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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
61

Der Einfluss von Melatonin auf den nephroprotektiven Effekt von Endothelprogenitorzellen im Mausmodell / The influence of melatonin to the renoprotective effect of endothelial progenitor cells in mouse models

Hildebrandt, Axel 15 August 2012 (has links)
No description available.
62

Modulation de la néovascularisation post-ischémique en présence de facteurs de risque cardiovasculaire

Turgeon, Julie 02 1900 (has links)
L’athérosclérose est la principale cause d’infarctus du myocarde, de mort subite d’origine cardiaque, d’accidents vasculaires cérébraux et d’ischémie des membres inférieurs. Celle-ci cause près de la moitié des décès dans les pays industrialisés. Lorsque les obstructions artérielles athérosclérotiques sont tellement importantes que les techniques de revascularisation directe ne peuvent être effectuées avec succès, la sévérité de l’ischémie tissulaire résiduelle dépendra de l’habilité de l’organisme à développer spontanément de nouveaux vaisseaux sanguins (néovascularisation). La néovascularisation postnatale est le résultat de deux phénomènes : la formation de nouveaux vaisseaux à partir de la vasculature existante (angiogenèse) et la formation de vaisseaux à partir de cellules souches progénitrices (vasculogenèse). Notre laboratoire a démontré que plusieurs facteurs de risque associés aux maladies cardiovasculaires (tabagisme, vieillissement, hypercholestérolémie) diminuaient également la réponse angiogénique suite à une ischémie. Cependant, les mécanismes précis impliqués dans cette physiopathologie sont encore inconnus. Un point commun à tous ces facteurs de risque cardiovasculaire est l’augmentation du stress oxydant. Ainsi, le présent ouvrage visait à élucider l’influence de différents facteurs de risque cardiovasculaire et du stress oxydant sur la néovascularisation. Nos résultats démontrent que l’exposition à la fumée de cigarette et le vieillissement sont associés à une diminution de la néovascularisation en réponse à l’ischémie, et que ceci est au moins en partie causé par une augmentation du stress oxydant. De plus, nous démontrons que les acides gras dérivés de la diète peuvent affecter la réponse à l’ischémie tissulaire. La première étude du projet de recherche visait à évaluer l’impact de l’exposition à la fumée de cigarette sur la néovascularisation post-ischémique, et l’effet d’une thérapie antioxydante. L’exposition à la fumée de cigarette a été associée à une réduction significative de la récupération du flot sanguin et de la densité des vaisseaux dans les muscles ischémiques. Cependant, une récupération complète de la néovascularisation a été démontrée chez les souris exposées à la fumée de cigarette et traitées au probucol ou aux vitamines antioxydantes. Nous avons démontré qu’une thérapie antioxydante administrée aux souris exposées à la fumée de cigarette était associée à une réduction significative des niveaux de stress oxydant dans le plasma et dans les muscles ischémiques. De plus, les cellules endothéliales progénitrices (EPCs) exposées à de l’extrait de fumée de cigarette in vitro présentent une diminution significative de leur activité angiogénique (migration, adhésion et incorporation dans les tissus ischémiques) qui a été complètement récupérée par le probucol et les vitamines antioxydantes. La deuxième étude avait pour but d’investiguer le rôle potentiel de la NADPH oxydase (Nox2) pour la modulation de la néovascularisation post-ischémique dans le contexte du vieillissement. Nous avons trouvé que l’expression de la Nox2 est augmentée par le vieillissement dans les muscles ischémiques des souris contrôles. Ceci est associé à une réduction significative de la récupération du flot sanguin après l’ischémie chez les vieilles souris contrôles comparées aux jeunes. Nous avons aussi démontré que la densité des capillaires et des artérioles est significativement réduite dans les muscles ischémiques des animaux vieillissants alors que les niveaux de stress oxydant sont augmentés. La déficience en Nox2 réduit les niveaux de stress oxydant dans les tissus ischémiques et améliore la récupération du flot sanguin et la densité vasculaire chez les animaux vieillissants. Nous avons aussi démontré que l’activité fonctionnelle des EPCs (migration et adhésion à des cellules endothéliales matures) est significativement diminuée chez les souris vieillissantes comparée aux jeunes. Cependant, la déficience en Nox2 est associée à une récupération de l’activité fonctionnelle des EPCs chez les animaux vieillissants. Nous avons également démontré une augmentation pathologique du stress oxydant dans les EPCs isolées d’animaux vieillissants. Cette augmentation de stress oxydant dans les EPCs n’est pas présente chez les animaux déficients en Nox2. La troisième étude du projet de recherche a investigué l’effet des acides gras dérivés de la diète sur la néovascularisation postnatale. Pour ce faire, les souris ont reçu une diète comprenant 20% d’huile de maïs (riche en oméga-6) ou 20% d’huile de poisson (riche en oméga-3). Nos résultats démontrent qu’une diète riche en oméga-3 améliore la néovascularisation post-ischémique au niveau macro-vasculaire, micro-vasculaire et clinique comparée à une diète riche en oméga-6. Cette augmentation de la néovascularisation postnatale est associée à une réduction du ratio cholestérol total/cholestérol HDL dans le sérum et à une amélioration de la voie VEGF/NO dans les tissus ischémiques. De plus, une diète riche en acides gras oméga-3 est associée à une augmentation du nombre d’EPCs au niveau central (moelle osseuse) et périphérique (rate). Nous démontrons aussi que l’activité fonctionnelle des EPCs (migration et