Spectroscopic Studies of Atmospherically- and Biologically-Relevant Interfaces: Lipids, Ions, and Interfacial Water Structure

Adams, Ellen M.

January 2016

No description available.

Chemistry

sea spray aerosols

Langmuir monolayers

Brewster angle microscopy

sum frequency generation spectroscopy

Composés macrocycliques bioactifs : synthèse et étude de leurs interactions avec des membranes biologiques modèles / Bioactive macrocyclic compounds : syntheses and study of their interactions with biological membrane models

Sautrey, Guillaume

09 December 2011

Le travail suivant est consacré d'une part à l'emploi du calix[4]arène comme une plate-forme organisatrice de principes actifs pour la conception de nouvelles prodrogues. Ce concept a été développé avec des substances antibactériennes ou antivirales, choisies comme modèles. Les conjugués calixarène - anti-infectieux ainsi synthétisés sont amphiphiles et insolubles dans l'eau. Leur comportement interfacial a été étudié via l'interface eau-air, mime d'une interface hydrophile-hydrophobe physiologique, à l'aide de la technique des films monomoléculaires de Langmuir. Nos résultats indiquent que ces prodrogues étalées à l'interface eau-air peuvent libérer leurs principes actifs dans la sous-phase. La méthodologie développée pour ces études de réactivité interfaciale pourrait à l'avenir être appliquée à d'autres prodrogues à base de calix[4]arène. Un second projet a concerné le trifluoroacétate de tétra-p-(guanidinoéthyl)-calix[4]arène (CX1). Ce composé présente des propriétés antibactériennes à large spectre, couplées à une faible toxicité cellulaire. Nos travaux ont visé à mieux comprendre son mode d'action, lié à une perturbation des parois bactériennes, par une approche physico-chimique. La technique de Langmuir a donc été employée afin d'étudier les interactions entre le CX1 et des films monomoléculaires de phospholipides étalés à l'interface eau-air, utilisés comme modèles de membrane bactérienne. Nos résultats nous ont permis de proposer un mode d'organisation des membranes bactériennes sous l'influence du CX1. Nous avons ainsi apporté des précisions sur son mécanisme d'action qui pourraient être utiles dans le développement de nouveaux calixarènes antibactériens / This work begins with utilization of the calix[4]arene macrocycle as organizing platform of anti-infectious molecules shaped as prodrug. The concept has been explored using antibacterial (nalidixic acid) and antiviral (aciclovir, ganciclovir) molecules, chosen as models. The calixarene - anti-infectious conjugates synthesized have amphiphilic structure and are insoluble in aqueous media. Their interfacial behavior was studied via the air-water interface, considered as mimic of biological hydrophilic-hydrophobic interfaces, using Langmuir monolayers technique. Our results indicate that calixarene-based prodrugs spread at the air-water interface are able to release anti-infectious molecules into the subphase. The original methodology employed for interfacial reactivity studies could be applied to further calixarene-based prodrugs. A second project concerns the trifluoroacetate salt of tetra-p-(guanidinoethyl)-calix[4]arene (CX1). CX1 is antibacterial, active against various Gram-positive and Gram-negative bacteria, with low eukaryotic cell toxicity. The aim of our work was to get more insight in the mechanism of action of CX1, involving bacterial wall disruption, by a physico-chemical approach. The Langmuir monolayers technique was employed in order to study interactions between CX1 and phospholipid monolayers spread at the air-water interface, used as models of bacterial membranes. Our results led us to propose a particular reorganization mode of bacterial membranes upon interactions with CX1. This proposal gives more understanding in the mechanism of biological activity of CX1, and could be helpful in developing new antibacterial calixarene derivatives

Calixarènes

Couches de Langmuir-Blodgett

Promédicaments

Phospholipides

Antiinfectieux

Modèles de Membrane

Films de Langmuir

Pm-irras

Calixarenes

Langmuir Monolayers

Prodrugs

Phospholipids

Antiinfectious

Membrane Models

Pm-irras

547.63

615.19

Interação de capsaicinóides com sistema modelo de membrana celular / Capsaicinoids interaction of with cell model membrane system

