Global ETD Search

11	Atividade in vitro, individual ou em combinação, de voriconazol, itraconazol e terbinafina contra isolados brasileiros de Pythium insidiosum. Argenta, Juliana Siqueira January 2008 (has links) Pythium insidiosum, classificado no Reino Stramenopila e Classe Oomycetes, é o agente etiológico da pitiose, uma doença diagnosticada principalmente em eqüinos, caninos e humanos. As atividades in vitro do voriconazol, itraconazol e terbinafina, sozinhos ou em combinação, foram estudadas empregando uma metodologia de macrodiluição baseada na técnica M 38-A (CLSI, 2002) contra 30 isolados clínicos de Pythium insidiosum, com o objetivo de avaliar novas medidas para tratar infecções causadas por este agente utilizando quimioterapia. As combinações (terbinafina e voriconazol; terbinafina e itraconazol) tiveram suas interações avaliadas utilizando a técnica de checkerboard seguindo o modelo da macrodiluição em caldo. Terbinafina foi ativa quando testada sozinha, mostrando uma concentração inibitória mínima (CIM) e concentração fungicida mínima ≤ 8,0 mg/L para todos os isolados. Voriconazol e itraconazol foram inativos contra os isolados testados quando usados sozinhos. A combinação de voriconazol com terbinafina foi sinérgica contra 17% das amostras e indiferente em 25 (83%) amostras. O uso concomitante de terbinafina e itraconazol foi sinérgico contra 17% e indiferente contra 83% das amostras. As interpretações de ambas as interações foram equivalentes para 26 isolados (87%): vinte e três foram indiferentes e três mostraram efeito sinérgico. Antagonismo não foi observado. A terapia combinada é uma alternativa à monoterapia, especialmente para pacientes com infecções invasivas que são difíceis de tratar. Estes resultados precisam ser correlacionados com relatos clínicos; e ensaios in vivo, usando modelos animais, podem preencher a lacuna entre avaliações clínicas e avaliações in vitro das drogas. / Pythium insidiosum is classified in the kingdom Stramenopila, class Oomycetes. It causes pythiosis, a disease mainly diagnosed in horses, dogs, and humans. In order to evaluate new approaches to treat infections caused by Pythium insidiosum using chemotherapy, the in vitro activities of voriconazole, itraconazole and terbinafine, alone or in combination, against 30 clinical isolates were studied employing a macrodilution methodology based on the M 38-A technique (CLSI, 2002). The combinations (terbinafine plus voriconazole and terbinafine plus itraconazole) had their interactions evaluated using the checkerboard technique following the broth macrodilution design. Terbinafine was active when used as a single drug, showing minimal inhibitory concentration (MIC) and minimal fungicidal concentration ≤ 8,0 mg/L for all the isolates. Voriconazole and itraconazole were inactive against the isolates tested when used alone. The combination of voriconazole with terbinafine was synergic against 17% of the strains and indifferent on 25 (83%) strains. The concomitant use of terbinafine and itraconazole was synergic against 17% and indifferent against 83% of the strains. The interpretations of both interactions were equivalent for 26 isolates (87%): twenty three were indifferent and three showed synergistic effect. Antagonism was not observed. Combination therapy provides an alternative to monotherapy, especially for patients with invasive infections that are difficult to treat. These results need to be correlated with clinical outcomes, and in vivo assays using experimental animal models could bridge the gap between in vitro and clinical evaluation of drugs. Micologia veterinaria Pythium insidiosum Drogas Pythium insidiosum Voriconazole Itraconazole Terbinafine Susceptibility test
12	Esporotricose sistêmica experimental: Avaliação in vivo da β (1-3) glucana em associação ao itraconazol em modelo murino / Experimental systemic sporotrichosis: evaluation in vivo _ (1-3) glucan and in association to itraconazole in murine model Martins, Anelise Afonso January 2012 (has links) A esporotricose, micose subcutânea causada pelo fungo dimórfico Sporothrix schenckii, acomete o homem e várias espécies de animais, sendo os felinos domésticos a espécie mais comumente envolvida nos relatos zoonóticos da enfermidade. Considerando as dificuldades terapêuticas no tratamento da micose, incluindo toxicidade e o desenvolvimento de resistência aos antifúngicos disponíveis, o estudo objetivou avaliar a eficácia in vivo do imunomodulador (1-3) glucana e em associação ao Itraconazol no tratamento da esporotricose sistêmica experimental, além de avaliar a presença do S. schenckii na cavidade oral e a produção de óxido nítrico. Foram utilizados 96 ratos Wistar, machos, os quais foram divididos em seis grupos de 16 animais, sendo eles G1: 0,5mg de glucana previamente (três doses) e pós a inoculação; G2: 0,5 mg glucana pós inoculação; G3: grupo controle; G4: 0,5mg de glucana associada a 10mg/kg de itraconazol; G5: 10mg/kg de itraconazol; e grupo G6: duas doses de 0,5mg de glucana associado a 10mg/kg de itraconazol. Os animais foram inoculados com 0,1ml do inóculo fúngico pela via intraperitoneal e veia lateral da cauda, após uma semana iniciou-se o tratamento dos grupos, quando estes apresentavam sinais clínicos da enfermidade. Após acompanhamento