The Effects of High Glucose Exposure on Endothelial Microparticles

Turner, Maddison

January 2017

Individuals with diabetes have an increased mortality due to the macro- and microvascular complications, which are commonly preceded by endothelial dysfunction. We have shown that endothelial microparticles (eMPs) are markers and mediators of vascular injury and pathology. However, their utility as a biomarker of hyperglycemia-induced endothelial damage and their influence on the vasculature remains unclear. We hypothesized that high glucose (HG) exposure alters eMPs protein composition, making them reflective of active signalling processes characteristic of a hyperglycemic environment. In addition, HG alters eMPs bioactivity, making them more potent inducers of oxidative stress, thrombosis and endothelial damage. Therefore, we assessed the exclusive effects of HG on eMPs formation, composition, and signalling. Results: Exposure of endothelial cells to high glucose for 24 hours caused a 3-fold increase in eMPs formation, increased mean vesicle size and their absolute electronegativity. Proteomic analysis of eMPs identified 1,212 independent proteins, with 68 exclusive to HG and associated with signalling processes related to metabolic processes, oxidation-reduction reactions, hemostasis and thrombosis and cellular interactions at the vascular wall. Compared to eMPs formed under normal conditions, eMPs formed in response to HG possess a ~3-fold greater procoagulant activity, induced a greater production of cellular ROS and were more potent inhibitors of endothelial-dependent relaxation. Conclusions/Interpretation: Taken together our results indicate HG alters the composition of eMPs, making them more potent mediators of endothelial damage. With similar changes in bioactivity being evident in the protein composition and the associated enriched biological processes, eMPs protein content may provide insight into the pathophysiological status of the cells in a hyperglycemic environment and provide use clinically, to identify dysregulated pathways for therapeutic targeting.

Microparticles

Extracellular Vesicles

High Glucose

Endothelial Dysfunction

The Effects of HIV Infection on Endothelial Function

Chi, D., Henry, J., Kelley, J., Thorpe, R., Smith, J. K., Krishnaswamy, G.

01 January 2000

Endothelial dysfunction and/or injury is pivotal to the development of cardiovascular and inflammatory pathology. Endothelial dysfunction and/or injury has been described in Human Immunodeficiency Virus (HIV) infection. Elaboration of circulating markers of endothelial activation, such as soluble adhesion molecules and procoagulant proteins, occurs in HIV infection. Certain endothelial cells, such as those lining liver sinusoids, human umbilical vein endothelial cells, bone marrow stromal endothelial cells or brain microvascular endothelial cells, have been shown to be variably permissive for HIV infection. Entry of virus into endothelial cells may occur via CD4 antigen or galactosyl-ceramide receptors. Other mechanisms of entry including chemokine receptors have been proposed. Nevertheless, endothelial activation may also occur in HIV infection either by cytokines secreted in response to mononuclear or adventitial cell activation by virus or else by the effects of the secreted HIV-associated proteins, gp 120 (envelope glycoprotein) and Tat (transactivator of viral replication) on endothelium. Enhanced adhesiveness of endothelial cells, endothelial cell proliferation and apoptosis as well as activation of cytokine secretion have all been demonstrated. Synergy between select inflammatory cytokines and viral proteins in inducing endothelial injury has been shown. In HIV infection, dysfunctional or injured endothelial cells potentiate tissue injury, inflammation and remodeling, and accelerate the development of cardiovascular disease.

atherosclerosis

cytokines

endothelial dysfunction

gp120

inflammation

Tat

Associations between affective traits and endothelial function in depressed adults

