Global ETD Search

201	Effet d'un traitement au témozolomide par infusion intra-artérielle avec ou sans ouverture osmotique de la barrière hémato-encéphalique / The effect of a temozolomide treament by intra-arterial infusion with or without osmotic disruption of the blood-brain barrier Drapeau, Annie January 2017 (has links) Le glioblastome (GBM) est la tumeur cérébrale primaire la plus fréquente et agressive chez l’adulte. Son traitement, une exérèse chirurgicale maximale suivi d’un traitement adjuvant (radiothérapie et témozolomide [TMZ]), n’offre qu’un bénéfice modeste de survie médiane (14.6 mois vs. 12.1 mois pour radiothérapie post-chirurgie seule) (STUPP et al., 2005). Le TMZ demeure l’agent de choix pour le traitement du GBM. Malgré sa biodisponibilité approchant 100% suivant son administration per os (PO) (Diez et al., 2009), sa pénétration dans le liquide céphalorachidien n’est que de 20% (Ostermann et al., 2004). Ainsi, il se peut que les limites thérapeutiques du TMZ soient reliées aux barrières hémato-encéphalique (BHE) et hémato-tumorale (BHT). Plusieurs stratégies alternatives tentent de contourner ces barrières comme l’administration intra-artérielle (IA) avec une ouverture osmotique de la BHE (OBHE). Cette technique permet une plus grande distribution d’agent thérapeutique au système nerveux central (SNC). L’utilisation de cette stratégie avec le témozolomide n’a jamais été étudiée à ce jour. Nous avons émis l’hypothèse que son utilisation permettra d’augmenter la concentration de TMZ dans le SNC et que, lorsque combiné avec la radiothérapie, permettra de rehausser son activité anti-tumorale. Les objectifs du projet sont : (1) l’évaluation de la sensibilité des cellules F98 au TMZ in vitro; (2) la caractérisation de la neuropharmacocinétique du TMZ in vivo, selon différents modes d’administration; et (3) l’évaluation de l’effet anti-tumoral du TMZ in vivo, selon différents modes d’administration. Les expérimentations in vivo ont été exécutées dans le modèle syngénique Fischer-F98, porteur de tumeur gliale. L’expérimentation in vitro a démontré une résistance importante des cellules F98 au TMZ. La méthodologie développée a permis de démontrer que l’infusion IA avec et sans OBHE augmente la concentration maximale et l’aire sous la courbe du TMZ dans la tumeur cérébrale et dans le parenchyme cérébral ipsilatéral du rat Fischer-F98. Par contre, aucun bénéfice de survie n’a été observé en utilisant ces stratégies alternatives. Au contraire, l’acheminement augmenté du TMZ au SNC semble toxique. Un bénéfice de survie a été mesuré suite à l’ajout d’un traitement de radiothérapie, mais de façon indépendante au mode de livraison de TMZ ou de solution saline normale (groupe contrôle). Enfin, nos résultats témoignent de l’impact du mode d’acheminement sur la distribution d’un agent thérapeutique au SNC. En détournant la BHE, l’utilisation judicieuse d’approches alternatives combinée à un agent thérapeutique approprié a un grand potentiel clinique dans le traitement des GBM. / Abstract : Glioblastoma (GBM) is the most frequent and aggressive primary brain tumor in adults. Its’ standard treatment, maximal surgical resection followed by an adjuvant treatment (radiotherapy and temozolomide [TMZ]) offers only a modest median survival benefit of 14.6 months (vs. 12.1 months with post-surgery radiotherapy alone) (Stupp et al., 2005). TMZ remains the therapeutic agent of choice for the treatment of GBM. Despite its bioavailability approaching 100% after a per os administration (Diez et al., 2009), its cerebrospinal fluid penetration is only of 20% (Ostermann et al., 2004). Thus, TMZ’s therapeutic limitations could be due to the blood-brain barrier (BBB) and blood-tumor barrier (BTB). Alternative routes of drug delivery attempt to bypass these barriers. For example, intra-arterial (IA) administration with an osmotic blood-brain barrier disruption (OBBBD) allows greater drug distribution to the central nervous system (CNS). Its use with TMZ, with or without radiotherapy, has never been studied. We hypothesized that it will increase TMZ concentration in the CNS and that, when