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Showing 11 to 19 of 19 (0.045 seconds)Spelling suggestions: "subject:"hydroperoxide""
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Regioselectivity In The Ene Reaction Of Singlet Oxygen With Cyclic Alkenes And Application Of Ene Reaction To Stereoselective Synthesis Of Carbaheptopyranose DerivativesDogan, Sengul Dilem 01 October 2010 (has links) (PDF)
In the first part of this thesis is related to the regioselectivity in ene reaction of singlet oxygen with cyclic alkenes. The photooxygenation of 1-methyl-, 2,3-dimethyl-, 1,4-dimethylcyclohexa-1,4-dienes, 1,2,3,4,5,8-hexahydronaphthalene (16) and 2,3,4,7-tetrahydro-1H-indene (17) which are readily available through Birch reduction, yielded the ene products. The formed endocyclic dienes were trapped by the addition of singlet oxygen to give corresponding bicyclic endoperoxy-hydroperoxides. In the case of 1-methylcyclohexa-1,4-diene (13) and 1,4-dimethyl-cyclohexa-1,4-diene (15), cis-effect determined the product distribution. Photooxygenation of 2,3-dimethylcyclohexa-1,4-dienes (14) gave mainly exocyclic olefin, which was attributed to the lowered rotational barrier of the methyl group and increased reactivity of the methyl groups. Photooxygeneation of 1,2,3,4,5,8-hexahydronaphthalene (16) and 2,3,4,7-tetrahydro-1H-indene (17) shows importance of the geometry of the allylic hydrogen in the ground state.
In the second part of this thesis is related to the stereoselective synthesis of carbaheptopyranose derivatives. Two new carbaheptopyranoses, 5a-carba-6-deoxy-&alpha / -DL-galacto-heptopyranose (184) and 5a-carba-6-deoxy-&alpha / -DL-gulo-heptopyranose (185) have been prepared starting from cyclohexa-1,4-diene. The addition of dichloroketene to cyclohexa-1,4-diene followed by subsequent reductive elimination and Baeyer-Villiger oxidation formed the bicyclic lactone 188. Reduction of the lactone moiety followed by acetylation gave the diacetate 182b with cis-configuration. Introduction of additional acetate functionality into the molecule was achieved by singlet oxygen ene-reaction. The formed hydroperoxide 189 was reduced and then acetylated. The double bond in triacetate was further functionalized either by direct cis-hydroxylation using OsO4 or epoxidation followed by ring-opening reaction to give the hepto-pyranose derivatives 184 and 185.
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Oxidative lipid fragmentation; New mechanisms, synthesis and reactions of putative intermediatesGu, Xiaodong 30 July 2010 (has links)
No description available.
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Geração de oxigênio molecular singlete: termólise de endoperóxidos naftalênicos e reações de hidroperóxidos lipídicos com íon nitrônio / Generation of singlet molecular oxygen: thermolysis of naphthalene endoperoxides and reaction of lipid hydroperoxides with nitronium ionScalfo, Alexsandra Cristina 09 May 2014 (has links)
Oxigênio molecular singlete [O2(1Δg)], uma espécie excitada, desempenha um papel importante em sistemas químicos e biológicos. É um poderoso eletrófilo, que reage com moléculas ricas em elétrons através de cicloadições [2+2], [4+2] e reações tipo ene. Ácidos graxos poliinsaturados, proteínas e DNA são alvos vulneráveis para o ataque de O2(1Δg). Os endoperóxidos de derivados de naftaleno são muito úteis e versáteis como fontes limpas de O2(1Δg), uma vez que são quase quimicamente inertes. Por outro lado, o desenvolvimento de novas fontes de O2(1Δg) ainda é uma tarefa desafiadora. Os derivados de naftaleno são capazes de armazenar O2(1Δg) por reação de cicloadiação [4+2] e liberá-lo em temperaturas amenas, o que os torna muito adequados para uso em estudos biológicos. A síntese destes compostos está baseada em modificações nos substituintes ligados nas posições 1 e 4 da estrutura do naftaleno. Na primeira parte deste trabalho, a síntese de três endoperóxidos derivados do naftaleno solúveis em água foi realizada. DHPNO2 e NDPO2 foram preparados de acordo com métodos similares descritos na literatura. A síntese de um novo endoperóxido dicatiônico derivado do naftaleno (NBTEO2) foi desenvolvida, contendo dois grupos de cloreto de amônio quaternário nas posições 1,4 do anel aromático. O intermediário chave na síntese dos três endoperóxidos é o BBMN, o qual foi preparado a partir da bromação radicalar do 