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51	Glucose reduces endothelin inhibition of voltage-gated potassium channels in rat arterial smooth muscle cells Rainbow, R.D., Hardy, Matthew E., Standen, N.B., Davies, N.W. 09 1900 (has links) no / Prolonged hyperglycaemia impairs vascular reactivity and inhibits voltage-activated K+ (Kv) channels. We examined acute effects of altering glucose concentration on the activity and inhibition by endothelin-1 (ET-1) of Kv currents of freshly isolated rat arterial myocytes. Peak Kv currents recorded in glucose-free solution were reversibly reduced within 200 s by increasing extracellular glucose to 4 mm. This inhibitory effect of glucose was abolished by protein kinase C inhibitor peptide (PKC-IP), and Kv currents were further reduced in 10 mm glucose. In current-clamped cells, membrane potentials were more negative in 4 than in 10 mm glucose. In 4 mmd-glucose, 10 nm ET-1 decreased peak Kv current amplitude at +60 mV from 23.5 ± 3.3 to 12.1 ± 3.1 pA pF−1 (n = 6, P < 0.001) and increased the rate of inactivation, decreasing the time constant around fourfold. Inhibition by ET-1 was prevented by PKC-IP. When d-glucose was increased to 10 mm, ET-1 no longer inhibited Kv current (n = 6). Glucose metabolism was required for prevention of ET-1 inhibition of Kv currents, since fructose mimicked the effects of d-glucose, while l-glucose, sucrose or mannitol were without effect. Endothelin receptors were still functional in 10 mmd-glucose, since pinacidil-activated ATP-dependent K+ (KATP) currents were reduced by 10 nm ET-1. This inhibition was nearly abolished by PKC-IP, indicating that endothelin receptors could still activate PKC in 10 mmd-glucose. These results indicate that changes in extracellular glucose concentration within the physiological range can reduce Kv current amplitude and can have major effects on Kv channel modulation by vasoconstrictors. Endothelin-1 (ET-1) Arterial smooth muscle cells
52	Role of microRNA-145 in DNA damage signalling and senescence in vascular smooth muscle cells of Type 2 diabetic patients Hemmings, K.E., Riches-Suman, Kirsten, Bailey, M.A., O'Regan, D.J., Turner, N.A., Porter, K.E. 05 May 2021 (has links) Yes / Increased cardiovascular morbidity and mortality in individuals with type 2 diabetes (T2DM) is a significant clinical problem. Despite advancements in achieving good glycaemic control, this patient population remains susceptible to macrovascular complications. We previously discovered that vascular smooth muscle cells (SMC) cultured from T2DM patients exhibit persistent phenotypic aberrancies distinct from those of individuals without a diagnosis of T2DM. Notably, persistently elevated expression levels of microRNA-145 co-exist with characteristics consistent with aging, DNA damage and senescence. We hypothesised that increased expression of microRNA-145 plays a functional role in DNA damage signalling and subsequent cellular senescence specifically in SMC cultured from the vasculature of T2DM patients. In this study, markers of DNA damage and senescence were unambiguously and permanently elevated in native T2DM versus non-diabetic (ND)-SMC. Exposure of ND cells to the DNA-damaging agent etoposide inflicted a senescent phenotype, increased expression of apical kinases of the DNA damage pathway and elevated expression levels of microRNA-145. Overexpression of microRNA-145 in ND-SMC revealed evidence of functional links between them; notably increased secretion of senescence-associated cytokines and chronic activation of stress-activated intracellular signalling pathways, particularly the mitogen-activated protein kinase, p38a. Exposure to conditioned media from microRNA-145 overexpressing cells resulted in chronic p38a signalling in naïve cells, evidencing a paracrine induction and reinforcement of cell senescence. We conclude that targeting of microRNA-145 may provide a route to novel interventions to eliminate DNA-damaged and senescent cells in the vasculature and to this end further detailed studies are warranted. Type 2 diabetes Saphenous vein Smooth muscle cells DNA damage Senescence MicroRNA MicroRNA-145
53	Identifying and targeting the molecular signature of smooth muscle cells undergoing early vascular ageing Richces-Suman, Kirsten, Hussain, Alisah 06 May 2022 (has links) Yes / Early vascular ageing (EVA) is a pathological phenomenon whereby the vascular system ages more quickly than chronological age. This underpins many cardiovascular diseases including the complications of type 2 diabetes, aneurysm formation and hypertension. Smooth muscle cells (SMC) are the principal cell type in the vascular wall and maintain vascular tone. EVA-related phenotypic switching of these cells contributes towards disease progression. EVA is distinct from chronological ageing, and research is ongoing to identify a definitive molecular signature of EVA. This will facilitate the discovery of new clinical tests for early detection of EVA and identify therapeutic targets to halt (or prevent) EVA in SMC, thus reducing macrovascular morbidity and mortality. Smooth muscle cells Phenotype Early vascular ageing Type 2 diabetes Abdominal aortic aneurysm Hypertension