incorporation dans des tubules de cellules endothéliales matures) est améliorée et que le niveau de stress oxydant dans les EPCs est réduit par la diète riche en oméga-3. En conclusion, nos études ont permis de déterminer l’impact de différents facteurs de risque cardiovasculaire (tabagisme et vieillissement) et des acides gras dérivés de la diète (oméga-3) sur la néovascularisation post-ischémique. Nous avons aussi identifié plusieurs mécanismes qui sont impliqués dans cette physiopathologie. Globalement, nos études devraient contribuer à mieux comprendre l’effet du tabagisme, du vieillissement, des oméga-3, et du stress oxydant sur l’évolution des maladies vasculaires ischémiques. / Atherosclerosis is the main cause of myocardial infarction, sudden cardiac death, stroke and lower limb ischemia. It is responsible for nearly half of all deaths in industrialized countries. When atherosclerotic arterial obstructions are so important that direct revascularization techniques cannot be successfully performed, the severity of residual tissue ischemia depends on the ability of the organism to spontaneously develop new blood vessels (neovascularization). Postnatal neovascularization is the result of two phenomena: the formation of new bloods vessels from the existing vasculature (angiogenesis) and vessel formation from progenitor cells (vasculogenesis). Our laboratory has demonstrated that several cardiovascular risk factors (smoking, aging, and hypercholesterolemia) also impair the angiogenic response after ischemia. However, the precise mechanisms involved in that pathophysiology are still unknown. A common feature of all the cardiovascular risk factors is increased oxidative stress. Therefore, the purpose of the present work was to elucidate the influence of cardiovascular risk factors and oxidative stress on neovascularization. Our results demonstrate that exposure to cigarette smoke and aging are associated with impaired neovascularization in response to ischemia, and that this is at least in part due to increased oxidative stress. In addition, we demonstrate that fatty acids derived from the diet can modulate the response to tissue ischemia. The first study of the research project evaluated the effect of cigarette smoke exposure on neovascularization in response to ischemia, and the effect of an antioxidant therapy. Exposure to cigarette smoke was associated with a significant reduction in the recovery of blood flow perfusion and vessel density in ischemic muscles. However, a complete recovery of neovascularization was demonstrated in mice exposed to cigarette smoke that were treated with probucol or antioxidant vitamins. We found that antioxidant therapy in mice exposed to cigarette smoke was associated with a significant reduction of oxidative stress levels in the plasma and in ischemic muscles. In addition, endothelial progenitor cells (EPCs) exposed to cigarette smoke extracts in vitro showed a significant decrease in their angiogenic activities (migration, adhesion and homing into ischemic tissues) that was completely rescued by probucol and antioxidants vitamins. The goal of the second study was to investigate the potential role of NADPH oxidase (Nox2) in the modulation of ischemia-induced neovascularization in the context of aging. We found that the expression of Nox2 is increased by aging in ischemic muscles of control mice. This is associated with a significant reduction of blood flow recovery after ischemia in older compared to young control mice. We also demonstrated that the density of capillaries and arterioles is significantly reduced in ischemic muscles of older animals, whereas oxidative stress levels are increased. Nox-2 deficiency reduces oxidative stress levels in ischemic tissues and improves blood flow recovery and vascular densities in older animals. We also demonstrated that the functional activities of EPCs (migration and adhesion to mature endothelial cells) were significantly reduced in older compared to young mice. However, Nox2 deficiency is associated with preserved EPCs functional activities in older animals. We also demonstrated an age-dependent pathological increase of oxidative stress in EPCs that is not found in Nox2-deficient animals. The third study of the research project investigated the effect of fatty acids derived from the diet on postnatal neovascularization. To this end, mice received a diet containing either 20% corn oil (rich in omega-6) or 20% fish oil (rich in omega-3). Our results demonstrate that an omega-3 rich diet increases neovascularization in response to ischemia at the macrovascular, microvascular and clinical level compared to an omega-6 rich diet. This increased postnatal neovascularization is associated with decreased total cholesterol/HDL cholesterol ratio in the serum and improved VEGF/NO pathway in ischemic tissues. In addition, the omega-3 rich diet is associated with a significant increase of central (bone marrow) and peripheral (spleen) EPCs. We also show that the functional activities of EPCs (migration and incorporation into tubules) are improved and oxidative stress level in EPCs is reduced by the omega-3 rich diet. In conclusion, our studies have clarified the impact of cardiovascular risk factors (smoking and aging) and fatty acids derived from the diet (omega-3) on ischemia-induced neovascularization. We have also identified several mechanisms involved in that physiopathology. Globally, our studies should contribute to a better understanding of the effects of cigarette smoking, aging and omega-3 on the evolution of ischemic vascular diseases.
63

Traditional Chinese Medicine extracts exert angiogenic and protective effects towards human endothelial progenitor cells: from cellular function to molecular pathway