1,4-dimetilnaftaleno. Nossos resultados têm indicado que este composto dicatiônico pode ser uma fonte química de O2(1Δg) em potencial, e pode ser explorado em estudos com mitocôndrias, onde o papel biológico de O2(1Δg) é investigado. A segunda parte deste trabalho foi dedicada a investigar a geração de O2(1Δg) através das reações entre hidroperóxidos de lipídeos (ácido oleico, linoleico e colesterol), hidroperóxidos orgânicos (cumeno e t-butila), bem como peróxido de hidrogênio com NO2+, utilizando o composto NO2BF4. Evidências da geração de O2(1Δg) foram obtidas através de medidas de emissão de luz na região do infravermelho próximo, no comprimento de onda de 1270 nm. Além disso, a prova inequívoca da presença de O2(1Δg) foi demonstrada através da caracterização espectral direta da emissão de luz no infravermelho próximo. O uso de azida de sódio como captador físico de O2(1Δg), juntamente com as medidas da quimiluminescência, contribuíram para identificar a geração desta espécie na reação entre hidroperóxidos de lipídeos e NO2BF4. Embora seja uma abordagem química, nossos resultados adicionaram informações importantes sobre a peroxidação lipídica, principalmente quando espécies reativas de nitrogênio estão envolvidas. O O2(1Δg) poderia ser gerado como um subproduto da peroxidação lipídica em condições onde espécies reativas de nitrogênio interagem com hidroperóxidos lipídicos. Isto pode contribuir para um melhor entendimento deste evento complexo com implicações fisiológicas ou fisiopatológicas. / Singlet molecular oxygen [O2(1Δg)], an excited species, plays an important role in chemical and biological systems. It is a powerfull electrophile, reacting with electron rich molecules through [2+2] cycloadditions, [4+2] cycloadditions and ene reactions. Polyunsaturated fatty acids, proteins and DNA are vulnerable targets for O2(1Δg) reaction. Naphthalene derivatives endoperoxides are very useful and versatile as a clean source of O2(1Δg), once they are almost chemically inert. On the other hand, developing new sources of O2(1Δg) are still a challenging task. Naphthalene derivatives are able to trap O2(1Δg) by [4+2] cycloaddition and release it in mild temperatures, which make them very suitable for biological studies. The synthesis of these compounds is based on modifications in substituents bonded in 1,4 positions of nafhthalene backbone. In the first part of present work, the synthesis of three water soluble naphthalene derivatives endoperoxides was performed. DHPNO2, NDPO2 were prepared according to similar methods described in the literature. A new di-cationic naphthalene derivative endoperoxide (NBTEO2) synthesis was developed, containing two quaternary ammonium chloride groups in 1,4-positions of aromatic ring. The key intermediate: for the synthesis of the three endoperoxides is the compound BBMN, which was prepared from radicalar bromination of 1,4-dimethylnaphthalene. Our results have indicated that this di-cationic compound can be a potential chemical source of O2(1Δg) and may be explored in mitochondrial studies where O2(1Δg) biological role is investigated. The second part of this work is dedicated to the investigation of generation of O2(1Δg) through reaction of lipid hydroperoxides (oleic acid, linoleic acids and cholesterol), organic hydroperoxides (cumene and t-butyl), as well as hydrogen peroxide with NO2+, using the compound NO2BF4. Evidences of generation of O2(1Δg) were obtained recording the monomol light emission measurement in near infrared region at wavelength of 1270 nm. Moreover, the proof of the presence of O2(1Δg) was unequivocally demonstrated by the direct spectral characterization of near-infrared light emission. The use of sodium azide as a physical quencher of O2(1Δg), associated to chemiluminescence measurements, contributed to identify the generation of this species in the reaction of lipid hydroperoxides and NO2BF4. Although, it is a chemical approach, our results add important information about lipid peroxidation, mainly when reactive species of nitrogen are involved. O2(1Δg) might be generate as a byproduct of lipid peroxidation, in conditions where reactive nitrogen species interact with lipid hydroperoxides. This might contribute to a better understand of this complex event and physiological or physiopathological implications
