The effect of prolonged ischaemia and cryopreservation on the cell viability of human aortic and femoral artery allografts

The viability of the human arterial allograft cells depends on the time and method of vessel procurement and storage. In this study, an evaluation of the effect of the duration of 4 degrees C ischaemia and cryopreservation on human aortic and femoral artery allograft viability was performed. After the isolation of arterial wall cells, the identification of cultured cells was performed using mRNA analysis for estimation of smooth-muscle markers of differentiation: desmin and heavy-caldesmon. The viability of cells from the medial layer of the aortic wall ranged from 74 to 90% (61-79% for femoral arteries). Cold ischaemia time (from harvesting until the beginning of the preparation) is a statistically significant factor influencing smooth muscle cell viability. Smooth muscle cells represented the majority of live cell population.     

Morphometry of the amount of smooth muscle cells in the media of various rabbit arteries

Our objective in this study was to evaluate the relative amount of smooth muscle cells in the medial layer of various rabbit arteries. The fixation of smooth muscle cells in the arterial wall is difficult and the differential effect of glutaraldehyde (GA) and fixative vehicle on cell ultrastructure in different tissues is controversial. We compared the effect of various concentrations of the vehicle and glutaraldehyde (osmolarity ranges for total fixative, 350-1030 mOsm) on the arterial wall ultrastructure. We found that a 600 mOsm GA solution (isotonic vehicle; 2.5% GA) adequately preserves arterial wall structures. The relative amount of smooth muscle cells in the media differed in various segments along the arterial tree. It ranged from 35% (thoracic aorta) to 74% (tibial artery). The importance of weighting the contractile response of different arteries in vitro to their relative smooth muscle cell content is discussed.     

A histological study on the coronary artery of the indigenous black Bengal goat in Bangladesh.

The coronary artery of the black Bengal goat was studied by light microscopy. The wall of the coronary artery consisted of the tunica intima, tunica media and tunica externa. The tunica intima consisted of a single layer of flattened endothelium. The tunica media was well-developed and composed of mainly of smooth muscle cells together with some fine elastic fibers. The tunica externa consisted of predominant collagen fibers, and some elastic fibers and smooth muscle cells. Elastic fibers in the tunica externa formed a circular arrangement around the tunica media. Sex differences were not observed. The media with well-developed smooth muscle cells may be responsible for changes in functional physiological conditions of the heart.     

The role of cell proliferation and migration in the development of a neo-intimal layer in veins grafted into arteries,in rats

Summary The development of a thickened (hyperplastic) fibro-cellular neo-intima is a significant event in the adaptation of a vein grafted into an artery. The histogenesis of tissues in vein grafts was explored in a rat model where the source of endothelial and smooth muscle cells was from the adjacent artery. Cell proliferation was assessed by the incorporation of tritiated thymidine and autoradiography, up to 18 months after grafting. Cell migration was detected by prelabelling in the first 5 days after grafting and sampling at later times. The proliferation of cells in the arterial media adjacent to the graft was elevated above control levels as early as 2 days after grafting; it was maximal at 3 days and returned to low levels by day 21. During the first week, prelabelled smooth muscle cells in the tunica media of the adjacent artery migrated to the subendothelial space, where they continued to proliferate to produce arterial intimal hyperplasia. The migration of endothelial and smooth muscle cells proceeded across the anastomosis to populate the vein graft neo-intima, where smooth muscle cells continued to proliferate until 28 days after grafting. Cell migration and proliferation were significant factors in the histogenesis of vein graft neo-intimal hyperplasia in this model. These processes were controlled, perhaps by local regulatory factors, to form a vein graft, the wall of which was similar in thickness and structure to that of the host artery.     

Effect of longitudinal gravitational loads on the structure of the wall of the vertebral artery]

A single exposure to the greatest endurable gravitation stress causes such changes in the wall of the vertebral artery as division into layers, oedema, vacuolization of smooth muscle cells. Repeated exposure according to a training schedule resulted in reconstruction of the vascular wall (division of the medial sheath of the artery into several muscular layers). Concentration of smooth muscle cells in "layers" increased when training was after a "cumulative" schedule. Under conditions of increasing cumulative effect the collagenization of the media and dystrophy of the muscular and elastic tissue began. The greatest changes in the arterial wall took place in the upper parts of the vertebral artery at the level of the 2nd and 3d cervical vertebra.     