Tang, Yubo 02 July 2014 (has links) (PDF)
Despite intense research efforts, the repair of large bone defects is still not satisfactory and remains a major challenge in Orthopaedic Surgery. In this context bone tissue engineering has emerged as a promising strategy. However, one of the fundamental principles underlying tissue engineering approaches is that newly formed tissue must maintain sufficient vascularization to support its growth. Thus an active blood vessel network is an essential pre-requisite for scaffold constructs to integrate within existing host tissue. Currently, great efforts are made to address this problem employing transplantation of vascular cells and loading of appropriate biological factors. Endothelial progenitor cells (EPCs) are a heterogeneous subpopulation of bone marrow mononuclear progenitor cells with potential for differentiation to the endothelial lineage and thus vasculogenic capacity. However, clinical studies reported that with the increase of age, increased susceptibility to apoptosis and accelerated senescence may contribute to the numerical and functional impairments observed in EPCs, which may lead to a reduced angiogenic capacity and an increased risk of vascular disease. Hence attention has increasingly been paid to enhance mobilization and differentiation of EPCs for therapeutic purposes. A large body of evidence indicates that in Traditional Chinese Medicine (TCM) a plethora of herbs and herbal extracts are effective in the treatment of vascular diseases such as chronic wounds, diabetic retinopathy and rheumatoid arthritis. Thus, it seems rational to explore these medicinal plants as potential sources of novel angiomodulatory factors. In this thesis we demonstrated that treatment with TCM herbal extracts promote cell growth, cell migration, cell-matrix and capillary-like tube formation of BM-EPCs. Among these TCM extracts, Salidroside (SAL) and Icariin (ICAR) incubation increased VEGF and nitric oxide secretion, which in turn mediated the enhancement of angiogenic differentiation of BM-EPCs. A mechanic evaluation provided evidence that SAL stimulates the phosphorylation of Akt, mammalian target of rapamycin (mTOR) and ribosomal protein S6 kinase (p70S6K), as well as phosphorylated ERK1/2, which is associated with the cell migration and tube formation. Furthermore, a pilot in vivo study showed that SAL has the potential to enhance bone formation in a murine femoral critical-size bone defects model. Another new finding of the present study is that hydrogen peroxide (H2O2)-induced cytotoxicity is counteracted by TCM extracts. We found that SAL, Salvianolic acid B (SalB) and ICAR significantly abrogated H2O2-induced cell apoptosis, reduced the intracellular level of reactive oxygen species (ROS) and nicotinamide adenine dinucleotide phosphate-oxidase (NADPH) expression, and restored the mitochondrial membrane potential of BM-EPCs. Our data suggest that this protective effect of SalB is mediated by the activation of mTOR, p70S6K, 4EBP1, and by the suppression of MKK3/6-p38 MAPK-ATF2 and ERK1/2 signaling pathways after H2O2 stress. In addition, the investigation also demonstrates that ICAR owns the ability to inhibit apoptotic and autophagic programmed cell death via restoring the loss of mTOR and attenuation of ATF2 activity upon oxidative stress. Based on the outcomes of the present work, we propose SAL, SalB and ICAR as novel proanigiogenic and cytoprotective therapeutic agents with potential applications in the fields of systemic and site-specific tissue regeneration including ischaemic disease and extended musculoskeletal tissue defects.
64

Desenvolvimento de um substituto nanoestruturado a ser utilizado em associação com células-tronco para a terapia vascular em doença arterial periférica

