Global ETD Search

201	Impact of Collateral Enlargement on Smooth Muscle Phenotype Bynum, Alexander Jerome 01 December 2011 (has links) (PDF) Peripheral Artery Disease is a very serious disease characterized by an arterial occlusion due to atherosclerotic plaques. In response to an arterial occlusion, arteriogenesis occurs, causing smooth muscle cells to transition from a contractile to synthetic state. Also following an arterial occlusion, functional impairment was seen in the collateral circuit. An immunofluorescence protocol was developed in order to assess the impact of collateral enlargement (arteriogenesis) on smooth muscle phenotype at various time points. Smooth muscle α-actin was used to mark all smooth muscle cells, Ki-67 was used to label proliferating smooth muscle cells, and a fluorescent nuclear stain was used to quantify the number of cells present. Samples of the profunda femoris and gracilis were dissected from each mouse hind limb (one ligated, one sham) at three different time points: 3 days, 7 days, and 14 days after a femoral artery ligation surgery. Smooth muscle cell phenotype and luminal cross-sectional area were assessed in the profunda femoris and the midzone of the gracilis collaterals. Smooth muscle cells were proliferating at 3 and 7 days following the occlusion in the gracilis collaterals and significant collateral vessel growth was observed over the two week period. No proliferation was observed in the profunda femoris and although there was an increasing trend in vessel size over the two week period, the averages were not significantly different. The phenotypic transition of the smooth muscle cells was not the cause of vascular impairment in the collateral circuit. This shows that further research is needed to characterize impairment in the collateral circuit. Vascular Smooth Muscle Cells Arteriogenesis Immunofluorescence Mouse Collateral Circuit Peripheral Artery Disease Cell Biology Cellular and Molecular Physiology Pathogenic Microbiology Structural Biology
202	THE ROLE OF CANONICAL TRANSIENT RECEPTOR POTENTIAL CHANNEL SUBTYPE-6 IN PHENOTYPIC MODULATION OF VASCULAR SMOOTH MUSCLE CELLS AND ARTERIAL HEALING AFTER VASCULAR INTERVENTION Smith, Andrew Hart 26 January 2021 (has links) No description available. Surgery Medicine Molecular Biology
203	Apelin Regulation of K-Cl Cotransport in Vascular Smooth Muscle Cells. Sharma, Neelima 11 June 2014 (has links) No description available. Biomedical Research
204	The Regulation of Vascular Wall Cells by a TLR Ligand and Gp130 Cytokines Schnittker, David L.K. 10 1900 (has links) <p>Atherosclerosis is a disease affecting the blood vessels that is inflammatory in nature, and plays an important role in cardiovascular disease (CVD), one of the leading causes of morbidity and mortality worldwide. Oncostatin M (OSM), a member of the IL-6/gp130 cytokine family, has been implicated in atherosclerosis both in mouse models and in humans. OSM synergizes with other stimuli in various systems to regulate cells. Infectious pathogens as well as danger associated host molecules stimulate members of the innate immune system, including Toll-like Receptors (TLRs), to respond in a pro-inflammatory manner to cause cell activation and cytokine release. Experiments were performed to determine whether OSM and LPS (a TLR-4 ligand) synergize in regulation of vascular wall cells <em>in vitro</em>.</p> <p>Upon stimulation of Aortic Adventitial Fibroblasts from mice (MAAFs) and humans (HAoAFs) as well as Human Aortic Smooth Muscle Cells (HAoSMCs) with LPS in combination with OSM, it was determined that there was a synergistic increase in IL-6 and VEGF levels in the cell supernatants as measured by ELISA compared to either treatment alone. MAAFs were also able to synergistically express KC upon stimulation with LPS and OSM, while in HAoAFs and HAoSMCs, LPS induced IL-8 levels were supressed by OSM. These effects were unique to OSM among gp130 cytokine members, as treatment of these cells with LPS in combination with LIF, IL-6, IL-31, or IL-11 had no marked effects compared to LPS alone. Furthermore, MCP-1 steady state mRNA levels were elevated 6 hours post stimulation with LPS and OSM compared to either treatment alone in HAoAFs and HAoSMCs.</p> <p>While OSM did not appear to modulate TLR-4 expression, OSM treatment resulted in an increased phosphorylation signal in STAT-1,-3, and -5, as well as Akt in MAAFs and HAoAFs. In addition, combined LPS and OSM stimulation resulted in an increased phosphorylation signal of the MAPK p38 compared to either treatment alone. Furthermore, a neutralizing antibody to the OSMr-β was able to inhibit HAoAF IL-6 responses to PBMC conditioned medium. Together, these findings indicate that OSM and LPS can synergize <em>in vitro </em>to induce the expression of inflammatory factors in vascular wall cells, emphasizing the potential role of OSM, TLR-4 ligands, and adventitial fibroblasts in vascular inflammation.</p> / Master of Science (MSc) Oncostatin M Lipopolysaccharide Aortic Adventitial Fibroblasts Aortic Smooth Muscle Cells Toll-like Receptor Interleukin 6.