Trophoblastic invasion and the development of uteroplacental arteries in the macaque: immunohistochemical localization of cytokeratins,desmin, type IV collagen,laminin, and fibronectin

The processes by which trophoblast cells invade and modify the walls of the uteroplacental arteries of macaques during the course of gestation were examined. Antibodies to cytokeratins were employed to identify trophoblast, anti-desmin antibody to identify smooth muscle, and antibodies to type IV collagen, laminin, and fibronectin to examine changes in extracellular matrix distribution in the arterial wall. During early gestation, endovascular trophoblast adhered to the arterial wall, often in an asymmetrical distribution. As trophoblast cells moved outwardly into the tunica media, the basement membrane underlying the endothelium was lost, as indicated by gaps in the layer when stained for type IV collagen and laminin. Trophoblast cells became sequestered in the vessel wall where they hypertrophied and became surrounded by a capsule containing type IV collagen and laminin. As the trophoblast cells became established in the vessel wall, the muscular layer of the artery became discontinuous. Throughout gestation it was common for trophoblast cells to invade the vessel intimal layer and share the lining of the artery with typical endothelial cells. This general disposition of endovascular and intramural trophoblast persisted into late gestation. In addition, and contrary to the results of earlier studies of macaques, we identified trophoblastic invasion and modification of myometrial segments of the uteroplacental arteries in later gestation. We also found evidence of interstitial trophoblast cells among the stromal cells of the endometrium, especially during early gestation.     

Spatial distribution of osteoblast-specific transcription factor Cbfa1 and bone formation in atherosclerotic arteries

The mechanisms of ectopic bone formation in arteries are poorly understood. Osteoblasts might originate either from stem cells that penetrate atherosclerotic plaques from the blood stream or from pluripotent mesenchymal cells that have remained in the arterial wall from embryonic stages of the development. We have examined the frequency of the expression and spatial distribution of osteoblast-specific factor-2/core binding factor-1 (Osf2/Cbfa1) in carotid and coronary arteries. Cbfa1-expressing cells were rarely observed but were found in all tissue specimens in the deep portions of atherosclerotic plaques under the necrotic cores. The deep portions of atherosclerotic plaques under the necrotic cores were characterized by the lack of capillaries of neovascularization. In contrast, plaque shoulders, which were enriched by plexuses of neovascularization, lacked Cbfa1-expressing cells. No bone formation was found in any of the 21 carotid plaques examined and ectopic bone was observed in only two of 12 coronary plaques. We speculate that the sparse invasion of sprouts of neovascularization into areas underlying the necrotic cores, where Cbfa1-expressing cells reside, might explain the rarity of events of ectopic bone formation in the arterial wall. This study has also revealed that Cbfa1-expressing cells contain alpha-smooth muscle actin and myofilaments, indicating their relationship with arterial smooth muscle cells.     

Cytomegalovirus aggravates intimal hyperplasia in rats by stimulating smooth muscle cell proliferation

Epidemiological and animal studies suggest a role for cytomegalovirus (CMV) in restenosis. Previously, we demonstrated that proliferating smooth muscle cells (SMCs) in the injured arterial wall are particularly susceptible to CMV-induced effects. Therefore, we hypothesised that, depending on the time point of infection after vascular injury, CMV infection may affect cell proliferation either in the media or in the neointima, thereby aggravating the process of restenosis. In the present study, we focused on the individual layers of the arterial wall by evaluating, besides the neointima-to-media ratio, the medial and neointimal area and cellularity in the rat femoral artery. Vascular injury was photochemically induced in rat femoral arteries. Immediately or 14 days thereafter, rats were infected with rat CMV (RCMV) or mock infected. The presence of RCMV in the vascular wall was determined at 3, 5, 14 and 35 days after infection by quantitative real-time PCR. When rats were infected immediately after injury, a significant increase was seen only in the medial but not in the neointimal cross-sectional area. On the other hand, when rats were infected 14 days after the initial injury, a significant increase was only seen in the neointimal area, thereby confirming our hypothesis that RCMV infection primary affects proliferating SMCs. As the mean number of SMCs per microm2 in both cell layers was unchanged despite an increase in cross-sectional area, this implies that RCMV stimulated SMC proliferation. Furthermore, these vascular effects were observed without the virus being abundantly present in the vascular wall, suggesting that inflammatory and immune-mediated responses to RCMV infection are more important in aggravating the response to vascular injury than the virus itself.     

