Can erythropoietin improve skeletal myoblast engraftment in infarcted myocardium?

The benefits of skeletal myoblast transplantation are limited by the high rate of early cell death which is partly of ischemic origin. We, therefore, assessed whether graft survival could be improved by the additional use of the angiogenic cytokine erythropoietin (EPO). Thirty-five Lewis rats underwent coronary artery ligation and, two weeks later, were randomized to receive in-scar injections of control medium, skeletal myoblasts (5x10(6)) or skeletal myoblasts with EPO started the day before transplantation and continued for two weeks (500 U/kg three times a week). A fourth group was treated by EPO alone without injections. Function was assessed by 2D echocardiography before transplantation and one month thereafter. Compared with controls and hearts treated by EPO-alone, those transplanted with myoblasts yielded a significantly better recovery of LV ejection fraction, irrespective of whether they had received EPO or not. Neither the area of myoblast engraftment, nor angiogenesis differed between the myoblast-alone and the myoblast+EPO groups. Apoptosis was hardly detectable and, therefore, unaffected by EPO therapy. In this model, EPO failed to improve myoblast engraftment and postinfarction LV function. These negative findings justify to pursue the search for alternate cell survival-enhancing strategies.     

Combined autologous cellular cardiomyoplasty with skeletal myoblasts and bone marrow cells in canine hearts for ischemic cardiomyopathy

OBJECTIVES: Cellular cardiomyoplasty with isolated skeletal myoblasts and bone marrow mononuclear cells is an encouraging therapeutic strategy for heart failure. We investigated the achievements accomplished with combined cell therapy of skeletal myoblast and bone marrow mononuclear cell transplantation to the ischemic canine myocardium. METHODS: Autologous skeletal myoblasts (1 x 10(8)) and autologous bone marrow mononuclear cells (3 x 10(6)) were injected directly into the damaged myocardium of canine hearts that had undergone 2 weeks of left anterior descending coronary artery ligation. Treatment groups were as follows: skeletal myoblasts plus bone marrow mononuclear cells (combined cell therapy, n = 4), myoblasts (n = 4), bone marrow mononuclear cells (n = 4), and medium only (n = 4). In similarly designed supporting experiments, angiogenic factor expression was evaluated by enzyme-linked immunosorbent assay after cell transplantation in rat hearts that had undergone left anterior descending coronary artery ligation. RESULTS: Four weeks after cell implantation, echocardiography demonstrated better cardiac performance with reduced left ventricular dilation and significantly improved ejection fraction in the combined cell therapy group compared with that seen in the other groups (pretreatment, 37.7% +/- 1.1%, vs combined cell therapy, 55.4% +/- 8.6%; myoblasts, 47.4% +/- 7.4%; bone marrow mononuclear cells, 44.4% +/- 6.7%; medium only [control], 34.4% +/- 5.4%; P < .05). A significantly high number of neovessels were observed in the group receiving combined cell therapy only (combined cell therapy, 45.5 +/- 12 x 10(2)/mm2; myoblasts, 26.5 +/- 8 x 10(2)/mm2; bone marrow mononuclear cells, 30.7 +/- 15 x 10(2)/mm2; medium only [control], 7.1 +/- 1 x 10(2)/mm2; P < .05). Immunostained sections expressed the skeletal specific marker myosin heavy chain, although they did not express the cardiac specific marker troponin T. Results of enzyme-linked immunosorbent assay showed the highest expression of vascular endothelial growth factor (combined cell therapy, 2.9 +/- 0.7 ng/g tissue; myoblasts, 0.24 +/- 0.7 ng/g tissue; bone marrow mononuclear cells, 1.9 +/- 0.2 ng/g tissue; medium only [control], 0.19 +/- 0.004 ng/g tissue; P < .05) and hepatocyte growth factor in the combined cell therapy hearts. CONCLUSIONS: Combined autologous cellular therapy induced both myogenesis and angiogenesis with enhancement of cardiac performance and reduction of cardiac remodeling, suggesting a capable strategy for treating severe ischemic cardiomyopathy clinically.     