combined to radiotherapy, it will intensify its anti-neoplastic activity. The project was divided in three parts: (1) the evaluation of F98 cells’ in vitro sensitivity to TMZ; (2) the in vivo caracterization of TMZ’s neuropharmacokinetics, following different routes of administration; and (3) the in vivo evaluation of TMZ’s anti-tumoral effect, following different routes of administration. The syngenic glioma Fischer-F98 model was used in all in vivo experiments. Our results showed the F98 cells to be resistant to TMZ in vitro. The methodology developed showed that an IA infusion with and without OBBBD increased TMZ’s peak concentration and area under the curve in the brain tumor and ipsilateral brain parenchyma in the Fischer-F98 rat. All the while limiting systemic exposure. However, no survival benefit was observed with the use of these alternative strategies. More so, TMZ’s enhanced delivery to the CNS seemed toxic. A survival benefit was measured following the addition of radiotherapy. This was independent of the route of delivery of TMZ or normal saline. In summary, our results provide evidence that the method of TMZ administration does impact its CNS delivery. By bypassing the BBB, the judicious use of local delivery approaches combined with the appropriate therapeutic agent can have a great clinical potential in the treatment of glioblastomas. Barrière hémato-encéphalique Chimiothérapie intra-artérielle Culture cellulaire Glioblastome Modèle animal Spectrométrie de masse Témozolomide Glioblastoma Blood-brain barrier Intra-arterial chemotherapy Cell culture Animal model Osmotic blood-brain barrier disruption Mass spectrometry Temozolomide
202	MULTIFACTORIAL MODULATION OF THE BLOOD-BRAIN BARRIER: RELATIONSHIP TO STROKE Zhang, Bei 01 January 2013 (has links) The blood-brain barrier (BBB) is a dynamic interface, mainly consisting of highly specialized brain microvascular endothelial cells (BMECs) that segregate the central nervous system (CNS) from the peripheral circulation. Impairment of the BBB, due to disruption of tight junction (TJ) proteins and inflammatory responses, may initiate and/or contribute to the progress of CNS disorders, including stroke. Stroke is the second leading cause of death worldwide. It has been shown that aging and environmental pollutants can induce brain endothelium dysfunction, and are considered as risk factors for stroke. Deficiency of telomerase is highly linked with aging-associated vascular diseases. Evidence indicates that patients with shorter telomere length are at higher risk of heart disease or stroke. Results in this dissertation address the influence of telomerase reverse transcriptase (TERT), a key component of telomerase, on the BBB integrity in the context of ischemic stroke induced brain injury. Our results indicate that aging-related BBB alterations aggregate the stroke outcomes by inducing oxidative stress and stimulating proinflammatory responses on the brain microvessels. The ability of the BBB to protect the brain from harmful compounds indicates that the BBB may be targeted by chemical toxicants in the peripheral circulation. Polychlorinated biphenyls (PCBs) are persistent organic pollutants that frequently bind to nanoparticles (NPs) in the environment. Our results demonstrate that binding PCB153, one of the most abundant PCB congeners in the environment, to silica nanoparticles (PCB153-NPs) potentiates cerebrovascular toxicity and stroke outcomes via stimulation of inflammatory responses and disruption of BBB integrity. These events are mediated by activation of toll-like receptor 4 (TLR4), which subsequently recruits tumor necrosis factor-associated factor 6 (TRAF6) and initiates the production of multiple inflammatory mediators. Research presented in this dissertation demonstrates that aging and environmental pollutants play crucial roles in modifying the function of the BBB through alterations of inflammatory responses and TJ protein expression, which further contribute to the progression of stroke-induced cerebral ischemic injury. Blood-brain barrier Stroke Telomere Polychlorinated biphenyls Toll-like receptor 4 Medical Cell Biology Medical Toxicology Neurosciences