clínico durante a cinco semanas de tratamento e isolamento do agente na cavidade oral dos animais, estes foram eutanasiados e necropsiados para a coleta de sangue, avaliação anatomopatológica dos órgãos, retroisolamento do agente, quantificação das unidades formadoras de colônias (UFC) do baço e quantificação de óxido nítrico. Na primeira avaliação foi observado no grupo G1, uma prevenção da enfermidade desencadeada pela glucana, uma vez que, os animais pertencentes a esse grupo não apresentaram sinais clínicos, lesões anatomopatológicas e obtiveram a menor quantificação de UFC (p<0,5). No entanto no final do período experimental o G4 foi significativamente melhor dentre os grupos de tratamento, pois, findou o período com 70% dos animais sem qualquer alteração clínica, lesões macroscópicas nos órgãos e retroisolamento do agente, além de demonstrar menor quantificação nas UFCs e não ocorrer nenhum óbito decorrente da enfermidade. Os grupos G2, G5 e G6 foram significativamente melhor que o grupo controle uma vez que este grupo apresentou uma mortalidade de 31,25%, além de que 100% dos animais permanceram com alterações clínicas, lesões em órgão como fígado, baço e testículo e demonstraram maior quantificação de UFC (p<0,5). Quanto á produção de óxido nítrico foi verificado maior quantidade nos grupos que receberam a glucana em detrimento aos demais grupos. Em vista dos resultados obtidos conclui-se que a glucana induz a produção de óxido nítrico e os cinco tratamentos demostraram resultados satisfatórios, no entanto, a associação do antifúngico e (1-3) glucana propiciou uma regressão mais precoce das lesões no tratamento da esportricose sistêmica experimental. / Sporotrichosis is a subcutaneous mycosis caused by the dimorphic fungus Sporothrix schenckii, which affects humans and a wide variety of animals, domestic cats involved in reports of zoonotic illness. Considering the difficulties in the therapeutic treatment of ringworm, including toxicity and the development of resistance to antifungals available, the study aimed to evaluate the efficacy of the immunomodulator in vivo (1-3) glucan and in combination with Itraconazole in the treatment of experimental systemic sporotrichosis, beyond to evaluate the presence of S. Schenckii in the oral cavity of experimental animals and the production of oxide nitric. Were used 96 male Wistar rats, which were divided into 6 groups of 16 animals, and they were G1: 0.5 mg of glucan in advance (three doses) and after inoculation G2: 0.5 mg glucan after inoculation; G3: control group; G4: 0.5 mg of glucan associated with 10mg/kg of itraconazole; G5: 10mg/kg of itraconazole, and G6: two doses of 0.5 mg of glucan associated 10mg/kg of the itraconazole. The animals were inoculated with 0.1 ml of fungal inoculum by intraperitoneal and lateral tail vein, after one week started treatment groups when they showed clinical signs of disease. After clinical monitoring during the five weeks of treatment and isolation of the agent in the oral cavity of animals, they were euthanized and necropsied to collect blood, anatomopathological evaluation of organs, organ cultures of the agent, and quantification of colony forming units (CFU) of spleen. In the first evaluation was observed in G1, a prevention of the disease triggered by glucan, since the animals from this group showed no clinical signs, anatomopathologicals lesions and obtained the smaller number of CFU (p <0.5). However at the end of experimental period the G4 was significantly better among the treatment groups, therefore, ended the period with 70% of animals without any clinical alteration, macroscopic lesions in organs and organ cultures of the agent, beyond to demonstrate smaller number in CFUs and not occur any deaths resulting from illnes .The groups G2, G5 and G6 were significantly better than the control group since this group had a mortality rate of 31.25%, besides that 100% of the animals remained with clinical changes, lesions in organs such as liver, spleen and testis and demonstrated greater quantification of CFU (p <0,5). As the production of nitric oxide has been found much in the groups receiving the glucan rather than to the other groups. In view of these obtained results it is concluded that glucan induces the production of nitric oxide and the five treatments demonstrated efficacy to the reference sporotrichosis experimental systemically, however, the combination of antifungal (1-3) glucan provided an early regression of the lesions. Sporothrix schenckii Esporotricose glucana Itraconazol modelo murino Micoses : Subcutaneas Imunomodulacao Sporotrichosis Itraconazole Glucan Sporothrix scheckii