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Mechanisms of over-active endothelium-derived contracting factor signaling causing common carotid artery endothelial vasomotor dysfunction in hypertension and agingDenniss, Steven January 2011 (has links)
Background and Purpose:
The endothelium is a single-cell layer positioned at the blood-vascular wall interface, where in response to blood-borne signals and hemodynamic forces, endothelial cells act as central regulators of vascular homeostatic processes including vascular tone, growth and remodeling, inflammation and adhesion, and blood fluidity and coagulation. Agonist- or flow-stimulated endothelium-dependent vasorelaxation becomes impaired in states of cardiovascular disease (CVD) risk and has been identified as a possible biomarker of overall endothelial dysfunction leading to vascular dysregulation and disease pathogenesis. Accordingly, it is important to elucidate the mechanisms accounting for this endothelial vasomotor dysfunction. Upon stimulation, endothelial cells can synthesize and release a variety of endothelium-derived relaxing factors (EDRFs), the most prominent of which is nitric oxide (NO) derived from NO synthase (NOS). In addition, under certain CVD risk conditions including hypertension and aging, stimulated endothelial cells can become a prominent source of endothelium-derived contracting factors (EDCFs) produced in a cyclooxygenase (COX)-dependent manner. Consequently, endothelial dysfunction may be caused by under-active EDRF signaling and/or competitive over-active EDCF signaling. Much attention has been given to elucidating the mechanisms of under-active EDRF signaling and its role in causing endothelial dysfunction, wherein excess reactive oxygen species (ROS) accumulation and oxidative stress under CVD risk conditions have been recognized as major factors in reducing NO bioavailability thus causing under-active EDRF signaling and endothelial dysfunction. Less attention however, has been given to elucidating the mechanisms of over-active COX-mediated EDCF signaling and its role in causing endothelial dysfunction. Moreover, while COX-mediated EDCF signaling activity has been investigated in some segments of the vasculature, most notably the aorta, it has not been well-investigated in the common carotid artery (CCA), a highly accessible cerebral blood flow conduit particularly advantageous in exploring the roles of the endothelium in vascular pathogenesis. It was the global purpose of this thesis to gain a better understanding of the cellular-molecular mechanisms accounting for endothelial dysfunction in the CCA of animal models known to exhibit COX-mediated EDCF signaling activity, in particular essential (spontaneous) hypertension and aging.
Experimental Objective and Approach:
This thesis comprises three studies. Study I and Study II investigated the CCA of young-adult (16-24wk old) normotensive Wistar Kyoto (WKY) and Spontaneously Hypertensive (SHR) rats. Study III investigated the CCA of Adult (25-36wks old) and Aging (60-75wks old) Sprague Dawley (SD) rats treated in vivo (or not; CON) with L-buthionine sulfoximine (BSO) to chronically deplete the cellular anti-oxidant glutathione (GSH) and increase ROS accumulation and oxidative stress. The global objective and approach across these studies was to systematically examine the relative contributions of NOS and COX signaling pathways in mediating the acetylcholine (ACh)-stimulated endothelium-dependent relaxation (EDRF) and contractile (EDCF) activities of isometrically-mounted CCA in tissue baths in vitro, with a particular focus on elucidating the mechanisms of COX-mediated EDCF signaling activity. An added objective was to examine the in vivo hemodynamic characteristics of the CCA in each animal model investigated, serving both to identify the pressure-flow environment that the CCA is exposed to in vivo and to provide assessment of potential hypertension, aging, and oxidative stress effects on large artery hemodynamics.
Key Findings:
Study I hemodynamic analysis confirmed a hypertensive state in young adult SHR while also exposing a reduction in mean CCA blood flow in SHR compared to WKY accompanied by a multi-faceted pressure-flow interaction across the cardiac cycle relating to flow and pressure augmentation. Study III hemodynamic analysis found that neither aging nor chronic BSO-induced GSH depletion affected CCA blood pressure or blood flow parameters in SD rats.
