vitro expanded EPC-derived endothelial cells may be beneficial in the treatment of ischemic disease.

Potential of hematopoietic stem cell therapy in hepatology: a critical review

Adult stem cell plasticity raised expectations regarding novel cellular therapies of regenerative medicine after findings of unexpected plasticity were reported. In this review, reports of hematopoietic stem cells (HSCs) contributing to hepatocytic lineages are critically discussed with reference to rodent and human models. In particular, the role of liver injury and the potential contribution HSCs make to hepatic regeneration in both injury and physiological maintenance is reviewed. The relative contributions of genomic plasticity and cell fusion are studied across different model systems, highlighting possible factors that may explain differences between often conflicting reports. Insights from experimental studies will be described that shed light on the mechanisms underlying the migration, engraftment, and transdifferentiation of HSCs in liver injury. Although it appears that under differing circumstances, macrophage fusion, HSC fusion, and HSC transdifferentiation can all contribute to hepatic epithelial lineages, a much greater understanding of the factors that regulate the long-term efficacy of such cells is needed before this phenomenon can be used clinically.

Autologous intracoronary mononuclear bone marrow cell transplantation in chronic ischemic cardiomyopathy in humans

BACKGROUND

Recent data suggest that transplantation of autologous bone marrow cells (BMC) may contribute to myocardial repair after acute myocardial infarction. We hypothesized that patients with chronic ischemic cardiomyopathy could also benefit from autologous BMC transplantation in addition to established heart failure therapy.

METHODS AND RESULTS

Five patients with chronic ischemic cardiomyopathy caused by anterior myocardial infarction, 1.3+/-0.5 years ago and open infarct artery, received autologous mononuclear BMC transplantation via balloon catheter in the target vessel at the site of previous occlusion. Patients were followed up at 3 months (left heart catheterisation, 2D-echocardiography, dobutamine stress echocardiography, cardiopulmonary exercise testing) and at 12 months (2D-echocardiography, cardiopulmonary exercise testing). Follow-up examination showed no significant improvement neither in global, regional, and microvascular function, nor in physical performance.

CONCLUSIONS

In this pilot trial intracoronary transplantation of autologous, mononuclear BMC did not lead to any significant improvement in myocardial function and physical performance of patients with chronic ischemic heart disease.

Stem cells as future therapy in cardiology

This article focuses on the key studies relevant to the clinical application of stem-cell research in cardiovascular disease. The authors also discuss current and future directions in clinical cardiovascular stem-cell research, including the potential problems and pitfalls that must be addressed to ensure the safety, as well as the efficacy, of treatment regimens in this rapidly evolving therapeutic field.

Stem cell therapy for cardiac diseases

PURPOSE OF REVIEW

This review examines the knowledge that researchers have gained during the past year regarding some fundamental questions about stem cell therapy. These questions concern patient selection and safety, the optimal type of stem cells, the best route for their delivery, the fate of the transplanted cells, and the mechanism by which this therapy works.

RECENT FINDINGS

So far, candidates for cardiac stem cell therapy have been limited to patients with acute myocardial infarction and chronic ischemic heart failure. Currently, bone marrow stem cells seem to be the most attractive cell type for these patients. The cells may be delivered by means of direct surgical injection, intracoronary infusion, retrograde venous infusion, and transendocardial injection. Stem cells may directly increase cardiac contractility or passively limit infarct expansion and remodeling. This therapy is generally well tolerated, but the potential for accelerated atherogenesis remains a concern. Eventually, cell therapy may be combined with gene therapy to treat ischemic myocardium.

SUMMARY

Stem cell therapy for cardiac disease is a rapidly evolving field. Most of the evidence accumulated so far, including preclinical and clinical findings, confirms the potential of this novel therapy. However, most of the fundamental knowledge needed to guide the application of stem cell therapy in cardiac disease is still lacking.

Stimulation of endothelial progenitor cells: a new putative therapeutic effect of angiotensin II receptor antagonists