13	Esporotricose sistêmica experimental: Avaliação in vivo da β (1-3) glucana em associação ao itraconazol em modelo murino / Experimental systemic sporotrichosis: evaluation in vivo _ (1-3) glucan and in association to itraconazole in murine model Martins, Anelise Afonso January 2012 (has links) A esporotricose, micose subcutânea causada pelo fungo dimórfico Sporothrix schenckii, acomete o homem e várias espécies de animais, sendo os felinos domésticos a espécie mais comumente envolvida nos relatos zoonóticos da enfermidade. Considerando as dificuldades terapêuticas no tratamento da micose, incluindo toxicidade e o desenvolvimento de resistência aos antifúngicos disponíveis, o estudo objetivou avaliar a eficácia in vivo do imunomodulador (1-3) glucana e em associação ao Itraconazol no tratamento da esporotricose sistêmica experimental, além de avaliar a presença do S. schenckii na cavidade oral e a produção de óxido nítrico. Foram utilizados 96 ratos Wistar, machos, os quais foram divididos em seis grupos de 16 animais, sendo eles G1: 0,5mg de glucana previamente (três doses) e pós a inoculação; G2: 0,5 mg glucana pós inoculação; G3: grupo controle; G4: 0,5mg de glucana associada a 10mg/kg de itraconazol; G5: 10mg/kg de itraconazol; e grupo G6: duas doses de 0,5mg de glucana associado a 10mg/kg de itraconazol. Os animais foram inoculados com 0,1ml do inóculo fúngico pela via intraperitoneal e veia lateral da cauda, após uma semana iniciou-se o tratamento dos grupos, quando estes apresentavam sinais clínicos da enfermidade. Após acompanhamento clínico durante a cinco semanas de tratamento e isolamento do agente na cavidade oral dos animais, estes foram eutanasiados e necropsiados para a coleta de sangue, avaliação anatomopatológica dos órgãos, retroisolamento do agente, quantificação das unidades formadoras de colônias (UFC) do baço e quantificação de óxido nítrico. Na primeira avaliação foi observado no grupo G1, uma prevenção da enfermidade desencadeada pela glucana, uma vez que, os animais pertencentes a esse grupo não apresentaram sinais clínicos, lesões anatomopatológicas e obtiveram a menor quantificação de UFC (p<0,5). No entanto no final do período experimental o G4 foi significativamente melhor dentre os grupos de tratamento, pois, findou o período com 70% dos animais sem qualquer alteração clínica, lesões macroscópicas nos órgãos e retroisolamento do agente, além de demonstrar menor quantificação nas UFCs e não ocorrer nenhum óbito decorrente da enfermidade. Os grupos G2, G5 e G6 foram significativamente melhor que o grupo controle uma vez que este grupo apresentou uma mortalidade de 31,25%, além de que 100% dos animais permanceram com alterações clínicas, lesões em órgão como fígado, baço e testículo e demonstraram maior quantificação de UFC (p<0,5). Quanto á produção de óxido nítrico foi verificado maior quantidade nos grupos que receberam a glucana em detrimento aos demais grupos. Em vista dos resultados obtidos conclui-se que a glucana induz a produção de óxido nítrico e os cinco tratamentos demostraram resultados satisfatórios, no entanto, a associação do antifúngico e (1-3) glucana propiciou uma regressão mais precoce das lesões no tratamento da esportricose sistêmica experimental. / Sporotrichosis is a subcutaneous mycosis caused by the dimorphic fungus Sporothrix schenckii, which affects humans and a wide variety of animals, domestic cats involved in reports of zoonotic illness. Considering the difficulties in the therapeutic treatment of ringworm, including toxicity and the development of resistance to antifungals available, the study aimed to evaluate the efficacy of the immunomodulator in vivo (1-3) glucan and in combination with Itraconazole in the treatment of experimental systemic sporotrichosis, beyond to evaluate the presence of S. Schenckii in the oral cavity of experimental animals and the production of oxide nitric. Were used 96 male Wistar rats, which were divided into 6 groups of 16 animals, and they were G1: 0.5 mg of glucan in advance (three doses) and after inoculation G2: 0.5 mg glucan after inoculation; G3: control group; G4: 0.5 mg of glucan associated with 10mg/kg of itraconazole; G5: 10mg/kg of itraconazole, and G6: two doses of 0.5 mg of glucan associated 10mg/kg of the itraconazole. The animals were inoculated with 0.1 ml of fungal inoculum by intraperitoneal and lateral tail vein, after one week started treatment groups when they showed clinical signs of disease. After clinical monitoring during the five weeks of treatment and isolation of the agent in the oral cavity of animals, they were euthanized and necropsied to collect blood, anatomopathological evaluation of organs, organ cultures of the agent, and quantification of colony forming units (CFU) of spleen. In the first evaluation was observed in G1, a prevention of the disease triggered by glucan, since the animals from this group showed no clinical signs, anatomopathologicals lesions and obtained the smaller number of CFU (p <0.5). However at the end of experimental period the G4 was significantly better among the treatment groups, therefore, ended the period with 70% of animals without any clinical alteration, macroscopic lesions in organs and organ cultures of the agent, beyond to demonstrate smaller number in CFUs and not occur any deaths resulting from illnes .The groups G2, G5 and G6 were significantly better than the control group since this group had a mortality rate of 31.25%, besides that 100% of the animals remained with clinical changes, lesions in organs such as liver, spleen and testis and demonstrated greater quantification of CFU (p <0,5). As the production of nitric oxide has been found much in the groups receiving the glucan rather than to the other groups. In view of these obtained results it is concluded that glucan induces the production of nitric oxide and the five treatments demonstrated efficacy to the reference sporotrichosis experimental systemically, however, the combination of antifungal (1-3) glucan provided an early regression of the lesions. Sporothrix schenckii Esporotricose glucana Itraconazol modelo murino Micoses : Subcutaneas Imunomodulacao Sporotrichosis Itraconazole Glucan Sporothrix scheckii
