Expression of apoptosis-related proteins and structural features of cell death in explanted aortocoronary saphenous vein bypass grafts.

This study aimed to investigate the features of cell death occurring in aortocoronary saphenous vein bypass grafts. Human aortocoronary saphenous vein bypass grafts with angiographic luminal stenosis of > 75% were explanted from 14 patients at redo coronary artery bypass grafting. Proteins associated with apoptotic pathways were identified immunohistochemically using antibodies to Bcl-2, Fas, BAX, p53 and CPP32. Cells undergoing DNA fragmentation were identified by terminal deoxynucleotidyl transferase-mediated dUTP nick end labeling (TUNEL). DNA synthesis was investigated using the antibody to proliferating cell nuclear antigen (PCNA). Ultrastructural features of cell death were examined by electron microscopy. Anti-apoptotic (Bcl-2) and pro-apoptotic (Bax, p53, CPP32 and Fas) proteins were expressed throughout the graft wall, but marked differences in the characteristics of cell death were noted between atherosclerotic and non-atherosclerotic areas of the intima. In atherosclerotic areas, pro-apoptotic proteins were widely expressed, but ultrastructural analysis failed to identify cells showing typical features of apoptosis. In these areas, necrotic cells were frequently observed, with negative correlation of Bcl-2 expression with TUNEL. Pro-apoptotic proteins showed no correlation with TUNEL. In contrast, in non-atherosclerotic areas of vein grafts, the expression of both anti-apoptotic (Bcl-2) and pro-apoptotic proteins (p53, Bax and CPP32) correlated with TUNEL. In atherosclerotic areas, non-atherosclerotic intimal areas, and in the underlying media, the numbers of TUNEL+ cells correlated with PCNA positivity. Ultrastructurally, apoptotic bodies and features of necrosis were observed in non-atherosclerotic areas of grafts. The present observations indicate that in atherosclerotic areas, cell death occurs mainly by necrosis, while in non-atherosclerotic areas, cell death occurs by both necrosis and apoptosis. An imbalance between DNA fragmentation and DNA synthesis may contribute to graft instability and failure.

Colonisation of prosthetic grafts by immunocompetent cells in a sheep model.

The present study examined the distribution of immunocompetent cells in synthetic vascular grafts in an experimental sheep model. Sixty-two adult Merino sheep underwent synthetic patch closure of a longitudinal arteriotomy in the left common carotid artery. The synthetic patch materials used were gelatin sealed Dacron (n=10), fluoropassivated Dacron (n=10), Fluoropassiv (n=12), polyurethane (n=10), expanded polytetrafluoroethylene (n=10) and carbon-lined expanded polytetrafluoroethylene (n=10). The sheep were sacrificed after four weeks when the prosthetic patches were harvested and fixed in 10% neutral buffered formalin. Transverse sections were taken along the graft and paraffin embedded. Serial sections were stained with cell type specific antibodies to identify T-lymphocytes (CD3(+)), dendritic cells (S-100(+)), endothelial cells (von Willebrand factor(+)) and smooth muscle cells (smooth muscle alpha-actin(+)). All six graft types contained CD3(+) and S-100(+) cells in the neointima, within the synthetic matrix and in the perigraft layer. Three different tissue responses to synthetic materials were observed and the grafts were classified accordingly into three groups: (1) gelatin sealed Dacron, fluoropassivated Dacron and Fluoropassiv; (2) expanded polytetrafluoroethylene and carbon-lined expanded polytetrafluoroethylene; (3) polyurethane. The three synthetic materials in Group 1 showed almost identical reactions with least accumulation of immunocompetent cells within the synthetic material but greater accumulation of immuno-inflammatory infiltrates in the perigraft vascular tissue. In this group, new vessels penetrated into the synthetic material and there was prominent formation of foreign body (giant) cells. Group 2 showed greater accumulation of immunocompetent cells within the synthetic material itself but only sparse immuno-inflammatory infiltrates in the perigraft tissue. Group 3 showed a high degree of inflammatory response within both the synthetic material and the perigraft vascular tissue. These observations demonstrate that immunocompetent cells colonise the synthetic matrix of grafts and accumulate in the perigraft tissue, but inflammatory responses vary in different graft types.

