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Microvascular Architecture of the Elastase Emphysemic Hamster LungHossler, Fred E., Douglas, John E., Verghese, Abraham, Neal, Larry 01 January 1991 (has links)
Vascular corrosion casts of normal and elastaseinduced emphysemic hamster lungs, prepared with a low viscosity resin mixture consisting of Mercox and Sevriton, were observed by scanning electron microscopy. Casts were quantitated by measuring vascular volume or determining nonalveolar air space using confocal laser scanning microscopy. Normal lung casts were characterized by wellorganized fields of alveoli (about 70m in diameter) connected by distinct alveolar ducts. Emphysemic lung casts exhibited numerous bullae (often as large as 0.5 mm in diameter). The vasculature of the bullae indicated that they were formed by destruction of alveolar walls and subsequent coalescence of numerous alveolae. Remnants of alveolar walls, consisting of shallow ridges of capillaries, lined the bases of the bullae. Vascular volumes expressed as cast volume/total tissue volume were calculated at 20% and 12% for uninflated and inflated lungs, respectively, for both control and emphysemic lungs. Four months after elastase instillation, nonalveolar air space of the emphysemic lungs was increased by 73% over controls. These observations indicate that elastase emphysema results, initially, in remodeling of the alveolar structure (bullae formation) and loss of surface area for gas exchange, rather than from extensive loss of vasculature. Vascular corrosion casting is a useful technique for monitoring emphysema both morphologically and quantitatively.
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Vascular Corrosion Casts of the Spiral Valve Intestine of Siberian Sturgeon (Acipenser baerii), North American Paddlefish (Polyodon spathula) and the Yellow Stingray (Urobatis jamaicensis): A Comparative StudyLash, Jennifer A. 01 December 2013 (has links)
Both Elasmobranchii and Acipenseriformes have a spiral intestine, developed by the intestine folding inward and twisting upon itself. A comparative analysis of the digestive system of examples of Subclass Elasmobranchii (sharks and rays) to Order Acipenseriformes (sturgeon and paddlefish) was conducted through gross dissection and scanning electron microscopy (SEM) analysis. Urobatis jamaicensis, Acipenser baerii, and Polyodon spathula were used due to accessibility. Gross dissection analysis yielded that the acipenserids have a columnar spiral valve with 8 infoldings, and U. jamaicensis has a posterior spiral valve with 13 infoldings. SEM analysis showed angiogenesis, where visible, occurred inversely with age in all species. More venous vessels were present than arterial vessels in the outer layers of the intestine, the muscularis and serosa, while the majority of the arterioles were found in the mucosa and submucosa.
The vascularization pattern of the spiral valve in U. jamaicensis showed a diamond branching pattern on the surface anteriorly and posteriorly with a lateral drainage system at the midsection. Only the lateral drainage system was found in A. baerii and P. spathula. The daughter arterioles and venules to the intraintestinal artery and intraintestinal vein coincided with the turns present in the spiral valve of each species. This study suggests A. baerii and P. spathula are sister taxa and do not share a direct common ancestor with U. jamaicensis based on similarities and differences between the spiral valve vasculature.
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Microvascular Architecture of Mouse Urinary Bladder Described With Vascular Corrosion Casting, Light Microscopy, SEM, and TEMHossler, Fred E., Lametschwandtner, Alois, Kao, Race, Finsterbusch, Friederike 01 December 2013 (has links)
The urinary bladder is a unique organ in that its normal function is storage and release of urine, and vasculature in its wall exhibits specialized features designed to accommodate changes in pressure with emptying and filling. Although we have previously described the fine details of the microvasculature of the urinary bladder of the rabbit and dog, information on the fine details of the microvasculature of the mouse bladder were deemed to be of value because of the increasing use of this species in developing genetic models for studying human disorders. The present study shows that many of the special features of the microvasculature of the mouse urinary bladder are similar to those described in the rabbit and dog, including vessel coiling, abundant collateral circulation, arterial sphincters, and a dense mucosal capillary plexus.