Effectiveness of transient immunosuppression using cyclosporine for xenomyoblast transplantation for cardiac repair

We studied the survival of human myoblast for cellular myocardial reconstruction in a porcine model of chronic myocardial ischemia with immune tolerance using transient immunosuppression. A porcine model of chronic cardiac ischemia was created in 10 pigs (DMEM medium-injected n = 4; myoblast transplanted n = 6) by clamping ameroid ring around left circumflex coronary artery. Three weeks later, 3 x 10(8) human myoblasts carrying lac-z reporter gene were transplanted in multiple sites (0.25 mL each) into the left ventricular wall. Immunosuppression was achieved with 5 mg/kg cyclosporine for 6 weeks after cell transplantation. After animals were euthanized between 6 and 30 weeks after cell transplantation; the heart was removed for histological studies. Discontinuation of immunosuppression after 6 weeks of cell transplantation did not result in donor cell rejection. The lac-z-positive donor cells were detected in porcine host cardiac tissue for up to 30 weeks posttransplantation, expressing human skeletal myosin heavy chain. The results highlight the effectiveness of transient immunosuppression for myoblast transplantation for cardiac repair.     

Factors affecting functional outcome after autologous skeletal myoblast transplantation

BACKGROUND: This study assessed the extent to which the initial degree of functional impairment and the number of injected cells may influence the functional improvement provided by autologous skeletal myoblast transplantation into infarcted myocardium. METHODS: One week after left coronary artery ligation, 44 rats received into the infarcted scar, autologous skeletal myoblasts expanded in vitro for 7 days (mean, 3.5 x 10(6), n = 21), or culture medium alone (controls, n = 23). Left ventricular function was assessed by two-dimensional echocardiography. RESULTS: When transplanted hearts were stratified according to their baseline ejection fraction, a significant improvement occurred at 2 months in the less than 25% (from 21.4% to 37%), 25% to 35% (from 29% to 43.8%), and in the 35% to 40% (from 37.2% to 41.7%) groups, compared to controls (p = 0.048, 0.0057, and 0.034, respectively), but not in the more than 40% stratum. A significant linear relationship was found between the improvement in ejection fraction and the number of injected myoblasts, both at 1 and 2 months after transplantation (p < 0.0001). CONCLUSIONS: Autologous myoblast transplantation is functionally effective over a wide range of postinfarct ejection fractions, including in the sickest hearts provided that they are injected with a sufficiently high number of cells.     

Comparison of the effects of fetal cardiomyocyte and skeletal myoblast transplantation on postinfarction left ventricular function

OBJECTIVES: Transplantation of fetal cardiomyocytes improves function of infarcted myocardium but raises availability, immunologic, and ethical issues that justify the investigation of alternate cell types, among which skeletal myoblasts are attractive candidates. METHODS: Myocardial infarction was created in rats by means of coronary artery ligation. One week later, the animals were reoperated on and intramyocardially injected with culture growth medium alone (controls, n = 15), fetal cardiomyocytes (5 x 10(6) cells, n = 11), or neonatal skeletal myoblasts (5 x 10(6) cells, n = 16). The injections consisted of a 150-microL volume and were made in the core of the infarct, and the animals were immunosuppressed. Left ventricular function was assessed by echocardiography immediately before transplantation and 1 month thereafter. Myoblast-transplanted hearts were then immunohistologically processed for the expression of skeletal muscle-specific embryonic myosin heavy chain and cardiac-specific connexin 43. RESULTS: The left ventricular ejection fraction markedly increased in the fetal and myoblast groups from 39.3% +/- 3.9% to 45% +/- 3.4% (P =.086) and from 40.4% +/- 3.6% to 47.3% +/- 4.4% (P =.034), respectively, whereas it decreased in untreated animals from 40.6% +/- 4% to 36.7% +/- 2.7%. Transplanted myoblasts could be identified in all animals by the positive staining for skeletal muscle myosin. Conversely, clusters of connexin 43 were not observed on these skeletal muscle cells. CONCLUSIONS: These results support the hypothesis that skeletal myoblasts are as effective as fetal cardiomyocytes for improving postinfarction left ventricular function. The clinical relevance of these findings is based on the possibility for skeletal myoblasts to be harvested from the patient himself.     

Intramyocardial microdepot injection increases the efficacy of skeletal myoblast transplantation