14	Atividade in vitro, individual ou em combinação, de voriconazol, itraconazol e terbinafina contra isolados brasileiros de Pythium insidiosum. Argenta, Juliana Siqueira January 2008 (has links) Pythium insidiosum, classificado no Reino Stramenopila e Classe Oomycetes, é o agente etiológico da pitiose, uma doença diagnosticada principalmente em eqüinos, caninos e humanos. As atividades in vitro do voriconazol, itraconazol e terbinafina, sozinhos ou em combinação, foram estudadas empregando uma metodologia de macrodiluição baseada na técnica M 38-A (CLSI, 2002) contra 30 isolados clínicos de Pythium insidiosum, com o objetivo de avaliar novas medidas para tratar infecções causadas por este agente utilizando quimioterapia. As combinações (terbinafina e voriconazol; terbinafina e itraconazol) tiveram suas interações avaliadas utilizando a técnica de checkerboard seguindo o modelo da macrodiluição em caldo. Terbinafina foi ativa quando testada sozinha, mostrando uma concentração inibitória mínima (CIM) e concentração fungicida mínima ≤ 8,0 mg/L para todos os isolados. Voriconazol e itraconazol foram inativos contra os isolados testados quando usados sozinhos. A combinação de voriconazol com terbinafina foi sinérgica contra 17% das amostras e indiferente em 25 (83%) amostras. O uso concomitante de terbinafina e itraconazol foi sinérgico contra 17% e indiferente contra 83% das amostras. As interpretações de ambas as interações foram equivalentes para 26 isolados (87%): vinte e três foram indiferentes e três mostraram efeito sinérgico. Antagonismo não foi observado. A terapia combinada é uma alternativa à monoterapia, especialmente para pacientes com infecções invasivas que são difíceis de tratar. Estes resultados precisam ser correlacionados com relatos clínicos; e ensaios in vivo, usando modelos animais, podem preencher a lacuna entre avaliações clínicas e avaliações in vitro das drogas. / Pythium insidiosum is classified in the kingdom Stramenopila, class Oomycetes. It causes pythiosis, a disease mainly diagnosed in horses, dogs, and humans. In order to evaluate new approaches to treat infections caused by Pythium insidiosum using chemotherapy, the in vitro activities of voriconazole, itraconazole and terbinafine, alone or in combination, against 30 clinical isolates were studied employing a macrodilution methodology based on the M 38-A technique (CLSI, 2002). The combinations (terbinafine plus voriconazole and terbinafine plus itraconazole) had their interactions evaluated using the checkerboard technique following the broth macrodilution design. Terbinafine was active when used as a single drug, showing minimal inhibitory concentration (MIC) and minimal fungicidal concentration ≤ 8,0 mg/L for all the isolates. Voriconazole and itraconazole were inactive against the isolates tested when used alone. The combination of voriconazole with terbinafine was synergic against 17% of the strains and indifferent on 25 (83%) strains. The concomitant use of terbinafine and itraconazole was synergic against 17% and indifferent against 83% of the strains. The interpretations of both interactions were equivalent for 26 isolates (87%): twenty three were indifferent and three showed synergistic effect. Antagonism was not observed. Combination therapy provides an alternative to monotherapy, especially for patients with invasive infections that are difficult to treat. These results need to be correlated with clinical outcomes, and in vivo assays using experimental animal models could bridge the gap between in vitro and clinical evaluation of drugs. Micologia veterinaria Pythium insidiosum Drogas Pythium insidiosum Voriconazole Itraconazole Terbinafine Susceptibility test
15	Desenvolvimento e caracterização de nanopartículas poliméricas contendo itraconazol / Development and characterization of polymeric nanoparticles itraconazole Lucena, Percília de Andradea 19 March 2014 (has links) Submitted by Marlene Santos (marlene.bc.ufg@gmail.com) on 2014-12-16T19:58:48Z No. of bitstreams: 2 Dissertação - Percília de Andrade Lucena - 2014.pdf: 1506404 bytes, checksum: c895c029b3a1ac62acf42cd19fad7214 (MD5) license_rdf: 23148 bytes, checksum: 9da0b6dfac957114c6a7714714b86306 (MD5) / Approved for entry into archive by Luciana Ferreira (lucgeral@gmail.com) on 2014-12-22T10:32:36Z (GMT) No. of bitstreams: 2 Dissertação - Percília de Andrade Lucena - 2014.pdf: 1506404 bytes, checksum: c895c029b3a1ac62acf42cd19fad7214 (MD5) license_rdf: 23148 bytes, checksum: 9da0b6dfac957114c6a7714714b86306 (MD5) / Made available in DSpace on 2014-12-22T10:32:36Z (GMT). No. of bitstreams: 2 Dissertação - Percília de Andrade Lucena - 2014.pdf: 1506404 bytes, checksum: c895c029b3a1ac62acf42cd19fad7214 (MD5) license_rdf: 23148 bytes, checksum: 9da0b6dfac957114c6a7714714b86306 (MD5) Previous issue date: 2014-03-19 / Polymeric nanoparticles have been used as carriers of drugs that are able to increase the efficacy of many active ingredients. Among