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Microvascular Architecture of Mouse Urinary Bladder Described With Vascular Corrosion Casting, Light Microscopy, SEM, and TEMHossler, Fred E., Lametschwandtner, Alois, Kao, Race, Finsterbusch, Friederike 01 December 2013 (has links)
The urinary bladder is a unique organ in that its normal function is storage and release of urine, and vasculature in its wall exhibits specialized features designed to accommodate changes in pressure with emptying and filling. Although we have previously described the fine details of the microvasculature of the urinary bladder of the rabbit and dog, information on the fine details of the microvasculature of the mouse bladder were deemed to be of value because of the increasing use of this species in developing genetic models for studying human disorders. The present study shows that many of the special features of the microvasculature of the mouse urinary bladder are similar to those described in the rabbit and dog, including vessel coiling, abundant collateral circulation, arterial sphincters, and a dense mucosal capillary plexus.
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Microvasculature of the Urinary Bladder of the Dog: A Study Using Vascular Corrosion CastingHossler, Fred E., Kao, Race L. 01 June 2007 (has links)
The urinary bladder is an unusual organ in that its normal function includes filling and emptying with alternating changes in internal pressure. Although fluctuations in blood flow to the bladder wall are known to accompany these changes, detailed descriptions of the bladder microvasculature are sparse. The present study uses vascular corrosion casting and scanning electron microscopy to describe the three-dimensional anatomy of the microvasculature of the urinary bladder of the dog. Specialized features of that microvasculature, including collateral circulation, vessel folding, vessel orientation, the presence of valves and sphincters, and mucosal capillary density, that may enhance and control blood flow during normal bladder function, are described and discussed.
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Structure and Blood Supply of Intrinsic Lymph Nodes in the Wall of the Rabbit Urinary Bladder - Studies With Light Microscopy, Electron Microscopy, and Vascular Corrosion CastingHossler, Fred E., Monson, Frederick C. 01 November 1998 (has links)
The urinary bladder is especially subject to infection by virtue of its direct connection to the external urethral opening, and it is natural to anticipate the presence of a well-developed immunological mechanism to respond to this potential threat. The present study describes small, very highly vascular lymph nodes located in the wall of the rabbit bladder, which may be involved in a local response to foreign antigens. The vasculature and structure of these lymph nodes was described using a combination of vascular corrosion casting, ink injection, and light and electron microscopy. The distal abdominal aorta was cannulated, and after clearing the bladder vasculature with buffered saline, one of the following procedures was used: 1) the bladder was perfuse-fixed in preparation for light and electron microscopy; 2) the bladder vasculature was filled with India ink for vessel tracing; or 3) vascular corrosion casts of the vasculature were prepared by infusing resin comprised of a mixture of Mercox, methyl methacrylate monomer, and catalyst. The resulting casts were cleaned with KOH, formic acid, and water in preparation for scanning electron microscopy. Vascular casts and India ink injections revealed the presence of a number of isolated capillary tufts consisting of clusters of one to five 'glomeruli,' closely associated with the major vesicular vessels along the lateral walls of the bladder, and supplied by tertiary branches of these vessels. Light and electron microscopy showed that the capillary tufts represented the blood supply to small, ovoid lymph nodes located near the serosal surface of the bladder wall and usually restricted to the basal half of the bladder. These nodes were encapsulated and exhibited subcapsular sinuses, numerous small blood vessels, a limited number of high endothelial cells, and, occasionally, nerves and a follicular substructure. The nodes contained abundant lymphocytes, stellate stromal cells, macrophages, and eosinophils, but lacked the obvious cortical and medullary organization and germinal centers often seen in larger lymph nodes. Vascular corrosion casts, vascular ink injections, and microscopic examination confirmed the presence of small, highly vascular lymph nodes closely associated with the main vesicular vessels along the lateral walls of the rabbit bladder. A follicular substructure of the nodes appears to correspond with the 'glomerular' capillary arrangement within the nodes as seen with corrosion casts. The rich blood supply may be indicative of the high metabolic demand of lymphatic tissue, and may be altered in response to the level of activity of the node. The close association between the lymphatic tissue and the rich blood supply to the nodes may allow a rapid mobilization of lymphocytes during a local immune response to foreign agents.
