BIOMIMETIC DISSOLUTION: A TOOL TO EVALUATE AMORPHOUS SOLID DISPERSION PERFORMANCE

Puppolo, Michael McBride

January 2017

The pharmaceutical industry is at a critical juncture. With little remnants of the “Golden Age of the Pharmaceuticals” and applied pressure from large companies experiencing a dissipation of proprietary compounds, trends indicate a transition from a decade of stagnant productivity to one in which high throughput screening technologies and computational chemistry have diversified the discovery of new chemical entities (NCE). Despite these advances, drug discovery has been challenged by chemical entities that present delivery limitations due to the properties of their molecular structure. A recent evaluation of development pipelines indicated that approximately 70% of drug candidates exhibit poor aqueous solubility; thereby, resulting in erratic dissolution and insufficient bioavailability. Due to intrinsic physical properties, these compounds are known by the biopharmaceutics classification system (BCS) as class II compounds and are amendable to solubility and bioavailability enhancement platforms. Approaches such as pH adjustment, micronization, nanosuspensions, co-solvent solubilization, cyclodextrin inclusion complexation, salt formation, emulsified drug formulations and amorphous solid dispersions (ASD) are commonly utilized to maximize bioavailability and enrich in vivo absorption by prolonging exposure to high concentrations of dissolved drug in the gastrointestinal tract (GIT). Single-phase amorphous systems, such as solid dispersions, have been the focal point of the aforementioned practices as a result of their ability to promote a state of drug supersaturation over an extended duration of time. Within the structure of this dissertation, the application of concentration enhancing polymers for bioavailability enhancement of low solubility compounds was evaluated using solvent and fusion-based solid dispersion technologies. Exploiting a variety of analytical methodologies and tools, formulations produced by spray drying and hot melt extrusion (HME) techniques were investigated for sufficient dissolution enhancement. Studies revealed the selected formulation approaches provided a viable platform for manufacturing solid dispersions by illustrating systems that offered rapid and prolonged periods of supersaturation. While of the applications of single-phase amorphous solid dispersions are continuously expanding, their dissolution behavior is not as well understood. The overarching objective of dissolution testing during formulation development is to achieve biological relevance and predict in vivo performance. Proper in vitro dissolution testing can convey the influence of key in vivo performance parameters and be implemented for assessment and comparison of ASD formulations. Studies suggest that existing research fails to accurately address the intricacies associated with the supersaturated state. Upon solvation and during transit in the GIT, several high-energy drug-containing species are present in addition to free drug. Although these species are not absorbed in vivo, they play a pivotal role in generating and maintaining the supersaturation of a drug substance and function to replenish the supply of free drug as it permeates across the gastrointestinal membrane. Established dissolution apparatuses and methodologies in the United States Pharmacopeia (USP) focus on evaluation of total dissolved drug and may not be physiologically relevant for determining the amount of drug absorbed in vivo. Within the framework of this dissertation, a dissolution methodology was designed to reflect the physiochemical, physiological and hydrodynamic conditions that transpire throughout dissolution and absorption of an ASD during transit in the GIT. The apparatus and model present the ability to understand the kinetics and mechanisms of dissolution, supersaturation and nucleation. To support this hypothesis, analytical methods including high pressure liquid chromatography (HPLC) with ultraviolet (UV) detection were developed and fully validated. In parallel, a novel plasma membrane treatment was established to fabricate biomimetic membranes that possessed a hydrophilic and hydrophobic surface. The treated membranes are comprised of applied surface chemistries that emulate the unstirred aqueous layer created by microvilli protruding from the intestinal epithelial membrane as well as lipophilic constituents corresponding to the epithelial lipid membrane. Calculated in vitro similarity (f2) and difference (f1) factors support the hypotheses that plasma treated microporous polymer membranes exhibit biorelevant properties and demonstrate adequate biorelevance for in vitro dissolution studies. The described dissolution methodology has been applied as a tool for selection of candidates to move forward to pharmacokinetic studies. In a culminating study, in vitro – in vivo correlations (IVIVC) were performed employing the universal membrane-permeation non-sink dissolution method for formulations of Carbamazepine. To demonstrate the utility of the methodology, multiple level C correlations were established. The membrane-permeation model enables quantitative assessment of drug dissolution and absorption and offers a means to predict the relative in vivo performance of amorphous solid dispersions for BCS class II drug substances. / Chemistry

Chemistry, Analytical

Amorphous Solid Dispersions

Biomimetic Dissolution

Free Drug

In Vitro - in Vivo Correlation

Membrane-permeation Dissolution

Poorly Water Soluble

Desenvolvimento de membranas de poli(éter imida) sultonada para a permeacão de gases / Development of sulfonated poly(ether imide) membranes for gas permeation