205	THERAPEUTIC MECHANISMS OF INTERLEUKIN-19 FOR VASCULAR PROLIFERATIVE DISEASES Cuneo, Anthony January 2012 (has links) Cardiovascular disease is the leading cause of mortality in the western world. The pro-inflammatory and pro-proliferative etiology of vascular proliferative diseases is well characterized, while much less is known about the mechanisms of anti-inflammatory and anti-proliferative processes. Interleukin-19 (IL-19) is a newly described member of the IL-10 family of anti-inflammatory interleukins, and our group was the first to discover IL-19 expression in activated, synthetic, but not quiescent, contractile human vascular smooth muscle cells (hVSMC). We also found that IL-19 is anti-inflammatory and anti-proliferative for hVSMC. IL-19 is able to reduce the abundance of COX-2, IL-1β, IL-8, and Cyclin D1 transcripts which contain AU-rich elements (ARE) in their 3'-untranslated regions (3'-UTR). IL-19 is able to reduce the abundance of HuR, a stabilizing RNA-binding protein, which we feel provides a mechanism for these effects. The overall goal of this study is to elucidate IL-19's anti-inflammatory and anti-proliferative mechanism(s) in hVSMC in the context of vascular proliferative diseases. This goal has directed our overall hypothesis: IL-19's anti-proliferative and anti-inflammatory effects in hVSMC are mediated, at least in part, by modulation of HuR abundance and translocation, resulting in decreased stability of mRNA transcripts. HuR functions through a translocation mechanism, and IL-19 is able to reduce HuR cytoplasmic abundance. IL-19 also reduces HuR phosphorylation, which is a pre-requisite for HuR translocation, possibly through a PKCα-dependent mechanism. The stability of ARE-containing transcripts is reduced with IL-19 treatment, and reducing HuR expression by siRNA has the same inhibitory effect. VSMC are important mediators in the initiation of atherosclerosis. Oxidized low-density lipoprotein (ox-LDL) is able to induce IL-19 expression in these cells. VSMC are known to express scavenger receptors that take up ox-LDL. IL-19 is able to reduce the uptake of ox-LDL and the abundance of ox-LDL induced LOX-1 and CX-CL16 scavenger receptors. Interestingly, these scavenger receptors also have ARE in their 3'-UTR. IL-19 is able to reduce ox-LDL induced HuR cytoplasmic abundance. HuR knockdown by siRNA reduces the uptake of ox-LDL by hVSMC. These data suggest that IL-19 reduced scavenger receptor abundance may be due to decreased total and cytoplasmic HuR abundance. IL-19 reduces the abundance of ox-LDL induced COX-2 expression. Taken together, these results demonstrate that IL-19 down-regulates vital steps in vascular proliferative disease processes through an HuR-dependent mechanism. / Molecular and Cellular Physiology Biology, Molecular Biology, General Biology, Cell Atherosclerosis Human Antigen R (hur) Interleukin-19 (il-19) Oxidized Ldl (ox-ldl) Vascular Proliferative Diseases Vascular Smooth Muscle Cells (vsmc)
206	Keratose Hydrogels Promote Vascular Smooth Muscle Differentiation from c-kit+ Human Cardiac Stem Cells: Underlying Mechanism and Therapeutic Potential Ledford, Benjamin 23 March 2018 (has links) Cardiovascular disease is the leading cause of death in the United States, and coronary artery disease (CAD) kills over 370,000 people annually. There are available therapies that offer a temporary solution; however, only a heart transplant can fully resolve heart failure, and donor organ shortages severely limit this therapy. C-kit+ human cardiac stem cells (hCSCs) offers a viable alternative therapy to treat cardiovascular disease by replacing damaged cardiac tissue; however, low cell viability, low retention/engraftment, and uncontrollable in vivo differentiation after transplantation has limited the efficacy of stem cell therapy. Tissue engineering solutions offer potential tools to overcome current limitations of stem cell therapy. Materials derived from natural sources such as keratin from human hair offers innate cellular compatibility, bioactivity, and low immunogenicity. Keratin