Study I and II demonstrated that a COX-mediated EDCF response impaired ACh-stimulated endothelium-dependent vasorelaxation in pre-contracted CCA from young adult SHR, while EDRF signaling activity, predominantly mediated by NO, remained well-preserved compared to WKY. Examining ACh-stimulated contractile function specifically from a quiescent (non pre-contracted) state revealed that EDCF activity did exist in WKY CCA but could be completely suppressed by NO-mediated EDRF signaling activity, whereas the similarly robust NO-meditated EDRF signaling activity in SHR CCA could not fully suppress its >2-fold augmented EDCF activity vs. WKY CCA. Further pharmaco-dissection of ACh-stimulated contractile function in the SHR-WKY CCA model revealed that the EDCF signaling activity was completely dependent on the COX-1 (but not COX-2) isoform of COX and was almost exclusively mediated by the thromboxane-prostanoid (TP) sub-type of the prostaglandin (PG) G-protein coupled receptor family and by Rho-associated kinase (ROCK), a down-stream effector of the molecular switch RhoA. Furthermore, it was found that while exogenous ROS-stimulated CCA contractile function was similarly >2-fold augmented in SHR vs. WKY and dependent on COX-1 and TP receptor and ROCK effectors, ACh-stimulated CCA EDCF signaling activity was only minimally affected by in-bath ROS manipulating compounds. Additional biochemical and molecular analysis revealed that ACh stimulation was associated with PG over-production from an over-expressed COX-1 in SHR CCA, and with CCA plasma membrane localization and activation of RhoA.
Study III demonstrated that a COX-mediated EDCF response impaired ACh-stimulated endothelium-dependent vasorelaxation in pre-contracted CCA from Aging SD rats, while EDRF signaling activity, predominantly mediated by NO, remained well-preserved compared to Adult SD rats. Specific examination of ACh-stimulated contractile function revealed that EDCF activity did exist in Adult CCA but could be completely suppressed by NO-mediated EDRF signaling activity, whereas the similarly robust NO-meditated EDRF signaling activity in Aging CCA could not fully suppress its >3-fold augmented EDCF activity vs. Adult CCA. Further pharmaco-dissection of ACh-stimulated contractile function in the Adult-Aging SD rat CCA model revealed that EDCF signaling activity was completely dependent on COX-1, but while exogenous ROS was able to elicit a COX-dependent CCA contractile response, in-bath ROS manipulating compounds were found to be without effect on ACh-stimulated CCA EDCF signaling activity. Furthermore, biochemical analysis revealed that aging was not associated with a change in tissue (liver and vascular) GSH content or ROS accumulation. Chronic in vivo BSO treatment was effective in depleting tissue GSH content and increasing ROS accumulation, to a similar extent, in both Adult and Aging SD rats. However, regardless of age, neither ACh-stimulated NO-mediated EDRF signaling activity nor COX-mediated EDCF signaling activity were affected by these BSO-induced perturbations.
Conclusions and Perspective:
In the CCA of animals at the early pathological stages of either essential hypertension (young adult SHR) or normotensive aging (Aging SD rats), endothelial vasomotor dysfunction can be caused solely by over-active EDCF signaling, apparently disconnected from changes in NO bioavailability or oxidative stress. While NO and ROS may act, respectively, as negative and positive modulators of the established COX-PG-TP receptor-RhoA-ROCK cell-signaling axis mediating endothelium-dependent contractile activity, these factors do not appear to be essential to the mechanism(s) underlying the development of over-active EDCF signaling. Further elucidation of the cellular-molecular causes of over-active EDCF signaling, and its patho-biological consequences, in the SHR-WKY and Adult-Aging SD rat CCA models of EDCF activity established and hemodynamically characterized in this thesis, may help to identify new or more effective targets to be used in prevention or treatment strategies to combat the pathogenesis of CVD.