54	Adenosine and Vascular Homeostasis Simard, Trevor 30 May 2023 (has links) Despite advancements in percutaneous coronary intervention, stents are still limited by a 2% annual rate of in-stent restenosis (ISR) related to neointimal (NI) tissue proliferation. Efforts to prevent ISR formation remain the focus of ongoing work. Adenosine (ADO) is a purine nucleoside with integral roles in vascular homeostasis, though it has limited clinical application. ADO signals primarily via four receptors with ADO receptor-A2B (ADOR-A2B) considered to play an integral role in vascular healing. Dipyridamole (DP) is a commercially approved therapy known to improve vascular events and modulate adenosine biology. Our objectives with this study included (i) assessing whether ADO could serve as a biomarker of cardiac events; (ii) determine if DP could mitigate NI formation in a pre-clinical stent model; and, (iii) quantify the mechanisms of DP-related vasculoprotection, specifically related to ADOR-A2B. We assessed the analytic and biologic variability of circulating ADO levels in humans and demonstrated that circulating ADO was not predictive of cardiac events at one year following invasive coronary angiography. We then assessed whether modulation of adenosine biology with DP had therapeutic efficacy in a pre-clinical model. Utilizing meta-analysis, we confirmed the sustained effects of DP on vascular patency rates in both pre-clinical and clinical studies. We refined a pre-clinical rabbit model of stent implantation with assessment of stent healing by intravascular optical coherence tomography – with excellent translation to clinical observations. We then assessed DP in a pre-clinical model, demonstrating reduction in ISR and improved stent healing with DP compared to control. Last, we sought to elucidate the mechanisms behind the observed DP effects, specifically related to ADOR-A2B. In vivo, DP therapy demonstrated reduced NI smooth muscle cell (SMC) content. In vitro assessment of DP demonstrated dose-dependent inhibition of SMC proliferation and migration with alteration of SMC phenotypic switching, while selective modulation of ADOR-A2B and ADOR-A2B knockdown support an ADOR-A2B-mediated component to the observed DP effects. Adenosine biology is integral to vascular homeostasis. In humans, circulating adenosine levels in humans are not predictive of one year cardiovascular events. However, DP may improve vascular healing post stent implantation and warrants clinical evaluation for stent healing. The observed DP benefits may, in part, stem from ADOR-A2B modulation. ADOR-A2B is a viable target for assessment of small molecule modulation as a novel therapeutic target to improve vascular outcomes. adenosine dipyridamole in-stent restenosis optical coherence tomography neointima smooth muscle cells
55	Controlled Delivery of TGF-β1 from PLGA Nanoparticles Vaidya, Pratik K. 14 December 2012 (has links) No description available. Biomedical Engineering Biomedical Research TGF-&946 1 PLGA nanoparticles smooth muscle cells elastogenic induction
56	Engineering poly (ethylene glycol) hydrogels to regulate smooth muscle cell migration and proliferation Lin, Lin 02 September 2014 (has links) No description available. Biomedical Engineering Polymers Smooth muscle cells PEG hydrogels 3D cell migration 3D cell proliferation biomimetic
57	PARACRINE/AUTOCRINE ACTIONS OF INSULIN-LIKE GROWTH FACTOR I (IGF-I) IN TRANSGENIC MICE: EFFECTS OF IGF-I IN BONE AND SMOOTH MUSCLE CELLS IN VIVO Zhao, Guisheng 11 October 2001 (has links) No description available. Insulin-like growth factor I (IGF-I) Paracrine/autocrine action Transgenic mouse Bone Smooth Muscle Cells
58	Evaluation Of Adult Stem Cell Derived Smooth Muscle Cells For Elastic Matrix Regenerative Repair Swaminathan, Ganesh 09 June 2016 (has links) No description available. Biomedical Research Biomedical Engineering Biology
59	Molecular regulation of vascular alpha 2C adrenoceptors Eid, Ali Hussein 22 December 2004 (has links) No description available. ¿¿¿¿2C-AR ¿¿¿¿2C-ARs arteriolar cell estrogen smooth muscle smooth muscle cells
60	OSM Regulation of Responses to TLR-ligands in HASMC Guerette, Jessica 10 1900 (has links) <p>Allergic atopic asthma is a respiratory condition that involves immune responses to specific allergens resulting in coughing, wheezing, shortness of breath and tightness in the chest. During an atopic asthmatic attack, the immune system initiates cellular infiltration of lymphocytes and eosinophils, airway hyper-responsiveness and ECM remodeling, which manifests in lung dysfunction in chronic disease. ASMC have recently been shown to play a role in the inflammatory processes of asthma through the production of inflammatory mediators. Various cytokines and chemokines serve as stimulants for these pathways and therefore require further attention to examine inflammatory signaling. OSM, a member of the gp130 family of cytokines, is secreted by inflammatory cells and has been detected in the sputum of asthmatics. Previous findings have established the potential of OSM in induction of lung inflammation, its role in increasing ECM, and its potential role in asthma. Viral or bacterial infections cause asthma exacerbations which result in increased severity of symptoms. The innate immune system relies on pattern recognition receptors including the TLRs to recognize invading pathogens and activate cells such as macrophages and natural killer cells. Although there are a number of these TLRs, this project will focus on the role of TLR3 and TLR4 in ASMC. I generally hypothesized that OSM markedly increases lung cell airway smooth muscle cell responses to external stimulae, such as products of bacteria or viruses that activate toll-like receptors. This exacerbates inflammation and extracellular matrix remodeling which contributes to pathology in asthmatic patients. Findings in this thesis have demonstrated that OSM stimulation increases the production of various cytokines and chemokines and growth factors seen in asthma. Co-stimulations with OSM and TLR-ligands augmented the production of a variety of these inflammatory mediators in comparison to ligands alone. TLR responses were shown to be associated with TLR expression, at both the mRNA and protein level, as well through the activation of the JAK-STAT and NFκB pathways. These findings implicate ASMC in immunomodulatory roles in response to TLR-ligands and OSM, and could play a role in the increased severity of asthma seen during exacerbations.</p> / Master of Science (MSc) Asthma Oncostatin M Airway Smooth Muscle cells Toll-like Receptors Medical Immunology Medical Immunology

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