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Microvasculature of the Rabbit Urinary BladderHossler, Fred E., Monson, Frederick C. 01 January 1995 (has links)
Background: The urinary bladder requires a rich blood supply to maintain its functions, the storage and release of urine. Specialized properties of the bladder vasculature might be anticipated to ensure the integrity of this blood supply, because it is known that blood flow is reduced by distension during bladder filling. However, the bladder vasculature has been described in detail only at the gross level. A comprehensive, threedimensional view of the blood supply to the bladder wall is presented here. Methods: The microvasculature of the bladder of male New Zealand white rabbits was described using the combination of vascular corrosion casting, alkali digestion, light microscopy, and scanning and transmission electron microscopy. Following administration of an anticoagulant and an overdose of anesthetic, the abdominal aorta was cannulated just above the inferior mesenteric artery to permit flushing of the distal vasculature. The bladder vasculature was cleared of blood with buffered saline and then either perfuse‐fixed with buffered 2% glutaraldehyde and sectioned, or filled with “Mercox” resin to prepare vascular corrosion casts. Casts were cleaned with NaOH, formic acid, and water. In some cases fixed bladders were partially digested with NaOH to expose the mucosal capillary plexus. Results: The bladder is supplied with blood by single, left and right vesicular branches of the internal or external iliac arteries. The serpentine vesicular arteries extend along the lateral borders of the bladder from base to apex just deep to the serosal surface and send dorsal and ventral branches to supply the dorsal and ventral bladder walls. Veins accompany the arteries and exhibit numerous valves. A very dense complex of vessels at the apex of the bladder apparently serves to accommodate bladder distension. The muscularis and submucosa contains few vessels, but the mucosa is well vascularized. An especially dense capillary plexus is present in the lamina propria at its junction with the transitional epithelium. In the relaxed bladder these capillaries lie in grooves formed by the basal layers of the epithelium. The endothelial cells of these capillaries display few cytoplasmic vesicles and are continuous or fenestrated. These capillaries are often invested with pericytes. The mucosal capillary plexus may be associated with an epithelial transport function or may be necessary for urothelial metabolism or maintenance of the barrier function of the urothelium. Unusual capillary tufts, possibly associated with vascular lymphatic tissue, are found associated with the main vessels on the lateral walls in the basal half of the bladder. Conclusions: These methods present a clear, comprehensive, three‐dimensional view of the microvasculature of the bladder wall. They also identify several unique features of this vasculature and provide a basis for studies of the response of this vasculature to pathologic states and experimental manipulation.
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Advanced Studies in Veterinary Anatomy: Angiogenesis in Caprine Reproductive Organs of Non-Pregnant and Pregnant Normal and Swainsonine-Treated DoesHafez, Shireen Abdelgawad 22 April 2005 (has links)
The female reproductive organs are among the few adult tissues in which periodic angiogenesis normally occurs. Pathological angiogenesis can occur in various conditions, such as solid tumors. Vascular endothelial growth factor (VEGF) signaling often represents a critical rate-limiting step in physiological and pathological angiogenesis. This study utilizes development of utero-ovarian vasculature during pregnancy in goats as a model of physiological angiogenesis. Non-pregnant does and does at 4, 7, 10, 13, 16, and 18 weeks of gestation were used.