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| 15 |
Mechanisms of over-active endothelium-derived contracting factor signaling causing common carotid artery endothelial vasomotor dysfunction in hypertension and agingDenniss, Steven January 2011 (has links)
Background and Purpose:
The endothelium is a single-cell layer positioned at the blood-vascular wall interface, where in response to blood-borne signals and hemodynamic forces, endothelial cells act as central regulators of vascular homeostatic processes including vascular tone, growth and remodeling, inflammation and adhesion, and blood fluidity and coagulation. Agonist- or flow-stimulated endothelium-dependent vasorelaxation becomes impaired in states of cardiovascular disease (CVD) risk and has been identified as a possible biomarker of overall endothelial dysfunction leading to vascular dysregulation and disease pathogenesis. Accordingly, it is important to elucidate the mechanisms accounting for this endothelial vasomotor dysfunction. Upon stimulation, endothelial cells can synthesize and release a variety of endothelium-derived relaxing factors (EDRFs), the most prominent of which is nitric oxide (NO) derived from NO synthase (NOS). In addition, under certain CVD risk conditions including hypertension and aging, stimulated endothelial cells can become a prominent source of endothelium-derived contracting factors (EDCFs) produced in a cyclooxygenase (COX)-dependent manner. Consequently, endothelial dysfunction may be caused by under-active EDRF signaling and/or competitive over-active EDCF signaling. Much attention has been given to elucidating the mechanisms of under-active EDRF signaling and its role in causing endothelial dysfunction, wherein excess reactive oxygen species (ROS) accumulation and oxidative stress under CVD risk conditions have been recognized as major factors in reducing NO bioavailability thus causing under-active EDRF signaling and endothelial dysfunction. Less attention however, has been given to elucidating the mechanisms of over-active COX-mediated EDCF signaling and its role in causing endothelial dysfunction. Moreover, while COX-mediated EDCF signaling activity has been investigated in some segments of the vasculature, most notably the aorta, it has not been well-investigated in the common carotid artery (CCA), a highly accessible cerebral blood flow conduit particularly advantageous in exploring the roles of the endothelium in vascular pathogenesis. It was the global purpose of this thesis to gain a better understanding of the cellular-molecular mechanisms accounting for endothelial dysfunction in the CCA of animal models known to exhibit COX-mediated EDCF signaling activity, in particular essential (spontaneous) hypertension and aging.
Experimental Objective and Approach:
This thesis comprises three studies. Study I and Study II investigated the CCA of young-adult (16-24wk old) normotensive Wistar Kyoto (WKY) and Spontaneously Hypertensive (SHR) rats. Study III investigated the CCA of Adult (25-36wks old) and Aging (60-75wks old) Sprague Dawley (SD) rats treated in vivo (or not; CON) with L-buthionine sulfoximine (BSO) to chronically deplete the cellular anti-oxidant glutathione (GSH) and increase ROS accumulation and oxidative stress. The global objective and approach across these studies was to systematically examine the relative contributions of NOS and COX signaling pathways in mediating the acetylcholine (ACh)-stimulated endothelium-dependent relaxation (EDRF) and contractile (EDCF) activities of isometrically-mounted CCA in tissue baths in vitro, with a particular focus on elucidating the mechanisms of COX-mediated EDCF signaling activity. An added objective was to examine the in vivo hemodynamic characteristics of the CCA in each animal model investigated, serving both to identify the pressure-flow environment that the CCA is exposed to in vivo and to provide assessment of potential hypertension, aging, and oxidative stress effects on large artery hemodynamics.
Key Findings:
Study I hemodynamic analysis confirmed a hypertensive state in young adult SHR while also exposing a reduction in mean CCA blood flow in SHR compared to WKY accompanied by a multi-faceted pressure-flow interaction across the cardiac cycle relating to flow and pressure augmentation. Study III hemodynamic analysis found that neither aging nor chronic BSO-induced GSH depletion affected CCA blood pressure or blood flow parameters in SD rats.
Study I and II demonstrated that a COX-mediated EDCF response impaired ACh-stimulated endothelium-dependent vasorelaxation in pre-contracted CCA from young adult SHR, while EDRF signaling activity, predominantly mediated by NO, remained well-preserved compared to WKY. Examining ACh-stimulated contractile function specifically from a quiescent (non pre-contracted) state revealed that EDCF activity did exist in WKY CCA but could be completely suppressed by NO-mediated EDRF signaling activity, whereas the similarly robust NO-meditated EDRF signaling activity in SHR CCA could not fully suppress its >2-fold augmented EDCF activity vs. WKY CCA. Further pharmaco-dissection of ACh-stimulated contractile function in the SHR-WKY CCA model revealed that the EDCF signaling activity was completely dependent on the COX-1 (but not COX-2) isoform of COX and was almost exclusively mediated by the thromboxane-prostanoid (TP) sub-type of the prostaglandin (PG) G-protein coupled receptor family and by Rho-associated kinase (ROCK), a down-stream effector of the molecular switch RhoA. Furthermore, it was found that while exogenous ROS-stimulated CCA contractile function was similarly >2-fold augmented in SHR vs. WKY and dependent on COX-1 and TP receptor and ROCK effectors, ACh-stimulated CCA EDCF signaling activity was only minimally affected by in-bath ROS manipulating compounds. Additional biochemical and molecular analysis revealed that ACh stimulation was associated with PG over-production from an over-expressed COX-1 in SHR CCA, and with CCA plasma membrane localization and activation of RhoA.