the nanocarriers include nanocapsules (NCs), which are vesicular structures containing oil inside surrounded by a polymer wall and nanospheres (NSs) that are impregnated with polymer matrices drug throughout its surface. These structures have many applications such as optimizing drug delivery and reducing the toxic potential of drugs. Itraconazole family of a drug Azole has a broad spectrum of action against fungi and has appropriate pharmacokinetic characteristics for a drug. Thus, this study aims to develope and characterize nanostructured systems containing Itraconazole. Polymeric nanoparticles were obtained by the nanoprecipitation technique, lyophilized, characterized, and evaluated physical-chemically incorporated into mucoadhesive topical formulation. Nanocapsules containing Itraconazole showed encapsulation efficiency rate of 99 ± 6.9%, a mean diameter of 190 ± 10.1 nm, PDI 0.1 ± 0:06 and zeta potential -15 ± 2.5 mV. The nanospheres exhibited rate of encapsulation efficiency of 97 ± 2.8%, mean diameter 120 ± 0.8 nm, 0.1 ± 0.01 PDI and zeta potential -10 ± 3.5 mV. Lyophilization was carried out with 10% trehalose + 10% sucrose, achieving satisfactory results. The drug release after 30 days at 37 °C was 99% for the NCs and 92% for the NEs. The mucoadhesive topical formulation has in its composition 60% Poloxamer 188, 20% polyethylene glycol 400 and 5mg nanostructured itraconazole were incorporated homogeneously. The results indicate that the formulation of Itraconazole in polymeric nanoparticles has potential for in vivo use in the topical treatment of fungal infections. / Nanopartículas poliméricas têm sido utilizadas como carreadores de fármacos capazes de aumentar a eficácia de muitos insumos ativos. Dentre os nanocarreadores, destacam-se: nanocápsulas (NCs), que são estruturas vesiculares, contendo óleo no interior, circundadas por uma parede polimérica e nanoesferas (NEs) que são matrizes poliméricas impregnadas com fármaco por toda sua superfície. Essas estruturas possuem diversas aplicações como otimizar a entrega de fármacos e reduzir o potencial tóxico. O Itraconazol um fármaco da família dos azóis possui um amplo espectro de ação contra fungos e apresenta características farmacocinéticas apropriadas para um fármaco. Sendo assim, o presente trabalho tem como objetivo desenvolver e caracterizar sistemas nanoestruturados contendo Itraconazol. As nanopartículas poliméricas foram obtidas através da técnica da nanoprecipitação, liofilizadas, caracterizadas, avaliadas físicoquimicamente e incorporadas em formulação tópica mucoadesiva. As nanocápsulas contendo Itraconazol apresentaram taxa de eficiência de encapsulação de 99±6.9%, diâmetro médio de 190±10.1 nm, PDI 0.1±0.06 e potencial zeta -15±2.5 mV. As nanoesferas exibiram taxa de eficiência de encapsulação de 97±2.8%, diâmetro médio de 120±0.8 nm, PDI 0.1±0.01 e potencial zeta -10±3.5 mV. A liofilização foi realizada com 10% de trealose + 10% de sacarose, alcançando resultados satisfatórios. A liberação do fármaco após 30 dias a 37°C foi de 99% para as NCs e 92% para as NEs. A formulação tópica mucoadesiva possui em sua composição 60% Poloxamer 188 e 20% de Polietilenoglicol 400 e 5mg de itraconazol nanoestruturado foram incorporados homogeneamente. Os resultados indicam que a formulação de itraconazol em nanopartículas poliméricas apresenta potencial para utilização in vivo no tratamento tópico de infecções fúngicas. itraconazol Nanocápulas Nanoesferas Poli-(ε-caprolactona) Itraconazole Nanospheres Poly (ε-caprolactone) CIENCIAS BIOLOGICAS::FARMACOLOGIA
16	Heat induced evaporative antisolvent nanoprecipitation (HIEAN) of itraconazole Mugheirbi, N.A., Paluch, Krzysztof J., Tajber, L. 29 May 2014 (has links) Yes / Itraconazole (ITR) is an antifungal drug with a limited bioavailability due to its poor aqueous solubility. In this study, ITR was used to investigate the impact of nanonisation and solid state change on drug’s apparent solubility and dissolution. A bottom up approach to the production of amorphous ITR nanoparticles (NPs), composed of 100% drug, with a particle diameter below 250 nm, using heat induced evaporative antisolvent nanoprecipitation (HIEAN) from acetone was developed. The NPs demonstrated improved solubility and dissolution in simulated gastrointestinal conditions when compared to amorphous ITR microparticles. NPs produced with polyethylene glycol (PEG) or its methoxylated derivative (MPEG) as a stabiliser enabled the production of smaller NPs with narrower particle size distribution and enhanced apparent solubility. MPEG stabilised NPs gave the greatest ITR supersaturation levels (up to 11.6 ± 0.5 μg/ml) in simulated gastric fluids. The stabilising polymer was in an amorphous state. Dynamic vapour sorption data indicated no solid state changes in NP samples with water vapour at 25 °C, while crystallisation was apparent at 50 °C. HIEAN proved to be an efficient method of production of amorphous ITR NPs, with or without addition of a polymeric stabiliser, with enhanced pharmaceutical properties. / Libyan Ministry of Higher Education and Scientific Research through the Libyan Embassy, London and supported by the Science Foundation Ireland under Grant No. 12/RC/2275 (Synthesis and Solid State Pharmaceuticals Centre).