Braghirolli, Daikelly Iglesias January 2017 (has links)
Atualmente, existe uma grande necessidade médica por enxertos vasculares de pequeno calibre (< 6 mm), que possam ser utilizados em cirurgias de reconstrução vascular. Nesse trabalho, dois tipos de biomateriais vasculares foram desenvolvidos pela técnica de electrospinning: biomateriais de policaprolactona (PCL) e biomateriais de poli(carbonato de trimetileno – co – ácido lático) (PTMCLLA). Os biomateriais de PCL foram funcionalizados com heparina e com VEGF (PCL/Hep/VEGF). Os biomateriais de PTMCLLA foram desenvolvidos a partir de três razões de carbonato de trimetileno/ ácido lático: 20/80, 30/70 e 40/60. Os biomateriais de PCL apresentaram taxa de degradação lenta e alta elasticidade. A funcionalização dos biomateriais preveniu a coagulação do sangue e também favoreceu o crescimento de células-tronco mesenquimais (CTMs) e de células progenitoras endoteliais (CPEs) nessas estruturas. A análise de PCR demonstrou que o VEGF adsorvido aos biomateriais não foi suficiente para diferenciar as CTMs em células endoteliais. O cultivo das CPEs sobre os biomateriais aumentou a expressão de VE-caderina e a presença de VEGF nas estruturas manteve o nível de expressão de CD31 e CD34 nessas células. Após essas análises, os biomateriais de PCL/Hep/VEGF foram fabricados em formato tubular. As CPEs foram semeadas no lúmen do biomaterial, através de biorreatores de parede rotatória (BPR), e mantidas em cultivo, por biorreatores de perfusão (BP). O BPR favoreceu a distribuição homogênea das CPEs na parede luminal dos biomateriais enquanto que o BP estimulou seu crescimento e otimizou seu metabolismo energético. Os biomateriais produzidos a partir dos copolímeros de PTMCLLA 30/70 e 40/60 exibiram uma alta flexibilidade. Porém, os biomateriais de PTMCLLA 40/60 tiveram um grande enrugamento. Os biomateriais de PTMCLLA 30/70 suportaram a adesão e o crescimento de CTMs, de CPEs e de células musculares lisas. Os resultados obtidos no presente estudo demonstram que biomateriais de PCL/Hep/VEGF apresentam características físico-químicas compatíveis para o uso vascular. Ainda, previnem a formação de trombos em sua superfície e propiciam o desenvolvimento da camada endotelial em seu lúmen. Os biomateriais de PTMCLLA 30/70 exibem alta flexibilidade e suportam o desenvolvimento de células vasculares e de células-tronco mesenquimais. De acordo com esses resultados, é possível concluir que biomateriais de PCL/Hep/VEGF e de PTMCLLA 30/70 são candidatos promissores para aplicação como enxertos vasculares. / Currently, there is a great medical need for small caliber vascular grafts (<6 mm), which can be used in vascular replacement surgeries. In this work, two types of vascular biomaterials were developed by the electrospinning technique: biomaterials of polycaprolactone (PCL) and biomaterials of poly(trimethylene carbonate-co-L-lactide) (PTMCLLA). PCL biomaterials were functionalized with heparin and VEGF (PCL / Hep/VEGF). The PTMCLLA biomaterials were developed from three ratios of trimethylene carbonate/lactide: 20/80, 30/70 and 40/60. The PCL biomaterials presented a slow degradation rate and high elasticity. The functionalization of the biomaterials prevented the blood from clotting and also favored the growth of mesenchymal stem cells (MSCs) and endothelial progenitor cells (EPCs) in these structures. PCR analysis demonstrated that VEGF adsorbed by the biomaterials was not sufficient to differentiate the MSCs into endothelial cells. The cultivation of CPEs on the biomaterials increased their expression of VE-cadherin and the presence of VEGF in the structures maintained the cell expression of CD34 and CD31. After these analyzes, the PCL/Hep/VEGF biomaterials were produced in a tubular geometrical form. The CPEs were seeded into their lumen by rotating bioreactors (RB) and maintained in culture by perfusion bioreactors (PB). The RB favored the homogeneous distribution of the CPEs in the luminal wall of the biomaterials while the BP stimulated their growth and optimized their energetic metabolism. The biomaterials produced from the PTMCLLA 30/70 and 40/60 copolymers exhibited