proteins extracted using oxidative chemistry known as keratose (KOS) have shown therapeutic potential in a wide range of applications including cardiac regeneration. My studies utilize KOS hydrogels to modulate c-kit+ hCSC differentiation, and explore the capability of differentiated cells to regenerate vascular tissue. In the first Chapter, we reviewed literature relevant to keratin-based biomaterials and their biomedical applications, the use of stem cells in cardiovascular research, and the differentiation of vascular smooth muscle cells (VSMCs). The section on biomedical applications of keratin biomaterials focuses on the oxidized form of keratin known as keratose (KOS), because this was the material used for our research. Since we planned to use this material in conjunction with c-kit+ hCSCs, we also briefly explored the use of stem cells in cardiovascular research. Additionally, we examined some key signaling pathways, developmental origins, and the cell phenotype of VSMCs for reasons that will become clear after observing results from chapters 2 and 3. Based upon our review of the literature, KOS biomaterials and c-kit+ hCSCs were determined to be promising as a combined therapeutic for the regeneration of cardiac tissue. Research in Chapter 2 focused on characterizing the effects of KOS hydrogel on c-kit+ hCSC cell viability, proliferation, morphology, and differentiation. Results demonstrated that KOS hydrogels could maintain hCSC viability without any observable toxic effects, but it modulated cell size, proliferation, and differentiation compared to standard tissue culture polystyrene cell culture (TCPS). KOS hydrogel produced gene and protein expression consistent with a VSMC phenotype. Further, we also observed novel "endothelial cell tube-like" microstructures formed by differentiated VSMCs only on KOS hydrogel, suggesting a potential capability of the hCSC-derived VSMCs for in vitro angiogenesis. Results from this study lead us to question what signaling pathways might be responsible for the apparent VSMC differentiation pattern we observed on KOS hydrogels. Research in Chapter 3 explored the time course of VSMC differentiation, cell contractility, inhibition of VSMC differentiation, and measured protein expression of transforming growth factor beta 1 (TGF-β1) and its associated peptides for hCSCs cultured on KOS hydrogels, tissue culture polystyrene, and collagen hydrogels. A review of VSMC differentiation signaling pathways informed our decision to investigate the role of TGF-β1 in VSMC differentiation. Results demonstrated that KOS hydrogel differentiated hCSCs significantly increased expression for all three vascular smooth muscle (VSM) markers compared to TCPS differentiated cells. Additionally, KOS differentiated hCSCs were significantly more contractile than cells differentiated on TCPS. Recombinant human (rh) TGF-β1 was able to induce VSM differentiation on TCPS. VSM differentiation was successfully inhibited using TGF-β NABs and A83-01. Enzyme-Linked Immunosorbent Assay (ELISA) analysis revealed that both TCPS and KOS hydrogel differentiated cells produced TGF-β1, with higher levels being measured at early time points on TCPS and later time points on KOS hydrogels. Results from supplementing rhTGF-β1 to TCPS and KOS hydrogels revealed that KOS seems to interact with TGF-β to a greater extent than TCPS. Western blot results revealed that latency TGFβ binding protein (LTBP-1) and latency associated peptide (LAP) had elevated levels early during differentiation. Further, the levels of LTBP-1 and LAP were higher on KOS differentiated hCSCs than TCPS hCSCs. This study reaffirms previous results of a VSM phenotype observed on KOS hydrogels, and provides convincing evidence for TGF-β1 inducing VSM differentiation on KOS hydrogels. Additionally, results from ELISA and western blot provide evidence that KOS plays a direct role in this pathway via interactions with TGF-β]1 and its associated proteins LTBP-1 and LAP. Results from chapter 2 and 3 offered significant evidence that our cells