17	The Influence of PVAP on the Stability of Amorphous Solid Dispersions of Itraconazole Produced using Hot Melt Extrusion Technology Young, Cara January 2014 (has links) The purpose of this study was to improve the melt extrusion processability of polyvinyl acetate phthalate (PVAP) and investigate its use as a stabilizing polymer for supersaturated solutions of itraconazole (ITZ) in neutral pH aqueous media and in the solid-state during storage over time. Polyvinyl pyrrolidone vinyl acetate (PVPVA) was incorporated into PVAP as a carrier matrix with the aim of lowering the melt viscosity and increasing the plasticity of PVAP while maintaining its high glass transition temperature (Tg). Amorphous solid dispersions of ITZ (40% w/w) in a 30:70% w/w PVAP:PVPVA mixture were produced by melt extrusion. Solid-state analyses of the composition were performed using differential scanning calorimetry and X-ray diffraction. Dissolution analysis was conducted using a pH-change method. Solid-state analyses demonstrated that the extruded composition was entirely amorphous and ITZ was largely distributed in PVAP- and PVPVA-rich portions of the ternary dispersion. Dissolution analysis revealed that PVAP functioned to prolong the release of supersaturated levels of ITZ from the dispersion following an acidic-to-neutral pH transition. In the solid state, ITZ remained in its amorphous form throughout 6 months of storage. The results of this study suggest that substantial improvements in melt extrusion with PVAP can be achieved by incorporating PVPVA and that the PVAP-PVPVA polymer combination can stabilize amorphous ITZ. / Pharmaceutical Sciences Pharmaceutical Sciences Chemistry, Polymer Amorphous Itraconazole Melt Extrusion Polymer Polyvinyl Acetate Phthalate Solid Dispersions
18	Conception, synthèse et caractérisation de nouvelles macromolécules branchées biocompatibles pour encapsuler des principes actifs hydrophobes Elkin, Igor 08 1900 (has links) La vectorisation des médicaments est une approche très prometteuse tant sur le plan médical qu’économique pour la livraison des substances actives ayant une faible biodisponibilité. Dans ce contexte, les polymères en étoile et les dendrimères, macromolécules symétriques et branchées, semblent être les solutions de vectorisation les plus attrayantes. En effet, ces structures peuvent combiner efficacement une stabilité élevée dans les milieux biologiques à une capacité d’encapsulation des principes actifs. Grâce à leur architecture bien définie, ils permettent d’atteindre un très haut niveau de reproductibilité de résultats, tout en évitant le problème de polydispersité. Bien que des nombreuses structures dendritiques aient été proposées ces dernières années, il est cependant à noter que la conception de nouveaux nanovecteurs dendritiques efficaces est toujours d’actualité. Ceci s’explique par des nombreuses raisons telles que celles liées à la biocompatibilité, l’efficacité d’encapsulation des agents thérapeutiques, ainsi que par des raisons économiques. Dans ce projet, de nouvelles macromolécules branchées biocompatibles ont été conçues, synthétisées et évaluées. Pour augmenter leur efficacité en tant qu’agents d’encapsulations des principes actifs hydrophobes, les structures de ces macromolécules incluent un coeur central hydrophobe à base de porphyrine, décanediol ou trioléine modifié et, également, une couche externe hydrophile à base d’acide succinique et de polyéthylène glycol. Le choix des éléments structuraux de futures dendrimères a été basé sur les données de biocompatibilité, les résultats de nos travaux de synthèse préliminaires, ainsi que les résultats de simulation in silico réalisée par une méthode de mécanique moléculaire. Ces travaux ont permis de choisir des composés les plus prometteurs pour former efficacement et d’une manière bien contrôlable des macromolécules polyesters. Ils ont aussi permis d’évaluer au préalable la capacité de futurs dendrimères de capter une molécule médicamenteuse (itraconazole). Durant cette étape, plusieurs nouveaux composés intermédiaires ont été obtenus. L’optimisation des conditions menant à des rendements réactionnels élevés a été réalisée. En se basant sur les travaux préliminaires, l’assemblage de nouveaux dendrimères de première et de deuxième génération a été effectué, en utilisant les approches de synthèse divergente et convergente. La structure de nouveaux composés a été prouvée par les techniques RMN du proton et du carbone 13C, spectroscopie FTIR, UV-Vis, analyse élémentaire, spectrométrie de masse et GPC. La biocompatibilité de produits a été évaluée par les tests de cytotoxicité avec le MTT sur les macrophages murins RAW-262.7. La capacité d’encapsuler les principes actifs hydrophobes a été étudiée par les tests avec l’itraconazole, un antifongique puissant mais peu biodisponible. La taille de nanoparticules formées dans les solutions aqueuses a été mesurée par la technique DLS. Ces mesures ont montré que toutes les structures dendritiques ont tendance à former des micelles, ce qui exclue leurs applications en tant que nanocapsules unimoléculaires. L’activité antifongique des formulations d’itraconazole encapsulé avec les dendrimères a été étudiée sur une espèce d’un champignon pathogène Candida albicans. Ces tests ont permis de conclure que pour assurer l’efficacité du traitement, un meilleur contrôle sur le relargage du principe actif était nécessaire. / The drug molecule vectorization is a very promising approach in terms of both medical and economical factors for the delivery of active substances with low bioavailability. In this context, the star polymers and dendrimers, symmetrical and branched macromolecules, seem to be more attractive solutions. Indeed, these structures can effectively combine a high stability in biological media and the ability to encapsulate active ingredients. Thanks to the well-defined architecture, they can achieve a high level of reproducibility of results, while avoiding the problem of polydispersity. In recent years, many dendritic structures have been proposed; however, the design of new effective dendritic nanocarriers is