Albumin microbubble adherence to human coronary endothelium: implications for assessment of endothelial function using myocardial contrast echocardiography.

OBJECTIVES: We hypothesized that sonicated 5% human albumin microbubbles (Albunex) adhere to disrupted vascular endothelium and that this interaction is a marker of endothelial integrity. This study sought to identify sites and determinants of Albunex-endothelial cell (EC) attachment. BACKGROUND: Under normal conditions, Albunex microbubbles used in myocardial contrast echocardiography (MCE) pass unimpeded through the coronary microcirculation. During pathophysiologic states associated with endothelial dysfunction, however, microbubbles linger in the myocardium despite normal flow. The sites and conditions regulating microbubble adhesion are unknown. METHODS: Coverslips with cultured human coronary artery ECs were mounted in a parallel plate perfusion system and perfused with a suspension of fluorescein-labeled Albunex in culture medium, followed by a bubble-free wash at a wall shear rate of 100 s-1. To create inflammatory ECs, phorbol myristate acetate was added 4.5 h before perfusion, and flow cytometry was used to confirm an inflammatory response. Perfusions were performed under normal and inflammatory conditions using surfaces of confluent and subconfluent ECs and isolated extracellular matrix. Bubble adherence was quantified in 20 random fields per cover-slip using epifluorescent video microscopy. RESULTS: No microbubbles adhered to normal confluent ECs, although small numbers adhered to inflamed ECs (0.03 +/- 0.01 bubbles/cell, p < 0.01 vs. normal cells). Fever microbubbles attached to normal versus inflamed matrix of both partially exposed (1,800 +/- 520 vs. 4,100 +/- 1,000 bubbles/mm2, p = 0.05) and completely denuded (2,700 +/- 1,300 vs. 7,200 +/- 1,100 bubbles/ mm2, p < 0.03) endothelium. CONCLUSIONS: Albunex microbubbles preferentially adhere to inflammatory endothelial extracellular matrix. These data suggest that MCE can be used to noninvasively study endothelial integrity and may have implications for the assessment of preclinical atherosclerotic heart disease.

Flow cytometric characterization of myogenic cell populations obtained via the preplate technique: potential for rapid isolation of muscle-derived stem cells.

Myoblast transplantation has been investigated as a therapy for muscle-related diseases and as a gene delivery vehicle for therapeutic recombinant proteins. Clinical successes involving muscle cell transplantation have been limited, in part because of poor donor cell survival, and the heterogeneous nature of myogenic donor cells has largely been ignored. We have previously reported an isolation technique, preplating, that results in purified myogenic cells that are capable of significantly higher rates of donor cell survival leading to enhanced gene transfer to skeletal muscle. Characterization of these purified cells revealed that they display markers common to stem cells and are capable of multilineage differentiation. This study was performed to phenotypically characterize, by flow cytometry, muscle-derived cell populations obtained by the preplate technique for the purpose of eventually developing a method to quickly identify and isolate viable muscle cells best suited for transplantation. Muscle cell cultures were analyzed for expression of the surface proteins Sca-1, c-Kit, and CD34. We found that the preplate technique purifies distinct myogenic cell subpopulations expressing CD34 alone (Sca-1 negative) and Sca-1 alone (CD34 negative), but that this expression is subject to change with time in culture. Isolation and transplantation of phenotypically pure Sca-1-positive myogenic cells, obtained by magnetic cell sorting, demonstrates the ability to quickly select viable myogenic cells capable of regenerating skeletal muscle and restoring dystrophin expression within dystrophic host skeletal muscle. Flow cytometric described phenotypes will aid in the rapid isolation of specific donor cell populations for muscle cell transplants and muscle cell-mediated gene therapies, thereby enhancing their future success.

Myogenic cellular transplantation and regeneration: sorting through progenitor heterogeneity.