Berntson, Jessica

January 2018

Indiana University-Purdue University Indianapolis (IUPUI) / Depressed adults are at increased risk of developing atherosclerotic cardiovascular disease (CVD). However, heterogeneity in the depressed population engenders a key question: Are there subgroups of depressed adults at greater risk of developing CVD? Because other affective traits – i.e., anxiety, hostility/anger, and low trait positive affect – have also been associated with increased CVD risk, depressed adults with higher levels of these co-occurring affective traits may have an elevated risk of developing CVD. Consequently, the present study’s first aim was to examine, in depressed adults, which affective traits (depression, anxiety, hostility/anger, or low positive affect) are associated with endothelial function, a marker of cumulative CVD risk. In addition, because the other affective traits overlap with depressive symptom severity, this study’s second aim was to investigate which components of pairs of affective traits (shared versus unique) are related to endothelial function. Finally, given that the mechanisms underlying affective trait-endothelial function relationships in depressed adults are unknown, this study’s third aim was to explore traditional CVD risk status as a candidate mediator of observed relationships. To achieve these aims, I combined pre-treatment, cross-sectional data from three randomized controlled trials involving 138 depressed primary care patients with no history of clinical CVD. Assessments included validated self-report questionnaires for affective traits, brachial artery flow-mediated dilation (FMD) for endothelial function, and 10-year Framingham risk score for traditional CVD risk status. I conducted structural equation modeling (SEM) with confirmatory factor analysis to examine the relationships of interest after adjusting for age, sex, race/ethnicity, education, and baseline arterial diameter. Although the shared variance between each affective trait pair could not be modeled due to poor fit, adequate fitting models revealed that hostility/anger and the unique components of hostility/anger were associated with poorer endothelial function (standardized coefficients = -.18 and -.22, respectively). All of the other affective traits and their components (depression, anxiety, positive affect, unique depression, unique anxiety, and unique positive affect) were not related to endothelial function (all ps > .08). Traditional CVD risk status did not partially explain the relationship between the unique components of hostility/anger and endothelial function (standardized coefficient for the indirect effect = .00; p = .89). If my results are supported by future findings, it would suggest that depressed adults with hostility/anger (a) may be a subgroup of the depressed population at greater risk of developing CVD and (b) may be in need of earlier, more intense, and/or different CVD primary prevention efforts. Future studies are needed to confirm this relationship and identify underlying mechanisms.

depression

affective traits

cardiovascular disease

endothelial dysfunction

Utilizing novel dose equivalence methodologies to examine cocaine's effects on the vasculature