Accelerated Reendothelialization,Increased Neovascularization and Erythrocyte Extravasation after Arterial Injury in BAMBI?/? Mice

Background

Intimal injury rapidly activates TGFβ and enhances vascular repair by the growth of endothelial (EC) and vascular smooth muscle cells (VSMC). The response to the TGFβ family of growth factors can be modified by BAMBI (BMP, Activin, Membrane Bound Inhibitor) acting as a non-signaling, competitive antagonist of TGFβ type I receptors such as ALK 1 and 5. In vivo the effect of BAMBI will depend on its cell-specific expression and of that of the ALK type receptors. We recently reported EC restricted BAMBI expression and genetic elimination of BAMBI resulting in an in vitro and in vivo phenotype characterized by endothelial activation and proliferation involving alternative pathway activation by TGFβ through ALK 1.

Methodology/Principal Findings

To test the hypothesis that BAMBI modulates arterial response to injury via its effects on endothelial repair and arterial wall neovascularization we used a model of femoral arterial denudation injury in wild type (WT) and BAMBI^−/− mice. Arterial response was evaluated at 2 and 4 weeks after luminal endothelial denudation of femoral arteries. The BAMBI^−/− genotype mice showed accelerated luminal endothelial repair at 2 weeks and a highly unusual increase in arterial wall neovascularization compared to WT mice. The exuberant intimal and medial neovessel formation with BAMBI^−/− genotype was also associated with significant red blood cell extravasation. The bleeding into the neointima at 2 weeks transiently increased it’s area in the BAMBI^−/−genotype despite the faster luminal endothelial repair in this group. Vascular smooth muscle cells were decreased at 2 weeks in BAMBI^−/− mice, but comparable to wild type at 4 weeks.

Conclusions/Significance

The absence of BAMBI results in a highly unusual surge in arterial wall neovascularization that surprisingly mimiks features of intra-plaque hemorrhage of advanced atheroma in a mechanical injury model. This suggests important effects of BAMBI on arterial EC homeostasis that need to be further studied in a model of inflammatory atherosclerosis.     

Differential processes of vascular smooth muscle cell differentiation within elastic and muscular arteries of rats and rabbits: An immunofluorescence study of desmin and vimentin distribution

Summary Two main populations of smooth muscle cells exist in the arterial media of adult mammals with respect to expression of two intermediate filament proteins: vimentin-positive/desmin-negative cells (V+/D-) and vimentin-positive/desmin-positive ones (V+/D+). However, it is still not understood how this phenotypic diversity is established. Since the proportion and the distribution patterns of the two muscle cell populations depend both on the type of blood vessel and the species examined, the aim of the present study was to determine and to compare their developmental origin in various artery segments from two different species. Using confocal scanning laser microscopy and sections stained by means of immunofluorescence, the distribution patterns of desmin and vimentin were compared in transverse sections of thoracic and abdominal aortas (elastic arteries) and of the femoral artery (muscular artery) of newborn and adult rats (n=12) and rabbits (n=12). The comparison of sections labelled with specific antibodies showed the existence of a subpopulation of smooth muscle cells in the aortas, but not in the femoral artery which expressed desmin in newborns but not in adults. These data suggest that the phenotype of smooth muscle cells in elastic arteries but not in muscular arteries is modulated during development.     

Hypoxia, leukocytes, and the pulmonary circulation.