The number of circulating endothelial progenitor cells (EPCs) correlates with endothelial dysfunction and cardiovascular risk in humans. We explored whether angiotensin II receptor antagonist therapy affects the number of regenerative EPCs in patients with type 2 diabetes. In a prospective double-blind parallel group study, we randomly treated 18 type 2 diabetics with olmesartan (40 mg) or placebo for 12 weeks. We analyzed circulating CD34+ hematopoietic progenitor cells (flow cytometry) and EPCs (in vitro assay) before and after therapy. We verified the results in a second open trial treating 20 type 2 diabetics with 300 mg of irbesartan for 12 weeks. The number of EPCs was significantly lower in diabetic patients as compared with 38 age-matched healthy subjects (210+/-10 versus 258+/-18 per high-power field; P<0.05), whereas there was no significant difference with respect to hematopoietic progenitor cells. Treatment with olmesartan (n=9) significantly increased EPCs from 231+/-24 to 465+/-71 per high-power field (P<0.05), but not hematopoietic progenitor cells. In contrast, placebo treatment (n=9) did not affect EPCs and hematopoietic progenitor cells. With irbesartan therapy, EPC number increased significantly from 196+/-15 to 300+/-23 per high-power field (P<0.05) already after 4 weeks of treatment. At the end of 12-week therapy, patients had 310+/-23 EPCs per high-power field (P<0.05 versus baseline). Angiotensin II receptor antagonists increase the number of regenerative EPCs in patients with type 2 diabetes mellitus. This action may be of therapeutic relevance contributing to their beneficial cardiovascular effects.

Bone-marrow-derived cells for enhancing collateral development: mechanisms, animal data, and initial clinical experiences

Initial animal studies of single angiogenic agents, such as vascular endothelial growth factor (VEGF) and basic fibroblast growth factor (bFGF), generated enthusiasm for the concept that these agents might enhance collateral development and thereby provide alternative therapies for patients with vascular disease not amenable to traditional revascularization. The enthusiasm, apparently justified by the subsequent results of small nonrandomized phase-I clinical trials, was then tempered by the subsequent disappointing results of randomized clinical trials. In light of these disappointing results, investigators have pursued alternative strategies in an attempt to improve tissue perfusion. One such strategy is the utilization of bone marrow-derived cell therapy. This review discusses mechanistic pathways mediating the effects of such cell therapy, summarizes the animal and early clinical experience, and speculates on the potential of genetic manipulation of bone marrow-derived cells in an attempt to further enhance their potency.

Endothelial progenitor cells: characterization and role in vascular biology

Infusion of different hematopoietic stem cell populations and ex vivo expanded endothelial progenitor cells augments neovascularization of tissue after ischemia and contributes to reendothelialization after endothelial injury, thereby, providing a novel therapeutic option. However, controversy exists with respect to the identification and the origin of endothelial progenitor cells. Overall, there is consensus that endothelial progenitor cells can derive from the bone marrow and that CD133/VEGFR2 cells represent a population with endothelial progenitor capacity. However, increasing evidence suggests that there are additional bone marrow-derived cell populations (eg, myeloid cells, "side population" cells, and mesenchymal cells) and non-bone marrow-derived cells, which also can give rise to endothelial cells. The characterization of the different progenitor cell populations and their functional properties are discussed. Mobilization and endothelial progenitor cell-mediated neovascularization is critically regulated. Stimulatory (eg, statins and exercise) or inhibitory factors (risk factors for coronary artery disease) modulate progenitor cell levels and, thereby, affect the vascular repair capacity. Moreover, recruitment and incorporation of endothelial progenitor cells requires a coordinated sequence of multistep adhesive and signaling events including adhesion and migration (eg, by integrins), chemoattraction (eg, by SDF-1/CXCR4), and finally the differentiation to endothelial cells. This review summarizes the mechanisms regulating endothelial progenitor cell-mediated neovascularization and reendothelialization.

Plasticity of bone marrow-derived stem cells

Stem cell plasticity refers to the ability of adult stem cells to acquire mature phenotypes that are different from their tissue of origin. Adult bone marrow cells (BMCs) include two populations of bone marrow stem cells (BMCs): hematopoietic stem cells (HSCs), which give rise to all mature lineages of blood, and mesenchymal stem cells (MSCs), which can differentiate into bone, cartilage, and fat. In this article, we review the literature that lends credibility to the theory that highly plastic BMCs have a role in maintenance and repair of nonhematopoietic tissue. We discuss the possible mechanisms by which this may occur. Also reviewed is the possibility that adult BMCs can change their gene expression profile after fusion with a mature cell, which has brought into question whether this stem cell plasticity is real.

Cell transplantation and genetic engineering: new approaches to cardiac pathology

The remarkable progress in experimental cell transplantation, stem cell biology and genetic engineering promise new therapy and hopefully a cure for patients with end stage heart failure. Engineering of viable cardiac grafts with the potential to grow and remodel will provide new solutions to the serious problems of heart donor shortage. The ability to replace the injured heart muscle will have a dramatic influence on medicine, especially with the increasing number of patients with heart failure. This innovative research, now tested in human patients, still faces significant problems that need to be solved before it can be considered as an established therapeutic tool. The present review will focus on selected topics related to the promise and obstacles associated with cell transplantation, with and without genetic manipulation, for myocardial repair.