still relevant. This is due to many reasons such as related to biocompatibility, encapsulation efficiency of therapeutic agents, as well as economic reasons. In this project, new branched biocompatible macromolecules were designed, synthesized and evaluated. To increase their effectiveness as encapsulation agents for hydrophobic active principles, the structures of the proposed macromolecules include a hydrophobic central core on the basis of porphyrin, decanediol or modified triolein, and also a hydrophilic outer layer based on succinic acid and polyethylene glycol. The choice of structural elements of future dendrimers was based on the data on their biocompatibility and the results of our preliminary synthesis works, as well as the in silico simulations performed by using the method of molecular mechanics. The preliminary studies allowed for selecting the most promising compounds to effectively form polyesters macromolecules in well controlled manner, as well as to assess in advance the ability of future dendrimers to capture a drug molecule (itraconazole). During this phase, several new intermediates were obtained. The optimization of reaction conditions leading to high yields was performed. Based on the preliminary work, the assembly of new dendrimers of first and second generations was performed, by using the divergent and convergent synthesis approaches. The structures of new compounds were characterized by proton and 13C carbon NMR, FTIR, UV-Vis, elemental analysis, mass spectrometry, and GPC techniques. The biocompatibility of products was evaluated by cytotoxicity tests with MTT on murine RAW 262.7 macrophages. The ability to encapsulate hydrophobic active principles was studied by testing with itraconazole, an antifungal agent with low bioavalability. The size of nanoparticles formed in aqueous solutions was measured by the DLS technique. These measurements showed that all dendritic structures tend to form micelles, which excludes their application as unimolecular nanocapsules. The antifungal activity of itraconazole formulations with dendrimers was studied in a kind of a pathogenic fungus Candida albicans. These tests lead to the conclusion that to ensure the effectiveness of treatment, more control over the release of the active ingredient has been needed. Dendrimère Polyester Biocompatibilité Modélisation in silico Assemblage chimique Encapsulation Itraconazole Propriétés antifongiques Dendrimer Biocompatibility In silico modelization Chemical assembly Encapsulation Active ingredient Itraconazole Anti-fungal properties
19	Conception, synthèse et caractérisation de nouvelles macromolécules branchées biocompatibles pour encapsuler des principes actifs hydrophobes Elkin, Igor 08 1900 (has links) La vectorisation des médicaments est une approche très prometteuse tant sur le plan médical qu’économique pour la livraison des substances actives ayant une faible biodisponibilité. Dans ce contexte, les polymères en étoile et les dendrimères, macromolécules symétriques et branchées, semblent être les solutions de vectorisation les plus attrayantes. En effet, ces structures peuvent combiner efficacement une stabilité élevée dans les milieux biologiques à une capacité d’encapsulation des principes actifs. Grâce à leur architecture bien définie, ils permettent d’atteindre un très haut niveau de reproductibilité de résultats, tout en évitant le problème de polydispersité. Bien que des nombreuses structures dendritiques aient été proposées ces dernières années, il est cependant à noter que la conception de nouveaux nanovecteurs dendritiques efficaces est toujours d’actualité. Ceci s’explique par des nombreuses raisons telles que celles liées à la biocompatibilité, l’efficacité d’encapsulation des agents thérapeutiques, ainsi que par des raisons économiques. Dans ce projet, de nouvelles macromolécules branchées biocompatibles ont été conçues, synthétisées et évaluées. Pour augmenter leur efficacité en tant qu’agents d’encapsulations des principes actifs hydrophobes, les structures de ces macromolécules incluent un coeur central hydrophobe à base de porphyrine, décanediol ou trioléine modifié et, également, une couche externe hydrophile à base d’acide succinique et de polyéthylène glycol. Le choix des éléments structuraux de futures dendrimères a été basé sur les données de biocompatibilité, les résultats de nos travaux de synthèse préliminaires, ainsi que les résultats de simulation in silico réalisée par une méthode de mécanique moléculaire. Ces travaux ont permis de choisir des composés les plus prometteurs pour former efficacement et d’une manière bien contrôlable des macromolécules polyesters. Ils ont aussi permis d’évaluer au préalable la capacité de futurs dendrimères de capter une molécule médicamenteuse (itraconazole). Durant cette étape, plusieurs nouveaux composés intermédiaires ont été obtenus. L’optimisation des conditions menant à des rendements réactionnels élevés a été réalisée. En se basant sur les travaux préliminaires, l’assemblage de nouveaux dendrimères de première et de deuxième génération a été effectué, en utilisant les approches de synthèse divergente et convergente. La structure de nouveaux composés a été prouvée par les techniques RMN du proton et du carbone 13C, spectroscopie FTIR, UV-Vis, analyse élémentaire, spectrométrie de masse et GPC. La biocompatibilité de produits a été évaluée par les tests de cytotoxicité avec le MTT sur les macrophages murins RAW-262.7. La capacité d’encapsuler les principes actifs hydrophobes a été étudiée par les tests avec l’itraconazole, un antifongique puissant mais peu biodisponible. La taille de nanoparticules formées dans les solutions aqueuses a été mesurée par la technique DLS. Ces mesures ont montré que toutes les structures dendritiques ont tendance à former des micelles, ce qui exclue leurs applications en tant que nanocapsules unimoléculaires. L’activité antifongique des formulations d’itraconazole encapsulé avec les dendrimères a été étudiée sur une espèce d’un champignon pathogène Candida albicans. Ces tests ont permis de conclure que pour assurer l’efficacité du traitement, un meilleur