203	A Model for Studying Vasogenic Brain Edema Shukla, Anshu 01 January 2006 (has links) Convection-enhanced delivery (CED) is a proven method for targeted drug delivery to the brain that circumvents the blood-brain barrier (BBB). Little study has been conducted in understanding CED in pathological brain states. This is of importance when dealing with chemotherapeutic agent delivery to brain tumors, where vasogenic edema (VE) exists. The current study aims to characterize a model of VE suitable for studying CED.VE was produced in the right hemisphere of the rat brain using multiple infusions of hyperosmotic mannitol (0.25mL/kg/s over 30 seconds) delivered through the right internal carotid artery. Magnetic resonance imaging (MRI) revealed consistent edema formation and high water levels in the ipsilateral gray and white matter within an hour of the first infusion. Evan's Blue (EB) staining verified that VE has formed. However, apparent diffusion coefficient (ADC) and histological examination revealed also that some possible cytotoxic edema formed.This model provides a reproducible technique for generating a large area of edema for CED study. Further studies with lower doses of mannitol, while titrating to changes in ADC and values for fractional water content, may modify this model with a greater component of VE and less cerebral toxicity. edema vasogenic edema hyperosmotic mannitol blood-brain barrier targeted drug delivery Anatomy Medicine and Health Sciences Nervous System
204	Imaging neuroinflammatory processes with USPIO-MRI Brown, Andrew Peter January 2009 (has links) This thesis examines the utility of USPIO-MRI to provide a tool of tracking macrophage recruitment to sites of neuroinflammation within the CNS. Recruited macrophages and microglia resident in CNS tissue play a key role in the pathophysiology of a number of neuroinflammatory diseases such as neuropathic pain and multiple sclerosis. Under activated conditions, microglia and macrophages will phagocytose invading cells and CNS debris. It has been shown that ultrasmall superparamagnetic particles of iron oxide (USPIO), such as Sinerem, injected systemically, are engulfed by macrophages, which in turn migrate to sites of tissue injury. USPIOs can be visualised as a distinct reduction in signal intensity on T2* weighted MR images. However, there are still some issues regarding the distinction between iron-laden recruited macrophages and the entry of free iron across a permeable blood brain barrier (BBB) in disease cases. Hence, it was shown that intravenously injected Sinerem is cleared from the peripheral circulation within 24 hours, indentifying this as a time point as suitable for MCP-1 injection. Data showed that free USPIO can be visualised in the brain and that there is a linear relationship between Sinerem concentration and T2* signal intensity changes. MCP-1 induces macrophage recruitment to the site of microinjection and causes BBB breakdown at between 3 and 4 hours. In particular it was shown that T2* signal intensity changes are seen, in the presence of an intact BBB, as a result of Sinerem laden macrophages. This finding was verified by the co-localisation of ED-1 positive cells and Prussian blue positive regions. It was demonstrated that there is a strong correlation between T2* signal changes and the number of macrophages. This demonstrates that USPIO-MRI can be used to characterise macrophage infiltration in neuroinflammation in the presence of an intact BBB. 616.8