Immunohistochemical and ultrastructural evidence that dendritic cells infiltrate stenotic aortocoronary saphenous vein bypass grafts.

We earlier speculated that antigen-presenting dendritic cells may be involved in the immune reactions leading to saphenous vein bypass graft failure. The purpose of this study was to confirm whether dendritic cells are present in stenotic human saphenous vein bypass grafts. Segments of stenotic saphenous vein grafts were explanted from 14 patients at re-do bypass operation and ten normal saphenous veins were harvested during femoro-popliteal grafting. Sections of specimens were analysed using cell type specific antibodies to identify dendritic cells (CD1a, S-100), T-lymphocytes (CD3), macrophages (CD68), smooth muscle cells (alpha-SMA) and endothelial cells (FVIII). Dual immunostaining, confocal immunofluorescent laser scanning microscopy and electron microscopy were used. Stenotic grafts showed structural alterations of intimal hyperplasia and varying degrees of atherosclerotic degeneration. No cells expressing CD1a and S-100 were observed in the intima and media of normal saphenous veins. Cells expressing these antigens were present around areas of medial neovascularization and within intimal atherosclerotic lesions in saphenous vein bypass grafts. Electron microscopy demonstrated the presence of cells containing a well-developed tubulovesicular system which is unique to cells from the dendritic cell family. Double immunohistochemistry and confocal immunofluorescent microscopy revealed the co-localization of T-lymphocytes with dendritic cells. Dendritic cells are present in stenotic saphenous vein bypass grafts. Dendritic cells may be responsible for antigen presentation and modulation of immune reactions in accelerated graft atherosclerosis through their interaction with T-lymphocytes.

Electron-microscopic detection of apoptotic and necrotic cell death in non-atherosclerotic areas of stenotic aortocoronary saphenous vein bypass grafts.

Aortocoronary saphenous vein bypass grafts undergo structural alterations within the arterialized vein, resulting in graft stenosis and failure. Areas of the acellular intima contribute to fissuring, cracking and ulceration, while areas of the media become highly vascular but thinned. This study aimed to examine the ultrastructural features of cell death, including apoptosis and necrosis, in non-atherosclerotic areas of the stenotic aortocoronary saphenous vein bypass grafts. Thirteen stenotic vein grafts were obtained at redo coronary artery bypass grafting. The ultrastructural features of cell death were analysed by electron microscopy. Typical features of necrosis, including focal areas of cytoplasmic oedema, plasmalemmal destruction and nuclear condensation with cytoplasmic organelle destruction, were observed throughout the intima and media. Features of apoptosis, including the presence of apoptotic bodies, were also identified in the hyperplastic intima and its adjacent media. Our observations suggest that both apoptosis and necrosis occur in non-atherosclerotic areas of stenotic aortocoronary saphenous vein bypass grafts.

Accumulation of lymphocytes, dendritic cells, and granulocytes in the aortic wall affected by Takayasu's disease.

The aim of this study was to analyze the cellular composition of the arterial wall in Takayasu's disease and to investigate the contribution of the various cell types to the immunoinflammatory processes and degenerative alterations of the vessel wall in this disease. Specimens of aorta were obtained at operation from 10 patients with Takayasu's arteritis. The duration of disease ranged from 2 months to 13 years. Immunohistochemical investigation was carried out using the antibodies CD3 (to identify T-cells), CD20 (B-cells), S-100 (dendritic cells), CD68 (macrophages), CD15 (granulocytes), von Willebrand factor (endothelial cells), and alpha-smooth muscle actin (smooth muscle cells). All specimens showed distinctive histologic features of Takayasu's arteritis and contained inflammatory infiltrates, but the degree of their accumulation within the aortic wall varied. Inflammatory infiltrates within the deep part of the intima, around areas of neovascularization and within the adventitia contained T-cells colocalizing with dendritic cells. Nodules formed by large numbers of intermingling T-cells and B-cells enriched with dendritic cells were observed in the adventitia. Massive accumulation of granulocytes and their destruction within the adventitia were prominent in all cases. This is the first study that establishes the presence of dendritic cells and granulocytes in Takayasu's disease. Dendritic cells are probably involved in the immunoinflammatory processes through their interaction with T-cells and B-cells. The present observations may help understanding of the pathogenesis of Takayasu's disease.