exhibited a VSMC phenotype, and that TGF-β1 signaling was a key contributor for the observed phenotype, but we still needed an animal model to explore the therapeutic potential of our putative VSMCs. Research in Chapter 4 investigated a disease model to test the ability of KOS hydrogel differentiated cells to regenerate vascular tissue. To measure vascular regenerative capability, we selected a murine model of critical limb ischemia (CLI). CLI was induced in 3 groups (n=15/group) of adult mixed gender NSG mice by excising the femoral artery and vein, and then treated the mice with either PBS (termed as PBS-treated), Cells differentiated on TCPS (termed as Cells from TCPS), or KOS hydrogel-derived VSMCs (termed as Cells from KOS). Blood perfusion of the hind limbs was measured immediately before and after surgery, then 14, and 28 days after surgery using Laser Doppler analysis. Tissue vascularization, cell engraftment, and skeletal muscle regeneration were measured using immunohistochemistry, 1,1'-Dioctadecyl3,3,3',3'-Tetramethylindocarbocyanine Perchlorate (DiL) vessel painting, and hematoxylin and eosin (HandE) pathohistological staining. During the 4-week period, both cell treatment groups showed significant increases in blood perfusion compared to the PBS-treated control, and at day 28 the Cells from KOS group had significantly better blood flow than the Cells from TCPS group. Additionally, the Cells from KOS group demonstrated a significant increase in the ratio of DiL positive vessels, capillary density, and a greater density of small diameter arterioles compared to the PBS-treated group. Further, both cell-treated groups had similar levels of engraftment into the host tissue. We conclude that Cells from KOS therapy increases blood perfusion in an NSG model of CLI, but does not lead to increased cell engraftment compared to other cell based therapies. Overall, the results from this dissertation demonstrated that KOS hydrogels produce VSMC differentiation from c-kit+ hCSCs mediated by TGF-β1 signaling, and that the differentiated cells are able to increase blood perfusion in a CLI model by increasing capillary density, suggesting enhanced angiogenesis. Future studies should explore potential protein-protein interactions between KOS, TGF-β1 and its associated proteins. Additionally, we should plan animal studies that examine the efficacy of our cells to regenerate cardiac tissue following an acute myocardial infarction (AMI). / PHD Keratin/Keratose Biomaterials Human c-kit+ cardiac stem cells Differentiation Vascular smooth muscle cells Hind limb ischemic mouse model Laser Doppler Imaging Blood flow Cardiovascular diseases
207	Die Bedeutung von "Peroxisome Proliferator-Activated Receptors" in der Pathogenese von Gefäßwandläsionen und ihr Einfluß auf die Migration und Proliferation vaskulärer Zellen Götze, Stephan 05 May 2003 (has links) Die Migration und Proliferation vaskulärer Zellen spielt eine entscheidende Rolle in der Pathogenese atherosklerotischer Gefäßwandveränderungen und trägt zudem in hohem Maße zu restenosebedingten Komplikationen interventioneller Therapien der Atherosklerose bei. Dies bedingt ein großes Interesse an pharmakologischen Interventionsmöglichkeiten zur Prävention / Therapie atherosklerotischer und restenotischer vaskulärer Läsionen. Dabei kommen neben lokal applizierbaren Substanzgruppen insbesondere Pharmaka in Betracht, die bereits Anwendung zur Behandlung metabolischer Risikofaktoren kardiovaskulärer Erkrankungen finden. Hierzu gehören insbesondere die oralen Antidiabetika vom Typ der Thiazolidindeone, die als Liganden für den "Peroxisome Proliferator-Activated Receptor gamma" (PPARg) agieren. PPARs sind eine Gruppe neuer Regulatoren der Genexpression, für die in den vergangenen Jahren eine Reihe vaskulärer Wirkungen nachgewiesen wurden. Wir konnten zeigen, daß die Proliferation und Migration von Gefäßmuskelzellen durch PPARg-Liganden gehemmt wird. Untersuchungen zu den beteiligten Signalübertragungsschritten ergaben, daß die pharmakologische Aktivierung von PPARg in Gefäßmuskelzellen