205	Efeitos da hipertensão e do treinamento aeróbio sobre a expressão/atividade de diferentes componentes da barreira hematoencefálica. / Effects of hypertension and aerobic training on the expression / activity of different components of the blood-brain barrier. Fragas, Matheus Garcia de 29 June 2018 (has links) A hipertensão arterial cursa com disfunção autonômica e lesão da barreira hematoencefálica (BHE) em áreas de controle autonômico. Demonstramos recentemente que o treinamento aeróbio corrige a lesão da BHE, e a disfunção autonômica, a qual se encontra correlacionada com a integridade da BHE observada nos hipertensos treinados. O objetivo deste trabalho é avaliar a expressão gênica e proteica de componentes da BHE envolvidos na mediação das respostas cardiovasculares à hipertensão e ao treinamento aeróbio (T). Ratos espontaneamente hipertensos (SHR) e seus controles normotensos (WKY) (250-300g) foram submetidos ao protocolo de T em esteira ou mantido sedentários (S) por 4 semanas. Ao final do T os animais dos grupos experimentais foram canulados para aquisição das variáveis hemodinâmicas. A seguir procedeu-se à infusão intra-arterial de 2 corantes (Rodamina-d, 70 KD, e FITC-d,10 KD) e 20 min após os encéfalos foram coletados para realização de ensaios de fluorescência no Núcleo Paraventricular do Hipotálamo (PVN). Outros ratos dos grupos experimentais foram perfundidos com salina via transcardíaca e realizada a microdissecção do PVN. O mRNA foi extraído e sua concentração de foi analisada pela técnica de RT-PCR. Para investigar os efeitos da hipertensão e do T nos componentes da BHE, foram utilizados os seguintes primers: Occludina, Claudina-5, Zônula Ocludens 1 (proteínas da junção oclusiva), Caveolina-1 (indicador de transporte transcelular), Laminina alfa 1 e Colágeno 4 (componentes da membrana basal), PDGFRβ (marcador de pericitos)e Aquaporina-4 (indicador de podócitos de astrócitos), todos eles normalizados para o HPRT endógeno. Os dados de PCR em tempo real foram quantificados pelo método 2Δ ΔCT. Além disso, outros ratos dos mesmos grupos experimentais foram perfundidos com paraformaldeído 4% para a fixação do encéfalo. O tecido foi crioprotegido e seccionado em criostato, 30 um, os cortes foram incubados em anticorpos primários (Reca-1(marcador endotelial), Claudina-5, Caveolina-1, PDGFRβ e Aquaporina-4) e secundários (Alexa Flúor 488 e 594), e sua quantificação no PVN foi realizada através da densidade integrada. Não foi observada diferença na pressão arterial entre os grupos T e S, porém, houve bradicardia de repouso nos animais T (SHR-T:317±3 e WKY-T:308±2) comparados com os animais S (SHR-S: 344±4 e WKY-S: 323±3). A permeabilidade da BHE foi reduzida e normalizada pelo T nos animais hipertensos (SHR-S: 13,6±1,2% e SHR-T: 3,8±0,4%; WKY-S: 3,9±0,2% e WKY-T: 4,1±0,16%), e análise do RT-PCR não mostrou nenhuma diferença para Claudina, PDGFRβ e Aquaporina-4 entre os T e S. A expressão gênica de Caveolina-1 estava aumentada nos SHR comparado aos WKY, e o T foi capaz de reduzir sua expressão (SHR-T: 1,05±0,1). O que foi confirmado pela expressão proteica no PVN: a Caveolina-1 encontrava-se aumentada significativamente nos SHR-S em relação aos WKY, e o T reduziu sua expressão no PVN dos SHR. Conclusão: Nossos dados sugerem que o aumento da permeabilidade da BHE no PVN de hipertensos é devida ao aumento de transcitose, identificada pela expressão de Caveolina-1 e que o treinamento aeróbio reverte esta permeabilidade ao reduzir o transporte transcelular sem alterar o transporte paracelular. / The arterial hypertension courses with autonomic dysfunction and Blood Brain Barrier (BBB) damage in areas of autonomic control. We recently demonstrated that aerobic training corrects the damage to the BBB, and autonomic dysfunction, which is correlated with the integrity of the BBB observed in trained hypertense subjects. The objective of this work is to evaluate the gene and protein expression of BBB components involved in mediating cardiovascular responses to hypertension and aerobic training (T). Spontaneously hypertensive rats (SHR) and their normotensive controls (WKY) (250-300g) were submitted to treadmill protocol or maintained sedentary (S) for 4 weeks. At the end of the T, the animals of the experimental groups were cannulated to acquire the hemodynamic variables. Intra-arterial infusion of two dyes (Rhodamine-d, 70 KD, and FITC-d, 10 KD) and 20 min after brains were collected for fluorescence assays in the Paraventricular Nucleus of hypothalamus (PVN). Other rats from the experimental groups were perfused with transcardiacally with saline and the PVN was microdissected. The mRNA was extracted and its concentration was analyzed