Global ETD Search

171	Efeitos neurodegenerativos da metilecgonidina e da cocaína em cultura celular primária de hipocampo / Neurodegenerative effects of methylecgonidine and cocaine in hippocampal primary cell culture Raphael Caio Tamborelli Garcia 28 September 2009 (has links) O uso da cocaína na forma de crack vem crescendo nos últimos anos quando comparado às demais vias de administração. Contribuem para esse fato a obtenção quase imediata de efeitos e a maior facilidade de uso, que dispensa a necessidade de material injetável. O usuário de crack sofre os efeitos não só da cocaína, mas também de seu produto de pirólise, a metilecgonidina (AEME). Existem evidências de que a cocaína leva à neurodegeneração, entretanto a participação da AEME nesse processo ainda não foi estudada. A proposta deste estudo foi investigar a participação da AEME no processo neurodegenerativo utilizando cultura primária de hipocampo realizada a partir de fetos de ratos. Foram realizados ensaios de viabilidade celular (MTT) e da atividade da lactato desidrogenase (LDH), além da avaliação morfológica por microscopia de fluorescência. Foi estudada também a participação do dano oxidativo no processo de neurodegeneração, como a formação de aduto de DNA; atividade das enzimas antioxidantes glutationa peroxidase (GPx), glutationa redutase (GR) e glutationa S-transferase (GST); e a produção de malonaldeído (MDA), um biomarcador de peroxidação lipídica. Tanto a cocaína quanto a AEME mostraram-se neurotóxicas. A partir dos ensaios de viabilidade e da avaliação morfológica foi possível inferir que, em células hipocampais, a cocaína leva à morte celular tanto por necrose quanto por apoptose e que a provável via envolvida na neurodegeneração da AEME é a apoptose. A AEME não causou lesão direta ao DNA, uma vez que não foi observada a formação de adutos nem com a desoxiguanosina (d-G), a base nitrogenada mais reativa, nem com DNA comercial. Mais ainda, nossos resultados mostraram que a AEME e a cocaína, nas concentrações de 1 e 2 mM, respectivamente, foram equipotentes e a incubação concomitante das duas substâncias nessas concentrações apresentou efeito aditivo após 48 horas de exposição. A morte de células hopocampais evidenciada a partir de 24 horas de exposição foi precedida pela diminuição da atividade da GPx após 3 horas de incubação tanto com a AEME e a cocaína, quanto com a associação entre essas substâncias. A atividade da GST também diminuiu, no entanto, somente após 6 horas de exposição, antecedendo a morte celular. Não foi observada alteração na atividade da GR. Houve um aumento, porém, não estatisticamente significativo, de MDA após 48 horas de incubação. Nossos resultados sugerem uma maior susceptibilidade à neurodegeneração com o uso de crack do que com a cocaína isoladamente. / Smoking crack has increased in the last years when compared to the other routes of cocaine administration. Its advantage is the quicker and stronger high effects and its ease of use without the need of needles. Smoking crack involves inhaling not only cocaine, but also its pyrolysis product, methylecgonidine (AEME). There are evidences that cocaine causes neurodegeneration, but AEME involvement in this process has not been studied yet. The aim of this study was to investigate AEME participation in neurodegeneration using a primary hippocampus culture made from rat fetuses. Cellular viability assays (MTT), lactate dehydrogenase activity (LDH) and morphological evaluations with fluorescence microscopy were performed. The involvement of oxidative injury in the neurodegeneration process was also studied through DNA adduct formation; the evaluation of antioxidants enzymes activities as glutathione peroxidase (GPx), glutathione reductase (GR) and glutathione S-transferase (GST); and the production of malonaldehyde (MDA), a lipoperoxidation biomarker. Both cocaine and AEME showed neurotoxic effects. Through viability assays and morphologic evaluations we can suggest that, in hippocampal cells, cocaine cell death mechanism involves not only necrosis, but also apoptosis and that AEME pathway involved in neurodegeneration is only apoptosis. AEME did not produce a direct DNA injury, as no DNA adduct was observed with desoxyguanosine (d-G), the most reactive nitrogenous base, nor with commercial DNA. Moreover, our results showed that 1 and 2 mM of AEME and cocaine, respectively, were equipotent and the concomitant incubation of both compounds in those concentrations showed additive effect after 48 hours of exposure. Hippocampal cell death at 24 hours was preceded by a decrease in GPx activity after 3 hours of incubation with AEME, cocaine and association between these two compounds. GST activity also decreased but only after 6 hours of exposure, also before cell death. There was no alteration in GR activity. There was an increase, although not statistically significant, in MDA after 48 hours of exposure. As smoking crack abusers are exposed to both cocaine and AEME, our results suggest a higher susceptibility to neurodegeneration in smoking crack than with cocaine alone. Crack Cultura primária de hipocampo Metilecgonidina Neurodegeneração Neurotoxicidade Produto de pirólise de cocaína Cocaine pyrolysis product Crack cocaine Hippocampal primary culture Methylecgonidine Neurodegeneration Neurotoxicity