Iwaki, Yurika Okamoto

18 April 2016

Este trabalho visa ao entendimento da interação de capsaicinóides com membranas celulares utilizando sistemas modelo. Dentre os alcalóides derivados de plantas do gênero Capsicum, a capsaicina e a dihidrocapsaicina respondem por 90% dos capsaicinóides, que são usados como analgésicos e antiinflamatórios, devido a sua interação específica com receptores. O mecanismo neurofarmacológico já foi bastante estudado, mas o modo de ação não neural ainda não foi elucidado. Usamos extratos brutos (EBs) de pimenta malagueta e de dedo-de-moça, que têm atividade superficial, e afetaram monocamadas de Langmuir de fosfatidil colina de dipalmitoíla (DPPC) e fosfatidil glicerol de dipalmitoíla (DPPG). Tais efeitos não tiveram dependência expressiva com a carga, pois o EB de dedo-de-moça interagiu mais fortemente com o DPPC do que com o DPPG, ao passo que o contrário se verificou para o EB de malagueta. Também não houve diferença significativa entre os EBs das duas pimentas. Nas monocamadas de Langmuir representativas para a bactéria S. aureus, ambos os EBs tiveram efeito, tanto nas isotermas de pressão quanto nos resultados de espectroscopia de absorção e reflexão no infravermelho com modulação de polarização (PM-IRRAS), sem distinção significativa entre malagueta e dedo-de-moça. No entanto, as medidas de vazamento com lipossomos mostraram maior interação com o EB de dedo-de-moça, o que é consistente com a atividade bactericida para S. aureus. De fato, a concentração inibitória mínima (MIC) foi 0,13 mg mL-1 para o EB da pimenta dedo-de moça e 4,0 mg mL-1 para o EB de malagueta. Para a E. coli, os EBs interagiram com as monocamadas de Langmuir sem diferenças dignas de nota para as duas pimentas, e nas medidas de vazamento o efeito maior foi para a dedo-de-moça. Não houve efeito bactericida para nenhum dos extratos. Isso se explica porque bactérias gram-negativas, como a E. coli, têm uma camada externa protetora de lipossacarídeos (LPS). Das medidas de monocamadas de Langmuir representativas da camada de LPS, observou-se pouca incorporação dos EBs. Conclui-se, assim, que os EBs não conseguem causar rompimento da camada de LPS. Do conjunto dos resultados, infere-se que o mecanismo de ação para a S. aureus envolve solubilização parcial da membrana, e não há relação entre pungência e atividade bactericida, pois a pimenta dedo-de-moça, que é menos pungente, teve maior efeito do que a malagueta. Depreende-se, também, que a ação de extratos de pimenta deve depender da interação com receptores na membrana, o que explica porque o uso de tais extratos tem sido principalmente em aplicações tópicas. / This study is aimed at understanding the interaction of capsaicinoids with cell membranes using model systems. Among the alkaloids derived from plants of the genus Capsicum, capsaicin and dihydrocapsaicin account for 90% of capsaicinoids, which are used as analgesic and anti-inflammatory due to their interaction with specific receptors. The neuropharmacological mechanism has been well studied, but the non-neural mode of action has not been elucidated. Here, we use crude extracts (EBs) of malagueta and dedo-de-moça chilli peppers, which are surface active, and affected Langmuir monolayers of dipalmitoyl phosphatidylcholine (DPPC) and dipalmitoyl phosphatidyl glycerol (DPPG). Such effects did not depend on the charge, since EB from dedo-de-moça interacted more strongly with DPPC than with DPPG, while the opposite applied for malagueta. In addition, there was no significant difference between the two EBs. For Langmuir monolayers representing the bacteria S. aureus, both EBs affected the surface pressure isotherms and the polarizationmodulated infrared reflection-absorption spectroscopy (PM-IRRAS) data, without significant distinction between dedo-de-moça and malagueta. However, in the leakage measurements with liposomes the EB from dedo-de-moça was more efficient in rupturing the liposome, which is consistent with the bactericidal activity for S. aureus. In fact, the minimum inhibitory concentration (MIC) was 0.13 mg mL-1 for dedo-de-moça and 4.0 mg mL-1 for malagueta. For the Langmuir monolayers mimicking the E. coli membrane, the EBs interacted much in the same way, while the EB from dedo-de-moça caused larger leakage in liposomes. There was no bactericidal effect of the EBs. This is explained by the fact that gram-negative bacteria, such as E. coli, have a protective outer layer of liposaccharides (LPS). In monolayers representing LPS, there was little incorporation of EBs, from which one infers that the EBs cannot cause disruption of the LPS layer. Taking all these results together, it appears that the mechanism of action for S. aureus involves partial solubilization of the membrane. Furthermore, there is no relationship between pungency and bactericidal activity because dedo-de-moça, which is less pungent, had greater effect than malagueta. It seems also that the action of pepper extracts must depend on the interaction with membrane receptors, which explains why the use of such extracts has been essentially in topical applications.