by the RT-PCR technique. To investigate the effects of hypertension and T in the BBB components, the following primers were used: Occludin, Claudin-5, Zonula Ocludens 1 (tight junction proteins), Caveolina-1 (indicator of transcellular transport), Laminin α 1 and Collagen-4 (basement membrane components), PDGFRβ (pericyte marker) and Aquaporin-4 (astrocyte podocyte indicator), all standardized for endogenous HPRT. Real-time PCR data were quantified by the method 2ΔΔCT. In addition, other rats from the same experimental groups were perfused with 4% paraformaldehyde for fixation of the brain. The tissue was cryoprotected and cross-sectioned, 30 m, sections were incubated on primary (Reca-1 (endothelial marker), Claudin-5, Caveolin-1, PDGFRβ and Aquaporin-4) and secondary antibodies (Alexa Fluor 488 and 594), and its quantification in thePVN was performed through the integrated density. There was no difference in blood pressure between the T and S groups, but there was resting bradycardia in the T animals (SHR-T: 317 ± 3 and WKY-T: 308 ± 2) compared to S controls (SHR-S: 344 ± 4 and WKY-S: 323 ± 3). The permeability of BBB was reduced and normalized by T in hypertensive animals (SHR-S: 13.6 ± 1.2% and SHR-T: 3.8 ± 0.4%; WKY-S: 3.9 ± 0, 2% and WKY-T: 4.1 ± 0.16%), and RT-PCR analysis showed no difference for Claudin-5, PDGFRβ and Aquaporin-4 between T and S. Caveolin-1 gene expression was increased in SHR compared to WKY, and T was able to reduce its expression (SHR-T: 1.05 ± 0.1). This was confirmed by protein expression in PVN: Caveolin-1 was significantly increased in SHR-S relative to WKY, and T reduced its expression in the PVN of SHR. Conclusion: Our data suggest that increased permeability of BBB in the PVN of hypertense individuals is due to the increase transcytosis as identified by Caveolin-1 expression and that aerobic training reverses this permeability by reducing transcellular transport without altering the paracellular transport.
206	A disfunção da barreira hematoencefálica em SHR é normalizada pelo treinamento aeróbio de baixa a moderada intensidade. / Blood brain barrier dysfunction in SHR is normalized by low to moderate intensity exercise training. Buttler, Leila 17 August 2016 (has links) A hipertensão cursa com importante déficit autonômico e lesão da barreira hematoencefálica (BHE) enquanto que o treinamento aeróbio (T) de hipertensos reduz acentuadamente a lesão da BHE, mantendo sua integridade no PVN, NTS e RVLM mesmo na persistência de níveis pressóricos elevados. Esta rápida resposta ao T (2 semanas) é condicionada pela redução da disponibilidade de ANGII nas áreas encefálicas, simultâneo aumento da expressão de podócitos dos astrócitos e desativação da microglia, os quais ocorrem simultaneamente à redução do simpático vasomotor (2 semanas) e antes mesmo do aumento da variabilidade da frequência cardíaca, da atividade parassimpática ao coração, da instalação da bradicardia de repouso e queda parcial da pressão arterial, que se instalam a partir da 4ª semana de T. Alterações na permeabilidade da BHE de hipertensos (lesão com prejuízo estrutural/funcional) e treinados (manutenção da integridade estrutural/funcional) são importantes fatores a condicionar respectivamente a disfunção autonômica na hipertensão ou a sua correção pelo treinamento. / The arterial hypertension is accompanied by important autonomic dysfunction and blood-brain barrier (BBB) lesion while aerobic training (T) in hypertension strongly decreases the BBB lesion, maintaining its integrity on the PVN, NTS and RVLM even in the persistence of high blood pressure (BP) levels. This early response to T (2 weeks) is conditioned by the reduction of ANGII availability, increased expression of astrocytic podocytes and deactivation of the microglia in brain areas. These responses occurred simultaneously with the reduction of vasomotor sympathetic activity (2 weeks) and before the increase of both heart rate variability and parasympathetic activity, resting bradycardia and partial BP fall, appearing only at the 4th week. Changes on the BBB permeability in hypertension (lesion with structural/functional damage) and trained (maintenance of the structural/ functional integrity) are important factors to condition the autonomic dysfunction in hypertension or its correction by the training, respectively. Aerobic training Angiotensin II Angiotensina II Autonomic modulation Barreira hematoencefálica Blood brain barrier Hipertensão Hypertension Modulação autonômica Treinamento aeróbio