172	Papel de selenoproteínas na neurotoxicidade induzida por metilmercúrio, em camundongos, e potencial bioinseticida de uma alga da Antártica (Prasiola crispa) em modelo de Drosophila melanogaster Zemolin, Ana Paula Pegoraro 20 August 2012 (has links) Submitted by Diego Santos (diegosantos@unipampa.edu.br) on 2015-04-10T11:49:39Z No. of bitstreams: 1 111010003.pdf: 1306168 bytes, checksum: 65e96979f53ded7b91f629af13358a87 (MD5) / Made available in DSpace on 2015-04-10T11:49:41Z (GMT). No. of bitstreams: 1 111010003.pdf: 1306168 bytes, checksum: 65e96979f53ded7b91f629af13358a87 (MD5) Previous issue date: 2012-08-20 / O metilmercúrio (MeHg) é um agente tóxico que causa importantes prejuízos à saúde humana e ambiental. Parte desses efeitos está relacionado a sua capacidade de induzir estresse oxidativo. Os mecanismos precisos pelos quais o MeHg leva ao estresse oxidativo ainda não estão bem esclarecidos. Dados na literatura apontam para a participação de selenoproteínas como a glutationa peroxidase e a tioredoxina redutase neste processo. Neste estudo, buscou-se investigar o papel de isoformas de glutationa peroxidase (GPx1 e GPx4) e da tioredoxina redutase (TrxR1) na neurotoxicidade induzida por MeHg em camundongos, focando na atividade e expressão destas proteínas. Nossos resultados mostraram, que o tratamento de camundongos Swiss machos adultos com MeHg (40 mg/L na água de beber) durante 21 dias causa uma diminuição significativa na atividade das enzimas GPx e TrxR no córtex e cerebelo dos animais tratados, em comparação com os controles. Observou-se também uma significativa redução na expressão de GPx1, GPx4 e TrxR1 no cerebelo dos animais tratados, enquanto que no córtex apenas GPx4 e TrxR1 foram afetadas. Concomitantemente a estes resultados, observou-se um aumento significativo na atividade das enzimas antioxidantes SOD, CAT, GR e GST no cerebelo e da CAT no cortex. A expressão de HSP70 foi significativamente aumentada no cerebelo dos animais tratados. Estes dados denotam uma clara resposta celular antioxidante frente aos efeitos tóxicos do MeHg em nosso modelo, reforçando dados da literatura que indicam o estresse oxidativo como um importante mecanismos na neurotoxicidade induzida por este organometal. Além disso, nossos resultados apontam para isoformas de glutationa peroxidase e tioredoxina redutase como importantes alvos moleculares do MeHg e, ao menos, em nosso conhecimento, este é o primeiro estudo demonstrando o papel da GPx4 na neurotoxicidade induzida por este agente tóxico ambiental. Outro objetivo deste trabalho foi investigar os efeitos biológicos do extrato da alga Prasiola crispa(PcE), oriunda do continente Antártico, nos modelos de Drosophila melanogaster e Nauphoeta cinérea. Organismos adaptados a ambientes extremos como a Antártica tendem a apresentarem uma constituição única em termos de metabólitos secundários. Desta forma, estudos que visem à elucidação de efeitos biológicos de organismos oriundos destas regiões tendem a apresentarem relevância do ponto de vista biotecnológico. Nossos dados apontam para um potencial biocida de PcE nos modelos de mosca-da-fruta (Drosophila melanogaster) e barata cinerea (Nauphoeta cinerea), visto que a administração do extrato induziu toxicidade nos dois modelos. A toxicidade em D. melanogaster foi avaliada como percentagem de mortalidade, atividade locomotora (geotaxia negativa) e alterações bioquímicas incluindo atividade acetilcolinesterase (AChE) e marcadores de estresse oxidativo.Também foi investigada a ação cardiotóxica do extrato no modelo de coração semi-isolado de barata cinerea. A administração do extrato(2mg/ml) foi feita por 24 horas e, nas moscas, causou um aumento massivo na mortalidade (aumento de 7,6 vezes em relação ao controle). Também foi observado um aumento significativo na atividade locomotora, indicando uma ação neurotóxica do extrato. A atividade AChE, os níveis de glutationa e formação de hidroperóxido manteve-se inalterada. A atividade da glutationa