Capsaicinóides

Capsaicinoids

Dedo-de-moça pepper

Filmes de Langmuir-Blodgett

Langmuir Blodgett film

Langmuir monolayers

Liposome

Lipossomos

Malagueta pepper

Monocamadas de Langmuir

Pimenta dedo-de-moça

Pimenta malagueta

Interação do ibuprofeno e capsaicinóides com filmes da Langmuir e Langmuir-Blodgett contendo fosfolipídios / Interaction of ibuprofen and capsaicinoids with Langmuir and Langmuir-Blodgett films containing phospholipids

Geraldo, Vananélia Pereira Nunes

21 March 2013

O ibuprofeno é um antiinflamatório não esteróide, com baixa solubilidade em água, que apresenta diversos efeitos colaterais, incluindo lesão gástrica e intestinal. Esses efeitos podem depender da interação com a membrana celular, o que nos motivou a investigar, na primeira parte deste trabalho, a incorporação do ibuprofeno em monocamadas de Langmuir como modelos de membrana celular. Monocamadas de dipalmitoil fosfatidil glicerol (DPPG) e dipalmitoil fosfatidil colina (DPPC) co-espalhadas com o ibuprofeno ou depositadas sobre subfases contendo o fármaco foram estudadas por meio das isotermas de pressão e potencial de superfície. Foram observados efeitos significativos para monocamadas de DPPC, particularmente na transição de fase líquido-expandida para líquido-condensada, com modificações relevantes na elasticidade da monocamada. Esses efeitos aumentaram com a concentração do ibuprofeno. Para os dois tipos de fosfolipídios, o ibuprofeno pôde penetrar na região hidrofóbica, o que foi confirmado por espectroscopia de reflexão e absorção no infravermelho com modulação da polarização (PM-IRRAS), indicando assim a presença de interações hidrofóbicas. A análise por microscopia no ângulo de Brewster (BAM) mostrou que o ibuprofeno impede a formação de grandes domínios de DPPC, enquanto que não foram observadas alterações significativas para o DPPG. A interação entre o ibuprofeno e o DPPG também foi confirmada após a imobilização da monocamada mista em filmes LB com alterações na absorção no UV-Vis da molécula de ibuprofeno. No que diz respeito às implicações biológicas, a ação farmacológica que depende diretamente da interação com a membrana deve ocorrer primeiramente em regiões neutras via penetração do ibuprofeno na região hidrofóbica da membrana celular. A segunda parte deste trabalho foi dedicada à interação de capsaicinóides extraídos da pimenta malagueta com monocamadas de Langmuir constituídas de DPPG e DPPC. A capsaicina é um potente analgésico de uso tópico, que pode causar dessensibilização no local de aplicação dependendo da dose e, portanto há interesse na sua incorporação em sistemas de liberação controlada, como os lipossomos. A técnica de Langmuir foi empregada para verificar essa possibilidade. Os capsaicinóides expandiram as monocamadas de DPPG e aumentaram sua elasticidade. As isotermas de potencial de superfície indicaram que os capsaicinóides provocam aumento de 10% no momento de dipolo numa concentração de 30% em mol. Para os filmes mistos de DPPC e capsaicinóides, a área mínima diminuiu e a elasticidade da monocamada aumentou. De acordo com as isotermas de potencial, os momentos de dipolo diminuíram para as monocamadas de DPPC independentemente da concentração de capsaicinóides. Esses resultados sugerem que as moléculas de DPPC são solubilizadas para a subfase na presença do fármaco. A partir destes resultados, conclui-se que os capsaicinóides podem ser incorporados em estruturas lipídicas, constituídas principalmente de DPPG, o que é relevante para uso em sistemas de liberação de fármacos. / Ibuprofen is a nonsteroidal anti-inflammatory drug, with low solubility in water, which exhibits side effects including gastric and intestinal injury, often irreversible. Some of these effects may depend on the interaction with the cell membrane, which motivated us to investigate the incorporation of ibuprofen in Langmuir monolayers as cell membrane models, in the first part of this thesis. Dipalmitoyl phosphatidyl choline (DPPC) or dipalmitoyl phosphatidyl glycerol (DPPG) monolayers co-spread with ibuprofen or deposited on ibuprofen-containing aqueous subphases were studied using surface pressure and surface potential isotherms. Significant effects were observed for DPPC monolayers, particularly at the liquid-expanded to liquid-condensed phase transition, with relevant changes in the elasticity of the monolayer. These effects increased with the ibuprofen concentration. For both types of phospholipids, ibuprofen could penetrate into the hydrophobic part of the monolayer, which was confirmed with polarization-modulated infrared reflection absorption spectroscopy (PM-IRRAS), thus indicating the presence of hydrophobic interactions. BAM images showed that ibuprofen prevents the formation of large domains of DPPC, while no significant changes were observed for DPPG. The interaction between DPPG-ibuprofen was also confirmed for deposited layers in the form of LB films, with changes in the ibuprofen UV-Vis absorption. As for the biological implications, the pharmacological action depending directly on the membrane interaction should occur primarily with zwitterionic regions of the membrane via penetration of ibuprofen in the hydrophobic part of the monolayer. The second part of this thesis is dedicated to the interaction of capsaicinoids, extracted from malagueta pepper, with Langmuir monolayers of DPPC and DPPG. Capsaicin is a powerful analgesic of topical use, which can cause desensitization in the application site depending on the dose, and therefore there is interest in its incorporation in drug delivery systems, such as liposomes. The Langmuir technique was employed to verify this possibility. The capsaicinoids expanded the DPPG monolayer and increased its elasticity. Surface potential isotherms indicated that the capsaicinoids increased the average dipole moment by 10 % for 30 mol % of capsaicinoids. For the mixed films of DPPC and capsaicinoids, the minimum area decreased and the elasticity increased. According to the surface potential isotherms, the dipole moments decreased for DPPC monolayers regardless of the capsaicinoid concentrations. These results suggest that the DPPC molecules are solubilized into the subphase in the presence of the drug. From these results, it is concluded that the capsaicinoids can be incorporated into structures as the liposomes constituted mainly of DPPG, which is relevant for use in drug delivery systems.