207	Evaluation of novel efflux transport inhibitor for the improvement of drug delivery through epithelial cell monolayer Sonawane, Amit January 2015 (has links) Blood-brain barrier (BBB) is a unique membranous barrier, which segregates brain from the circulating blood. It works as a physical and metabolic barrier between the central nervous system (CNS) and periphery. In mammals, endothelial cells were shown to be of BBB and are characterized by the tight junctions along with efflux system which are responsible for the restriction of movement of molecules within the cells. Efflux system consists of multidrug resistance proteins such as P-glycoprotein (P-gp). P-gp removes substances out back from the brain to the blood before they reach to the brain. So the barrier is impermeable to many compounds such as amino acids, ions, small peptides and proteins, making it the most challenging factor for the development of new drugs for targeting CNS. Curcumin is a bioactive compound that has a number of health promoting benefits such as anti-inflammatory, anticancer, anti-oxidant agent; as well as a role in neurodegenerative diseases, but low oral bioavailability is the major limiting factor. Low water solubility and rapid metabolism are the two important factors responsible for poor bioavailability of curcumin. Galaxolide is a musk compound and previously known for the bioaccumulation of toxic components in the aquatic animals by interference with the activity of multidrug/multixenobiotic resistance efflux transporters (MDR/MXR). The bioavailability of curcumin can be enhanced when administered with galaxolide. This study was carried out to investigate the effect of galaxolide on the permeation of curcumin through the epithelial cell monolayers. MDCKII-MDR1 cell monolayer is used an in vitro blood-brain barrier model while Caco-2 monolayer is used as an in vitro intestinal model, which also expresses the P-glycoprotein. The curcumin and galaxolide were separately solubilised in the DMSO and used in combination to perform permeation study, to determine the effect of galaxolide on curcumin permeation through epithelial cell monolayers. The galaxolide shows an efflux protein inhibition activity and this activity was used to enhance permeation of curcumin through the Caco-2 monolayer. In summary, galaxolide is a novel permeation enhancer molecule, which can be used for the improvement of drug delivery of other bioactive compounds in future. 570
208	Neuronavigation-Guided Transcranial Ultrasound: Development towards a Clinical System and Protocol for Blood-Brain Barrier Opening Wu, Shih-Ying January 2016 (has links) Brain diseases including neurological disorders and tumors remain undertreated due to the challenge in accessing the brain, and blood-brain barrier (BBB) restricting drug delivery, which also profoundly limits the development of pharmacological treatment. Focused ultrasound (FUS) with acoustic agents including microbubbles and nanodroplets remains as the only method to open the BBB noninvasively, locally, and transiently to assist drug delivery. For an ideal medical system to serve a broad patient population, it requires precise and flexible targeting with simulation to personalize treatment, real-time monitoring to ensure safety and effectiveness, and rapid application, as repetitive pharmacological treatment is often required. Since none of current systems fulfills all the requirements, here we designed a neuronavigation-guided FUS system with protocol assessed in in vivo mice, in vivo non-human primates, and human skulls from in silico preplanning, online FUS treatment and real-time acoustic monitoring and mapping, to post-treatment assessment using MRI. Both sedate and awake non-human primates were evaluated with total treatment time averaging 30 min and 3-mm targeting accuracy in cerebral cortex and subcortical structures. The FUS system developed would enable transcranial FUS in patients with high accuracy and independent of MRI guidance. Blood-brain barrier High-intensity focused ultrasound Transcranial Doppler ultrasonography Brain--Diseases Biomedical engineering Nanoscience Electrical engineering