Identification of dendritic cells in ePTFE grafts explanted from humans.

Following implantation different cell types interact with synthetic vascular prostheses resulting in a complex immuno-inflammatory response. Dendritic cells are responsible for activating the primary T-lymphocyte immune response in various pathological conditions by their role as antigen-presenters. This study aimed at examining whether dendritic cells accumulate within small diameter expanded polytetrafluoroethylene (ePTFE, Goretex(R)) grafts explanted from humans. Segments of expanded polytetrafluoroethylene were explanted from 11 patients (6 male, 5 female), aged between 60 and 83 years (mean 70.7 years) at secondary or revision bypass operation. The graft implant duration varied from 4 months to 12 years (mean 40.5 months). Dendritic cells were identified immunohistochemically using S-100 antibody, as well as by electron microscopy. Immunohistochemical examination showed that all 11 explanted synthetic grafts contained S-100(+) cells colonising both the synthetic matrix itself, and the adjacent perigraft tissue. Electron microscopic analysis confirmed the presence of cells with a characteristic dendritic cell morphology within the grafts. Dendritic cells which accumulated within synthetic grafts were found to co-localise with T-lymphocytes. Based on these observations, we speculate that dendritic cells may be involved in the immuno-inflammatory responses following the implantation of synthetic vascular prostheses through their interaction with T-lymphocytes.

Immunophenotypic analysis of the aortic wall in Takayasu's arteritis: involvement of lymphocytes, dendritic cells and granulocytes in immuno-inflammatory reactions.

The present study was undertaken to examine the cellular composition of the aortic wall in Takayasu's arteritis and to investigate the association of different cell types in the immuno-inflammatory reactions of this disease. Specimens of aortic wall affected by Takayasu's arteritis were obtained from 10 patients (five male, five female), aged 32 to 68 years (mean 49.5 years) at elective operation. The mean duration of disease was 6.5 years (range 2 months to 13 years). Specimens were embedded in paraffin and the sections stained with antibodies to CD3 (to identify T cells), CD20 (B cells), S-100 (dendritic cells), CD15 (granulocytes), CD68 (macrophages), alpha-SMA (smooth muscle cells) and von Willebrand factor (endothelial cells). Immunohistochemical examination demonstrated that all specimens showed histological alteration with the replacement of the muscular and elastic layers of the media and adventitia by dense fibrous tissue, and were characterized by varying degrees of inflammatory cell infiltration. In five cases, inflammatory nodules consisting of numerous T cells and B cells were observed in the adventitia. Within the inflammatory nodules, as well as around areas of neovascularization in the deep portion of the intima, lymphocytes were co-localized with dendritic cells. In addition, in the adventitia, the accumulation of a large number of granulocytes was observed. The present study demonstrates that immune inflammation is a typical feature of Takayasu's disease, and that the interactions between dendritic cells and lymphocytes may be important in the control of the immune reactions in this vascular pathology.

Ultrastructural and immunohistochemical analysis of early myocardial changes following transmyocardial laser revascularization.

BACKGROUND AND AIM OF THE STUDY: Transmyocardial laser revascularization (TMR) has demonstrated significant relief in patients presenting with refractory angina. However, the mechanism by which TMR improves clinical symptoms is unclear. This study analyzes the early immunohistochemical and ultrastructural features of the human myocardium following TMR. METHODS: Specimens of myocardium that contained laser channels were removed in toto at autopsy from three male patients, ages 41, 57, and 65 (mean age 55.8) who had died 1 to 11 days (mean 6.8) following laser revascularization. Consecutive parallel sections of specimens were stained with cell-type specific antibodies to CD3 (to identify T-lymphocytes), CD68 (macrophages), Factor VIII (endothelial cells), and myosin (myocytes). Additionally, adjacent areas of myocardium that contained laser channels were processed and analyzed by transmission electron microscopy. RESULTS: The internal lining surface of laser channels was composed of vacuolized and condensed myocardial debris. No obvious connections were noted between laser channels and the ventricular cavity. No endothelialization of channels was observed, whereas the adjacent noninjured myocardium demonstrated microvessels lined by well-preserved endothelial cells. The laser channels were surrounded by zones of necrotic cardiomyocytes. CONCLUSIONS: Our observations suggest that laser channels are not lined by endothelial cells during the early stages following TMR. Mechanisms other than direct myocardial perfusion from the ventricular cavity by patent endothelialized channels may explain the immediate relief from angina provided by TMR.