high flexibility. However, the PTMCLLA 40/60 biomaterials exhibited substantial wrinkling. The PTMCLLA 30/70 biomaterials supported the adhesion and growth of MSCs, CPEs and smooth muscle cells. This study has demonstrated that PCL/Hep/VEGF biomaterials have physicochemical characteristics compatible with vascular use. Furthermore, they prevent thrombus formation on their surfaces and promote the development of the endothelial layer in their lumen. Biomaterials of PTMCLLA 30/70 exhibit high flexibility and support the development of vascular and mesenchymal stem cells. According to these results, it can be concluded that PCL/Hep/VEGF and PTMCLLA 30/70 biomaterials are promising candidates for use as vascular grafts.
65

Implication de la sérotonine et des récepteurs 5-HT 2A/2B dans le remodelage des valves cardiaques et des bioprothèses valvulaires / Involvement of serotonin and 5-HT2A/2B receptors in cardiac valve and bioprosthetic remodeling

Ayme-Dietrich, Estelle 29 January 2016 (has links)
L’hypothèse d’un lien entre valvulopathies et surexpression du système sérotoninergique fait suite aux lésions valvulaires observées lors de tumeurs carcinoïdes (taux sanguins de 5-HT élevés) et lors de l’utilisation chronique d’agonistes sérotoninergiques 5-HT2 (comme les dérivés de l’ergot de seigle, les fenfluramines). Le dogme actuel repose sur un effet prolifératif de la sérotonine, activant des cellules résidentes valvulaires, mais ne suffit pas à expliquer la dégénérescence de bioprothèses acellulaires. Nos travaux ont permis d’identifier des cellules progénitrices endothéliales (CD34+/CD309+), exprimant les récepteurs 5-HT2A et 5-HT2B, au sein de lésions valvulaires humaines aortiques et mitrales, quelle que soit l’étiologie de leur dégénérescence. Ils ont permis de mettre en évidence un rôle double de la sérotonine dans la dégénérescence valvulaire : 1) la stimulation des récepteurs 5-HT2B contribue à la mobilisation sanguine des progéniteurs CD34+ (recrutés à partir de la moelle osseuse, et migrant dans le tissu valvulaire), 2) le rôle des récepteurs 5-HT2 dans la transdifférenciation des progéniteurs endothéliaux en cellules activées, au sein de la matrice valvulaire. La suite de ce travail permettra de développer 1) un biomarqueur prédictif d’atteinte valvulaire, dans des populations à haut risque, 2) de développer un modèle cellulaire de valvulopathie pour étudier les mécanismes impliqués dans le remodelage valvulaire et leurs voies de signalisation, et 3) de déterminer des cibles thérapeutiques autour du système sérotoninergique, permettant de ralentir la progression des lésions et retarder l’exérèse chirurgicale, seule alternative actuelle.Abstract / Several studies have established an association between some cardiac valve injuries and overexpression of the serotonergic system. Valve lesions are observed following carcinoid tumours (with high blood levels of 5-HT) and during the chronic use of 5-HT2 serotonergic agonists (ergot derivatives or fenfluramines). The current dogma is based on a mitogenic effect of serotonin, by activating 5-HT2B receptors, leading to resident valvular cells proliferation, but does not explain the degeneration of acellular cardiac bioprosthesis. Our work identified endothelial progenitor cells (CD34 + / CD309 +), expressing 5-HT2A and 5-HT2B receptors, in human aortic and mitral valve lesions, regardless of the etiology of their degeneration. Our work highlights the dual role of serotonin in valvular degeneration: 1) stimulation of the 5-HT2B receptor contributes to blood mobilization of CD34+ progenitors (recruited from the bone marrow, and migrating in the valve tissue), 2) the role of 5-HT2 receptors in the transdifferentiation of endothelial progenitor cells in activated valvular cells. The results of this work could drive to the development of 1) a predictive biomarker of cardiac valve injuries in high-risk populations, 2) a model to study heart valve disease cellular and molecular mechanisms, and 3) identify therapeutic targets around the serotonergic system, to slower the progression of the lesions and delay surgical replacement, the only current alternative.
66