209	Etude des conséquences de stress hypoxiques répétés sur l’intégrité d’un modèle in vitro de barrière hémato-encéphalique / Study of consequences of repeated hypoxic stress on integrity Chatard, Morgane 08 February 2017 (has links) La barrière hémato-encéphalique (BHE) est la structure essentielle au système nerveux central (SNC), localisée au sein des capillaires cérébraux. Elle est responsable du maintien de l’homéostasie cérébrale ainsi que de sa protection. En effet, les pathologies affectant le SNC sont souvent associées à une altération au niveau de la BHE. L’un des nombreux facteurs, pouvant altérer l’homéostasie du SNC, est l’hypoxie puisque le cerveau est le premier consommateur d’oxygène. De nombreuses études ont démontré qu’une hypoxie aigüe (modélisation de l’ischémie cérébrale transitoire ou l’AVC), altère la perméabilité de cette barrière. Cependant, certaines pathologies sont liées à une hypoxie intermittente, notamment les troubles respiratoires associés au sommeil, comme le syndrome d’apnées du sommeil. Cette hypoxie intermittente ne semble pas être sans conséquence sur la structure et la fonction du cerveau, car des études menées chez l’Homme ont démontré que ces patients souffraient de troubles cognitifs. L’enjeu dans l’étude de ces pathologies est d’avoir une meilleure compréhension des mécanismes amenant à l’altération de la BHE, afin de développer des stratégies thérapeutiques adéquates. Toutefois, peu d’études à ce jour se sont intéressées à l’impact de l’hypoxie intermittente sur la BHE en raison de la complexité du cerveau. De ce fait, les modèles in vitro de BHE semblent être des outils adéquats à l’étude de la BHE en conditions pathologiques. L’objectif de ce travail de thèse a été de mettre en place un modèle in vitro de BHE permettant l’étude de l’impact de stress hypoxiques répétés sur l’intégrité de cette barrière.Le modèle mis en place est un modèle de co-culture « contact » mettant en jeu des cellules endothéliales cérébrales immortalisées de souris et des astrocytes immortalisés de rat. En effet, de nombreuses études ont montré l’importance des interactions entre les astrocytes et les cellules endothéliales, dans la mise en place du phénotype de barrière de la BHE. Nous avons fait le choix de développer un modèle murin afin d’être en adéquation avec les études menées, chez le petit animal, au laboratoire. Ce modèle a été caractérisé en termes de résistance électrique transendothelial (TEER), de perméabilité membranaire, de jonctions serrées et de transporteurs d’efflux. Ce modèle répond aux critères attendus pour un modèle in vitro de BHE et est rapide à mettre en place.L’impact cellulaire de l’hypoxie intermittente est difficile à étudier in vitro en raison de la rapidité du phénomène. De ce fait, nous avons mis en place une méthode alternative d’induction de stress hypoxique par un agent chimique, l’hydralazine, qui soit reproductible, contrôlable et réversible, afin d’étudier les mécanismes cellulaires et moléculaires induits au niveau de cette BHE. / The blood-brain barrier (BBB) is the essential structure of the central nervous system (CNS), located at the level of brain capillaries. The BBB is responsible for the maintenance of cerebral homeostasis and its protection. Indeed, diseases affecting the CNS are often related to a disorder at the BBB’s site. One of the several factors which can alter the homeostasis of the CNS, is hypoxia because the brain is one of the the first consumer of oxygen of the body. Several studies showed that acute hypoxia (mimic transient brain ischemia or stroke), could alter BBB permeability. However, some disorders are related to intermittent hypoxia, particularly sleep related