insbesondere die durch die Mitogen-aktivierten Protein Kinasen ERK1/2 vermittelte Signaltransduktion beeinflußt. Diesbezüglich haben wir nachgewiesen, daß PPARg in Gefäßmuskelzellen die mitogene Signaltransduktion via ERK1/2 MAPK -> Elk-1 -> c-fos und die chemotaktische Signalübertragung via ERK1/2 MAPK -> Ets-1 -> Matrixmetalloproteinase-9 hemmt. Wir konnten ferner zeigen, daß PPARg-Liganden die Endothelzellmigration hemmen, die durch die Neovaskularisation atherosklerotischer Plaques und der damit verbundenen erhöhten Vulnerabilität einer Plaqueruptur eine Rolle in der Pathobiologie der Atherosklerose spielt. Diese migrationshemmende Wirkung der PPARg-Liganden basiert vermutlich auf einer Inhibition der für die Endothelzellmigration erforderlichen Signaltransduktion über den PI3 Kinase -> Akt -> eNOS Pathway. Die Inhibition dieses Signalwegs könnte die Folge der von uns beobachteten PPARg-Ligand-induzierten Expression der Phosphatase PTEN sein, die den PI3K -> Akt Signalweg negativ reguliert und die Aktivierung und Phosphorylierung von Akt inhibiert. Somit haben PPARg-aktivierende Liganden eine wichtige Funktion in der Behandlung der metabolischen Hauptrisikofaktoren kardiovaskulärer Erkrankungen, spielen aber gleichzeitig eine vermutlich ebenso wichtige Rolle in der Protektion atherosklerotischer und restenosebedingter Gefäßwandveränderungen durch direkte vaskuläre Effekte. / Migration and proliferation of vascular cells not only play an important role in the pathogenesis of atherosclerotic lesion formation, but also contribute to restenosis after therapeutic angioplasty. Therefore, pharmacological strategies for the prevention and/or treatment of atherosclerotic and restenotic vascular lesions are of great clinical interest. This involves substances that can be locally administered via stents, as well as agents that are already in clinical use for the treatment of metabolic risk factors. Among the latter, antidiabetic thiazolidinediones which function as ligands for the "peroxisome proliferator-activated receptor gamma" (PPARg), have been identified as promising drugs to target vascular lesion formation. PPARs constitute a group of novel regulators of gene expression, that exert several vascular effects. We report that vascular smooth muscle cell proliferation and migration is inhibited by PPARg-ligands. Investigating the signalling steps that are involved, we find that pharmacological activation of PPARg interferes with signal transduction through the mitogen-activated protein kinases ERK1/2 in vascular smooth muscle cells. We demonstrate that PPARg inhibits mitogenic signal transduction via ERK1/2 MAPK -> Elk-1 -> c-fos and also blocks chemotactic signalling through the ERK1/2 MAPK -> Ets-1 -> matrix metalloproteinase-9 pathway in vascular smooth muscle cells. We also showed that PPARg-ligands inhibit endothelial cell migration, which participates in the neovascularization of atherosclerotic plaques, thereby contributing to plaque destabilization and increased risk of plaque hemorrhage. This antimigratory action of PPARg-ligands results from an inhibition of signal transduction via PI3 Kinase -> Akt -> eNOS, a pathway that is crucial for endothelial cell migration. Since we observed a PPARg-ligand-induced upregulation of PTEN, a phosphatase that negatively regulates the PI3K -> Akt signalling pathway, this might constitute the mechanism by which PPARg-ligands inhibit endothelial cell migration. In conclusion, PPARg-activating ligands may provide a dual benefit in cardiovascular disease by ameliorating metabolic risk factors, as well as protecting the vasculature from atherosclerotic and restenotic alterations through direct vascular effects. Migration PPARgamma Signaltransduktion Gefäßmuskelzellen migration PPARgamma signal transduction vascular smooth muscle cells 610 Medizin und Gesundheit 33 Medizin XI 4400 ddc:610