Desenvolvimento de um substituto nanoestruturado a ser utilizado em associação com células-tronco para a terapia vascular em doença arterial periférica

Braghirolli, Daikelly Iglesias January 2017 (has links)
Atualmente, existe uma grande necessidade médica por enxertos vasculares de pequeno calibre (< 6 mm), que possam ser utilizados em cirurgias de reconstrução vascular. Nesse trabalho, dois tipos de biomateriais vasculares foram desenvolvidos pela técnica de electrospinning: biomateriais de policaprolactona (PCL) e biomateriais de poli(carbonato de trimetileno – co – ácido lático) (PTMCLLA). Os biomateriais de PCL foram funcionalizados com heparina e com VEGF (PCL/Hep/VEGF). Os biomateriais de PTMCLLA foram desenvolvidos a partir de três razões de carbonato de trimetileno/ ácido lático: 20/80, 30/70 e 40/60. Os biomateriais de PCL apresentaram taxa de degradação lenta e alta elasticidade. A funcionalização dos biomateriais preveniu a coagulação do sangue e também favoreceu o crescimento de células-tronco mesenquimais (CTMs) e de células progenitoras endoteliais (CPEs) nessas estruturas. A análise de PCR demonstrou que o VEGF adsorvido aos biomateriais não foi suficiente para diferenciar as CTMs em células endoteliais. O cultivo das CPEs sobre os biomateriais aumentou a expressão de VE-caderina e a presença de VEGF nas estruturas manteve o nível de expressão de CD31 e CD34 nessas células. Após essas análises, os biomateriais de PCL/Hep/VEGF foram fabricados em formato tubular. As CPEs foram semeadas no lúmen do biomaterial, através de biorreatores de parede rotatória (BPR), e mantidas em cultivo, por biorreatores de perfusão (BP). O BPR favoreceu a distribuição homogênea das CPEs na parede luminal dos biomateriais enquanto que o BP estimulou seu crescimento e otimizou seu metabolismo energético. Os biomateriais produzidos a partir dos copolímeros de PTMCLLA 30/70 e 40/60 exibiram uma alta flexibilidade. Porém, os biomateriais de PTMCLLA 40/60 tiveram um grande enrugamento. Os biomateriais de PTMCLLA 30/70 suportaram a adesão e o crescimento de CTMs, de CPEs e de células musculares lisas. Os resultados obtidos no presente estudo demonstram que biomateriais de PCL/Hep/VEGF apresentam características físico-químicas compatíveis para o uso vascular. Ainda, previnem a formação de trombos em sua superfície e propiciam o desenvolvimento da camada endotelial em seu lúmen. Os biomateriais de PTMCLLA 30/70 exibem alta flexibilidade e suportam o desenvolvimento de células vasculares e de células-tronco mesenquimais. De acordo com esses resultados, é possível concluir que biomateriais de PCL/Hep/VEGF e de PTMCLLA 30/70 são candidatos promissores para aplicação como enxertos vasculares. / Currently, there is a great medical need for small caliber vascular grafts (<6 mm), which can be used in vascular replacement surgeries. In this work, two types of vascular biomaterials were developed by the electrospinning technique: biomaterials of polycaprolactone (PCL) and biomaterials of poly(trimethylene carbonate-co-L-lactide) (PTMCLLA). PCL biomaterials were functionalized with heparin and VEGF (PCL / Hep/VEGF). The PTMCLLA biomaterials were developed from three ratios of trimethylene carbonate/lactide: 20/80, 30/70 and 40/60. The PCL biomaterials presented a slow degradation rate and high elasticity. The functionalization of the biomaterials prevented the blood from clotting and also favored the growth of mesenchymal stem cells (MSCs) and endothelial progenitor cells (EPCs) in these structures. PCR analysis demonstrated that VEGF adsorbed by the biomaterials was not sufficient to differentiate the MSCs into endothelial cells. The cultivation of CPEs on the biomaterials increased their expression of VE-cadherin and the presence of VEGF in the structures maintained the cell expression of CD34 and CD31. After these analyzes, the PCL/Hep/VEGF biomaterials were produced in a tubular geometrical form. The CPEs were seeded into their lumen by rotating bioreactors (RB) and maintained in culture by perfusion bioreactors (PB). The RB favored the homogeneous distribution of the CPEs in the luminal wall of the biomaterials while the BP stimulated their growth and optimized their energetic metabolism. The biomaterials produced from the PTMCLLA 30/70 and 40/60 copolymers exhibited high flexibility. However, the PTMCLLA 40/60 biomaterials exhibited substantial wrinkling. The PTMCLLA 30/70 biomaterials supported the adhesion and growth of MSCs, CPEs and smooth muscle cells. This study has demonstrated that PCL/Hep/VEGF biomaterials have physicochemical characteristics compatible with vascular use. Furthermore, they prevent thrombus formation on their surfaces and promote the development of the endothelial layer in their lumen. Biomaterials of PTMCLLA 30/70 exhibit high flexibility and support the development of vascular and mesenchymal stem cells. According to these results, it can be concluded that PCL/Hep/VEGF and PTMCLLA 30/70 biomaterials are promising candidates for use as vascular grafts.
67