S-transferase aumentou significativamente após a administração de PcE, já a atividade da catalase diminuiu significativamente em moscas que receberam o extrato. No modelo de coração semi-isolado de barata, foi observado uma diminuição da freqüência cardíaca. A incubação do extrato com DTNB, um forte agente oxidante, bloqueou significativamente o efeito cardiotóxico do extrato, sugerindo que compostos redutores podem ser responsáveis pelo efeito observado. Desta forma, este estudo demonstrou os efeitos tóxicos de PcE, em dois modelos de inseto, sugerindo seu potencial como bioinseticida. Os mecanismos precisos relacionados a este efeito ainda necessitam de esclarecimentos, entretanto, alterações em sistemas antioxidantes vitais podem estar envolvidos. / Methylmercury (MeHg) is a toxic agent that causes severe damage to human health and the environment. These effects are related to its ability to induce oxidative stress. The precise mechanisms by which MeHg leads to oxidative stress are not well understood. Data from literature point to the involvement of selenoproteins such as glutathione peroxidase and thioredoxin reductase in this process. In this study, we sought to investigate the role of isoforms of glutathione peroxidase (GPx4 and GPx1) and thioredoxin reductase (TrxR1) in MeHg-induced neurotoxicity in mice, focusing on activity and expression of these proteins. Our results showed that treatment of adult male mice Swiss with MeHg (40 mg / L in drinking water) for 21 days causes a significant decrease in GPx and TrxR enzyme activity in the cerebral cortex and cerebellum of treated animals when compared to controls. We also observed a significant reduction in the expression of GPx1, GPx4 and TrxR1 in the cerebellum of the treated animals, whereas in the cortex only GPx4 and TrxR1 are affected..In parallel, we observed a significant increase in antioxidant enzymes SOD, CAT, GR and GST in the cerebellum and CAT in cortex. HSP70 expression was significantly increased in the cerebellum of the treated animals. These results show a clear antioxidant cell response against the toxic effects of MeHg in our model, reinforcing the literature data indicating oxidative stress as an important mechanism in the neurotoxicity induced by this organometal. Furthermore, our results point to isoforms of glutathione peroxidase and thioredoxin reductase as important molecular targets of MeHg and, at least, to our knowledge, this is the first study demonstrating the role of GPx4 in the neurotoxicity induced by this toxic environmental agent. Another objective of this study was to investigate the biological effects of the extract of the alga Prasiola crispa (PcE), from the Antarctic continent, in the insect models Drosophila melanogaster and Nauphoeta cinerea. Organisms adapted to extreme environments such as Antarctica tend to present a unique composition in terms of secondary metabolites. Thus, studies aimed at elucidating the biological effects of organisms from these areas tend to be relevant in a biotechnological point of view. Our data demonstrates a potential biocide PcE effect in the fruit fly (Drosophila melanogaster) and lobster cockroach (Nauphoeta cinerea), since the administration of the extract induced toxicity in both models. Toxicity in D. melanogaster was assessed as percentage of mortality, locomotor activity (negative geotaxis) and biochemical measurements including acetylcholinesterase (AChE) and markers of oxidative stress. We also investigated the cardiotoxic action of the extract in a cockroach semi-isolated heart model. The administration of the extract (2 mg / ml) for 24 hours toflies, caused a massive increase in mortality (7.6-fold increase compared to control). We also observed a significant increase in locomotor activity, indicating a neurotoxic action of the extract. AChE activity, glutathione levels and the formation of hydroperoxide remained unchanged. The activity of glutathione S-transferase significantly increased after administration of PcE while catalase activity was significantly decreased in flies that received the extract. A significant decrease in heart rate in the cockroach semi-isolated heart model was observed after PcE administration. The incubation of the extract with DTNB, a strong oxidizing agent, significantly blocked the cardiotoxic effect of the extract, suggesting that reducing compounds may be responsible for the observed effect. Thus, this study demonstrated, for the first time, the toxic effects of PcE, in two insect models, suggesting its potential as a bioinsecticide. The precise mechanisms related to this effect still need clarification, however, changes in vital antioxidant systems may be involved. Metilmercúrio Neurotoxicidade Glutationa peroxidase Tioredoxina redutase Prasiola crispa Antártica Efeito bioinseticida Methylmercury Neurotoxicity Glutathione peroxidase Thioredoxin reductase Prasiola crispa Antarctica Effect of insecticide