Lamarre, Neil Stanley

January 2013

ABSTRACT: UTILIZING NOVEL DOSE EQUIVALENCE METHODOLOGIES TO EXAMINE COCAINE'S EFFECTS ON THE VASCULATURE Neil S. Lamarre Doctor of Philosophy Temple University School of Medicine, 2013 Doctoral Advisory Committee Chair: Ronald J. Tallarida, Ph.D. Cocaine abuse and addiction is a serious health problem, resulting in thousands of emergency room visits and deaths each year in the United States. It is particularly toxic to the cardiovascular system, including deleterious effects on the peripheral vasculature. These effects are not well understood, but evidence suggests chronic cocaine use may lead to endothelial dysfunction, thereby increasing relative risk of a number of other cardiovascular diseases including stroke, aneurysm, myocardial infarction, hypertension, etc. Data from our lab, and others, suggest that the presence of a functional endothelium has a dramatic effect on the contractility of the rat aorta that is agonist-specific. Attenuation of this endothelium-dependent vasodilatory component of agonist action is a primary feature of endothelial dysfunction. We have utilized dose equivalence theory to calculate the dose response relationship for the endothelium-dependent vasodilatory component of an agonist causing overt vasoconstriction. This component cannot be measured directly, but our novel methodology allows us to quantitate agonist-specific impairment of vasodilation, and describe it using the familiar parameters of the dose response curve. Another strength of this method, relative to currently used in vitro methods, is that it also avoids the confounding variable of a second agonist used to produce the initial vasoconstriction. To validate the methodology, a pilot study was performed examining the endothelial dysfunction in STZ-induced diabetic rats, as a positive control for endothelial dysfunction. Interestingly, this treatment showed impairment in the endothelium-dependent vasodilatory component of action of norepinephrine, but not of angiotensin-II. Thus, our initial hypothesis was confirmed - that disruption of the vasodilatory components of various agonists are independent, and that agonist-specific information may prove useful. Next, we employed our new methodology utilizing the rat aorta as our vascular model to test the hypothesis that chronic cocaine administration causes endothelial dysfunction. We first examined the endothelium-dependent vasodilation component of a number of physiologically important vasoconstrictors, and attempted to determine which vasodilatory mediators contributed to the effect. We found the endothelium to have a profound effect on the dose response curve to three important endogenous agonists. These data suggest that under conditions of endothelial dysfunction exaggerated vasoconstriction could occur, even within normal plasma concentration ranges of these vasoconstrictors, resulting in elevated blood pressure and further damage to the endothelium over time. No endothelial dysfunction was observed with this treatment paradigm, using our methodology or the standard approach. This may be a result of insufficient duration of cocaine treatment, or a result of our selection of the rat aorta as a model. We wanted to further investigate which vasodilatory mechanisms were involved in this vasodilatory component of action. We inhibiting various endothelium-derived mediators of this vasodilatory component of action (such as nitric oxide or prostacyclin), which revealed differential activation of these mediators by the agonists examined. For example, inhibition of nitric oxide synthesis abolished the endothelium-dependent vasodilatory component of endothelin-1, but only partially attenuated that of angiotensin-II. Thus, the agonist-specific pattern of impairment may also prove useful in examining the underlying mechanisms of impaired vasodilation. Endothelial dysfunction is one reported consequence of long term cocaine abuse; however, there are conflicting reports on the acute vascular effects of cocaine, with some reports concluding that cocaine is a vasoconstrictor, and some reporting its action as a vasodilator. There are in vitro reports of cocaine causing release of vasoconstrictors from the endothelium, which supports the longstanding notion of cocaine as a vasoconstrictor. However, one recent report demonstrates a dose-dependent vasodilatory effect of cocaine in rat aorta that is independent of the endothelium. This complexity is perhaps due, in part, to cocaine's affinity for a number of molecular targets, acting in combination. In examining the acute action of cocaine in our preparation, we observed an "inverted-U" shaped dose response, also referred to as a hormetic dose response curve. We then applied dose equivalence methodology in order to derive the "unknown" second component contributing the vasodilatory action of cocaine at higher doses. This methodology lets us calculate this unknown component, and describe it with the familiar parameters of a dose response curve, which could potentially aid in the identification of the unknown component. The preliminary studies with acute cocaine utilized a sub-maximal dose of phenylephrine in order to observe tension changes in either direction. This prompted us to further characterize the interaction of cocaine with other alpha adrenoceptor agonists. Importantly, because cocaine alone had no effect at doses up to 100 µM, but potentiated the vasoconstriction of alpha agonists, the interaction is therefore synergistic. This constitutes evidence of a previously undescribed mechanism contributing to cocaine's vasoconstricting effect. In vivo, reuptake inhibition is a major mechanism for cocaine-induced vasoconstriction, but is excluded in this experiment by virtue of low levels of sympathetic innervation in the rat aorta, and the use of methoxamine, an alpha agonist not subject to the reuptake mechanisms. This interaction may contribute to cocaine-induced vasoconstriction in the coronary arteries, especially in circumstances of endothelial dysfunction. In summary, the work presented in this dissertation applies new methodologies utilizing dose equivalence theory to the study of cocaine's effects on peripheral vasculature, and presents novel findings of synergy with respect to cocaine's enhancement on the action of alpha adrenoceptor-mediated vasoconstriction. / Pharmacology

Pharmacology

Cocaine

Dose Equivalence

Endothelial Dysfunction

Isobole

Einfluss des Multidrug Resistance Protein-1 auf die vaskuläre Funktion im Modell des Streptozotocin-induzierten Diabetes der Maus / Role of multidrug resistance protein-1 on endothelial dysfunction in streptozotocin-induced diabetes