Modulation du potentiel angiogène des progéniteurs endothéliaux humains par des biomarqueurs plasmatiques vasculaires / Angiogenic potential modulation of human endothelial progenitor cells by vascular plasmatic biomarkers

d'Audigier, Clément 02 October 2013 (has links)
Rationnel : L’implication établie des progéniteurs endothéliaux circulants dans les phénomènes de néovascularisation chez l’adulte a stimulé la recherche de thérapeutiques angiogènes basées sur la greffe de ces cellules. Deux types cellulaires au phénotype endothélial sont actuellement définis entre autres par leur cinétique d’apparition en culture : les progéniteurs précoces (CFU-EC ou CAC) et tardifs (ECFC). Notre équipe a montré que l’injection thérapeutique de cellules mononucléées de moelle osseuse (BM-MNC) permettait la néovascularisation du site ischémié chez des patients atteints d’artériopathie des membres inférieurs, et que les néovaisseaux formés avaient le phénotype d’ECFC. Nous avons dans un premier temps mesuré les concentrations de différentes protéines modulant l’angiogenèse, chez des patients atteints de pathologies ischémiques et cardiovasculaires, ou impliquant des anomalies vasculaires associées à la fibrose. Ainsi, le transforming growth factor - β1 (TGF-β1) dans la fibrose pulmonaire idiopathique (FPI), la thrombospondine-1 (TSP-1) dans l’artériopathie des membres inférieurs (AMI), et le placental growth factor (PlGF) chez les patients atteints de pathologies cardiovasculaires [syndrome coronarien aigu (SCA), ou patients devant subir une chirurgie de la valve ou un pontage coronarien], se sont distingués comme potentiel biomarqueur plasmatique dans ces pathologies, et ont été étudiés dans la biologie des ECFC humaines.Résultats : Le taux plasmatique de TGF-β1 est augmenté chez les patients atteints de FPI par rapport à la population contrôle ; il a un effet pro-angiogène in vivo (vascularisation des implants de Matrigel®) et in vitro (prolifération et migration des ECFC) via les récepteurs ALK-1, ALK-5 et TGF-βRII. Le taux plasmatique de TSP-1 est augmenté chez les patients artéritiques par rapport à la population contrôle. Par ailleurs les néovaisseaux formés de patients artéritiques ayant été traités par injection locale de BM-MNC expriment la TSP-1. Dans les modèles murins de Matrigel®-plugs et d’ischémie du membre inférieur (IMI), la TSP-1 induit une diminution de la vascularisation des implants ainsi qu’une diminution de la revascularisation du membre ischémié. In vitro, la TSP-1 augmente l’adhésion via un mécanisme N-Terminal dépendant, et diminue le potentiel angiogène (prolifération et migration) des ECFC via sa liaison au récepteur CD47, ce qui active la voie de signalisation SDF-1/CXCR4. Le taux plasmatique de PlGF est augmenté chez les patients atteints de SCA par rapport à 2 populations contrôles ; il est également augmenté chez les patients ayant subit une chirurgie cardiaque. Les PlGF-1 et -2 potentialisent la tubulogenèse des ECFC in vitro via la phosphorylation du récepteur VEGFR1. Cet effet est aboli lorsque le VEGFR1 est inhibé par ARN interférence ou par le composé chimique « 4321 ». De plus ce composé « 4321 » inhibe la vascularisation des implants de Matrigel®, ainsi que la revascularisation du membre ischémié dans le modèle d’IMI.Conclusions : Le TGF-β1 joue un rôle dans le remodelage vasculaire de la FPI via les ECFC ; la TSP-1 est un potentiel biomarqueur de l’angiogenèse induite par les ECFC dans l’AMI ; l’inhibition de la voie PlGF/VEGFR1 module la tubulogenèse induite par les ECFC, cellules impliquées dans la formation de nouveaux vaisseaux. Nous avons ainsi mis en évidence 3 protéines modulant l’angiogenèse dans 3 contextes pathologiques différents, caractérisés par un remodelage vasculaire et où les ECFC sont impliquées dans leurs mécanismes physiopathologiques. Ces 3 protéines se présentent donc comme de potentiels biomarqueurs plasmatiques, modulant les propriétés angiogènes des ECFC et pouvant influencer leur efficacité en tant que produit de thérapie cellulaire. Ces protéines jouent un rôle probable dans l’équilibre homéostatique au décours des pathologies concernées. / Rationale: The pro-angiogenic capacities of endothelial progenitor cells are now well established, and their involvement in neovascularization events in adults has stimulated the research in the field of angiogenic therapy based on transplant of these cells. Current data converge towards the notion of two cell types with endothelial phenotype, defined at least by their kinetics of appearance in culture: early endothelial progenitor cells (CFU-EC or CAC) and late (ECFC). Our team has shown that the therapeutic injection of bone marrow mononuclear cells (BM-MNC) led to neovascularization of the ischemic site in patients with critical limb ischemia, and that the new vessels formed bore the phenotype of ECFC. We initially measured the concentrations of different proteins modulating angiogenesis in patients with ischemic and cardiovascular diseases, or involving vascular abnormalities associated with fibrosis. Thus, the transforming growth factor - ß1 (TGF-ß1) in idiopathic pulmonary fibrosis, the thrombospondin-1 (TSP-1) in peripheral artery disease, and the placental growth factor (PlGF) in patients with cardiovascular diseases [acute coronary syndrome (ACS), patients undergoing valve surgery or coronary artery bypass surgery], emerged as potential plasmatic biomarkers in these pathological settings, and have been studied in the biology of human ECFC.Results: TGF-ß1 plasma level is increased in patients with idiopathic pulmonary fibrosis (IPF) compared to the control population; it exerts a pro-angiogenic effect in vivo (vascularization of Matrigel ®-plugs) and in vitro (proliferation and migration of ECFC) via ALK-1, ALK-5 and TGF-ßRII receptors. TSP-1 plasma level is increased in patients with peripheral artery disease (PAD) compared to the control population. In addition, the new vessels formed in PAD patients treated by local injection of BM-MNC express TSP-1. In murine models of Matrigel ®-plugs and hindlimb ischemia, TSP-1 induces a decrease in plugs vascularization and impaired revascularization of ischemic limb. In vitro, TSP-1 increases ECFC adhesion via an N-terminal dependent mechanism and reduces their angiogenic potential (proliferation and migration) via its binding to CD47 receptor, which activates the SDF-1/CXCR4 signaling pathway. PlGF plasma level is increased in ACS patients compared with the control population and stable angina patients and is also increased in patients undergoing cardiac surgery. PlGF-1 and -2 potentiate ECFC tubulogenesis in vitro via phosphorylation of the VEGFR1 receptor. This effect was abolished when the ECFC VEGFR1 is inhibited by RNA interference or by the chemical compound "4321". In addition this compound "4321" inhibits the vascularization of Matrigel ®-plugs, and revascularization of the ischemic limb in the hindlimb ischemia model.Conclusions: TGF-ß1 is involved in the IPF vascular remodeling through ECFC; TSP-1 is a potential biomarker of angiogenesis induced by ECFC in PAD; the inhibition of the PlGF/VEGFR1 pathway modulates ECFC tubulogenesis, cells involved in the formation of new vessels. We thus identified three proteins that modulate angiogenesis in three different pathological settings characterized by a vascular remodeling and where ECFC are involved in their pathophysiology. These three proteins therefore state as potential plasmatic biomarkers, modulating ECFC angiogenic properties and are able to influence their efficacy as a cell therapy product. These plasmatic biomarkers likely play a role in the homeostasis of those pathologies progress.
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Traditional Chinese Medicine extracts exert angiogenic and protective effects towards human endothelial progenitor cells: from cellular function to molecular pathway