173	The synthesis and evaluation of 1-methyl-3-pyrrolines and 1-methylpyrroles as substrates and inhibitors of monoamine oxidase B / Modupe O. Ogunrombi Ogunrombi, Modupe Olufunmilayo January 2007 (has links) Very little is known about why and how the Parkinson's disease (PD) neurodegenerative process begins and progresses. In the course of developments for treatment of PD, the discovery of the inhibition of monoamine oxidase (MAO B) was a conceptual breakthrough, and has now been firmly established. MAO B has also been implicated in the neurodegenerative processes resulting from exposure to xenobiotic amines. For example, MAO B catalyzes the first step of the bioactivation of the parkinsonian inducing pro-neurotoxin, 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP). Additional insight into the mechanism of catalysis of MAO B and the mechanism of neurotoxicity by MPTP is therefore very valuable in the pursuit of the treatment of PD. / Thesis (Ph.D. (Pharmaceutical Chemistry))--North-West University, Potchefstroom Campus, 2008. Monoamine oxidase B MPTP 1-methyl-3-phenyl-3-pyrroline 1-methyl-3-phenyl-3-pyrrole Neurotoxicity Dopamine Striata Reversible inhibitors Competitive inhibition Structure-activity relationship
174	Drug consumption and stressful experiences in adolescent mice: behavioural, neorotoxic and neurochemical responses Ros i Simó, Clara, 1984- 15 March 2013 (has links) Adolescence is a critical developmental period in which the brain emerges from an immature state to adulthood. This process of brain development is associated to greater cognitive capacity but also to altered emotional behaviour, such as anxiety and depressive symptoms; as well as increased sensation-seeking and risk taking behaviour. The proper development of brain and behaviour into adulthood can be negatively affected by external factors such as drug abuse and environmental conditions. This work consists firstly on, studying the impact of binge ethanol, 3, 4-Methylenedioxymethamphetamine (MDMA) and its combination in adolescent mice. Secondly, study the consequences of early-life stressful experiences (social isolation) into adulthood. Main results obtained from the first objective are that the combination of binge ethanol and MDMA induces emotional-like alterations. These alterations can be prevented by antidepressant treatment. In addition, MDMA induces memory impairments that may be associated to oxidative damage to specific proteins in the hippocampus. Neuroinflammation is also present after MDMA treatment, but not after binge ethanol treatment, in mice striatum. Metabolomic studies indicate that brain metabolism is altered after binge ethanol, MDMA or its combination. Even though these are only preliminary results, these alterations might be due to an imbalance in tryptophan metabolism. Regarding the second objective, our findings indicate that social isolation during adolescence induces an altered response to novel and stressful situations. These alterations are probably due to altered HPA axis activity. / L'adolescència és un període crític en el desenvolupament de l’individu en el qual el cervell va d’un estat immadur a l’edat adulta. Aquest procés va acompanyat d’una elevada capacitat cognitiva però també de freqüents alteracions de tipus emocional, com l’ansietat o els símptomes depressius, així com la cerca de sensacions de risc. Un bon desenvolupament del cervell i del comportament es pot veure negativament afectat per factors externs com són l’abús de drogues i les condicions ambientals desfavorables. Aquest projecte consisteix en primer lloc, a estudiar l'impacte de l’alcohol en excés, la 3, 4-Metilendioximetamfetamina (MDMA) i la seva combinació en ratolins adolescents. En segon lloc, estudiar les conseqüències en l’edat adulta d’experiències estressants durant l’adolescència. Els principals resultats obtinguts referents al primer objectiu són que la combinació d'alcohol en excés i MDMA provoca alteracions de tipus emocional. Aquestes alteracions poden ser previngudes pel tractament amb antidepressius. A més, la MDMA indueix un deteriorament de la memòria que pot estar associada amb el dany oxidatiu a proteïnes específiques de l'hipocamp. També s’ha observat una resposta neuroinflamatòria en el cos estriat dels ratolins després del tractament amb MDMA, però no després del tractament amb etanol en