Wick, Matthias Christian

January 2013

Vaskuläre Komplikationen wie Atherosklerose sind bei Diabetikern weit verbreitet. Eine erhöhte Produktion reaktiver Sauerstoffspezies trägt zu einer Dysfunktion des Endothels bei Diabetes und hohen Glukosespiegeln bei. Glutathion (GSH) ist das häufigste zelluläre Thiol und stellt ein bedeutendens Antioxidans des menschlichen Organismus dar. Das Multidrug Resistance Protein 1 (MRP 1) ist im Endothel der Haupttransporter von oxidiertem GSH. Blockiert man MRP 1, so wird unter oxidativem Stress der intrazelluläre GSH-Spiegel erhalten. In dieser Arbeit wird der Einfluss von MRP 1 auf die endotheliale Funktion und Produktion reaktiver Sauerstoffspezies bei Diabetes und erhöhten Glukosespiegeln anhand von MRP 1-/- -Mäusen und Wildtyp-FVB-Tieren untersucht. Acht Wochen nach Injektion von STZ wurde die endothelabhängige Vasorelaxation an den isolierten thorakalen Aorten bestimmt. Diabetische Wildtyp-Tiere wiesen eine signifikant verminderte endothelabhängige Vasorelaxation auf. In MRP 1-/- -Tieren hingegen kam es zu keiner Beeinträchtigung der Endothelfunktion. Die endothelunabhängige Vasorelaxation war nicht signifikant unterschiedlich. STZ-induzierter Diabetes führte zu einer signifikant erhöhten Produktion von Superoxidanionen sowie Wasserstoffperoxid in Wildtyp-Tieren. Diabetische MRP 1-/- -Mäuse hingegen zeigten keinen Anstieg der Produktion reaktiver Sauerstoffspezies. Erhöhte Glukosekonzentrationen führten in vitro in humanen aortalen Endothelzellen ebenso zur erhöhten Superoxidanion-Produktion. In Zellen, in denen MRP 1 mittels siRNA herunterreguliert war, zeigte sich keine Erhöhung von Superoxidanionen. In Wildtyp-Mäusen führte Diabetes zu einer Verminderung des vaskulären GSH-Spiegels, wohingegen bei MRP 1-/- -Tieren keine Veränderung auftrat. Diese Daten weisen auf die wichtige Rolle von MRP 1 bei der unter hohen Glukosekonzentrationen auftretenden endothelialen Dysfunktion hin. MRP 1 stellt somit einen neuen Ansatzpunkt in der Behandlung der durch Diabetes ausgelösten vaskulären Dysfunktion dar. / Vascular complications and atherosclerosis are common in patients with diabetes. An increased production of reactive oxygen species contributes to endothelial dysfunction in diabetes. A major cellular defense against reactive oxygen species is Glutathione. The multidrug resistance associated protein 1 is the main transporter of oxidized glutathione in endothelial cells. Blockade of MRP 1 prevents endothelial cell dysfunction induced by reactive oxygen species. Diabetes was induced in 12 week old male MRP 1-/- mice or corresponding FVB background wildtype mice by injection of streptozotocin. Eight weeks thereafter endothelium-dependent vasorelaxation was blunted in isolated thoracic aortae. In aortae from diabetic mice lacking MRP 1, endothelium-dependent vasorelaxation was only mildly impaired. STZ induced diabetes increased aortic superoxide and hydrogen peroxide production in wildtype animals, while in aortae from MRP 1-/- mice the reactive oxygen species production was nearly unchanged by diabetic conditions. Aortic levels of reduced glutathione were diminished in diabetic FVB. Glutathione levels did not change in diabetic MRP 1-/- mice. These data indicate that MRP 1 plays an important role for endothelial dysfunction and reactive oxygen species production in diabetes and under conditions of high glucose. MRP 1 therefore may represent a therapeutic target in treatment of diabetes induced vascular dysfunction.

Endothelial dysfunction

Glutathion

Reactive Oxygen Species

Diabetes

ddc:610

Is methylglyoxal a causative factor for the pathogenesis of type 2 diabetes mellitus and endothelial dysfunction?