Tang, Yubo 26 May 2014 (has links)
Despite intense research efforts, the repair of large bone defects is still not satisfactory and remains a major challenge in Orthopaedic Surgery. In this context bone tissue engineering has emerged as a promising strategy. However, one of the fundamental principles underlying tissue engineering approaches is that newly formed tissue must maintain sufficient vascularization to support its growth. Thus an active blood vessel network is an essential pre-requisite for scaffold constructs to integrate within existing host tissue. Currently, great efforts are made to address this problem employing transplantation of vascular cells and loading of appropriate biological factors. Endothelial progenitor cells (EPCs) are a heterogeneous subpopulation of bone marrow mononuclear progenitor cells with potential for differentiation to the endothelial lineage and thus vasculogenic capacity. However, clinical studies reported that with the increase of age, increased susceptibility to apoptosis and accelerated senescence may contribute to the numerical and functional impairments observed in EPCs, which may lead to a reduced angiogenic capacity and an increased risk of vascular disease. Hence attention has increasingly been paid to enhance mobilization and differentiation of EPCs for therapeutic purposes. A large body of evidence indicates that in Traditional Chinese Medicine (TCM) a plethora of herbs and herbal extracts are effective in the treatment of vascular diseases such as chronic wounds, diabetic retinopathy and rheumatoid arthritis. Thus, it seems rational to explore these medicinal plants as potential sources of novel angiomodulatory factors. In this thesis we demonstrated that treatment with TCM herbal extracts promote cell growth, cell migration, cell-matrix and capillary-like tube formation of BM-EPCs. Among these TCM extracts, Salidroside (SAL) and Icariin (ICAR) incubation increased VEGF and nitric oxide secretion, which in turn mediated the enhancement of angiogenic differentiation of BM-EPCs. A mechanic evaluation provided evidence that SAL stimulates the phosphorylation of Akt, mammalian target of rapamycin (mTOR) and ribosomal protein S6 kinase (p70S6K), as well as phosphorylated ERK1/2, which is associated with the cell migration and tube formation. Furthermore, a pilot in vivo study showed that SAL has the potential to enhance bone formation in a murine femoral critical-size bone defects model. Another new finding of the present study is that hydrogen peroxide (H2O2)-induced cytotoxicity is counteracted by TCM extracts. We found that SAL, Salvianolic acid B (SalB) and ICAR significantly abrogated H2O2-induced cell apoptosis, reduced the intracellular level of reactive oxygen species (ROS) and nicotinamide adenine dinucleotide phosphate-oxidase (NADPH) expression, and restored the mitochondrial membrane potential of BM-EPCs. Our data suggest that this protective effect of SalB is mediated by the activation of mTOR, p70S6K, 4EBP1, and by the suppression of MKK3/6-p38 MAPK-ATF2 and ERK1/2 signaling pathways after H2O2 stress. In addition, the investigation also demonstrates that ICAR owns the ability to inhibit apoptotic and autophagic programmed cell death via restoring the loss of mTOR and attenuation of ATF2 activity upon oxidative stress. Based on the outcomes of the present work, we propose SAL, SalB and ICAR as novel proanigiogenic and cytoprotective therapeutic agents with potential applications in the fields of systemic and site-specific tissue regeneration including ischaemic disease and extended musculoskeletal tissue defects.
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Thromboresistant and rapid-endothelialization effects of dopamine and staphylococcal protein A mediated anti-CD34 coating on 316L stainless steel for cardiovascular devices

Chen, Jialong, Li, Quanli, Xu, Jianguang, Zhang, Le, Maitz, Manfred F., Li, Jun 07 January 2020 (has links)
There is convincing evidence in vivo that the vascular homing of endothelial progenitor cells (EPCs) contributes to rapid endothelial regeneration, which could prevent thrombosis and restenosis of cardiovascular devices. To enhance the EPC homing on cardiovascular devices, immobilization of an EPC capture agent (e.g. an anti-CD34 antibody) on the surface of cardiovascular devices is critical. We describe a way of immobilizing anti-CD34 Ab on 316L Stainless Steel (316L SS). For this, surface modification of 316L SS was performed via self-polymerization of dopamine (DA) and covalent grafting of staphylococcal protein A (SPA). On this coating the anti-CD34 Abs were oriented immobilized through their Fc constant region with SPA. In this process, the results of quartz crystal microbalance, X-ray photoelectron spectroscopy and water contact angle studies indicate that DA, SPA and anti-CD34 Ab were successfully immobilized onto the surface step by step. In vitro blood-compatibility tests confirmed that the modified surface induced less pro-coagulant fibrinogen denaturation, less platelet adhesion and lower activation of the adherent platelets. The affinity of EPCs for the modified surface has been demonstrated under flow conditions. This study provides potential applications for cardiovascular implant materials.
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The effect of anti-CD34 antibody orientation control on endothelial progenitor cell capturing cardiovascular devices

Chen, Jialong, Li, Quanli, Li, Jun, Maitz, Manfred F. 11 October 2019 (has links)
Efficient immobilization of the antibody to the substrate is of crucial importance in the development of anti-CD34-based endothelial progenitor cells capturing cardiovascular devices. This should go along with precise control of the antibody orientation by appropriate immobilization technology for retaining antibody activity, like in immunosensors. Recently, great attention was paid to immobilization of anti-CD34 antibody onto substrates by covalent binding, but at random orientation. Here, to investigate the biological effect of antibody orientation, we have prepared two kinds of anti-CD34 antibody coated surfaces, with random immobilization and oriented immobilization. The immunological binding activity (IBA) of the antibody at oriented immobilization was 3.48 times higher than at random immobilization, indicating that the two different surfaces were successfully prepared. The endothelial progenitor cell-capturing capability of oriented antibody-immobilized surface was 1.35 and 1.64 times higher than for the random immobilized surface after seeding for 2 and 12 h under flow condition, respectively. The endothelial progenitor cell-capturing efficiency per antibody by oriented immobilization was 5.16 and 6.26 times higher than for the random after seeding for 2 and 12 h under flow condition, respectively. In addition, the oriented antibody-immobilized surface possessed better blood-compatibility. These results clearly revealed the significance of antibody orientation which could retain its biological effect and may revolutionize the antibody-immobilization protocols used in cardiovascular and other bloodcontacting biomedical devices.

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