Arteries of the reproductive tract were injected <i>in situ</i> with Microfil®. The tracts were fixed, dehydrated, and rendered transparent to reveal the paths of arteries. The ovarian artery was tortuous and lay in close apposition to the uterine tributary of the ovarian vein in all specimens studied. In non-pregnant does, this arrangement may serve as a local utero-ovarian pathway for the corpus luteum (CL) luteolysis at the end of non-fertile estrous cycle. During pregnancy, this arterio-venous arrangement may transfer luteotropic substances from uterus to ovary, which may serve in maternal recognition of pregnancy and fit the fact that the goat is CL dependent throughout gestation. In some cases of triplets, the size of the uterine branch of the ovarian artery was equal to or even larger than that of its parent artery and/or the ipsilateral uterine artery; and the vaginal artery contributed a connecting branch to the uterine artery. These physiological adaptations of the ovarian and/or vaginal arteries correlate well with the increasing nutrient demands of the growing multiple fetuses.
In a second experiment, the vasculature of the uterus and ovaries was injected <i>in situ</i> with a mixture of Batson's No.17® and methyl methacrylate and then processed for observation by SEM. The microvasculature differed between non-pregnant and pregnant does, and with advancing gestation. We concluded that goats possess a <i>multivillous</i> type placenta. Capillary sinusoids and crypts on the fetal surface of the caruncle may compensate for the negative effect of the increased interhemal distance. Intussusceptive angiogenesis should be considered as equally possible and important mechanism as sprouting angiogenesis during placental development. Capillary diameters increased significantly during pregnancy especially after 4 weeks. Capillary density index was 66.8, 68.7, 55.5, 63.5, 70.1, 70.4, 64.5 percent in non-pregnant, 4, 7, 10, 13, 16, and 18 weeks of pregnancy, respectively. In the ovary, coiling of the ovarian branch of the ovarian artery around the ovarian tributary of the ovarian vein was observed. This may represent a local channel required for product transport from ovarian vein to ovarian artery and might have a role in regulating blood pressure to various ovarian structures.
Immunolocalization of VEGF was performed as a third experiment. Immunostaining was observed in cyto- trophoblasts, maternal epithelial tissues, and vascular endothelium and smooth muscle, but not in binucleate giant cells or connective tissue. No apparent differences were observed in intensity and pattern of VEGF staining associated with advancing gestation. Luteal and follicular cells, and endothelium and smooth muscles of the ovarian vasculature positively stained. Patterns and intensity of staining of VEGF suggest that the fetus is directing its own survival by producing growth factors affecting fetal and maternal tissues. VEGF may have a role in growth and differentiation of cytotrophoblasts, as well as, development and maintenance of CL.
In the fourth experiment, the sequential expression of VEGF and its receptors (fms-like tyrosine kinase, Flt-1 and kinase-insert domain-containing receptor, KDR) was measured using real-time quantitative PCR. Targets were detected in all studied tissues; however, levels of expression differed according to the stage of pregnancy. Expression of VEGF and its receptor mRNAs increased with advancing pregnancy, which correlates with the expansion of vasculature during pregnancy. Differences in the time-courses of the expression of Flt-1 and KDR mRNAs during pregnancy suggest that each receptor plays a different role in the angiogenic process.
As an application of our model of angiogenesis, we tested the effect of swainsonine (active compound of locoweed and a potential anti-cancer drug) on the process. Does treated with swainsonine were euthanized at 7 and 18 weeks. No significant differences were found in sinusoidal diameters in treated does at 7 weeks, but a decrease in capillary density index was noted. In the ovary, focal avascular areas were observed in the corpus luteum of swainsonine-treated does at 7 weeks of pregnancy. Swainsonine caused great distortion in the uterine and ovarian vasculature at 18 weeks. A decrease in intensity of the immunoreactivity to VEGF antibody was observed in tissues from swainsonine-treated does at 7 and 18 weeks. There was no substantial effect of swainsonine on the expression of VEGF and its receptors' mRNAs in any of the studied tissues (except in the left ovary, where it had an inhibitory effect) at 7 weeks of pregnancy, but it had an inhibitory effect at 18 weeks. Demonstration of swainsonine's potential to negatively affect vascular development and suppress genes likely involved in angiogenesis at critical stages of blood vessel proliferation lends credibility to its potential as anti-cancer drug. / Ph. D.