Dhar, Arti

27 September 2010

The number of people having diabetes mellitus is increasing worldwide at an alarming rate. An unbalanced diet rich in carbohydrates and saturated fats, obesity and lack of physical activity, are being blamed. The worldwide prevalence of diabetes for all age-groups has been estimated to be 2.8% in 2000 and projected to be 4.4% by the year 2030. The pathogenesis of diabetes, especially the recent epidemic increase in type 2 diabetes, is still far from clear. Endothelial dysfunction, commonly defined as reduced endothelium-dependent relaxation due to reduced availability of the vasodilator mediator nitric oxide (NO), is a hallmark of diabetes mellitus. Methylglyoxal (MG) is a highly reactive dicarbonyl compound mainly formed as an intermediate during glycolysis. MG is also formed to a lesser extent from protein and amino acid metabolism. However, the relative contribution of various metabolic precursors to MG formation is not known. Levels of MG have been found to be elevated in diabetic and hypertensive conditions but it is not known whether MG is the cause or the effect of these pathological conditions. The aim of my project was (i) to quantify the amount of MG and oxidative stress produced from various substrates in cultured A10 vascular smooth muscle cells (VSMCs), (ii) to investigate the acute in vivo effects of a single dose of MG on glucose tolerance in male Sprague-Dawley (SD) rats, (iii) to investigate the effects of MG on endothelial function and (iv) to investigate the effects, and the underlying molecular mechanisms, of chronic administration of MG on glucose homeostasis in male SD rats. The results show that aminoacetone, a protein metabolism intermediate, is the most potent substrate for MG formation on a molar basis, whereas D-glucose and fructose are equipotent. I also established optimum sample preparation protocols for reproducible measurement of MG in biological samples by high performance liquid chromatography (HPLC). In normal SD rats a single acute dose of MG induced glucose intolerance, reduced adipose tissue glucose uptake and impaired the insulin signalling pathway, which was prevented by the MG scavenger and advanced glycation end product (AGE) breaking compound, alagebrium (ALT-711). MG and high glucose (25 mM) induced endothelial dysfunction in rat aortic rings and cultured endothelial cells by reducing endothelial nitric oxide synthase (eNOS) phosphorylation at Ser-1177, activity and NO production. MG and high glucose also increased oxidative stress and further reduced NO availability in rat aortic rings and cultured endothelial cells. Chronic administration of MG in normal SD rats by continuous infusion with a subcutaneously implanted minipump for 28 days (60 mg/kg/day), induced metabolic and biochemical abnormalities of glucose homeostasis and insulin regulation that are characteristic of type II diabetes. In MG treated rats, insulin stimulated glucose uptake in adipose tissue, and glucose stimulated insulin release from freshly isolated pancreas, were significantly reduced as compared to saline treated control rats. At a molecular level, insulin gene transcription was significantly impaired and apoptosis and DNA fragmentation were more prevalent in the pancreas of MG treated rats as compared to untreated control rats. All of these in vivo effects of MG were attenuated by the MG scavenger, alagebrium. Our data strongly indicate that MG is a causative factor in the pathogenesis of endothelial dysfunction and type 2 diabetes mellitus.

Methylglyoxal

insulin resistance

endothelial dysfunction

type 2 diabetes

Is methylglyoxal a causative factor for the pathogenesis of type 2 diabetes mellitus and endothelial dysfunction?