Objective: Recent progress in the field of cellular cardiomyoplasty has opened new prospects for the treatment of ischemic heart disease and currently moves from bench to bedside. The aim of the present study was to develop a novel cell delivery technique, reducing target tissue damage and improving cell dispersion and engraftment. Methods: In 30 male Fischer F344 rats an infarction of the left ventricle was generated by ligation of the left anterior descendent artery. Seven days after infarction, either 15 microdepots of 10 μl myoblast cell suspension (microdepot group) or culture medium (control group) were injected into the infarcted region using an automatic pressure injection device, or three depots of 50 μl myoblast cell suspension (macrodepot group) were injected using the standard surgical technique. Echocardiography was performed in all rats before and 6 weeks after cell injection. In all groups the perioperative mortality was below 20%. Six weeks after cell transplantation, a significant improvement of ejection fraction was seen in both myoblast treated groups compared to controls (macrodepot, microdepot, control; 53.7±11.9, 70.7±2.0, 39.1±6.4; P=0.026, P<0.001). The microdepot group showed a more decent improvement than the macrodepot group (70.7±2.0 vs. 53.7±11.9, P=0.013). In both treated groups, grafted myoblasts differentiated into multinucleated myotubes within host myocardium, however, the engraftment pattern was different and angiogenesis was enhanced in the microdepot group. Conclusions: Intramyocardial multisite pressure injection allows the safe and reliable transplantation of several myoblast microdepots into an infarcted myocardium and improves the efficacy of myoblast transplantation compared to the standard technique.     

Feasibility and safety of autologous myoblast transplantation in patients with ischemic cardiomyopathy

Successful autologous skeletal myoblast transplantation into infarcted myocardium in a variety of animal models has demonstrated improvement in cardiac function. We evaluated the safety and feasibility of transplanting autologous myoblasts into infarcted myocardium of patients undergoing concurrent coronary artery bypass grafting (CABG) or left ventricular assist device implantation (LVAD). In addition, we sought to gain preliminary information on graft survival and any potential improvement of cardiac function. Eighteen patients with a history of ischemic cardiomyopathy participated in a phase I, nonrandomized, multicenter pilot study of autologous skeletal myoblast transplantation concurrent with CABG or LVAD implantation. Twelve patients with a history of previous myocardial infarction (MI) and a left ventricular ejection of less than 30% were enrolled in the CABG arm. In a second arm, six patients underwent LVAD implantation as a bridge to heart transplantation and were required to donate their heart for testing at the time of heart transplant. Myoblasts were successfully transplanted in all patients without any acute injection-related complications or significant long-term unexpected adverse events. Follow-up PET scans showed new areas of viability within the infarct scar in CABG patients. Echocardiography measured an average improvement in left ventricular ejection fraction (LVEF) from 25% to 34%. Histological evaluation in four out of five patients who underwent heart transplantation documented survival and engraftment of the skeletal myoblasts within the infarcted myocardium. These interim results demonstrate survival, feasibility, and safety of autologous myoblast transplantation and suggest that this modality may offer a potential therapeutic treatment for end-stage heart disease.     

Construction of skeletal myoblast-based polyurethane scaffolds for myocardial repair

Intramyocardial transplantation of skeletal myoblasts augments postinfarction cardiac function. However, poor survival of injected cells limits this therapy. It is hypothesized that implantation of myoblast-based scaffolds would result in greater cell survival. Rat skeletal myoblasts were seeded on highly porous polyurethane (PU) scaffolds (7.5 x 7.5 x 2.0 mm). The effect of several scaffold pretreatments, initial cell densities, and culture periods was tested by DNA-based cell count and viability assessment. Seeded PU scaffolds were implanted on infarcted hearts and immunohistology was performed 4 weeks later. Precoating with laminin allowed the most favorable cell attachment. An initial inoculation with 5 x 10(6) cells followed by a 15-day culture period resulted in optimal myoblast proliferation. Four weeks after their implantation in rats, numerous myoblasts were found throughout the seeded patches although no sign of differentiation could be observed. This myoblast seeding technique on PU allows transfer of a large number of living myoblasts to a damaged myocardium.     

Polyurethane Scaffolds Seeded With Genetically Engineered Skeletal Myoblasts: A Promising Tool to Regenerate Myocardial Function

In animal models, intramyocardial injection of primary skeletal myoblasts is supposed to promote tissue regeneration and to improve cardiac function after myocardial infarction. The usage of genetically engineered myoblasts overexpressing the paracrine factors involved in tissue repair is believed to enhance these effects. However, cell therapy via injection is always accompanied by a high death rate of the injected cells. Here, we describe the construction of a growth factor‐producing myoblast‐seeded scaffold to overcome this limitation. Skeletal myoblasts were isolated and expanded from newborn Lewis rats. Cells were seeded on polyurethane (PU) scaffolds (Artelon) and transfected with DNA of VEGF‐A, HGF, SDF‐1, or Akt1 using the lipid‐based Metafectene Pro method. Overexpression was verified by ELISA, RT‐PCR (VEGF‐A, HGF, and SDF‐1) and Western blot analysis (Akt1). The seeded scaffolds were transplanted onto damaged myocardium of Lewis rats 2 weeks after myocardial infarction. Six weeks later, their therapeutic potential in vivo was analyzed by measurement of infarction size and capillary density. Primary rat skeletal myoblasts seeded on PU scaffolds were efficiently transfected, achieving transfection rates of 20%. In vitro, we noted a significant increase in expression of VEGF‐A, HGF, SDF‐1, and Akt1 after transfection. In vivo, transplantation of growth factor‐producing myoblast‐seeded scaffolds resulted in enhanced angiogenesis (VEGF‐A, HGF, and Akt1) or a reduced infarction zone (SDF‐1 and Akt1) in the ischemically damaged myocardium. In summary, we constructed a growth factor‐producing myoblast‐seeded scaffold which combines the beneficial potential of stem cell transplantation with the promising effects of gene‐therapeutic approaches. Because this matrix also allows us to circumvent previous cell application drawbacks, it may represent a promising tool for tissue regeneration and the re‐establishment of cardiac function after myocardial infarction.     