Capsaicin

Capsaicina

Filmes de Langmuir-Blodgett

Ibuprofen

Ibuprofeno

Langmuir monolayers

Langmuir-Blodgett films

Malagueta pepper

Monocamadas de Langmuir

Pimenta malagueta

PM-IRRAS

PM-IRRAS

Interação de capsaicinóides com sistema modelo de membrana celular / Capsaicinoids interaction of with cell model membrane system

Yurika Okamoto Iwaki

18 April 2016

Este trabalho visa ao entendimento da interação de capsaicinóides com membranas celulares utilizando sistemas modelo. Dentre os alcalóides derivados de plantas do gênero Capsicum, a capsaicina e a dihidrocapsaicina respondem por 90% dos capsaicinóides, que são usados como analgésicos e antiinflamatórios, devido a sua interação específica com receptores. O mecanismo neurofarmacológico já foi bastante estudado, mas o modo de ação não neural ainda não foi elucidado. Usamos extratos brutos (EBs) de pimenta malagueta e de dedo-de-moça, que têm atividade superficial, e afetaram monocamadas de Langmuir de fosfatidil colina de dipalmitoíla (DPPC) e fosfatidil glicerol de dipalmitoíla (DPPG). Tais efeitos não tiveram dependência expressiva com a carga, pois o EB de dedo-de-moça interagiu mais fortemente com o DPPC do que com o DPPG, ao passo que o contrário se verificou para o EB de malagueta. Também não houve diferença significativa entre os EBs das duas pimentas. Nas monocamadas de Langmuir representativas para a bactéria S. aureus, ambos os EBs tiveram efeito, tanto nas isotermas de pressão quanto nos resultados de espectroscopia de absorção e reflexão no infravermelho com modulação de polarização (PM-IRRAS), sem distinção significativa entre malagueta e dedo-de-moça. No entanto, as medidas de vazamento com lipossomos mostraram maior interação com o EB de dedo-de-moça, o que é consistente com a atividade bactericida para S. aureus. De fato, a concentração inibitória mínima (MIC) foi 0,13 mg mL-1 para o EB da pimenta dedo-de moça e 4,0 mg mL-1 para o EB de malagueta. Para a E. coli, os EBs interagiram com as monocamadas de Langmuir sem diferenças dignas de nota para as duas pimentas, e nas medidas de vazamento o efeito maior foi para a dedo-de-moça. Não houve efeito bactericida para nenhum dos extratos. Isso se explica porque bactérias gram-negativas, como a E. coli, têm uma camada externa protetora de lipossacarídeos (LPS). Das medidas de monocamadas de Langmuir representativas da camada de LPS, observou-se pouca incorporação dos EBs. Conclui-se, assim, que os EBs não conseguem causar rompimento da camada de LPS. Do conjunto dos resultados, infere-se que o mecanismo de ação para a S. aureus envolve solubilização parcial da membrana, e não há relação entre pungência e atividade bactericida, pois a pimenta dedo-de-moça, que é menos pungente, teve maior efeito do que a malagueta. Depreende-se, também, que a ação de extratos de pimenta deve depender da interação com receptores na membrana, o que explica porque o uso de tais extratos tem sido principalmente em aplicações tópicas. / This study is aimed at understanding the interaction of capsaicinoids with cell membranes using model systems. Among the alkaloids derived from plants of the genus Capsicum, capsaicin and dihydrocapsaicin account for 90% of capsaicinoids, which are used as analgesic and anti-inflammatory due to their interaction with specific receptors. The neuropharmacological mechanism has been well studied, but the non-neural mode of action has not been elucidated. Here, we use crude extracts (EBs) of malagueta and dedo-de-moça chilli peppers, which are surface active, and affected Langmuir monolayers of dipalmitoyl phosphatidylcholine (DPPC) and dipalmitoyl phosphatidyl glycerol (DPPG). Such effects did not depend on the charge, since EB from dedo-de-moça interacted more strongly with DPPC than with DPPG, while the opposite applied for malagueta. In addition, there was no significant difference between the two EBs. For Langmuir monolayers representing the bacteria S. aureus, both EBs affected the surface pressure isotherms and the polarizationmodulated infrared reflection-absorption spectroscopy (PM-IRRAS) data, without significant distinction between dedo-de-moça and malagueta. However, in the leakage measurements with liposomes the EB from dedo-de-moça was more efficient in rupturing the liposome, which is consistent with the bactericidal activity for S. aureus. In fact, the minimum inhibitory concentration (MIC) was 0.13 mg mL-1 for dedo-de-moça and 4.0 mg mL-1 for malagueta. For the Langmuir monolayers mimicking the E. coli membrane, the EBs interacted much in the same way, while the EB from dedo-de-moça caused larger leakage in liposomes. There was no bactericidal effect of the EBs. This is explained by the fact that gram-negative bacteria, such as E. coli, have a protective outer layer of liposaccharides (LPS). In monolayers representing LPS, there was little incorporation of EBs, from which one infers that the EBs cannot cause disruption of the LPS layer. Taking all these results together, it appears that the mechanism of action for S. aureus involves partial solubilization of the membrane. Furthermore, there is no relationship between pungency and bactericidal activity because dedo-de-moça, which is less pungent, had greater effect than malagueta. It seems also that the action of pepper extracts must depend on the interaction with membrane receptors, which explains why the use of such extracts has been essentially in topical applications.