Growth and regeneration of skeletal muscle fibers in response to injury are made possible by the presence of resident myogenic progenitor cells. Researchers have attempted to isolate and transplant these cells to regenerate new muscle in cases involving injury, disease, or genetic deficiencies. Reports from such experiments underscore the functional diversity of progenitors obtained from skeletal muscle; however, currently there is no reliable means by which to positively identify and isolate the most desirable muscle progenitor populations. Taking a cue from the hematopoietic community, researchers in this area have begun to investigate cell surface protein expression in progenitor populations. Previous findings in cultured myogenic cells and our results in cells obtained directly from dissociated muscle suspensions indicate that cells sorted based on their expression of the commonly-studied myogenic cell surface proteins Sca-1 and CD34 exhibit differing regenerative abilities. However, results obtained to date are insufficient to clearly delineate whether the expression of either of these proteins is an exclusive characteristic of efficient myogenic progenitors. Nonetheless, observations from these studies clearly suggest that progenitor heterogeneity should be an important consideration during the development and implementation of muscle regeneration strategies. Additional research is necessary to establish reliable selection criteria for the isolation of efficient progenitors, which will facilitate therapeutic discoveries and enhance our understanding of factors affecting regeneration outcomes.

Directions in cardiovascular tissue engineering.

The generation of tissue replacements or supplements for diseased tissue within the cardiovascular system has been the target of recent tissue engineering efforts. While clinically applicable methodologies remain to be achieved, important foundational experimentation has been performed in recent years to begin the move toward engineered tissue replacement therapy. Inadequacies of current valve, vessel, and other heart prostheses are reviewed briefly, followed by the discussion of selected progress in the supplementation or replacement of each cardiovascular component with tissue constructs. Topics addressed include the endothelialization of bio-prosthetic valves and synthetic vascular grafts, the generation of tissue valve leaflets and vascular conduits, the genetic manipulation of endothelial cells with implications for graft endothelialization, and cardiomyoplasty achieved through cellular and genetic means.

Muscle-derived stem cells.

The existence of cells with stem cell-like abilities derived from various tissues can now be extended to include the skeletal muscle compartment. Although researchers have focused on the utilization of these cells with regard to their myogenic capacity, initially exploring more efficient cellular therapy treatments for muscular dystrophy, it is becoming increasingly apparent that such cells may one day be used in the treatment of non-myogenic disorders. Evidence regarding the existence and differentiation capacity of muscle-derived stem cells is discussed, along with current theories regarding their proposed position within the myogenic hierarchy.

Muscle-derived stem cells: characterization and potential for cell-mediated therapy.

Skeletal muscle may represent a convenient source of stem cells for cell-mediated gene therapy and tissue-engineering applications. A population of cells isolated from skeletal muscle exhibits both multipotentiality and self-renewal capabilities. Satellite cells, referred to by many as muscle stem cells, are myogenic precursors that are capable of regenerating muscle and demonstrating self-renewal properties; however, they are considered to be committed to the myogenic lineage. Muscle-derived stem cells, which may represent a predecessor of the satellite cell, are considered to be distinct. This article considers the evidence for the existence of muscle-derived stem cells as well as their potential embryonic origin. Comparison of muscle-derived stem cells to bone marrow and hematopoietic-derived stem cells illustrates similarities and distinctions among these various stem cells. Hematopoietic stem cell research provides lessons for the isolation of a defined phenotype as well as for the expansion of the stem cells in vitro. Recent investigations highlighting the potential of stem cell transplantation for the treatment of muscular dystrophies are discussed.

Effect of retroviral transduction on human endothelial cell phenotype and adhesion to Dacron vascular grafts.

PURPOSE: Retroviral transduction for genetic enhancement of endothelial cell (EC) anti-thrombotic phenotype offers potential for improving the clinical success of vascular graft seeding; however, application of this technique may bring concomitant alteration in cell functionality. METHODS: Human microvascular ECs were transduced with a retroviral vector encoding for the marker gene beta-galactosidase. Transduced endothelial cells (rtECs) and nontransduced endothelial cells (ntECs) were evaluated by flow cytometry for expression of intercellular adhesion molecule (ICAM)-1 and tissue factor (TF) on both smooth (coverslips) and graft (Dacron, 6 mm inside diameter) surfaces under static and shear exposed conditions. Graft EC retention was measured after 6-hour pulsatile perfusions. Platelet and neutrophil adherence was measured on perfused coverslips. RESULTS: Lower levels of ICAM-1 were expressed by rtECs on coverslips under both static (p < 0.01 vs static ntECs) and shear exposed conditions (p < 0.01 vs static and shear ntECs). Accordingly, fewer polymorphonuclear leukocytes adhered to rtEC monolayers (p < 0.01 vs ntECs). No difference in ICAM-1 and TF expression by static graft seeded rtECs and ntECs was observed. However, graft-seeded rtECs that were exposed to wall shear stress displayed less TF than sheared ntECs (p < 0.05). Transduction did not affect EC retention to the sheared graft surface. CONCLUSIONS: These data suggest that retroviral transduction does not elicit a prothrombotic/proinflammatory phenotype, rather indices of these states appear in some conditions to be reduced. Further, transduction does not adversely affect EC adherence to Dacron graft surfaces under arterial hemodynamics.