excés. Finalment, estudis de metabolòmica indiquen que el metabolisme cerebral es veu alterat després de l’alcohol en excés, la MDMA o la seva combinació. Tot i que només són resultats preliminars, aquestes alteracions poden ser conseqüència d'un desequilibri en el metabolisme del triptòfan. Referent al segon objectiu, els nostres resultats indiquen que l'aïllament social durant l’adolescència indueix una resposta alterada a situacions novelles i estressants. Aquestes respostes anormals són probablement conseqüència d’alteracions en l’activitat de l’eix HPA. Behaviour Binge ethanol MDMA Memory Proteomics Metabolomics Neurotoxicity Environmental enrichment Comportament Alcohol en excés MDMA Memòria Proteòmica Metabolòmica Neurotoxicitat Enriquiment ambiental 616.8
175	Distribution and Long-term Effects of the Environmental Neurotoxin β-N-methylamino-L-alanine (BMAA) : Brain changes and behavioral impairments following developmental exposure Karlsson, Oskar January 2010 (has links) Many cyanobacteria are reported to produce the nonprotein amino acid β-N-methylamino-L-alanine (BMAA). Cyanobacteria are extensively distributed in terrestrial and aquatic environments and recently BMAA was detected in temperate aquatic ecosystems, e.g. the Baltic Sea. Little is known about developmental effects of the mixed glutamate receptor agonist BMAA. Brain development requires an optimal level of glutamate receptor activity as the glutamatergic system modulates many vital neurodevelopmental processes. The aim of this thesis was to investigate the developmental neurotoxicity of BMAA, and its interaction with the pigment melanin. Autoradiography was utilized to determine the tissue distribution of 3H-labelled BMAA in experimental animals. Behavioral studies and histological techniques were used to study short and long-term changes in the brain following neonatal exposure to BMAA. Long-term changes in protein expression in the brain was also investigated using matrix-assisted laser desorption ionization (MALDI) imaging mass spectrometry (IMS). A notable targeting of 3H-BMAA to discrete brain regions e.g. hippocampus and striatum in mouse fetuses and neonates was determined by autoradiography. BMAA treatment of neonatal rats on postnatal days 9–10 induced acute but transient ataxia and hyperactivity. Postnatal exposure to BMAA also gave rise to reduced spatial learning and memory abilities in adulthood. Neonatal rat pups treated with BMAA at 600 mg/kg showed early neuronal cell death in the hippocampus, retrosplenial and cingulate cortices. In adulthood the CA1 region of the hippocampus displayed neuronal loss and astrogliosis. Lower doses of BMAA (50 and 200 mg/kg) caused impairments in learning and memory function without any acute or long-term morphological changes in the brain. The MALDI IMS studies, however, revealed changes in protein expression in the hippocampus and striatum suggesting more subtle effects on neurodevelopmental processes. The studies also showed that BMAA was bound and incorporated in melanin and neuromelanin, suggesting that pigmented tissues such as in the substantia nigra and eye may be sequestering BMAA. In conclusion, the findings in this thesis show that BMAA is a developmental neurotoxin in rodents. The risks posed by BMAA as a potential human neurotoxin merits further consideration, particularly if the proposed biomagnifications in the food chain are confirmed. ALS/PDC Guam Developmental neurotoxicity Brain growth spurt Behavior Nonprotein amino acid Excitotoxic Cyanobacteria Apoptosis BMAA environmental toxin Algal blooming Algblomning algtoxin alggift hjärnutveckling Toxicology Toxikologi
176	Neurotoxicity of β-lactam antibiotics : experimental kinetic and neurophysiological studies Schliamser, Silvia E. January 1988 (has links) The neurotoxic potential of intravenous administered benzylpenicillin (BPC) was studied in rabbits with intact blood-CNS barriers and rabbits with experimental E. coli meningitis. At onset of epileptogenic EEG activity or seizures, serum, CSF and brain tissue were collected for assay of BPC. Based on the fact that, in tissues, BPC seems to remain extracellularly, brain concentrations of BPC were expressed as brain tissue fluid (BTF) levels, calculated as lOx the concentration in whole brain tissue. Neurotoxicity could be precipitated in all rabbits. In normal rabbits BTF levels of BPC were considerably higher than those in CSF indicating a better penetration across the blood-brain barrier (BBB). BPC penetrated better to CSF and BTF in meningitic rabbits than in normal controls, suggesting some degree of damage of the BBB concomitant with meningeal