Study III demonstrated that a COX-mediated EDCF response impaired ACh-stimulated endothelium-dependent vasorelaxation in pre-contracted CCA from Aging SD rats, while EDRF signaling activity, predominantly mediated by NO, remained well-preserved compared to Adult SD rats. Specific examination of ACh-stimulated contractile function revealed that EDCF activity did exist in Adult CCA but could be completely suppressed by NO-mediated EDRF signaling activity, whereas the similarly robust NO-meditated EDRF signaling activity in Aging CCA could not fully suppress its >3-fold augmented EDCF activity vs. Adult CCA. Further pharmaco-dissection of ACh-stimulated contractile function in the Adult-Aging SD rat CCA model revealed that EDCF signaling activity was completely dependent on COX-1, but while exogenous ROS was able to elicit a COX-dependent CCA contractile response, in-bath ROS manipulating compounds were found to be without effect on ACh-stimulated CCA EDCF signaling activity. Furthermore, biochemical analysis revealed that aging was not associated with a change in tissue (liver and vascular) GSH content or ROS accumulation. Chronic in vivo BSO treatment was effective in depleting tissue GSH content and increasing ROS accumulation, to a similar extent, in both Adult and Aging SD rats. However, regardless of age, neither ACh-stimulated NO-mediated EDRF signaling activity nor COX-mediated EDCF signaling activity were affected by these BSO-induced perturbations.
Conclusions and Perspective:
In the CCA of animals at the early pathological stages of either essential hypertension (young adult SHR) or normotensive aging (Aging SD rats), endothelial vasomotor dysfunction can be caused solely by over-active EDCF signaling, apparently disconnected from changes in NO bioavailability or oxidative stress. While NO and ROS may act, respectively, as negative and positive modulators of the established COX-PG-TP receptor-RhoA-ROCK cell-signaling axis mediating endothelium-dependent contractile activity, these factors do not appear to be essential to the mechanism(s) underlying the development of over-active EDCF signaling. Further elucidation of the cellular-molecular causes of over-active EDCF signaling, and its patho-biological consequences, in the SHR-WKY and Adult-Aging SD rat CCA models of EDCF activity established and hemodynamically characterized in this thesis, may help to identify new or more effective targets to be used in prevention or treatment strategies to combat the pathogenesis of CVD.
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SMAD3 in embryonic patterning, mesoderm induction, and colorectal cancer in the mouseWieduwilt, Matthew J. January 2003 (has links) (PDF)
Thesis (Ph. D.) -- University of Texas Southwestern Medical Center at Dallas, 2003. / Vita. Bibliography: 180-208.
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Geração de oxigênio molecular singlete: termólise de endoperóxidos naftalênicos e reações de hidroperóxidos lipídicos com íon nitrônio / Generation of singlet molecular oxygen: thermolysis of naphthalene endoperoxides and reaction of lipid hydroperoxides with nitronium ionAlexsandra Cristina Scalfo 09 May 2014 (has links)
Oxigênio molecular singlete [O2(1Δg)], uma espécie excitada, desempenha um papel importante em sistemas químicos e biológicos. É um poderoso eletrófilo, que reage com moléculas ricas em elétrons através de cicloadições [2+2], [4+2] e reações tipo ene. Ácidos graxos poliinsaturados, proteínas e DNA são alvos vulneráveis para o ataque de O2(1Δg). Os endoperóxidos de derivados de naftaleno são muito úteis e versáteis como fontes limpas de O2(1Δg), uma vez que são quase quimicamente inertes. Por outro lado, o desenvolvimento de novas fontes de O2(1Δg) ainda é uma tarefa desafiadora. Os derivados de naftaleno são capazes de armazenar O2(1Δg) por reação de cicloadiação [4+2] e liberá-lo em temperaturas amenas, o que os torna muito adequados para uso em estudos biológicos. A síntese destes compostos está baseada em modificações nos substituintes ligados nas posições 1 e 4 da estrutura do naftaleno. Na primeira parte deste trabalho, a síntese de três endoperóxidos derivados do naftaleno solúveis em água foi realizada. DHPNO2 e NDPO2 foram preparados de acordo com métodos similares descritos na literatura. A síntese de um novo endoperóxido dicatiônico derivado do naftaleno (NBTEO2) foi desenvolvida, contendo dois grupos de cloreto de amônio quaternário nas posições 1,4 do anel aromático. O intermediário chave na síntese dos três endoperóxidos é o BBMN, o qual foi preparado