Protein-, gene-, and cell-based therapeutic angiogenesis for the treatment of myocardial ischemia

Therapeutic angiogenesis aims at restoring perfusion to chronically ischemic myocardial territories by using growth factors or cells, without intervening on the epicardial coronary arteries. Despite angiogenesis having received considerable scientific attention over the last decade, it has not yet been shown to provide clinical benefit and is still reserved for patients who have failed conventional therapies. Nevertheless, angiogenesis is a very potent physiologic process involved in the growth and development of every animal and human, and it is likely that its use for therapeutic purposes, once its underlying mechanistic basis is better understood, will one day become an important modality for patients with CAD and other types of organ ischemia. This review summarizes current knowledge in therapeutic angiogenesis research.

Heart cell implantation after myocardial infarction

In the last 15 years, heart cell implantation to regenerate infarcted myocardium has gone from the bench to clinical trial. Several phase I and II controlled randomized trials showed the feasibility, the side effects and the potential efficacy of cell implantation after myocardial infarction in humans. Preclinical experiments investigating the mechanisms of heart function improvement after cell implantation showed controversial results regarding implanted cell differentiation into cardiomyocytes and highlighted other effects including neovascularization and modifications of the extra cellular matrix remodelling. Ongoing clinical and experimental studies should pave the way for cell implantation to become a therapeutic option to prevent and treat post-myocardial infarction congestive heart failure in a near future.

Bone marrow stem cells in the infarcted heart

Conventionally, the heart is perceived as a terminally differentiated organ, which is incapable of regeneration. Adult stem cell transplantation is aimed at replenishing the myocyte number to compensate for the cardiomyocyte loss during the process of cardiomyocyte necrosis following infarction. More recently, the focus has been shifted on the use of autologous skeletal myoblasts and bone marrow derived stem cells. Here, we have reviewed some interesting aspects of the fast emerging field of bone marrow derived stem cell therapy for cardiac repair.

Mesenchymal Stem Cells: Future Source for Reparative Medicine

Current treatments for ischemic cardiomyopathy are aimed toward minimizing the deleterious consequences of damaged myocardium. The possibility of treating heart failure by generating new myocardium and vascular structures has provided major impetus for recent stem cell research. Mesenchymal stem cells (MSCs), also referred to as marrow stromal cells, differentiate into a wide variety of lineages, including myocardial smooth muscle and possibly endothelial cells. The multilineage potential of MSCs, their ability to elude detection by the host's immune system, and their relative ease of expansion in culture make MSCs a very promising source of stem cells for transplantation. This paper reviews animal and human trials studying the role of MSCs in cardiomyogenesis and vasculogenesis in postinfarct myocardium, factors that stimulate MSC differentiation, routes of MSC delivery, and methods of detecting MSC engraftment.

Mobilization of bone marrow-derived stem cells after myocardial infarction and left ventricular function

AIMS

Recent data suggest that the administration of bone marrow-derived stem cells (BMSC) might improve myocardial perfusion and left ventricular (LV) function after acute myocardial infarction (AMI). The aim of this study was to assess spontaneous mobilization of BMSC expressing the haematopoietic and endothelial progenitor cell-associated antigen CD34+ after AMI and its relation to post-infarction remodelling.

METHODS AND RESULTS

Peripheral blood concentration of CD34+ BMSC was measured by flow cytometry in 54 patients with AMI, 26 patients with chronic stable angina (CSA), and 43 normal healthy subjects. In patients with AMI, LV function was measured by 2D-echocardiography. Eighteen AMI patients were reassessed at 1 year. BMSC concentration was higher in patients with AMI (mean peak value: 7.04+/-6.27 cells/microL), than in patients with CSA (3.80+/-2.12 cells/microL, P=0.036) and in healthy controls (1.87+/-1.52 cells/microL, P<0.001). At multivariable analysis statin use (P<0.001), primary percutaneous intervention (P=0.048) and anterior AMI (P=0.05) were the only independent predictors of increased BMSC mobilization after AMI. In the 28 patients without subsequent acute coronary events reassessed at 1 year follow-up, CD34+ cell concentration was an independent predictor of global and regional improvement of LV function (r=0.52, P=0.004 and r=-0.41, P=0.03, respectively).

CONCLUSION

AMI is followed by enhanced spontaneous mobilization of BMSC, in particular, in patients on statin therapy and following a primary percutaneous intervention. More importantly persistent spontaneous mobilization of BMSC might contribute to determine a more favourable post-AMI remodelling.