Dendritic cells in aortocoronary saphenous vein bypass grafts.

Dendritic cells are specialised leucocytes responsible for capturing and presenting antigens to T lymphocytes, which in turn mediate immune responses in various pathological conditions. The observations in this study demonstrate that dendritic cells are present in stenotic aortocoronary saphenous vein bypass grafts, which suggest that these cells may be involved in inflammatory actions which may subsequently contribute to graft failure.

Involvement of dendritic cells in long-term aortocoronary saphenous vein bypass graft failure.

Antigen-presenting dendritic cells are present in atherosclerotic lesions in human arterial intima, but have not been investigated in atherosclerotic and hyperplastic stenotic lesions that affect vein grafts used as arterial conduits. This study was undertaken to examine whether dendritic cells are present in aortocoronary artery saphenous vein bypass grafts affected by high-grade atheromatous stenosis. Stenotic saphenous vein coronary artery bypass grafts (angiographic luminal stenosis > 75%) were harvested from 10 patients (nine male, one female), aged 4271 years (mean 56.5) at re-do operation. The mean time interval from bypass surgery to the excision of stenotic grafts was 11.5 years (range 2-21). The specimens were fixed in 10% buffered formalin, embedded in paraffin blocks and the sections stained with antibodies to S-100 (to identify dendritic cells), CD3 (T cells), CD68 (macrophages), von Willebrand factor (endothelial cells) and alpha-smooth muscle actin (smooth muscle cells) using avidin-biotin complex immunoperoxidase technique. Normal veins were obtained during saphenous vein femoro-popliteal grafting. The stenotic venous grafts showed histological features typical of extensive arterialization, intimal hyperplasia, atherosclerotic plaque-like lesions, calcification and thrombosis. In areas of intimal hyperplasia, S-10O-positive cells were distributed irregularly among smooth muscle cells. S-100-positive dendritic cells were seen most frequently within atherosclerotic plaque-like lesions where they co-localized with CD3+ cells and CD68+ cells. S-100-positive dendritic cells were also seen accumulating within calcific foci. No S-100-positve cells were found in normal, ungrafted saphenous veins. We conclude that dendritic cells are present in aortocoronary saphenous vein bypass grafts affected by high grade stenosis. Dendritic cells are probably involved in immune mechanisms of atherogenesis through their interactions with T cells and macrophages. The accumulation of dendritic cells within calcific foci suggests their contribution to the calcification of stenotic venous grafts.

Dendritic cells in venous pathologies.

Dendritic cells are potent antigen-presenting cells responsible for the activation of T-lymphocytes in various immune responses. Their role in the initiation of immune reactions in allergies, autoimmune diseases, tumors, transplantation, and, more recently, in atherosclerosis has been well established, but their involvement in venous pathologies has not been previously investigated. The aim of this study was to determine whether dendritic cells are present in veins affected by varicosity and thrombophlebitis. Three groups of veins obtained at operation were studied: (1) varicose veins of the great saphenous vein from patients who were undergoing vein stripping for primary varicosity; (2) segments of the great saphenous vein from patients with varicosity complicated by thrombophlebitis; and (3) great saphenous veins without varicosity or thrombophlebitis from patients who were undergoing femoropopliteal bypass grafting. The specimens were fixed in 10% neutral buffered formalin and embedded in paraffin, and the sections were stained with antibodies to S-100 (to identify dendritic cells), CD3 (T-lymphocytes), CD68 (macrophages), von Willebrand factor (endothelial cells), alpha-smooth muscle actin (smooth muscle cells), and CD15 (mast cells) by use of avidin-biotin complex (ABC) immunoperoxidase technique. Immunohistochemical examination showed that no S-100-positive dendritic cells were present in normal saphenous veins. In contrast, S-100-positive cells with dendritic cell morphology were detected in the intima and media of veins with varicosity and thrombophlebitis, where they represented a minor cell population. S-100-positive dendritic cells were located between smooth muscle cells as well as around areas of neovascularization where they colocalized with T-lymphocytes. The present work suggests that dendritic cells might be involved in pathological processes in veins affected by varicosity and thrombophlebitis. The authors speculate that dendritic cells may be involved in the inflammatory mechanisms in these veins through their interaction with T-lymphocytes.