a partir da bromação radicalar do 1,4-dimetilnaftaleno. Nossos resultados têm indicado que este composto dicatiônico pode ser uma fonte química de O2(1Δg) em potencial, e pode ser explorado em estudos com mitocôndrias, onde o papel biológico de O2(1Δg) é investigado. A segunda parte deste trabalho foi dedicada a investigar a geração de O2(1Δg) através das reações entre hidroperóxidos de lipídeos (ácido oleico, linoleico e colesterol), hidroperóxidos orgânicos (cumeno e t-butila), bem como peróxido de hidrogênio com NO2+, utilizando o composto NO2BF4. Evidências da geração de O2(1Δg) foram obtidas através de medidas de emissão de luz na região do infravermelho próximo, no comprimento de onda de 1270 nm. Além disso, a prova inequívoca da presença de O2(1Δg) foi demonstrada através da caracterização espectral direta da emissão de luz no infravermelho próximo. O uso de azida de sódio como captador físico de O2(1Δg), juntamente com as medidas da quimiluminescência, contribuíram para identificar a geração desta espécie na reação entre hidroperóxidos de lipídeos e NO2BF4. Embora seja uma abordagem química, nossos resultados adicionaram informações importantes sobre a peroxidação lipídica, principalmente quando espécies reativas de nitrogênio estão envolvidas. O O2(1Δg) poderia ser gerado como um subproduto da peroxidação lipídica em condições onde espécies reativas de nitrogênio interagem com hidroperóxidos lipídicos. Isto pode contribuir para um melhor entendimento deste evento complexo com implicações fisiológicas ou fisiopatológicas. / Singlet molecular oxygen [O2(1Δg)], an excited species, plays an important role in chemical and biological systems. It is a powerfull electrophile, reacting with electron rich molecules through [2+2] cycloadditions, [4+2] cycloadditions and ene reactions. Polyunsaturated fatty acids, proteins and DNA are vulnerable targets for O2(1Δg) reaction. Naphthalene derivatives endoperoxides are very useful and versatile as a clean source of O2(1Δg), once they are almost chemically inert. On the other hand, developing new sources of O2(1Δg) are still a challenging task. Naphthalene derivatives are able to trap O2(1Δg) by [4+2] cycloaddition and release it in mild temperatures, which make them very suitable for biological studies. The synthesis of these compounds is based on modifications in substituents bonded in 1,4 positions of nafhthalene backbone. In the first part of present work, the synthesis of three water soluble naphthalene derivatives endoperoxides was performed. DHPNO2, NDPO2 were prepared according to similar methods described in the literature. A new di-cationic naphthalene derivative endoperoxide (NBTEO2) synthesis was developed, containing two quaternary ammonium chloride groups in 1,4-positions of aromatic ring. The key intermediate: for the synthesis of the three endoperoxides is the compound BBMN, which was prepared from radicalar bromination of 1,4-dimethylnaphthalene. Our results have indicated that this di-cationic compound can be a potential chemical source of O2(1Δg) and may be explored in mitochondrial studies where O2(1Δg) biological role is investigated. The second part of this work is dedicated to the investigation of generation of O2(1Δg) through reaction of lipid hydroperoxides (oleic acid, linoleic acids and cholesterol), organic hydroperoxides (cumene and t-butyl), as well as hydrogen peroxide with NO2+, using the compound NO2BF4. Evidences of generation of O2(1Δg) were obtained recording the monomol light emission measurement in near infrared region at wavelength of 1270 nm. Moreover, the proof of the presence of O2(1Δg) was unequivocally demonstrated by the direct spectral characterization of near-infrared light emission. The use of sodium azide as a physical quencher of O2(1Δg), associated to chemiluminescence measurements, contributed to identify the generation of this species in the reaction of lipid hydroperoxides and NO2BF4. Although, it is a chemical approach, our results add important information about lipid peroxidation, mainly when reactive species of nitrogen are involved. O2(1Δg) might be generate as a byproduct of lipid peroxidation, in conditions where reactive nitrogen species interact with lipid hydroperoxides. This might contribute to a better understand of this complex event and physiological or physiopathological implications
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| 18 |
Oxidative Lipid Fragmentation; New Mechanisms, Synthesis and Reactions of Putative IntermediatesGu, Xiaodong January 2010 (has links)
No description available.