Transplantation of cryopreserved muscle cells in dilated cardiomyopathy: effects on left ventricular geometry and function

OBJECTIVE: Cell transplantation to prevent congestive heart failure in patients with inherited dilated cardiomyopathy might require the use of noncardiac donor cells unaffected by the genetic defect and cryopreservation to permit cell storage until the time of transplantation. However, the effects of cryopreservation on peripheral muscle cells harvested from a cardiomyopathic recipient and their subsequent ability to restore cardiac structure and function after transplantation are unknown. METHODS: Skeletal myoblasts and vascular smooth muscle cells from cardiomyopathic hamsters (delta-sarcoglycan-deficient BIO 53.58 hamster) and age-matched normal donor hamsters were isolated, expanded in culture, and cryopreserved. After reanimation in culture, cell morphology and growth rate were assessed and compared with values seen in noncryopreserved cells. A total of 4 x 10(6) previously cryopreserved skeletal myoblasts (n = 10) and vascular smooth muscle cells (n = 10) harvested from cardiomyopathic donors were then transplanted into the left ventricles of 17-week-old BIO 53.58 hamsters. Hearts injected with culture medium alone (n = 11) served as controls. Heart function was assessed 5 weeks after transplantation on a Langendorff apparatus, and left ventricular geometry was quantified by means of computerized planimetry. Staining with 5-bromo-2'-deoxyuridine identified the injected cells. RESULTS: Vascular smooth muscle cells from cardiomyopathic donors had an abnormal morphology and diminished growth rates in culture compared with vascular smooth muscle cells from normal donors. These markers of injury were exacerbated by cryopreservation. In contrast, vascular smooth muscle cells from normal donors and skeletal myoblasts from either cardiomyopathic or normal donors appeared normal in culture and were unaffected by cryopreservation. Both cryopreserved vascular smooth muscle cells and skeletal myoblasts from cardiomyopathic donors formed a viable muscle-resembling tissue that prevented wall thinning, limited left ventricular dilatation, and preserved global systolic function in hamsters with a genetic dilated cardiomyopathy. However, attenuation of cardiac remodeling and preservation of global heart function was greater after skeletal myoblast transplantation compared with vascular smooth muscle cell transplantation in parallel to the in vitro morphologic and growth characteristics of these cells. CONCLUSIONS: Cryostorage of healthy donor cells does not prevent the benefits of cell transplantation on limiting remodeling and preserving cardiac function in the failing heart. The health of donor cells in vitro predicts their subsequent benefits on cardiac structure and function after transplantation. Cryopreservation of donor cells might facilitate a clinically applicable and effective approach for ventricular restoration with cell-transplantation therapy for patients with inherited dilated cardiomyopathy.     

Human myoblast engraftment is improved in laminin-enriched microenvironment

BACKGROUND: One major challenge in developing cell therapy for muscle diseases is to define the best condition for the recipient's muscle to niche donor cells. We have examined the efficiency of human myoblast transplantation in an immunodeficient animal model, after local irradiation, as well as the potential impact of laminin on myoblast behavior. METHODS: Human myoblasts were injected into preirradiated tibialis anterior muscles from immunodeficient mice. The donor cell engraftment, proliferation, and laminin content within the transplanted muscles were evaluated by immunocytochemistry. Additionally, the effect of laminin upon myoblast proliferation, migration, and survival was ascertained in vitro. RESULTS: Engraftment of human myoblasts into the skeletal muscle of immunodeficient Rag2-/gammac-/C5- mice presubjected to local irradiation provided the best niche for myoblast engraftment, as demonstrated by the number of viable and proliferating donor cells found in the host muscle. Local irradiation significantly enhanced laminin deposition within the recipient's muscle and donor cells were preferentially located in laminin-enriched areas. The same batch of myoblasts used for in vivo injections also responded to laminin in vitro with increased proliferation and cell survival, as well as an improved migratory response. CONCLUSIONS: We show that local irradiation enhances the laminin content in the host muscle microenvironment and provides a better engraftment of human myoblasts. In addition, laminin increases myoblast proliferation, survival, and migration in vitro. These data provide combined in vivo and in vitro evidence that laminin status should be taken into account when designing experimental and clinical cell therapy strategies for muscle disease.     