inflammation. E. coli meningitis did not increase the neurotoxicity of BPC. In control rabbits the intracistemal injection of saline resulted in some degree of pleocytosis. Unmanipulated animals are therefore preferable as controls. Epileptogenic EEG-changes was the most precise of the two variables used for demonstration of neurotoxicity. EEG-changes were therefore used as neurotoxicity criterion in the following rabbit experiments. To evaluate the effect of uraemia alone and uraemia plus meningitis on the neurotoxity of BPC in rabbits, cephaloridine was used to induce uraemia. Meningitis was induced by intracistemal inoculation of a cephalosporinresistant strain of E. cloacae. Untreated rabbits were used as controls. Uraemia resulted in increased BTF penetration of BPC, possibly explained by permeability changes in the BBB and/or decreased binding of BPC to albumin. Uraemia did not result in increased penetration of BPC into the CSF of non-meningitic rabbits. Uraemic non-meningitic rabbits had the highest BTF levels of BPC at the criterion, indicating that cephaloridine-induced renal failure increased the epileptogenic threshold in these rabbits. The combination of uraemia and meningitis increased the neurotoxicity of BPC since the criterion was reached at considerably lower BTF levels of BPC. Meningitis, either alone or together with uraemia, did not increase the neurotoxicity in comparison to control rabbits. Higher BTF levels of BPC were found in meningitic rabbits than in controls with intact blood-CNS barriers at onset of EEG-changes. In all groups of rabbits there was a pronounced variability of BPC levels in the CSF while the intra-group variations in BTF levels were much smaller. Thus, BTF and not CSF levels were decisive for the neurotoxicity of BPC. Using the same EEG-model, the neurotoxic potential of imipenem/cilastatin (I) and a new penem derivative, FCE 22101 were compared in a cross-over study. Both I and FCE 22101 were significantly more neurotoxic than BPC. While BTF levels of the three antibiotics could be detected in all tested rabbits, detectable CSF levels were only found in one of twelve rabbits treated with I or FCE 22101, indicating that BTF concentrations rather than CSF ones are decisive for neurotoxicity of ß-lactam antibiotics. The EEG-model used was found to be a suitable model for cross-over studies of intravenously administered antibiotics. Using the "silent-second" as EEG-threshold, a CNS interaction between intraperitoneally administered BPC and intravenous thiopental was demonstrated in rats. The most probably site for this interaction is the organic acid transport system out of the CNS. Thiopental distribution in the rat brain seemed to depend not only on its lipid solubility. / <p>Diss. (sammanfattning) Umeå : Umeå universitet, 1988, härtill 5 uppsatser.</p> / digitalisering@umu benzylpenicillin blood-brain barrier ß-lactam antibiotics CSF CNS EEG imipenem /cilastatin FCE 22101 meningitis neurotoxicity of silent-second thiopental transport system uraemia
177	The synthesis and evaluation of 1-methyl-3-pyrrolines and 1-methylpyrroles as substrates and inhibitors of monoamine oxidase B / Modupe O. Ogunrombi Ogunrombi, Modupe Olufunmilayo January 2007 (has links) Very little is known about why and how the Parkinson's disease (PD) neurodegenerative process begins and progresses. In the course of developments for treatment of PD, the discovery of the inhibition of monoamine oxidase (MAO B) was a conceptual breakthrough, and has now been firmly established. MAO B has also been implicated in the neurodegenerative processes resulting from exposure to xenobiotic amines. For example, MAO B catalyzes the first step of the bioactivation of the parkinsonian inducing pro-neurotoxin, 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP). Additional insight into the mechanism of catalysis of MAO B and the mechanism of neurotoxicity by MPTP is therefore very valuable in the pursuit of the treatment of PD. / Thesis (Ph.D. (Pharmaceutical Chemistry))--North-West University, Potchefstroom Campus, 2008. Monoamine oxidase B MPTP 1-methyl-3-phenyl-3-pyrroline 1-methyl-3-phenyl-3-pyrrole Neurotoxicity Dopamine Striata Reversible inhibitors Competitive inhibition Structure-activity relationship