208	Antiinflammatorische Zytokine in der Pathogenese des Asthma bronchiale / Untersuchungen an pulmonalen Entzündungszellen und humanen Bronchialmyozyten John, Matthias 21 May 2002 (has links) Die Ergebnisse der Arbeit weisen mehrfach auf eine defizitäre IL-10 Produktion in Alveolarmakrophagen von Asthmatikern hin. Die reduzierte IL-10 Expression auf Protein- und Genebene korrelierte mit einer erhöhten Produktion proinflammatorischer Zytokine (TNF-?, MIP1-?, GM-CSF). Diese Beobachtung impliziert einen Defekt in der IL-10 Synthese, der in einer verstärkten und prolongierten pulmonalen Entzündungsantwort resultiert. Daraus läßt sich schlußfolgern, dass beim Asthma bronchiale eine Dysbalance zwischen pro- und antiinflammatorischen Zytokinen pathogenetisch von Bedeutung ist. Die verringerte Sensitivität von Alveolarmakrophagen auf die inhibitorischen Effekte von exogenem IL-10 im Vergleich zu Blutmonozyten ist durch Unterschiede in den Mechanismen der Signaltransduktion bedingt (37, 54). Der Nachweis der Expression von proinflammatorischen Zytokinen in Bronchialmyozyten (RANTES, IL-8) führte zu einer Neubewertung dieser Zellen als Immuneffektorzellen in der Pathogenese des Asthma bronchiale. Neben der Kontraktilität sind Myozyten auch aktiv an der Aufrechterhaltung der Atemwegsentzündung beteiligt. Die inhibitorischen Effekte von IL-10 und IL-13 auf die Synthese proinflammatorischer Chemokine (RANTES, IL-8, MIP-1() in migrierten Entzündungszellen und residenten Bronchialmyozyten konnten in verschiedenen Arbeiten gut dokumentiert werden. Die Vielzahl antiinflammatorischer Effekte von IL-10, die sich auf unterschiedliche Zellsysteme wie Monozyten, Makrophagen und Bronchialmyozyten erstrecken, unterstreicht die pathogenetische Bedeutung dieses Zytokins. Der molekulare Mechanismus, welcher die IL-10 Wirkung vermittelt, ist derzeit noch nicht vollständig aufgeklärt. Angenommen wird eine rezeptorvermittelte Inhibition von Transkriptionsfaktoren des Stat Systems und NF-(B (76). Zukünftige molekularbiologische und klinische Studien sind jedoch notwendig, um den Kenntnisstand der Effekte antiinflammatorischer Zytokine zu vertiefen, und die Gabe von rekombinantem IL-10 als möglichen Ansatz zur Therapie chronisch entzündlicher Lungenerkrankungen zu evaluieren (81). / The results of this present thesis show a deficiency of IL-10 production in alveolar macrophages in asthma. The reduced IL-10 expression on protein and m-RNA level correlated with an increased production of pro-inflammatory cytokines such as TNF-(, MIP1- ( and GM-CSF. These observations implicate an impaired IL-10 synthesis in asthma with a subsequent prolongation of the inflammatory response. This leads to the conclusion that a dysbalance between pro- and anti-inflammatory cytokines is present in asthma and may be therefore of pathogenetic importance. The reduced sensitivity of alveolar macrophages to the inhibitory effects of exogenous IL-10 compared to peripheral blood monocytes may be caused by different signal transduction mechanisms. The expression of the proinflammatory cytokines RANTES and IL-8 in cultured human airway smooth muscle cells led to the conclusion that airway smooth muscle cells may act beside their contractile function as immunomodulatory cells in the pathogenesis of asthma. The inhibitory effects of IL-10 and IL-13 on the synthesis of proinflammatory cytokines (RANTES, IL-8, MIP1-() in immigrated inflammatory cells and resident cells such as airway smooth muscle cells have been shown in several publications that are part of the present thesis. The numerous antiinflammatory effects of IL-10 on different inflammatory cell systems such as monocytes/macrophages and smooth muscle cells underline the pathogenetic importance of this cytokine. The molecular mechanisms that mediate the IL-10 effects involve the transcription factors NF-(B and the Stat-System. Future studies are needed to determine the molecular mechanisms of the anti-inflammatory effects of IL-10 and IL-13 more deeply and to evaluate their application for the therapy of chronic inflammatory pulmonary diseases. Asthma Zytokine Atemwegsmyozyten Alveolarmakrophagen cytokines asthma airway smooth muscle cells alveolar macrophages 610 Medizin und Gesundheit 33 Medizin YB 6400 ddc:610