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A comparison of feto-placental vascularity in normal and growth restricted pregnanciesJunaid, Toluwalope Oluwafunmilayo January 2016 (has links)
In human pregnancy, the feto-placental vessels are crucial for efficient materno-fetal transfer; hence they play a pivotal role in the pathogenesis of fetal growth restriction (FGR). We, as well as other research groups, have observed abnormalities in the FGR feto-placental vasculature, which, though inconclusive, were suggestive of a state of panhypovascularity. The goal of the work presented in this thesis was to investigate this. We hypothesised that the placenta may be panhypovascular in FGR due to failed angiogenesis; and enhancing angiogenesis in the placenta may improve fetal growth. Custom-designed techniques including advanced imaging, computer-aided analyses and tube-forming experiments were employed to compare feto-placental vessels and endothelial cells in placentas from normal and FGR-complicated pregnancies while aiming to answer two main research questions: (i) is the FGR placenta panhypovascular? (ii) can angiogenesis be induced or enhanced to improve placental vascularity?Findings include: (i) shorter arterial [p = 0.03 and 0.009 when data adjusted for placental surface area (PA) and weight (PW) respectively] and longer venous path [p = 0.05 and 0.03, adjusted for PA and PW respectively] in FGR placentas though no difference in the total number of arterial or venous branches, diameter, and tortuosity of the vessels compared to normal; (ii) altered angiogenic behaviour/response of FGR placental endothelial cells following in vitro pharmacological manipulation of WNT signalling; (iii) human placental endothelial cells are capable of regaining their angiogenic potential following withdrawal of WNT inhibition. These findings discount the hypothesis of panhypovascularity in FGR placentas, but identify additional, previously unreported, feto-placental vascular abnormalities associated with FGR. Also, the findings provide evidence that impairment of WNT signalling may play a role in defective angiogenesis and consequent dysvascularity in the FGR placenta. The evidence suggests the WNT pathway should be explored as a potential new target for therapeutic interventions to correct placental dysvascularity in FGR.
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Ultrastructure and Blood Supply of the Tegmentum Vasculosum in the Cochlea of the DucklingHossler, Fred E., Olson, Kenneth R., Musil, George, McKamey, Michael I. 17 April 2002 (has links)
The tegmentum vasculosum of the duckling consists of a highly folded epithelium which extends over the dorsal and lateral walls of the cochlear duct, separating the scala media from the scala vestibuli. This epithelium consists of two distinct cell types, dark cells and light cells, and is well vascularized. The surface of the epithelium is formed by a mosaic of alternating dark and light cells. The goblet-shaped dark cells have an electron-dense, organelle-rich cytoplasm, and are expanded basally by extensive basolateral plasma membrane infoldings, within which are numerous mitochondria. Dark cells are isolated from each other and from the capillaries within the epithelium by intervening light cells. In contrast, columnar light cells exhibit an electron-lucent, organelle-poor cytoplasm and may extend from the underlying capillaries to the endolymphatic surface. Light cells contain abundant, coated endocytic vesicles on their apical surfaces and are bound, apically, to other light cells or to dark cells by tight junctions and desmosomes. Laterally, light cells are linked to each other either by complex, fluid-filled membrane interdigitations or by extensive gap junctions. Plasma membrane interdigitations and obvious, fluid-filled intercellular spaces characterize the lateral borders between light and dark cells. Vascular corrosion casting reveals the three-dimensional anatomy of the cochlear vasculature. A continuous arteriolar loop fed by anterior and posterior cochlear arterioles encircles the cochlear duct. The rich capillary beds of the tegmentum vasculosum are supplied by arching arterioles arising from this loop. These capillaries are the continuous type and are situated primarily within the core of the epithelium or along its border with the scala vestibuli. The structure and blood supply of the tegmentum vasculosum are characteristic of an epithelium involved in active transport.
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