Overexpression of connexin 43 in skeletal myoblasts: Relevance to cell transplantation to the heart

OBJECTIVE: Skeletal myoblast transplantation is a promising strategy for treating end-stage heart failure. One potential problem in the development of functional, synchronously contracting grafts is the degree of intercellular communication between grafted myoblasts and host cardiomyocytes. Thus it is expected that enhancement of intercellular gap junction formation would result in improved efficiency of skeletal myoblast transplantation. In this study we investigated whether myoblasts overexpressing connexin 43, a major cardiac gap junction protein, would enhance this intercellular communication. METHODS AND RESULTS: L6 rat skeletal myoblast cell lines overexpressing connexin 43 were generated by means of gene transfection and clonal selection. Connexin 43 overexpression of these myoblasts, which continued both in undifferentiated and differentiated states (up to 17-fold greater protein level in comparison with control-transfected myoblasts, as measured with Western blotting), was observed on cell surfaces where gap junctions should exist. Both dye microinjection and scrape loading with fluorescent dyes showed enhancement in intercellular dye transfer between connexin 43-transfected myoblasts compared with that found in control-transfected cells. Morphologically, these myoblasts fused and differentiated into multinucleated myotubes more rapidly, demonstrating a higher level of cellular creatine kinase activity as a marker of myogenic differentiation throughout the culture period compared with that of control-transfected myoblasts. CONCLUSIONS: We have generated connexin 43-overexpressing skeletal myoblast cell lines that resulted in improved formation of functional intercellular gap junctions, which could be relevant to synchronous contraction of grafted myoblasts in the heart. In addition, these cells demonstrated more rapid differentiation, which would also be advantageous in a graft for transplantation to the heart.     

Autologous skeletal myoblasts transduced with a new adenoviral bicistronic vector for treatment of hind limb ischemia

OBJECTIVE: We aimed to achieve angiogenic synergism between human vascular endothelial growth factor 165 (VEGF 165 ) and angiopoietin-1 (Ang-1) using a new adenoviral bicistronic vector concurrently with cell therapy to repair an ischemically damaged hind limb in a rabbit model. METHODS: Rabbit autologous primary skeletal myoblasts were isolated and labeled with retrovirally transduced LacZreporter gene, 4,6-diamidino-2-phenylindole (DAPI), and 5-bromo-2'-deoxyuridine (BrdU). Hind limb ischemia was created in 48 female New Zealand White rabbits by means of femoral artery ligation at 8 different places, and was assessed at angiography. Animals were randomized to receive intramuscular injection of either Dulbeco's Modified Eagle Medium (DMEM;group 1, n = 8), nontransduced myoblasts (group 2, n = 10), or myoblasts transduced with Ad-Null (group 3, n = 10), Ad-VEGF (group 4, n = 10), or Ad-Bicis (group 5, n = 8). Six weeks after treatment neovascularization in the limb was assessed at angiography. The animals were euthanized, and tissue was harvested for histologic study. RESULTS: Extensive transplanted myoblast survival was observed in all cell-transplanted groups, as visualized with DAPI, BrdU, and LacZ staining. Angiographic blood vessel count revealed enhanced neovascularization in group 5 (25.14 +/- 5.14) compared with group 4 (13.62 +/- 4.52), group 3 (6.09 +/- 0.09), group 2 (4.67 +/- 3.49), and group 1 (3.18 +/- 7.76). Immunostaining for von Willebrand factor confirmed significantly increased capillary density ( P < .01) at high-power microscopic field in group 5 (19.04 +/- 1.59) compared with group 4 (15.31 +/- 1.55), group 3 (6.53 +/- 0.97), group 2 (5.69 +/- 0.51), and group 1 (3.03 +/- 0.20). CONCLUSION: Simultaneous expression of VEGF and Ang-1 from bicistronic vector transduced skeletal myoblasts potently stimulated enhanced functional neovascularization in a rabbit model of limb ischemia.     