209	Histomorphometrische Untersuchungen myokardialer Blutgefäßveränderungen nach Herztransplantation. Hiemann, Nicola 14 December 1998 (has links) Anhand von immunhistochemischen Färbemethoden wurde die Expression von CD 31 (immunhistochemischer Marker für Endothelzellen) und -Aktin (immunhistochemischer Marker für glatte Muskelzellen) auf Zellen der intramyokardialen Blutgefäße herztransplantierter Patienten histomorphometrisch ausgewertet. In die Bewertung der myokardialen Strukturen ging auch die Untersuchung der jeweiligen zugehörigen HE-Färbungen mit ein. Ziel dieser Untersuchungen war die Beurteilung von qualitativen und quantitativen Unterschieden dieser Marker während eines Untersuchungszeitraumes von 14 Monaten nach Herztransplantation (HTx) bei Patienten mit einer angiographisch diagnostizierten Transplantatvaskulopathie (TVP) mit Patienten ohne einer prä- bzw. postmortem diagnostizierten TVP. Der Einsatz dieser Immunomarker richtete sich hierbei auf die selektive Darstellung der terminalen Strombahn mit der Fragestellung, ob ein intramyokardiales morphologisches Korrelat zu der TVP der epikardialen Blutgefäße existiert und ob die histomorphometrische Auswertung der bewerteten Strukturen eine mögliche Frühdiagnose der TVP nach HTx zuläßt. Des weiteren sollte eine mögliche Assoziation der TVP mit den demographischen Charakteristika sowie der Anzahl und dem Schweregrad der Rejektionsepisoden der untersuchten Patienten überprüft werden. Als Basis dienten dabei in Paraffin eingebettete rechtsventrikuläre Rejektionskontrollbiopsien, die im Rahmen der routinemäßig durchgeführten Abstoßungsdiagnostik entnommenen wurden. Nach morphologischer Bewertung dieser Schnitte im Hinblick auf die Existenz und den Schweregrad einer Abstoßungsreaktion wurden diese immunhistochemisch aufbereitet und anschließend quantitativausgewertet. Im Rahmen dieser Arbeit weist die quantitativ- histomorphometrische Erfassung intramyokardialer Blutgefäße in rechtsventrikulären Rejektionskontrollbiopsien auf die mögliche Frühdiagnose einer TVP nach HTx hin. Dieses Verfahren könnte die zur Zeit verwendeten diagnostischen Methoden ergänzen. Jedoch sind noch weitere prospektive klinische Studien für die Validierung dieser Ergebnisse notwendig. / In this study, immunohistochemical and histomorphometric investigations were performed in order to investigate the expression of CD 31 (immunohistochemical marker for endothelial cells) and -Aktin (immunohistochemical marker for smooth muscle cells) on cells of intramyocardial blood vessels in heart transplant (HTx) patients. The evaluation of myocardial structures also implicated the investigation of the corresponding histological H & E stainings. The aim of this study was to ascertain whether HTx patients with angiographic evidence of graft vessel disease (GVD) showed different qualitative and quantitative expression of the above mentioned immunomarkers than HTx patients with no angiopraphic or postmortem signs of this phenomenon. The investigation time included the first 14 months after HTx. The use of these immunomarkers made possible the selective representation of the terminal vascular system to answer the question, as to whether there existed an intramyocardial morphological correlate to GVD of epicardial coronary arteries and whether histomorphometric evaluation of small vessels permits early diagnosis of GVD after HTx. In addition, demographic data, as well the number and grade of rejection episodes of the studied patients, were reviewed in order to ascertain whether there might be an association of these characteristics with GVD. The material studied consisted of paraffin-embedded right ventricular rejection control samples from routine postoperative diagnostic management, which were used to reveal acute rejection episodes. After morphological evaluation of histological slices with regard to the appearence and severity of acute rejection, immunohistochemical staining was performed and finally a quantitative investigation was done. According to the results of this study, quantitative histomorphometric investigations of intramyocardial blood vessels in right ventricular rejection control samples permit the early diagnosis of GVD after HTx and completes the present diagnostic tools. But further prospective clinical studies are necessary to confirm these results. Herztransplantation Transplantatvaskulopathie glatte Muskelzellen Frühdiagnose heart transplantation graft vessel disease smooth muscle cells early diagnosis 610 Medizin und Gesundheit 33 Medizin YI 6536 ddc:610