Capsaicinóides

Filmes de Langmuir-Blodgett

Lipossomos

Monocamadas de Langmuir

Pimenta dedo-de-moça

Pimenta malagueta

Capsaicinoids

Dedo-de-moça pepper

Langmuir Blodgett film

Langmuir monolayers

Liposome

Malagueta pepper

Interação do ibuprofeno e capsaicinóides com filmes da Langmuir e Langmuir-Blodgett contendo fosfolipídios / Interaction of ibuprofen and capsaicinoids with Langmuir and Langmuir-Blodgett films containing phospholipids

Vananélia Pereira Nunes Geraldo

21 March 2013

O ibuprofeno é um antiinflamatório não esteróide, com baixa solubilidade em água, que apresenta diversos efeitos colaterais, incluindo lesão gástrica e intestinal. Esses efeitos podem depender da interação com a membrana celular, o que nos motivou a investigar, na primeira parte deste trabalho, a incorporação do ibuprofeno em monocamadas de Langmuir como modelos de membrana celular. Monocamadas de dipalmitoil fosfatidil glicerol (DPPG) e dipalmitoil fosfatidil colina (DPPC) co-espalhadas com o ibuprofeno ou depositadas sobre subfases contendo o fármaco foram estudadas por meio das isotermas de pressão e potencial de superfície. Foram observados efeitos significativos para monocamadas de DPPC, particularmente na transição de fase líquido-expandida para líquido-condensada, com modificações relevantes na elasticidade da monocamada. Esses efeitos aumentaram com a concentração do ibuprofeno. Para os dois tipos de fosfolipídios, o ibuprofeno pôde penetrar na região hidrofóbica, o que foi confirmado por espectroscopia de reflexão e absorção no infravermelho com modulação da polarização (PM-IRRAS), indicando assim a presença de interações hidrofóbicas. A análise por microscopia no ângulo de Brewster (BAM) mostrou que o ibuprofeno impede a formação de grandes domínios de DPPC, enquanto que não foram observadas alterações significativas para o DPPG. A interação entre o ibuprofeno e o DPPG também foi confirmada após a imobilização da monocamada mista em filmes LB com alterações na absorção no UV-Vis da molécula de ibuprofeno. No que diz respeito às implicações biológicas, a ação farmacológica que depende diretamente da interação com a membrana deve ocorrer primeiramente em regiões neutras via penetração do ibuprofeno na região hidrofóbica da membrana celular. A segunda parte deste trabalho foi dedicada à interação de capsaicinóides extraídos da pimenta malagueta com monocamadas de Langmuir constituídas de DPPG e DPPC. A capsaicina é um potente analgésico de uso tópico, que pode causar dessensibilização no local de aplicação dependendo da dose e, portanto há interesse na sua incorporação em sistemas de liberação controlada, como os lipossomos. A técnica de Langmuir foi empregada para verificar essa possibilidade. Os capsaicinóides expandiram as monocamadas de DPPG e aumentaram sua elasticidade. As isotermas de potencial de superfície indicaram que os capsaicinóides provocam aumento de 10% no momento de dipolo numa concentração de 30% em mol. Para os filmes mistos de DPPC e capsaicinóides, a área mínima diminuiu e a elasticidade da monocamada aumentou. De acordo com as isotermas de potencial, os momentos de dipolo diminuíram para as monocamadas de DPPC independentemente da concentração de capsaicinóides. Esses resultados sugerem que as moléculas de DPPC são solubilizadas para a subfase na presença do fármaco. A partir destes resultados, conclui-se que os capsaicinóides podem ser incorporados em estruturas lipídicas, constituídas principalmente de DPPG, o que é relevante para uso em sistemas de liberação de fármacos. / Ibuprofen is a nonsteroidal anti-inflammatory drug, with low solubility in water, which exhibits side effects including gastric and intestinal injury, often irreversible. Some of these effects may depend on the interaction with the cell membrane, which motivated us to investigate the incorporation of ibuprofen in Langmuir monolayers as cell membrane models, in the first part of this thesis. Dipalmitoyl phosphatidyl choline (DPPC) or dipalmitoyl phosphatidyl glycerol (DPPG) monolayers co-spread with