Dhar, Arti

27 September 2010

The number of people having diabetes mellitus is increasing worldwide at an alarming rate. An unbalanced diet rich in carbohydrates and saturated fats, obesity and lack of physical activity, are being blamed. The worldwide prevalence of diabetes for all age-groups has been estimated to be 2.8% in 2000 and projected to be 4.4% by the year 2030. The pathogenesis of diabetes, especially the recent epidemic increase in type 2 diabetes, is still far from clear. Endothelial dysfunction, commonly defined as reduced endothelium-dependent relaxation due to reduced availability of the vasodilator mediator nitric oxide (NO), is a hallmark of diabetes mellitus. Methylglyoxal (MG) is a highly reactive dicarbonyl compound mainly formed as an intermediate during glycolysis. MG is also formed to a lesser extent from protein and amino acid metabolism. However, the relative contribution of various metabolic precursors to MG formation is not known. Levels of MG have been found to be elevated in diabetic and hypertensive conditions but it is not known whether MG is the cause or the effect of these pathological conditions. The aim of my project was (i) to quantify the amount of MG and oxidative stress produced from various substrates in cultured A10 vascular smooth muscle cells (VSMCs), (ii) to investigate the acute in vivo effects of a single dose of MG on glucose tolerance in male Sprague-Dawley (SD) rats, (iii) to investigate the effects of MG on endothelial function and (iv) to investigate the effects, and the underlying molecular mechanisms, of chronic administration of MG on glucose homeostasis in male SD rats. The results show that aminoacetone, a protein metabolism intermediate, is the most potent substrate for MG formation on a molar basis, whereas D-glucose and fructose are equipotent. I also established optimum sample preparation protocols for reproducible measurement of MG in biological samples by high performance liquid chromatography (HPLC). In normal SD rats a single acute dose of MG induced glucose intolerance, reduced adipose tissue glucose uptake and impaired the insulin signalling pathway, which was prevented by the MG scavenger and advanced glycation end product (AGE) breaking compound, alagebrium (ALT-711). MG and high glucose (25 mM) induced endothelial dysfunction in rat aortic rings and cultured endothelial cells by reducing endothelial nitric oxide synthase (eNOS) phosphorylation at Ser-1177, activity and NO production. MG and high glucose also increased oxidative stress and further reduced NO availability in rat aortic rings and cultured endothelial cells. Chronic administration of MG in normal SD rats by continuous infusion with a subcutaneously implanted minipump for 28 days (60 mg/kg/day), induced metabolic and biochemical abnormalities of glucose homeostasis and insulin regulation that are characteristic of type II diabetes. In MG treated rats, insulin stimulated glucose uptake in adipose tissue, and glucose stimulated insulin release from freshly isolated pancreas, were significantly reduced as compared to saline treated control rats. At a molecular level, insulin gene transcription was significantly impaired and apoptosis and DNA fragmentation were more prevalent in the pancreas of MG treated rats as compared to untreated control rats. All of these in vivo effects of MG were attenuated by the MG scavenger, alagebrium. Our data strongly indicate that MG is a causative factor in the pathogenesis of endothelial dysfunction and type 2 diabetes mellitus.

Methylglyoxal

insulin resistance

endothelial dysfunction

type 2 diabetes

The relationship between glucose metabolism byproduct, D-lactate, and vascular endothelial cell dysfunction and possible role in diabetes