Modeling stem cell population growth: incorporating terms for proliferative heterogeneity.

Expansion of the undifferentiated stem cell phenotype is one of the most challenging aspects in stem cell research. Clinical protocols for stem cell therapeutics will require standardization of defined culture conditions. A first step in the development of predictable and reproducible, scalable bioreactor processes is the development of mathematical growth models. This paper provides practical models for describing cell growth in general, which are particularly well suited for examining stem cell populations. The nonexponential kinetics of stem cells derive from proliferative heterogeneity, which is biologically recognized as mitosis, quiescence, senescence, differentiation, or death. Here, we examined the assumptions of the Sherley model, which describes heterogeneous expansion in the absence of cell loss. We next incorporated terms into the model to account for A) cell loss or apoptosis and B) cell differentiation. We conclude that the basic assumptions of the model are valid and a high correlation between the modified equations and experimental data obtained using muscle-derived stem cells was observed. Finally, we demonstrate an improved estimation of the kinetic parameters. This study contributes to both the biological and mathematical understanding of stem cell dynamics. Further, it is expected that the models will prove useful in establishing standardization of cell culture conditions and scalable systems and will be required to develop clinical protocols for stem cell therapeutics.

Targeting and ultrasound imaging of microbubble-based contrast agents.

Preparation and characterization of targeted microbubbles (ultrasound contrast agents) is described. Specific ligands were attached to the microbubble shell, and ligand-coated microbubbles were selectively attached to various targets, using either an avidin biotin model system or an antigen-antibody system for targeting to live activated endothelial cells. Firm attachment of microbubbles to the target was achieved. Forces necessary to detach microbubbles from the target were estimated to exceed dozens of pN. Microbubbles were bound to the target even in the rapidly moving stream of the aqueous medium. Down to 20 ng of the ultrasound contrast material on the target surface could be detected by the ultrasound imaging with a commercial medical imaging system. At high bubble density on the target surface, strong ultrasound image attenuation was observed.

Microbubbles targeted to intercellular adhesion molecule-1 bind to activated coronary artery endothelial cells.

BACKGROUND: Preclinical atherosclerosis is associated with increased endothelial cell (EC) expression of leukocyte adhesion molecules (LAMs), which mediate monocyte adhesion during atherogenesis. Identification of cell-surface LAMs may uniquely allow assessment of endothelial function, but there are no in vivo methods for detecting LAMs. We tested a new microbubble designed to bind to and allow specific ultrasound detection of intercellular adhesion molecule-1 (ICAM-1). METHODS AND RESULTS: A perfluorobutane gas-filled lipid-derived microsphere with monoclonal antibody to ICAM-1 covalently bound to the bubble shell was synthesized. Bubbles with either nonspecific IgG or no protein on the shell were synthesized as controls. Coverslips of cultured human coronary artery ECs were placed in a parallel-plate perfusion chamber and exposed to 1 of the 3 microbubble species, followed by perfusion with culture medium. Experiments were performed with either normal or interleukin-1beta-activated ECs overexpressing ICAM-1, and bubble adherence was quantified with epifluorescent videomicroscopy. There was limited adherence of control bubbles to normal or activated ECs, whereas a 40-fold increase in adhesion occurred when anti-ICAM-1-conjugated bubbles were exposed to activated ECs compared with normal ECs (8.1+/-3.5 versus 0.21+/-0.09 bubbles per cell, respectively, P<0.001). Although diminished, this difference persisted even after perfusion at higher wall shear rates. CONCLUSIONS: A gas-filled microbubble with anti-ICAM-1 antibody on its shell specifically binds to activated ECs overexpressing ICAM-1. Diagnostic ultrasound in conjunction with targeted contrast agents has the unique potential to characterize cell phenotype in vivo.