breathing disorders, such as sleep apnea syndrome. This intermittent hypoxia does not seem to be innocent on the brain structure and function, since studies in humans have demonstrated that these patients suffer from cognitive disorders. The challenge in the study of such pathologies is represented by a better understanding of mechanisms leading to this alteration, in order to develop adequate therapeutic strategies. Nevertheless, few studies have focused, to date, on the impact of intermittent hypoxia on the BBB, due to the complexity of the brain structure in vivo. In this regard, in vitro BBB model appear to be suitable tools for the study of BBB in pathologies conditions. The aim of this thesis was to set up an in vitro BBB model suitable for the study of BBB’s integrity after repeated hypoxic stress exposure. Barrière hémato-encéphalique Hydralazine Hypoxie répétée Modèle in vitro Intégrité Blood-brain barrier Hydralazine Repeated hypoxia In vitro model Integrity
210	Stereoselective Transport of Drugs Across the Blood-Brain Barrier (BBB) <i>In Vivo</i> and <i>In Vitro</i> : Pharmacokinetic and Pharmacodynamic Studies of the (<i>S</i>)- and (<i>R</i>)-Enantiomers of Different 5-HT<sub>1A</sub> Receptor Agonists and Antagonists Yan, Hongmei January 2002 (has links) <p>Delivery of drugs to the brain requires passage across the blood-brain barrier (BBB). Both for drugs already on the market and for new drugs under development, it is important to know to what extent a drug enters the CNS. Many drugs used clinically are racemic mixtures, <i>i.e.</i> equal parts of the (<i>S</i>)- and (<i>R</i>)-enantiomers. </p><p>The present studies focus on the enantiomers and racemates of a number of 5-HT<sub>1A</sub> receptor agonists and antagonists (pindolol, propranolol, 8-OH-DPAT and other 8-substituted-2-(di-<i>n</i>-propylamino)tetralin derivatives) and BBB transport <i>in vitro</i> and distribution to the brain <i>in vivo.</i> Assays (HPLC-based) were set up or developed for determination of the racemates and the pure enantiomers (chiral column) of drugs in plasma and brain tissue. BBB transport was assessed <i>in vitro</i> using bovine brain endothelial cells cocultured with rat astrocytes. The physicochemical constants (log P, pKa) and plasma protein binding were determined. Pindolol, propranolol and several tetralines accumulated over time in brain tissue. For pindolol and propranolol, but not for most tetralins, the distribution to the brain was stereoselective, (<i>S</i>)>(<i>R</i>). Pretreatment with verapamil, an inhibitor of drug efflux <i>via</i> P-glycoprotein, differentially decreased the brain/plasma ratios of the enantiomers of pindolol and propranolol, indicating that verapamil may also inhibit an influx transport mechanism. <i>In vitro</i> results with racemic pindolol, propranolol and tetralins showed no differences in BBB transport between the enantiomers. A more rapid apical to basolateral transport (influx) <i>vs</i>. the basolateral to apical (efflux) transport of propranolol (not pindolol) and most tetralins <i>in vitro</i> indicated active transport across the BBB. </p><p>In conclusion, the combined <i>in vivo</i> and <i>in vitro</i> results are consistent with active transport of the studied compounds across the BBB rather than passive diffusion due to their lipophilicity. Some, but not all, chiral drugs are stereoselectively distributed to the brain. Stereoselective plasma protein binding or stereoselective transport across brain endothelial cells does not seem to explain the stereoselective accumulation of pindolol and propranolol. The stereochemical configuration of compounds contributes to their pharmacokinetic as well as their pharmacodynamic uniqueness. The characteristics of the enantiomers of chiral compounds need to be determined empirically rather than based on generalizations from structural or physicochemical information.</p> Neurosciences pindolol propranolol 2-(di-n-propylamino)tetralin racemate enantiomer drug distribution brain rat blood-brain barrier Neurovetenskap Neurology Neurologi

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