2013 June 1900

Diabetes mellitus is a chronic disease associated with vascular complications. Vascular endothelial dysfunction caused by increased endothelial cell apoptosis contributes to diabetic cardiovascular complications. The glucose metabolic by-product, D-lactate, is elevated in diabetics and it is unknown whether it contributes to endothelial cell apoptosis. We hypothesized that diabetic D-lactate levels induce apoptosis in human vascular endothelial cells (HUV-EC-C). HUV-EC-C were incubated with 0.2 mM D-lactate (DLA) and mRNA expression of PI3K/AKT pathway members (AKT1, Bcl-2, BAD, eNOS, PI3K) were measured using Quantitative RT-PCR. DLA downregulated all genes at 6 and 24 hours, followed by increase in expression after 48 hours except PI3K, which remained below control. To further investigate apoptosis, the Human Apoptosis PCR Array was used and expression of all proapoptotic genes (TNF family members) and antiapoptotic genes (IAP family members) were decreased and increased, respectively, at 24 hours followed by an increase and decrease, respectively, at 48 hours. Caspase activity, measured using the Caspase-Glo® 3/7 Assay after HUV-EC-C exposure to 0.2 mM DLA alone or in combination with 20 mM glucose (GLU) or 5 µM methylglyoxal (MG), was increased after 1, 72, and 96 hours. Furthermore, to know whether DLA (0.2 mM) and DLA (0.2 mM), GLU (20 mM) and MG (5 µM) combined cause changes in cellular energy metabolism, creatine (Cr) and high-energy phosphate substrates (CrP, ATP, ADP, AMP) were quantified using HPLC and no changes were observed. We further measured ROS production in HUV-EC-C treated with 0.06-2 mM DLA alone or 0.2 mM DLA with 5-30 mM GLU or 5-160 μM MG. All DLA concentrations increased ROS production by 160% to 216%. DLA with GLU or MG significantly increased ROS production compared to GLU or MG alone. Lastly, D-lactate dehydrogenase (D-LDH) expression was determined using Quantitative RT-PCR and D-LDH was not detected in HUV-EC-C. In conclusion, DLA altered expression of different pro- and anti-apoptotic genes in HUV-EC-C. Furthermore, exposure of HUV-EC-C to DLA levels typically present in diabetics resulted in time-dependent changes in caspase activity, possibly due to excessive ROS production. Whether these changes eventually lead to endothelial dysfunction in diabetes needs further investigation.

D-lactate

endothelial dysfunction

apoptosis

vascular complications

diabetes

Thermal analysis of vascular reactivity

Deshpande, Chinmay Vishwas

15 May 2009

Cardiovascular disease (CVD) is the leading cause of death in the United States. Analysis of vascular reactivity (VR) in response to brachial artery occlusion is used to estimate arterial health and to determine the likelihood of future cardiovascular complications. Development of a sensitive technique to assess VR is fundamental to the field of preventive cardiology. The conventional technique to study VR is by monitoring arterial diameter changes during hyperemia following occlusion using ultrasound based methods. Such measurements require highly qualified technicians and expensive equipment; and are complicated by signal noise introduced by motion and posture among others. It is well known that tissue temperature changes are a direct response to variations in blood flow, and it has been observed in small clinical studies that variations in fingertip temperature during brachial artery occlusion and subsequent hyperemia is a simple surrogate for the measurement of vascular reactivity and endothelial dysfunction. Given the promising nature of thermal monitoring to study VR, this thesis focuses on the analysis of the underlying physics affecting fingertip temperature during vascular occlusion and subsequent hyperemia. I will quantify the contribution of hemodynamic, anatomical and environmental factors over digit temperature changes, which will serve to determine the sensitivity of the digital thermal monitoring (DTM) technique. I have quantified the effect of several contributing factors to fingertip temperature and DTM results. The aims of this thesis focus on: (1) creation of a mathematical model of heat transfer at baseline, during, and after a reactive hyperemia test; and (2) validation of the model and experimental analysis of thermal and flow parameters in healthy volunteers. The proposed project is an innovative study that intends to show and quantify the relationship between VR and digital thermal reactivity, translating mathematical models based on the physics of heat transfer and fluid mechanics to clinical application. The parametric studies performed with the zeroth order model served to separate the contribution of environment and blood flow over the temperature curves measured during brachial artery occlusion. The thermal models developed were able to reproduce the trend of the temperature response observed experimentally at the fingertip.