ibuprofen or deposited on ibuprofen-containing aqueous subphases were studied using surface pressure and surface potential isotherms. Significant effects were observed for DPPC monolayers, particularly at the liquid-expanded to liquid-condensed phase transition, with relevant changes in the elasticity of the monolayer. These effects increased with the ibuprofen concentration. For both types of phospholipids, ibuprofen could penetrate into the hydrophobic part of the monolayer, which was confirmed with polarization-modulated infrared reflection absorption spectroscopy (PM-IRRAS), thus indicating the presence of hydrophobic interactions. BAM images showed that ibuprofen prevents the formation of large domains of DPPC, while no significant changes were observed for DPPG. The interaction between DPPG-ibuprofen was also confirmed for deposited layers in the form of LB films, with changes in the ibuprofen UV-Vis absorption. As for the biological implications, the pharmacological action depending directly on the membrane interaction should occur primarily with zwitterionic regions of the membrane via penetration of ibuprofen in the hydrophobic part of the monolayer. The second part of this thesis is dedicated to the interaction of capsaicinoids, extracted from malagueta pepper, with Langmuir monolayers of DPPC and DPPG. Capsaicin is a powerful analgesic of topical use, which can cause desensitization in the application site depending on the dose, and therefore there is interest in its incorporation in drug delivery systems, such as liposomes. The Langmuir technique was employed to verify this possibility. The capsaicinoids expanded the DPPG monolayer and increased its elasticity. Surface potential isotherms indicated that the capsaicinoids increased the average dipole moment by 10 % for 30 mol % of capsaicinoids. For the mixed films of DPPC and capsaicinoids, the minimum area decreased and the elasticity increased. According to the surface potential isotherms, the dipole moments decreased for DPPC monolayers regardless of the capsaicinoid concentrations. These results suggest that the DPPC molecules are solubilized into the subphase in the presence of the drug. From these results, it is concluded that the capsaicinoids can be incorporated into structures as the liposomes constituted mainly of DPPG, which is relevant for use in drug delivery systems.

Capsaicina

Filmes de Langmuir-Blodgett

Ibuprofeno

Monocamadas de Langmuir

Pimenta malagueta

PM-IRRAS

Capsaicin

Ibuprofen

Langmuir monolayers

Langmuir-Blodgett films

Malagueta pepper

PM-IRRAS

Hodnocení přípravy monovrstevných lipidových modelů kožní bariéry / Evaluation of preparation of monolayer lipid skin barrier models

Růžičková, Karolína

January 2019

Charles University, Faculty of Pharmacy in Hradec Králové Department of Pharmaceutical Technology Author: Karolína Růžičková Supervisor: PharmDr. Barbora Švecová, Ph.D. Consultant: Mgr. Anna Nováčková Title of thesis: Evaluation of preparation of monolayer lipid skin barrier models Skin, the protective barrier of human body, consists of several layers. The uppermost one is the stratum corneum, part of epidermis, whose extracellular matrix is composed mainly of ceramides, cholesterol and free fatty acids. The composition and arrangement of skin lipids are essential for the proper skin barrier function. Various multilayer and monolayer models are used to study skin lipids at the molecular level. Some of the evaluation methods are Langmuir monolayers at the air interface. In this work I dealt with the behavior of monolayer lipid models at four different pH values of the liquid subphase. Lipids isolated from human skin, lipid mixture prepared from the individual components, and a mixture of fatty acids were compared as well. Langmuir isotherms and the Brewster angle microscopy at different compression rates were used for this purpose. The results showed that pH of the subphase has no major effect on lipids arrangement. Lipids were most likely to form a tight monolayer at neutral pH 7,0, at a...