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Synthèse et étude de cages moléculaires photo-modulables et génération de nano-cristaux d’or par photo-catalyse supramoléculaire / Synthesis and study of photo-gated molecular cages and generation of gold nanocrystals by supramolecular photocatalysisMongin, Cédric 18 December 2013 (has links)
Les objectifs de cette thèse sont articulés autour de deux axes principaux : la synthèse et l’étude de cages moléculaires photo-modulables, et la génération de nano-cristaux d’or par photo-catalyse supramoléculaire. Ces deux thématiques sont reliées entre elles par l’exploitation des propriétés photophysiques et photochimiques d’un motif commun, le 9,10-diphénylanthracène (DPA). Dans un premier temps, de nouvelles architectures tridimensionnelles photo-modulables de type cage moléculaire ont été conçues et étudiées. En présence d’oxygène, l’irradiation directe ou sensibilisée du DPA permet de former réversiblement le dérivé endoperoxyde et ainsi moduler les propriétés de complexation de la cage. Les différentes stratégies de synthèse mises en place reposent sur l’exploitation conjuguée de la réactivité de la 2,4,6-trichloro-1,3,5-triazine, et de réactions de chimie « click » (métathèse des oléfines, cycloaddition de Huisgen). L’étude et la modulation des propriétés des reconnaissances ont été effectuées sur des sels de cations alcalins (sodium et césium) et suivies par émission de fluorescence et spectroscopie d’absorption UV-visible. Les résultats obtenus avec deux cages possédant des constantes d'associations élevées (logK = 8,7 pour le cation sodium) montrent une augmentation de la constante d’association d’un facteur 10 et 20 pour respectivement le sodium et le césium entre la forme DPA et la forme endoperoxyde. Dans un second temps, des photocatalyseurs supramoléculaires basés sur le chromophore DPA ont été étudiés en vue de la synthèse de nano-cristaux d’or nus. L’association du chromophore avec des thioéthers permet de former un complexe en phase organique par extraction de sels d’or(III) depuis une phase aqueuse. L’irradiation à 400nm permet la réduction de l’or(III) par transfert d’énergie depuis le 9,10-diphénylanthracène. Les atomes d’or sont ensuite relargués en phase aqueuse pour former des nano-cristaux nus qui ont pu être caractérisés par MET, XPS, AFM et DLS. Par ailleurs, ce procédé est catalytique dans le toluène et un système de réduction en flux continu a été mis au point permettant un turnover moyen de 150. / The goals of this thesis are organized around two major axes: the synthesis and study of photo-gated molecular cages, and the generation of gold nanocrystals by supramolecular photocatalysis. These two themes are connected by the use of the photochemical and photophysical properties of a common chromophore, 9,10-diphenylanthracene (DPA). Three-dimensional photo-gated cage-like architectures were designed and synthesized. Various synthetic strategies based on the combined use of the 2,4,6-trichloro-1,3,5-triazine unit and "click" chemistry reactions (olefin metathesis, Huisgen cycloaddition) were employed for the synthesis. In the presence of oxygen, sensitized or direct irradiation of the DPA chromophore forms the corresponding endoperoxide derivative, thereby modulating the binding properties of the cage. The study and the modulation of the recognition properties were performed on various alkali metal cations and a strong binding of sodium and cesium was evidenced by fluorescence emission and UV-visible absorption spectroscopy. The cages investigated possessed high association constants towards sodium and cesium cations (logK = 8.7 for the sodium cation) which could be reversibly increased by a factor 10 and 20 for sodium and cesium, respectively, upon formation of the endoperoxide. Supramolecular photocatalysis of gold(III) reduction based on the DPA chromophore was also studied for the preparation of uncapped gold nanocrystals. The combination of the DPA chromophore with thioether chains allows the formation of a complex in the organic phase by extraction of gold(III) chloride from an aqueous phase. Irradiation at 400 nm enables the reduction gold(III) by energy transfer from the 9,10-diphenylanthracene followed by oxidation of the solvent. The gold atoms are subsequently released in the aqueous phase to form uncapped nanocrystals characterized using TEM, XPS, AFM, and DLS techniques. Furthermore, the process is catalytic in toluene, where a continuous flow reactor was developed. The latter allowed an average catalytic turnover of 150 to be determined.
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