Vascular reacitivty

Digital thermal monitoring

Endothelial dysfunction

Reactive hyperemia

Μελέτη της επίδρασης των ουραιμικών τοξινών στην δυσλειτουργία του ενδοθηλίου

Ζαφειρόπουλου, Καλλιόπη

28 July 2008

Στην χρόνια νεφρική ανεπάρκεια, η μειωμένη διήθηση του πλάσματος οδηγεί στην αυξημένη συγκέντρωση τοξινών στο αίμα. Αυτό προκαλεί δυσλειτουργία του ενδοθηλίου, η οποία περιλαμβάνει την φλεγμονή, την αθηροσκλήρωση και τελικά την υπέρταση. Στο πλαίσιο της μελέτης της δράσης των μη διηθούμενων τοξινών, χρησιμοποιήθηκε ορός ασθενών πριν και μετά την αιμοκάθαρση. Ως in vitro σύστημα μελέτης, χρησιμοποιήθηκε πρωτογενής καλλιέργεια ενδοθηλιακών κυττάρων από ομφάλια φλέβα ανθρώπου (HUVEC) και ελέγχθηκε η επίδραση ορού πριν και μετά την αιμοκάθαρση, στον πολλαπλασιασμό, την απόπτωση, την μετανάστευση και την «επούλωση πληγών» των κυττάρων αυτών. Επίσης, μελετήθηκε η έκφραση των μεταλλοπρωτεϊνασών MMP-2 και MMP-9 και των αναστολέων τους TIMP-1 και 2 σε επίπεδο mRNA και πρωτεΐνης καθώς και η έκφραση του κολλαγόνου IV και της ελαστίνης. Χρόνο- και δοσο-εξαρτώμενα πειράματα έδειξαν ότι ο μετά-ορός, σε σχέση με τον προ-ορό, επάγει τον πολλαπλασιασμό, την μετανάστευση και την διαδικασία της «επούλωσης πληγών» των ενδοθηλιακών κυττάρων με στατιστικά σημαντικό τρόπο, ενώ βρέθηκε να μειώνει την απόπτωση. Επίσης βρέθηκε ότι ο προ- ορός, σε σχέση με τον μετά- ορό, επάγει με στατιστικά σημαντικό τρόπο, την έκφραση και ενεργότητα των MMP-2 και MMP-9, ενώ καταστέλλει την έκφραση καθώς και τα επίπεδα των αναστολέων TIMP-1 και TIMP-2. Τέλος καταστέλλει την έκφραση των βασικών συστατικών της εξωκυττάριας ύλης, του κολλαγόνου IV και της ελαστίνης. Συμπερασματικά, ο ορός πριν την αιμοκάθαρση φαίνεται να συμμετέχει στην δυσλειτουργία του ενδοθηλίου, καταστέλλοντας τον πολλαπλασιασμό και την μετανάστευση και επάγοντας ταυτόχρονα την απόπτωση των ενδοθηλιακών κυττάρων. Παράλληλα ο προ-ορός καταστρέφει την εξωκυττάρια ύλη των ενδοθηλιακών κυττάρων επάγοντας τις MMP-2 και -9, καταστέλλοντας τους αναστολείς τους TIMP-1 και -2 και μειώνοντας ταυτόχρονα την έκφραση του κολλαγόνου IV και της ελαστίνης. / In chronic renal disease, reduced glomerular filtration results to increased toxin concentration in blood. This leads, among others, to endothelial dysfunction which concludes inflammation, atherosclerosis and finally hypertension. In this study, in order to investigate the effect of non-filtrated toxins, we used pre-haemodialysis and post-haemodialysis serum (control) from end-stage renal patients. As in vitro system of study we used the primary endothelial cell culture from human umbilical vein (HUVEC) and the effect of pre- and post- haemodialysis serum on cell proliferation, migration, apoptosis and wound healing was investigated. In addition, the expression of matrix metalloproteases MMP-2 and MMP-9 and their inhibitors TIMP-1 and TIMP-2 was examined. Time course and dose-response experiments revealed that pre-serum reduces proliferation, migration and wound healing, while induced apoptosis in a statistically significant manner. Pre-, compared to post-haemodialysis serum, induces the expression and activity of MMP-2 and MMP-9, while inhibits the expression of TIMP-1 and TIMP-2. Concluding, uremic toxins lead to endothelial dysfunction, inhibiting cell proliferation, cell migration and inducing apoptosis. In addition, uremic toxins contribute to the degradation of extracellular matrix, inducing MMP-2 and MMP-9 and inhibiting TIMP-1 and TIMP-2.

Ουραιμία

611.018 7

Endothelial dysfunction

Uremia