Characterizing Liquid-Fluid Interfaces Using Surface Light Scattering Spectroscopy

Thapa, Nabin K.

26 July 2019

No description available.

Physics

Surface Light Scattering Spectroscopy

surface tension

binary mixtures

Langmuir monolayers

thermal capillary waves

surface response function

liquid-vapor interfaces

liquid-liquid-vapor interfaces

Charging behaviour of the amine moiety at the air-water interface. A vibrational sum frequency study / Amingruppens laddningsbeteende vid ytgränsskiktet mellan vatten och luft. En vibrationssumfrekvensstudie

Gullstrand, Mikael

January 2021

Laddningsbeteendet hos amingruppen vid ytgränsskiktet mellan vatten och luft har studerats under ändring av vattenfasens pH och NaCl-koncentration via den ickelinjära laserspektroskopiska tekniken, vibrationssumfrekvensspektroskopi (VSFS). Modellen som användes för ytan bestod av ett Langmuirmonolager av 1-docosanamin, en icke-löslig fettkedjeamin med NH2-gruppen riktad mot vattenfasen. En av de huvudsakliga syftena med projektet var att bestämma det skenbara samt yt-pKa:t för amingruppen, såväl som att testa gränserna för de klassiska Poisson-Boltzmann-formuleringarna av teorin för det elektriska dubbellagret. Molekylär information av laddningsbeteendet hos aminen erhölls från VSFS-spektra genom att följa NH-, OH- och CH-sträckningsvibrationsmoderna. Specifikt så identifierades de spektrala dragen från den neutrala formen (R-NH2) och den laddade formen (R-NH3+) av aminen, vilka direkt korrelerades med monolagrets ytladdning. Intensiteten hos OH-banden från vattenmolekylerna i det diffusa dubbellagret kunde länkas till ytpotentialen och CH-vibrationerna från alkylkedjan av amino-tensiden kopplades slutligen till packningstätheten hos monolagret. Ytterligare experiment utfördes med en deutererad vattenfas (D2O) för att bekräfta sträckningsvibrationsmoderna hos NH3+, vilka aldrig tidigare har rapporterats. Resultaten visar på att fettkedjeaminen får ett avsevärt lägre yt- och skenbart pKa jämfört med bulken (∼ 4 jämfört med 10,5). Detta är i enlighet med vad Gouy-Chapmann-modellen av det elektriska dubbellagret förutser. Dessutom så indikerar datat att det inneboende pKa:t hos aminen också blir lägre vid ytan än för bulken (9,7±0,7 jämfört med 10,5), vilket kan beskrivas som en effekt av begränsningen i frihetsgrader hos den ytbundna aminen. Dock, så hindrades en mer utförlig kvantitativ jämförelse mot teorin av ett sämre val av det experimentella referensvärdet som användes för att jämföra data mellan olika dagar. Dessutom så var anpassningsrutinen för datat begränsad på grund av spektrala vibrationsöverlapp mellan de relativt svaga aminbanden och de mycket starkare vatten- och alkylsträckningssignalerna. Intressant nog, för högre pH-värden, då aminen är helt oladdad, bevisade sumfrekvensspektra att hydroxidjonen föredrar att adsorbera till ytan genom att monolagret fick en negativ nettoladdning. Överlag så förbättrar studierna som presenteras i denna master-projektuppsats vår molekylära förståelse kring hur den biofysiskt betydande amingruppen beter sig vid ytgränsskikt. / The charging behaviour of the amine moiety at the water-air interface upon changes in the aqueous subphase pH and NaCl concentration has been studied using  the non-linear laser spectroscopy technique, Vibrational Sum Frequency Spectroscopy (VSFS).  The model surface consisted of a Langmuir monolayer of 1-docosaneamine, an insoluble fatty amine that exposes its NH2  group to solution. One of the main purposes of the project is to determine the surface, and the apparent pKa of the amine moiety, as well as testing the limits of validity of classical formulations of the electrical double layer theory within the Poisson-Boltzmann formalism. Molecular information of the charging behaviour was obtained from the VSFS spectra by targeting the NH, OH and CH stretching modes. Specifically, spectral features from the neutral amine (i.e. R-NH2) and charged (R-NH3+) groups could be identified and directly correlated to the surface charge of the monolayer. The intensity of the  OH bands from water molecules in the diffuse double layer, were linked to the surface potential, and finally, the CH modes from the surfactant alkyl chain gave information of the packing density in the monolayer. Additional experiments were also carried out in D2O to help confirm the assignment of the NH3+ stretching modes that had not been previously reported. The results show that as predicted from the Gouy-Chapman electric double layer model, the apparent pKa of the fatty amine monolayer is significantly lower than in the bulk  (∼ 4 compared with 10.5) . However, the data show indication that the intrinsic pKa at the surface is also lower than in the bulk (9.7+/- 0.7, compared to 10.5), an effect that is ascribed to the 2D molecular confinement in the monolayer. A more quantitative comparison with the theoretical predictions was nonetheless hampered by a poor selection of the experimental reference for comparing data collected in different days, and the limitations in the fitting routines due spectral overlap of the relatively weak amine bands with the OH and CH stretching modes. Interestingly, at high pH when the fatty amine is fully uncharged, the sum frequency spectra show evidence that OH- ion preferentially adsorbed to the surface, making it effectively net negatively charged. Overall, the studies presented in this master thesis, improve our molecular understanding of the behaviour of the biophysically relevant amine-functionality at interfaces.