210	Autoregulation of the Human Cerebrovasculature by Neurovascular Coupling Farr, Hannah Abigail January 2013 (has links) Functional hyperaemia is an important mechanism by which increased neuronal activity is matched by a rapid and regional increase in blood supply. This mechanism is facilitated by a process known as “neurovascular coupling” – the orchestrated communication system involving the cells that comprise the neurovascular unit (neurons, astrocytes and the smooth muscle and endothelial cells lining arterioles). Blood flow regulation and neurovascular coupling are altered in several pathological states including hypertension, diabetes, Alzheimer’s disease, cortical spreading depression and stroke. By adapting and extending other models found in the literature, we create, for the first time, a mathematical model of the entire neurovascular unit that is capable of simulating two separate neurovascular coupling mechanisms: a potassium- and EET-based and a NO-based mechanism. These models successfully account for several observations seen in experiment. The potassium/EET-based mechanism can achieve arteriolar dilations similar in magnitude (3%) to those observed during a 60-second neuronal activation (modelled as a release of potassium and glutamate into the synaptic cleft). This model also successfully emulates the paradoxical experimental finding that vasoconstriction follows vasodilation when the astrocytic calcium concentration (or perivascular potassium concentration) is increased further. We suggest that the interaction of the changing smooth muscle cell membrane potential and the changing potassium-dependent resting potential of the inwardly rectifying potassium channel are responsible for this effect. Furthermore, our simulations demonstrate that the arteriolar behaviour is profoundly affected by depolarization of the astrocytic cell membrane, and by changes in the rate of perivascular potassium clearance or the volume ratio between the perivascular space and astrocyte. In the modelled NO-based neurovascular coupling mechanism, NO exerts its vasodilatory effects via neuronal and endothelial cell sources. With both sources included, the model achieves a 1% dilation due to a 60-second neuronal activation. When the endothelial contribution to NO production is omitted, the arteriole is more constricted at baseline. Without the endothelial NO contribution, the arteriolar change in diameter during neuronal activity is greater (6%). We hypothesize that NO has a dual purpose in neurovascular coupling: 1) it dixxxvi rectly mediates neurovascular coupling through release by neuronal sources, and 2) it indirectly modulates the size of the neurovascular coupling response by determining the baseline tone. Our physiological models of neurovascular coupling have allowed us to replicate, and explain, some of the phenomena seen in both neurovascular coupling-oriented and clinicallyoriented experimental research. This project highlights the fact that physiological modelling can be used as a tool to understand biological processes in a way that physical experiment cannot always do, and most importantly, can help to elucidate the cellular processes that induce or accompany our most debilitating diseases. blood flow regulation neurovascular coupling functional hyperaemia hyperemia vascular autoregulation neurons astrocytes arterioles smooth muscle cells endothelial cells astrocytes EET nitric oxide potassium inwardly rectifying physiological modelling computational modelling

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