Novel Duchenne Muscular Dystrophy Treatment Through Myoblast Transplantation Tolerance with Anti-CD45RB, Anti-CD154 and Mixed Chimerism

Duchenne muscular dystrophy (DMD) is a fatal disease caused by a defect in the skeletal muscle protein, dystrophin. One potential therapy for DMD involves transplantation of myoblasts from normal individuals. Unfortunately, myoblast allografts are particularly immunogenic and transplant tolerance in dystrophic (mdx/mdx) mice has not yet been achieved despite using strategies successful in other allograft models. Here, we attempted to induce 'central tolerance' using either haplo- or fully allogeneic bone marrow after conditioning with low-dose (3 Gy) whole body irradiation and anti-CD154 or anti-CD45RB mAbs. With one exception, these mice lacked persistent chimerism, long-term survival of myoblast allografts, or tolerance. In contrast, the addition of anti-CD45RB to anti-CD154 uniformly resulted in long-lived high-level mixed chimerism, long-term (>100 days) engraftment of allogeneic myoblasts and deletion of donor-reactive cells. Moreover, all recipients exhibited tolerance to second myoblast allografts or donor-specific tolerance to skin transplants performed >80 days after the initial graft. Thus, we now report that anti-CD45RB synergizes with anti-CD40L to promote stable mixed chimerism and robust tolerance to myoblast allografts for the first time. This novel protocol may be applicable to future clinical trials in myoblast transplantation for treatment of DMD and for transplantation of other immunogenic allografts.     

Cellular cardiomyoplasty improves diastolic properties of injured heart.

BACKGROUND: Acute myocardial infarction leads to loss of functional myocytes and structural integrity that often decreases diastolic compliance and increases resting myocardial segment length (diastolic creep). Successfully engrafting autologous skeletal myoblasts could improve compliance and potentially reverse creep. Thus, we transplanted myoblasts into cryoinjured rabbit heart (n = 15, CRYO) and measured regional diastolic properties in the presence (n = 9, +ENG) or absence (n = 6, -ENG) of engraftment. MATERIALS AND METHODS: Left ventricular (LV) pressures (P) and myocardial segment lengths (SL) were measured in vivo by micromanometry and sonomicrometry after cryoinjury (CRYO) and again 3 weeks following transplantation of myoblasts. Performance was estimated from the relationships between end-diastolic (ED) P and strain (epsilon) or between EDP and EDSL. Compliance was characterized by strain (epsilon(8)) and dynamic stiffness (dP/dL(8)) at 8 mm Hg. Creep was characterized by resting myocardial segment length (EDSL(0)) and static stiffness at 8 mm Hg (m(stat8)). RESULTS: Successful myoblast engraftment was determined via histologic examination. In nine +ENG animals, diastolic properties improved. Regional strain (epsilon(8)) increased (0.06 +/- 0.02 CRYO vs 0.10 +/- 0.04 +ENG; P = 0.0009) while dynamic stiffness (dP/dL(8)) decreased (43 +/- 23 mm Hg/mm CRYO vs 23 +/- 14 mm Hg/mm +ENG; P = 0.009). Static stiffness (m(stat8)) was unaffected (0.78 +/- 0.2 mm Hg/mm CRYO vs 0.72 +/- 0. 1 mm Hg/mm +ENG; P = 0.08), and creep did not occur (EDSL(0) = 10.3 +/- 2.8 CRYO vs 10.4 +/- 2.3 +ENG; P = 0.74). In the absence of myoblast engraftment (n = 6, -ENG), strain decreased (epsilon(8) = 0. 06 +/- 0.02 CRYO vs 0.05 +/- 0.02 -ENG; P = 0.048), but dynamic stiffness (dP/dL(8)) did not (36 +/- 19 mm Hg/mm CRYO vs 28 +/- 12 mm Hg/mm -ENG; P = 0.20). Furthermore, static stiffness decreased (0. 78 +/- 0.3 mm Hg/mm CRYO vs 0.65 +/- 0.2 mm Hg/mm -ENG; P = 0.05) and creep was obvious (EDSL(0) = 10.8 +/- 3.6 mm CRYO vs 13.0 +/- 4. 4 mm -ENG, P = 0.04). CONCLUSIONS: Myoblast engraftment may partially overcome the loss of myocytes and structural integrity that often follow chronic myocardial ischemia. Improved compliance and reversal of diastolic creep suggest regeneration of viable muscle within once infarcted myocardium.     