Data are rapidly accumulating in support of the idea that circulating monocytes and/or mononuclear fibrocytes are recruited to the pulmonary circulation of chronically hypoxic animals and that these cells play an important role in the pulmonary hypertensive process. Hypoxic induction of monocyte chemoattractant protein-1, stromal cell-derived factor-1, vascular endothelial growth factor-A, endothelin-1, and tumor growth factor-beta(1) in pulmonary vessel wall cells, either directly or indirectly via signals from hypoxic lung epithelial cells, may be a critical first step in the recruitment of circulating leukocytes to the pulmonary circulation. In addition, hypoxic stress appears to induce release of increased numbers of monocytic progenitor cells from the bone marrow, and these cells may have upregulated expression of receptors for the chemokines produced by the lung circulation, which thus facilitates their specific recruitment to the pulmonary site. Once present, macrophages/fibrocytes may exert paracrine effects on resident pulmonary vessel wall cells stimulating proliferation, phenotypic modulation, and migration of resident fibroblasts and smooth muscle cells. They may also contribute directly to the remodeling process through increased production of collagen and/or differentiation into myofibroblasts. In addition, they could play a critical role in initiating and/or supporting neovascularization of the pulmonary artery vasa vasorum. The expanded vasa network may then act as a conduit for further delivery of circulating mononuclear cells to the pulmonary arterial wall, creating a feedforward loop of pathological remodeling. Future studies will need to determine the mechanisms that selectively induce leukocyte/fibrocyte recruitment to the lung circulation under hypoxic conditions, their direct role in the remodeling process via production of extracellular matrix and/or differentiation into myofibroblasts, their impact on the phenotype of resident smooth muscle cells and adventitial fibroblasts, and their role in the neovascularization observed in hypoxic pulmonary hypertension.     

Hypoxic remodeling of the rat pulmonary arterial microcirculation assessed by microdissection.

Artery segments were microdissected from distal acini of the rat lung and studied by light and electron microscopy. Morphometric methods were used to quantify the structure of the wall at defined levels within the normal axial pathway and to determine the changes after 5 and 7 days of whole-animal exposure to hypobaric hypoxia at an inspiratory O2 fraction of 0.1. In the normal lung, at the level of the terminal bronchiolus, the artery wall comprised up to six layers of smooth muscle cells (SMCs). At the respiratory bronchiolar level, however, the wall contained fewer than two layers of SMCs with a consistently circumferential orientation. By the second-generation alveolar ducts (AD2), the medial layer was lost, replaced by subendothelial precursor smooth muscle cells (PCs) resembling intermediate cells. At this and the next level (AD3), the PC layer was often circumferentially discontinuous. Regression analysis of the morphometric data suggested, however, that the smallest AD3 artery is likely to have a layer of PCs but with virtually no measurable separation between them and the endothelium. The mean maximum radial diameter of SMCs decreased along the axial pathway with a significant difference between diameters at terminal bronchiolus and AD2 levels; yet the diameter of endothelial cells remained the same. After 7 days of hypoxia, no change was noted in the number of smooth muscle layers, but at the AD2 level the relative area of media in the total wall increased. This was due in part to hypertrophy of PCs, as evidenced by an increase in their mean maximum radial diameter.(ABSTRACT TRUNCATED AT 250 WORDS)     

Three-dimensional cytoarchitecture of the media of arteriovenous anastomoses in the rabbit ear

Arteriovenous anastomoses in the rabbit ear were examined with scanning electron microscopy to elucidate the structural differentiation of the media of the shunt. Arterial, intermediate, and venous segments in the shunt and two layers of the media in the intermediate segment were differentiated based on cell shape and cell organization. In the arterial segment, smooth muscle cells were spindle-shaped, either elongated or short, with a few branches, and were arranged circularly or diagonally with respect to the vessel's long axis. There were also stellate muscle cells with radiating processes. In the intermediate segment, the smooth muscle cells of the outer layer of the media were also arranged circularly and resembled the elongated cells in the arterial segments, but they were more irregular in shape and had more processes than those of the arterial segment. The epithelioid cells of the inner layer of the media were oval or polygonal and oriented irregularly with respect to the vessel's long axis, clustering to form longitudinal plicae. The smooth muscle cells of the venous segment were flat with many lateral processes and formed a thin, discontinuous layer. The smooth muscle cells in the arterial segment and those of the outer layer of the intermediate segment exhibited a highly rugged surface texture, indicating their strong contractility; the epithelioid cells and the smooth muscle cells in the venous segment exhibited a generally smooth surface, indicating less contractility. The intermediate segments were supplied with a dense nerve plexus. The intermediate segments, therefore, may be actively involved in the regulation of blood flow under neuronal influence.     