178	The synthesis and evaluation of 1-methyl-3-pyrrolines and 1-methylpyrroles as substrates and inhibitors of monoamine oxidase B / Modupe O. Ogunrombi Ogunrombi, Modupe Olufunmilayo January 2007 (has links) Very little is known about why and how the Parkinson's disease (PD) neurodegenerative process begins and progresses. In the course of developments for treatment of PD, the discovery of the inhibition of monoamine oxidase (MAO B) was a conceptual breakthrough, and has now been firmly established. MAO B has also been implicated in the neurodegenerative processes resulting from exposure to xenobiotic amines. For example, MAO B catalyzes the first step of the bioactivation of the parkinsonian inducing pro-neurotoxin, 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP). Additional insight into the mechanism of catalysis of MAO B and the mechanism of neurotoxicity by MPTP is therefore very valuable in the pursuit of the treatment of PD. / Thesis (Ph.D. (Pharmaceutical Chemistry))--North-West University, Potchefstroom Campus, 2008. Monoamine oxidase B MPTP 1-methyl-3-phenyl-3-pyrroline 1-methyl-3-phenyl-3-pyrrole Neurotoxicity Dopamine Striata Reversible inhibitors Competitive inhibition Structure-activity relationship
179	Proteomic Characterization of Induced Developmental Neurotoxicity Alm, Henrik January 2009 (has links) The developing brain goes through a number of developmental periods during which it displays an increased sensitivity to exogenous disturbances. On such period is the so called “Brain growth spurt” (BGS) which in humans takes place starting from the third trimester of pregnancy and throughout the first few years of life. The corresponding period in rats and mice is the first postnatal weeks. Exposure to relatively modest concentrations of the brominated flame retardant PBDE-99 during the second week of life in mice causes a more or less permanent impairment in the ability of the animals to adjust properly to environmental changes at adulthood. This “late response on early exposure” reflects the long-term consequences of disrupting the developing brain during a sensitive time period. The cellular mechanisms underlying the behavioral effects are far from clear. To address the initial damage occurring around the time of exposure, the approach used in this thesis is to use proteomics to analyze the effects of PBDE-99 on protein expression soon (24 hours) after exposure of the neonatal mouse on postnatal day (PND) 10.The thesis comprises the effects on the proteome in three distinct brain parts: cerebral cortex, striatum and the hippocampus. In addition, an in vitro model was developed and used to evaluate the PBDE-99 effects on cultured cerebral cortex cells from embryonic rat brains. Gel-based proteomics (2D-DIGE) coupled to MALDI- or ESI-MS has been used throughout for the proteomics experiments, but other techniques aimed at analyzing both proteins and mRNA have also been used to better characterize the effects. Even if the protein complements expressed by the different brain parts and separated with 2D-DIGE are seemingly similar, the effects are apparently specific for the different brain regions. In hippocampus, PBDE induces effects on proteins involved in metabolism and energy production, while the effects in striatum point towards effects on neuroplasticity. PBDE-99 changes the expression of cytoskeletal proteins in the cerebral cortex 24 hours after exposure. Interestingly, in vitro exposure of cerebral cortex cells to a PBDE-99 concentration in the same order of magnitude as in the in vivo neonatal brain also induces cytoskeletal effects, in the absence of cytotoxicity. This may suggest effects on regulatory aspects of cytoskeletal dynamics such as those involved in neurite sprouting. This thesis also addresses the problems involved in presenting proteomics data. Many of the available methods and approaches for presenting transcriptomics data are not suitable for isoform rich protein data. Modifications of existing methods and the development of a new approach (DEPPS) is also presented. Most importantly, the thesis presents the application and usefulness of proteomics as hypothesis generating techniques in neurotoxicology. Proteomics Brain Development Neurotoxicity 2D-DIGE Brain Growth Spurt Polybrominated Diphenyl Ether Neonatal Striatum Hippocampus Cerebral Cortex Parkinsonism Dyskinesia Toxicology Toxikologi