Structural features of cell death in atherosclerotic lesions affecting long-term aortocoronary saphenous vein bypass grafts.

Aortocoronary saphenous vein bypass grafts fail because of structural pathologies (thrombosis, intimal hyperplasia and atherosclerosis) within the 'arterialized' vein leading to graft stenosis. This study examined structural characteristics of atherosclerotic alterations in long-term aortocoronary artery saphenous vein bypass grafts with particular attention to the features of cell death in atherosclerotic lesions. Stenotic vein grafts were obtained from 10 patients at redo coronary artery bypass grafting operations. All the grafts were affected by histological abnormalities, with eight out of ten grafts showing evidence of atherosclerotic alterations in the intimal hyperplastic layer. Areas containing foam cells were examined by electron microscopy. Cells with cytoplasmic lipid accumulations were characterized by varying degrees of chromatin condensation, fragmentation or dispersion, by focal areas of oedema and vacuolisation of their cytoplasm, and by plasmalemmal destruction. Some lipid-filled cells exhibiting signs of destruction contained myofilaments and basal membrane fragments, allowing them to be identified as smooth muscle cells. Macrophage foam cells were found to have undergone similar destruction. No cells showing nuclear degeneration were observed to have intact cytoplasmic organelles. Neither were apoptotic bodies identified, but necrotic remnants were frequently seen. The results suggest that cell death in atherosclerotic lesions affecting aortocoronary artery saphenous vein bypass grafts occurs through oncosis rather than by apoptosis.

Neovascular expression of VE-cadherin in human atherosclerotic arteries and its relation to intimal inflammation.

OBJECTIVE: The present work aimed to investigate how the Ca(2+)-dependent cell adhesion molecule vascular endothelial (VE)-cadherin might be involved in atherogenesis. METHODS: Specimens of human carotid artery and aorta were obtained at operation. An immunohistochemical approach using cell-type specific antibodies examined how VE-cadherin expression in areas of neovascularisation related to the accumulation of immunocompetent and inflammatory cells within atherosclerotic plaque. Electron microscopy was used to examine the structural characteristics of neovessels and the cell composition in the surrounding intimal matrix. RESULTS: In all the non-atherosclerotic aortic segments, VE-cadherin expression was observed only in the adventitia and the outer third of the media. Within the atherosclerotic arterial segments, VE-cadherin was expressed in all layers of the arterial wall including the intima where VE-cadherin was expressed by endothelial cells in areas of neovascularization. In some neovessels, loss of VE-cadherin expression was associated with increased focal accumulation of T-cells, macrophages and dendritic cells. Electron-microscopic examination demonstrated varying degrees of endothelial continuity in the intimal neovessels. Within those neovessels which were surrounded by a large number of immunocompetent and inflammatory cells, some inter-endothelial cell contacts were open allowing the penetration of blood cells through patent intercellular zones. CONCLUSIONS: VE-cadherin is expressed in atherosclerotic lesions by endothelial cells associated with neovascularisation. Downregulation of VE-cadherin expression within some intimal neovessels is accompanied by increased entry of immunocompetent cells into the intimal matrix surrounding areas of neovascularization which suggests that disorganizing endothelial cell-to-cell interactions within neovessels is significant in atherogenesis.