Presence of specific bradykinin receptors in arterial and venous smooth muscle

The relationship between bradykinin action and its concentration was examined on isolated rings of the rabbit aorta, femoral artery, jugular vein and on isolated strips of the rat portal vein. The sensitivity of femoral artery and portal vein smooth muscles to bradykinin was disclosed. Venous smooth muscles were more sensitive to bradykinin as compared with arterial smooth muscles. Dissociation constants for the rabbit aorta, femoral artery, jugular vein and for the rat portal vein were 3.98 X 10(-6), 6.3 X 10(-6), 1.26 X 10(-7), and 7.6 X 10(-9)M, respectively. Effects of endogenous bradykinin in vivo might result from its primary action on the venous smooth muscle, action on the arterial smooth muscle and veno-arterial interactions.     

外源性硫化氢对家兔内毒素休克诱发肺动脉高压的干预作用

目的:探讨外源性硫化氢(H₂S)对家兔内毒素休克(ES)诱发肺动脉血管反应性的影响。方法:本实验采用家兔经颈静脉注射脂多糖(LPS,8 mg/0.8 ml/kg)复制家兔ES模型,并提前15 min腹腔注射H₂S供体硫氢化钠(NaHS,28μmol/kg)进行干预。随机将新西兰大耳白家兔分为4组(n=8):溶剂对照组、LPS组、LPS+NaHS组和NaHS组。监测平均动脉压(MAP)和平均肺动脉压(MPAP)的变化;应用血管环张力测定技术,检测各组家兔离体肺动脉张力变化;应用光镜和扫描电镜分别观察肺动脉管壁结构及肺动脉内皮细胞超微结构变化。结果:(1)注射LPS后家兔出现MAP降低、MPAP升高,成功复制家兔ES模型;与LPS组相比,LPS+NaHS组家兔MPAP在各个时间点均显著降低(P均﹤0.05);(2)与正常对照组相比,LPS组家兔肺动脉对苯肾上腺素(PE)的收缩反应增强,对乙酰胆碱(ACh)的舒张反应降低(P均﹤0.01);与LPS组相比,LPS+NaHS组家兔肺动脉对PE的收缩反应降低,而对ACh的舒张反应增强(P均﹤0.05)。...     

Ultrastructure of the smooth muscle cells of the femoral artery in rats exposed to vibration

Electron microscopic study of femoral arteries of white rats exposed to prolonged general vibration at a frequency of 100 Hz with an amplitude of 0.5-0.7 mm has been performed. Light and dark smooth muscle cells, as well as unchanged cells have been found in the vascular media of experimental animals. Light cells are swollen with destroyed myofilaments and great number of microtubules in cytoplasm. Dark cells are characterized by coagulation necrosis and melting of myofilaments. Vibration was shown to cause marked structural changes in smooth muscle cells mitochondria: destruction of internal and external membranes, increasing matrix osmophilia or swelling of mitochondria accompanied by crista fragmentation, as well as matrix clarification and disappearance. Morphometric analysis indicates a considerably decreased energy production by smooth muscle cell mitochondria. It has been concluded that vibrations have a damaging effect on medial smooth muscle cells of the femoral artery in the experimental animals.     