Langmuir monolayers

Vibrational Sum Frequency Spectroscopy

Fatty amine

Monovalent ions

Poisson Boltzmann theory

Langmuirmonolager

Vibrationssumfrekvensspektroskopi

Fettkedjeamin

Monovalenta joner

Poisson-Boltzmann-teori

Physical Chemistry

Fysikalisk kemi

Structure and Dynamics of Polyhedral Oligomeric Silsesquioxane (POSS) and Poly(Ethylene Glycol) (PEG) Based Amphiphiles as Langmuir Monolayers at the Air/Water Interface

Lee, Woojin

08 April 2008

Throughout the study of polymeric Langmuir monolayers at the air/water (A/W) interface, the Wilhelmy plate and Langmuir-Blodgett (LB) techniques along with Brewster angle microscopy (BAM) have been identified as key methods for acquiring structural, thermodynamic, rheological and morphological information. These techniques along with surface light scattering (SLS), a method for probing a monolayer's dynamic dilational rheological properties, will be used to characterize homopolymers, poly(ethylene oxide) (PEO) and poly(ethylene glycol) (PEG), and a new class of novel polymeric surfactants, telechelic (POSS-PEG-POSS) and hemi-telechelic (POSS-PEG) polyhedral oligomeric silsesquioxane (POSS) derivatives of PEG. PEO with number average molar mass, Mn > ~ 18 kg·mol-1 form stable spread Langmuir films at the A/W interface, while oligomeric PEG have ï -A isotherms that deviate from high molar mass PEO. Nonetheless, SLS reveals that the dynamic dilational viscoelastic properties of any Mn PEG(PEO) only depend on ï and not Mn. Likewise, POSS-PEG-POSS telechelics exhibit molar mass dependent ï -A isotherms, where low ï regimes (ï < 1 mN·m-1) have PEG-like behavior, but high ï regimes were dominated by POSS-POSS interactions. SLS studies reveal that the dynamic dilational moduli of POSS-PEG-POSS are greater than either PEO or an analogous POSS compound, trisilanolcyclohexyl-POSS. The ability to control rheological properties and the hydrophilic-lipophilic balance even allows one POSS-PEG-POSS (PEG Mn = 1 kg·mol-1) to form Y-type LB-multilayer films. For POSS-PEG systems, comparisons at comparable POSS:PEG ratios reveal short PEG chains (PEG Mn ~ 0.5 kg·mol-1) yield similar viscoelastic properties as POSS-PEG-POSS (PEG Mn ~ 1 kg·mol-1), while longer PEG chains (PEG Mn ~ 2 kg·mol-1) yield lower modulus films than comparable POSS-PEG-POSS. These differences are attributed to brush-like PEG conformations in short POSS-PEG versus mushroom-like PEG conformations in long POSS-PEG at the A/W interface. These results provide insight for designing PEG-based amphiphilic nanoparticles with controlled interfacial rheology. / Ph. D.

Viscoelasticity

Langmuir monolayers

Poly(ethylene oxide) (PEO)

Poly(ethylene glycol) (PEG)

Hemi-telechelic POSS-PEG

Telechelic POSS-PEG-POSS