Vascular endothelial growth factor transgene expression in cell-transplanted hearts

OBJECTIVE: We evaluated the effect of transplanted cell type, time, and region of the heart on transgene expression to determine the potential of combined gene and cell delivery for myocardial repair. METHODS: Lewis rats underwent myocardial cryoinjury 3 weeks before transplantation with heart cells (a mixed culture of cardiomyocytes, smooth muscle cells, endothelial cells and fibroblasts, n = 13), vascular endothelial growth factor-transfected heart cells (n = 13), skeletal myoblasts (n = 13), vascular endothelial growth factor-transfected skeletal myoblasts (n = 13), or medium (control, n = 12). Vascular endothelial growth factor expression in the scar, border zone, and normal myocardium was evaluated at 3 days and at 1, 2, and 4 weeks by means of quantitative polymerase chain reaction. Transplanted cells and vascular endothelial growth factor protein were identified immunohistologically on myocardial sections. RESULTS: Vascular endothelial growth factor levels were very low in control scars but increased transiently after medium injection. Transplantation with heart cells and skeletal myoblasts significantly increased vascular endothelial growth factor expression in the scar and border zone. Transplantation of vascular endothelial growth factor-transfected heart cells and vascular endothelial growth factor-transfected skeletal myoblasts further augmented vascular endothelial growth factor expression, resulting in 4- to 5-fold greater expression of vascular endothelial growth factor in the scar at 1 week. Peak vascular endothelial growth factor expression was greater and earlier in vascular endothelial growth factor-transfected heart cells than in vascular endothelial growth factor-transfected skeletal myoblasts. Vascular endothelial growth factor was primarily expressed by the transplanted cells. Some of the transplanted heart cells and vascular endothelial growth factor-transfected heart cells were identified in the endothelial layer of blood vessels in the scar. CONCLUSIONS: Transplantation of heart cells and skeletal myoblasts induces vascular endothelial growth factor expression in myocardial scars and is greatly augmented by prior transfection with a vascular endothelial growth factor transgene. Vascular endothelial growth factor expression is limited to the scar and border zone for 4 weeks. Both heart cells and skeletal myoblasts may be excellent delivery vehicles for cell-based myocardial gene therapy.     

Adenoviral-mediated uteroglobin gene transfer inhibits neointimal hyperplasia after balloon injury in the rat carotid artery

OBJECTIVE: Uteroglobin is a protein with potent anti-inflammatory and immunomodulatory effects. We hypothesize that induction of uteroglobin expression in the artery wall by local adenoviral gene transfer will decrease neointimal hyperplasia in the rat carotid artery after balloon injury. METHODS: Seven male Sprague-Dawley rats underwent balloon injury of the common carotid artery. After the injury, with flow occluded, the artery was instilled with 50 microL of the adenoviral vector encoding uteroglobin gene (Ad.UG) at a concentration of 1.35 x 10(11) pfu/mL (n = 7) or 0.68 x 10(11) pfu/mL (n = 7) (n = 7). Control animals were similarly treated: either an adenovirus encoding for beta-galactosidase gene (Ad.LacZ) at 1 x 10(11) pfu/mL (n = 7) or the phosphate-buffered saline (PBS) vehicle (n = 6) was used. The solution was allowed to dwell for 20 minutes. The rats were humanely killed after 14 days by perfusion fixation, and the carotid arteries were sectioned for analysis with computerized planimetry. The intima-media area ratios were calculated for each artery and compared with analysis of variance with Bonferroni/Dunn post hoc testing. One additional rat from the PBS, Ad.LacZ, and Ad.UG (1.35 x 10(11) pfu/mL) groups was humanely killed 4 days after treatment for carotid artery protein extraction and Western blotting. RESULTS: Uteroglobin protein production was confirmed in the Ad.UG-treated arteries with Western blotting. Morphometric analysis showed that the Ad.UG group at 1.35 x 10(11) pfu/mL had a significantly lower intima-media area ratio than both the Ad.LacZ (P =.002) and PBS (P =.004) controls. The Ad.UG group at 0.68 x 10(11) pfu/mL was also significantly different from the Ad. LacZ (P =.003) and PBS (P =.006) controls. There was no statistical difference between the two control groups or between the two Ad.UG groups. CONCLUSION: Adenoviral gene transfer of uteroglobin, delivered intraluminally after arterial injury causes the production of uteroglobin protein and has an inhibitory effect on neointimal accumulation in the rat model.     

Can cold or heat shock improve skeletal myoblast engraftment in infarcted myocardium?