Anatomy and Histology of the Cephalic Arterial Coilings in Hammerhead Sharks (Genus Sphyrna)

Hammerhead sharks (genus Sphyrna) show two large arterial coilings in a posteroventral hollow of the orbitary cavity. The posterior is made up of the hyoid artery which, after giving rise to the stapedial artery, enters the chondrocranium to originate the internal carotid and the cerebral arteries. The efferent pseudobranchial artery forms the anterior coiling, gives rise to the ophthalmic artery, enters the orbitary wall and joins the internal carotid artery. The histological sections of the arterial coilings showed the scarcity of smooth muscle cells in the tunica media as well as an important collagenic and elastic component in the arterial wall. Several venous vessels percolate through the coilings. A large amount of small (mean diameter = 73 μm), spheric corpuscles were observed in the connective tissue around the coilings. These corpuscles were also present in the palate and under the skin of the head of these sharks. They are comprised of spirally-arranged cells around a bundle of collagen fibres. We hypothesize that their association with the coilings could suggest some kind of involvement in detecting pressure changes in the blood supply to the head.     

小鼠血管损伤后巨噬细胞与平滑肌细胞的相互作用

目的研究血管损伤后病变形成过程中的巨噬细胞与平滑肌细胞的相互作用。方法C57BL/6（6～8周龄）小鼠24只,右侧股动脉植入透明塑料微导管,制作小鼠血管损伤模型,术后给予特异性抗体AFS98及APB5,分别阻断巨噬细胞和平滑肌细胞增殖的信息传导通路。给药2周后采集股动脉组织,用免疫组织化学的方法对血管病变进行分析。结果小鼠股动脉血管损伤2周后,病变部位聚集了大量的巨噬细胞、平滑肌细胞。给予阻断巨噬细胞增殖的信息传导通路的特异性抗体AFS98后,病变部位的巨噬细胞数量显著减少,平滑肌细胞数量反而增多。相反,给予抑制平滑肌细胞增殖的抗体APB5后,病变局部平滑肌细胞数量减少,而巨噬细胞数量急剧增加。结论小鼠股动脉血管损伤后,构成病变的细胞主要为巨噬细胞与平滑肌细胞。这两种细胞在分化成终末成熟细胞的过程中,存在着相互拮抗的作用。     

The innervation and fine structure of paraneuronic cells in an amphibian pulmonary artery

Summary The pulmonary artery of Bufo marinus contains large numbers of bipolar cells situated in the tunica adventitia and in the outer layers of the media. These cells show a bright green-yellow fluorescence (emission spectra 485 nm) after formaldehyde pre-treatment suggesting that they contain a primary monoamine. The most characteristic fine-structural feature of these cells is the presence of numerous dense-cored vesicles (80—300 nm diameter) in their cytoplasm. The cells are in close contact (20 nm gap) with both agranular and granular nerve fibres. Both EM-cytochemical and formaldehyde-induced fluorescence tests indicate that the granule-containing nerve fibres are adrenergic. The agranular nerve fibres form discrete synaptic contacts with pre-and post-synaptic membrane thickenings on the cells. This was never observed with respect to the adrenergic fibres. Each process of the cells is about 45 m long. The processes do not bear any special relationship to either vessels of the arterial vasa vasorum or medial smooth muscle cells. Their location in the wall of the artery suggests that they are functionally significant with respect to activity of the arterial media.     

Cell contribution of vasa-vasorum to early arterial intimal thickening formation

In occluded femoral artery segments, intimal thickening occurred and abundant neovascularization from the surrounding microcirculation developed. Under these conditions, the contribution of vasa-vasorum as a source of supplementary population of cells during the early intimal thickening formation was studied. Using a technique that specifically labels venules, predominantly postcapillary venules, a marker-Monastral Blue B-was used as a tracer to follow the pericyte, endothelial cell and monocyte/macrophage lineages. In the first two days of the experiment, the marker was restricted to the wall of the periarterial microcirculation, being incorporated by endothelial cells, pericytes and some monocytes/macrophages crossing the venule walls. Later, the marker continues to be observed in some of the following cells: endothelial cells and pericytes of the newly-formed vessels, fibroblast-like cells, transitional cells between pericytes and fibroblast-like cells, macrophages migrating into the interstitium, myointimal cells and neoendothelial cells of the arterial lumen. These findings provide evidence that, during arterial intimal thickening formation in occluded arterial segments, the periarterial microvascularization contributes, in addition to recruited macrophages, newly-formed endothelial cells and a supplementary population of fibroblast-like cells and myointimal cells.