180	EFEITO DA ADMINISTRAÇÃO ORAL DE AFLATOXINA B1 NAS CONVULSÕES INDUZIDAS EM RATOS / EFFECT OF ORAL ADMINISTRATION OF AFLATOXIN B1 IN PENTYLENETETRAZOL-INDUCED SEIZURES IN RATS Trombetta, Francielle 14 August 2014 (has links) Aflatoxins are produced by Aspergillus flavus fungi, mainly A. parasiticus and A. nomius. Aflatoxin B1 (AFB1) is the most common and highly toxic mycotoxin, presents carcinogenic, mutagenic and teratogenic effects. This mycotoxin has been detected in cultures of worldwide importance such as maize, groundnuts, beans, rice, wheat, cotton, sorghum, fruit and also in animal feed. AFB1 exerts its effects after its conversion into liver 8,9-epoxide by the action of cytochrome P-450, which reacts with cellular macromolecules, including proteins, RNA and DNA. Furthermore, there is an increase in levels of reactive oxygen species, altered neurobehavioral performance, damage to motor coordination, and decreased protein levels. Studies show that AFB1 alter the levels of neurotransmitters such as norepinephrine, serotonin and dopamine, and it is known that these changes influence the behavior of animals, also inhibits the activity of the enzyme Na+, K+-ATPase. This enzyme in the brain is essential for the maintenance of the electrochemical gradient, maintenance of resting potential and the release and uptake of neurotransmitters. Thus, a decrease in activity Na+, K+-ATPase could cause increased neuronal excitability, facilitating the occurrence of seizures. Thus, the aim of this study was to investigate the influence of AFB1 in facilitating seizures induced by a subconvulsant dose of pentylenetetrazol (PTZ), and evaluate its toxic effects on the brain, by determining the activity of Na+, K+-ATPase and oxidative stress parameters after acute exposure to AFB1 in rats. EEG recording of the animals was performed after acute oral administration of AFB1 (250 mg/kg) followed by a subconvulsant dose of pentylenetetrazol (30 mg/kg, ip). Prior administration of AFB1 to PTZ reduced the latency of myoclonus, did not alter the total amplitude of the brain waves, and concomitant exposure to PTZ reduced the activity total, α1 and α2/α3 of the enzyme Na+, K+-ATPase in the cerebral cortex. In the hippocampus, the AFB1 and PTZ reduced total and α2/α3 activity of the Na+, K+-ATPase. The AFB1 not alter the activity of catalase (CAT), and glutathione-S-transferase (GST) in the cerebral cortex of animals. We conclude that AFB1 exerts neurotoxic effect, facilitating seizures induced by PTZ possibly by inhibiting Na+, K+-ATPase activity. / As aflatoxinas são produzidas principalmente pelos fungos Aspergillus flavus, A. parasiticus e A. nomius. A aflatoxina B1 (AFB1) é a micotoxina mais frequente e altamente tóxica, apresenta efeitos carcinogênicos, mutagênicos e teratogênicos. Esta micotoxina tem sido detectada em culturas de importância em todo o mundo, como milho, amendoim, feijão, arroz, trigo, algodão, sorgo, frutas e também em rações de animais. A AFB1 exerce seus efeitos após sua conversão hepática em 8,9-epóxido, pela ação de enzimas do citocromo P-450, o qual reage com macromoléculas celulares, incluindo proteínas, RNA e DNA. Além disso, há um aumento nos níveis de espécies reativas de oxigênio, alteração do desempenho neurocomportamental, prejuízos à coordenação motora, e diminuição dos níveis proteicos. Estudos revelam que a AFB1 altera os níveis de neurotransmissores como a norepinefrina, serotonina e dopamina, e sabe-se que estas alterações influenciam no comportamento dos animais, como também inibe a atividade da enzima Na+,K+-ATPase, enzima que no cérebro, é essencial para a manutenção do gradiente eletroquímico, manutenção dos potenciais de repouso e liberação e captação de neurotransmissores. Assim, uma diminuição da atividade Na+,K+-ATPase pode ocasionar aumento da excitabilidade neuronal, facilitando a ocorrência de convulsões. Sendo assim, o objetivo deste trabalho foi investigar a influência da AFB1 em facilitar as convulsões induzidas por uma dose subconvulsivante de pentilenotetrazol (PTZ), e avaliar seus efeitos tóxicos sobre o cérebro, através da determinação da atividade da Na+,K+-ATPase e parâmetros de estresse oxidativo após a exposição aguda à AFB1 em ratos. Foi realizado o registro eletroencefalográfico dos animais após a administração oral aguda de AFB1 (250 μg/kg) seguida por uma dose subconvulsivante de pentilenotetrazol (30 mg/kg, i.p.). A administração prévia da AFB1 ao PTZ reduziu a latência das mioclonias, não alterou a amplitude global das ondas cerebrais, e a exposição concomitante ao PTZ reduziu a atividade total, α1 e α2/α3 da enzima Na+,K+-ATPase no córtex cerebral. No hipocampo, a AFB1 e o PTZ reduziram a atividade total e α2/α3 da Na+,K+-ATPase. A AFB1 não alterou a atividade da catalase (CAT) e da glutationa-S-transferase (GST) no córtex cerebral dos animais. Concluímos que a AFB1 exerce efeito neurotóxico, facilitando as convulsões induzidas por PTZ, possivelmente devido à redução da atividade da enzima Na+,K+-ATPase. Aflatoxina B1 Na+,K+-ATPase Estresse oxidativo Neurotoxicidade Convulsões Pentilenotetrazol Aflatoxin B1 Na+,K+-ATPase Oxidative stress Neurotoxicity Seizures Pentilenetetrazol CNPQ::CIENCIAS BIOLOGICAS::FARMACOLOGIA

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