OBJECTIVE: Cell death remains a major limitation of skeletal myoblast (SM) transplantation but the patterns of cell survival and proliferation in heart and their potential modulation by thermic stresses like heat shock (HS) and cryopreservation (Cryo) are still incompletely characterized. METHODS: To track SMs in situ, we developed a dual-marker system based on the semiconservative expression of the foreign soluble protein, beta-Galactosidase (beta-Gal) and the constitutive expression of the Y chromosome in a myocardial infarction model. Control medium or Lewis male rat SMs (fresh or subjected to Cryo or HS) were injected in Lewis female rats. RESULTS: There was a massive cell loss early after transplantation in the fresh group, which was only partially compensated for by a subsequent proliferation. Conversely, both Cryo and HS significantly improved early cell survival but blunted subsequent proliferation so that, at 15 days posttransplantation, the total number of engrafted donor-derived Y-positive cells did not differ significantly between the three groups. Most of them expressed a skeletal muscle phenotype. CONCLUSIONS: These data confirm the high death rate of in-scar transplanted myoblasts, demonstrate the ability of those that survive to proliferate and differentiate along the myogenic pathway but do not support the efficacy of either Cryo or HS for increasing the ultimate magnitude of myoblast engraftment.     

Current status and future prospects for cell transplantation to prevent congestive heart failure

Although most cardiac cell therapy trials have focused on patients with acute myocardial infarction, attempts at "regenerating" chronically failing hearts have also been performed. These studies have entailed use of skeletal myoblasts and bone marrow-derived cells. In the case of skeletal myoblasts, the randomized placebo-controlled myoblast autologous grafting in ischemic cardiomyopathy (MAGIC) trial has failed to show that myoblast injections increased ejection fraction beyond that seen in controls but the finding that the highest dose of myoblasts resulted in a significant antiremodeling effect compared with the placebo group provides an encouraging signal. In the case of bone marrow cells, surgical injections of the mononuclear fraction combined with coronary artery bypass surgery have not shown a substantial benefit but positive results have been reported with intraoperative epicardial injections of CD133(+) progenitors. There are three possible reasons for these mixed results. The first is the marked heterogeneity of cell functionality (particularly in the case of bone marrow), which would expectedly translate into variable clinical outcomes. The second reason is the low rate of sustained engraftment. The third possible explanation is a mismatch between the choice of end points and the presumed mechanism of action of the cells. The initial assumption that adult stem cells could effect myocardial tissue regeneration has led to usual focus on ejection fraction as the major surrogate endpoint. It is now increasingly recognized that adult stem cells, in contrast to their embryonic counterparts, have little if any regenerative capacity and that their presumed beneficial effects more likely involve paracrine signaling, in which case infarct size, perfusion, or left ventricular volumes might be more appropriate markers. Altogether, these observations provide a framework for future research, the results of which will then have to be integrated in the protocol design of second-generation clinical trials.     

Intramuscular migration of myoblasts transplanted after muscle pretreatment with metalloproteinases

The effect of pretreatments of host muscles with metalloproteinases (MMPs) or with notexin on the migration of transplanted myoblasts was investigated. Transgenic TnILacZ mice in which the beta-galactosidase gene is under the control of a quail fast skeletal troponin I gene promoter were used as donors. A polyethylene microtube with four perforations was inserted in the tibialis anterior (TA) of CD1 mice. Both pretreatment substances and cells were slowly injected through that microtube. Muscles were pretreated 2 days before myoblast injection either with a mixture of collagenase, matrilysin, and notexin or with only collagenase and matrilysin or only notexin. As control for our experiments, TnILacZ and C2C12 myoblasts were also injected in TA muscles not pretreated. Comparison of short and long-term myoblast radial migration was performed using a dye (PKH26) and X-gal staining, respectively. The recipient mice were immunosuppressed with FK506. Two days after myoblast transplantation, the cell movement in muscles pretreated with collagenase, matrilysin, and notexin was slightly greater than in muscles pretreated only with collagenase and matrilysin but was about twice that observed in muscles treated with notexin alone. Almost no radial migration of TnILacZ myoblasts was observed in untreated muscles. The C2C12 myoblasts showed a four-to fivefold higher migration capacity than TnILacZ myoblasts. At 15 days after TnILacZ myoblast transplantation, the farthest positive beta-gal muscle fibers show a two- to threefold extension of the initial migration observed at 2 days, demonstrating the ability of myoblasts to continue the migration following all pretreatments and even in the untreated muscles. In addition, more muscle fibers expressed the beta-gal reporter gene in muscles pretreated only with MMPs. Our results clearly demonstrate that muscle pretreatments with MMPs increase myoblast migration and fusion with host muscle fibers after transplantation and that the C2C12 cell line producing MMPs has a higher migratory capacity.