contrôle sur le relargage du principe actif était nécessaire. / The drug molecule vectorization is a very promising approach in terms of both medical and economical factors for the delivery of active substances with low bioavailability. In this context, the star polymers and dendrimers, symmetrical and branched macromolecules, seem to be more attractive solutions. Indeed, these structures can effectively combine a high stability in biological media and the ability to encapsulate active ingredients. Thanks to the well-defined architecture, they can achieve a high level of reproducibility of results, while avoiding the problem of polydispersity. In recent years, many dendritic structures have been proposed; however, the design of new effective dendritic nanocarriers is still relevant. This is due to many reasons such as related to biocompatibility, encapsulation efficiency of therapeutic agents, as well as economic reasons. In this project, new branched biocompatible macromolecules were designed, synthesized and evaluated. To increase their effectiveness as encapsulation agents for hydrophobic active principles, the structures of the proposed macromolecules include a hydrophobic central core on the basis of porphyrin, decanediol or modified triolein, and also a hydrophilic outer layer based on succinic acid and polyethylene glycol. The choice of structural elements of future dendrimers was based on the data on their biocompatibility and the results of our preliminary synthesis works, as well as the in silico simulations performed by using the method of molecular mechanics. The preliminary studies allowed for selecting the most promising compounds to effectively form polyesters macromolecules in well controlled manner, as well as to assess in advance the ability of future dendrimers to capture a drug molecule (itraconazole). During this phase, several new intermediates were obtained. The optimization of reaction conditions leading to high yields was performed. Based on the preliminary work, the assembly of new dendrimers of first and second generations was performed, by using the divergent and convergent synthesis approaches. The structures of new compounds were characterized by proton and 13C carbon NMR, FTIR, UV-Vis, elemental analysis, mass spectrometry, and GPC techniques. The biocompatibility of products was evaluated by cytotoxicity tests with MTT on murine RAW 262.7 macrophages. The ability to encapsulate hydrophobic active principles was studied by testing with itraconazole, an antifungal agent with low bioavalability. The size of nanoparticles formed in aqueous solutions was measured by the DLS technique. These measurements showed that all dendritic structures tend to form micelles, which excludes their application as unimolecular nanocapsules. The antifungal activity of itraconazole formulations with dendrimers was studied in a kind of a pathogenic fungus Candida albicans. These tests lead to the conclusion that to ensure the effectiveness of treatment, more control over the release of the active ingredient has been needed. Dendrimère Polyester Biocompatibilité Modélisation in silico Assemblage chimique Encapsulation Itraconazole Propriétés antifongiques Dendrimer Biocompatibility In silico modelization Chemical assembly Encapsulation Active ingredient Itraconazole Anti-fungal properties
20	Improvement in the bioavailability of poorly water-soluble drugs via pulmonary delivery of nanoparticles Yang, Wei 23 October 2009 (has links) High throughput screening techniques that are routinely used in modern drug discovery processes result in a higher prevalence of poorly water-soluble drugs. Such drugs often have poor bioavailability issues due to their poor dissolution and/or permeability to achieve sufficient and consistent systemic exposure, resulting in sub-optimal therapeutic efficacies, particularly via oral administration. Alternative formulations and delivery routes are demanded to improve their bioavailability. Nanoparticulate formulations of poorly water-soluble drugs offer improved dissolution profiles. The physiology of the lung makes it an ideal target for non-invasive local and systemic drug delivery for poorly water-soluble drugs. In Chapter 2, a particle engineering process ultra-rapid freezing (URF) was utilized to produce nanostructured aggregates of itraconazole (ITZ), a BCS class II drug, for pulmonary delivery with approved biocompatible excipients. The obtained formulation, ITZ:mannitol:lecithin (1:0.5:0.2, w/w), i.e. URF-ITZ, was a solid solution with high surface area and ability to achieve high magnitude of supersaturation. An aqueous colloidal dispersion of URF-ITZ was suitable for nebulization, which demonstrated optimal aerodynamic properties for deep lung delivery and high lung and systemic ITZ levels when inhaled by mice. The significantly improved systemic bioavailability of inhaled URF-ITZ was mainly ascribed to the amorphous morphology that raised the drug solubility. The effect of supersaturation of amorphous URF-ITZ relative to nanocrystalline ITZ on bioavailability following inhalation was evaluated in Chapter 3. The nanoparticulate amorphous ITZ composition resulted in a significantly higher systemic bioavailability than for the nanocrystalline ITZ composition, as a result of the higher supersaturation that increased the permeation. In Chapter 4, pharmacokinetics of inhaled nebulized aerosols of solubilized ITZ in solution versus nanoparticulate URF-ITZ colloidal dispersion were investigated, under the hypothesis that solubilized ITZ can be absorbed faster through mucosal membrane than the nanoparticulate ITZ. Despite similar ITZ lung deposition, the inhaled solubilized ITZ demonstrated significantly faster systemic absorption across lung epithelium relative to nanoparticulate ITZ in mice, due in part to the elimination of the phase-to-phase transition of nanoparticulate ITZ. / text Drug delivery systems Poorly water-soluble drugs Pulmonary delivery Bioavailability Itraconazole Ultra-rapid freezing URF-ITZ Nanoparticles Nanoparticulate drug formulations

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