Michelle Silva Vila Chã

21 December 2009

A busca por membranas com propriedades adequadas a separação de gases em escala industrial tem levado a modificação e sIntese de polImeros de engenharia, com objetivo de obter membranas com propriedades adequadas. Uma das modificaçoes que tem se apresentado promissora é a inserção de grupos sulfônicos em polImeros comerciais. Espera-se que o polImero sulfonado apresente um aumento na permeação de gases polares, em relação a gases apolares, devido a sua estrutura mais polar e flexIvel. Neste contexto, o objetivo do presente trabalho é a sIntese e caracterização de membranas de poli(éter imida) sulfonada para a permeação de gases. Um planejamento experimental foi desenvolvido, em diferentes condiçoes reacionais de temperatura, tempo e excesso de um dos reagentes (ácido acético), para a sIntese de poli(éter imida) sulfonada (SPEI). Através deste planejamento, constatou-se que as variáveis que mais influenciam o grau de sulfonação são a temperatura e o tempo. O polImero com o maior grau de sulfonação, determinado por capacidade de troca iônica (IEC= 92 mEq H+/g), foi utilizado para o preparo da membrana de SPEI, obtida pela técnica de inversão de fase por evaporação do solvente, utilizando-se clorofórmio como solvente. Este filme foi caracterizado a partir das seguintes análises: espectroscopia de infravermelho (FTIR), calorimetria diferencial de varredura (DSC), análise termogravimétrica (TGA) e microscopia eletrônica de varredura (MEV), a fim de avaliar a influência da inserção do grupo sulfônico na matriz polimérica. O espectro de infravermelho de SPEI apresentou bandas relacionadas as vibraçoes assimétricas em 1240 cm-1 (ligação O=S=O), ligação simétrica em 1171 cm-1 (O=S=O) e ligação S-O entre 1010-1024 cm-1. Isto indica a presença de grupos sulfônicos. A análise de DSC foi realizada entre 150-250C. Nesta faixa, não foram observadas alteraçoes na temperatura de transição vItrea (Tg) do polImero modificado (217C). Acredita-se que a decomposição do grupo sulfona aconteça antes da temperatura atingir o Tg do polImero. Esta suposição é confirmada na análise de TGA. As imagens de MEV mostraram que foram obtidos filmes livres de poros e defeitos. A membrana da SPEI foi utilizada no ensaio de permeaçao dos gases 02, N2 e C02, a fim de determinar a permeabilidade e seletividade da membrana. As permeabilidades encontradas para o gas oxigênio foram de 0,76 barrer para a PEI e 0,46 barrer para a SPEI. A seletividade do dióxido de carbono em relaçao ao oxigênio aumentou de 3,5, na membrana de PEI, para 4,83, na membrana de SPEI. Em relaçao ao nitrogênio, as permeabilidades medidas foram 0,064 barrer e 0,043 barrer, para a PEI e para a SPEI, respectivamente, enquanto a seletividade em relaçao ao C02 aumentou de 41,1 para 55,5. Estes resultados indicam que o efeito de sorçao predominou devido ao aumento das interaçöes moleculares, reduzindo assim o volume livre, o que tornou a membrana sulfonada mais compacta, com permeabilidade menor e maior seletividade. Estes resultados corroboram com a premissa de que a sulfonaçao é um processo promissor para o desenvolvimento de membranas mais eficientes. / The search for membranes with suitable properties for gas separation in industrial scale has led to the modification and synthesis of engineering polymers with the purpose of obtaining membranes with superior properties. 0ne of the modifications that have been considered promising is the insertion of sulfonic groups in commercial polymers. Due to its structure more polar and flexible, it is expected that the sulfonated polymer present an increase in polar gas permeation in relation to nonpolar gases. In this context, the objective of this work is the synthesis and characterization of membranes of poly (ether imide) sulfonated for the permeation of gases. An experimental design was developed in different reaction conditions of temperature, time and an excess of one of the reagents (acetic acid), for the synthesis of poly (ether imide) sulfonated, SPEI. Through this planning, it was found that the variables that most influenced the degree of sulfonation are temperature and time. The polymer with the highest degree of sulfonation, by ion exchange capacity (IEC = 92 mEq H+ I g), was used to prepare SPEI membrane obtained by the technique of solvent evaporation, using chloroform. This film was characterized from the following analysis: infrared spectroscopy (FTIR), differential scanning calorimetry (DSC), thermogravimetric analysis (TGA) and scanning electron microscopy (SEM) to evaluate the influence of insertion of the sulfonic group in the polymer matrix. The infrared spectrum showed bands of SPEI related to asymmetric vibrations at 1240cm- 1 (S = 0 = 0), in symmetric stretch at 1171 cm-1 (0 = S = 0) and S0 stretch between 1010-1024cm-1. This indicates the presence of sulfonic groups. The DSC analysis was carried out between 150-250C. In this range, there are no significant changes in glass transition temperature of the modified polymer (217C). It is believed that the decomposition of the sulfone group occurs before the temperature reaches the Tg of the polymer. This assumption is confirmed in the TGA analysis. The images of SEM showed that films were obtained free of pores and defects. The membrane SPEI obtained by the technique of solvent evaporation, was used for testing permeation of gases 02, N2 and C02 in order to determine the permeability and selectivity of the membrane. The permeabilities found for oxygen were 0.76 barrer for PEI and 0.46 barrer for SPEI. The selectivity of carbon dioxide relative to oxygen increased from 3.5 to 4.83. Regarding nitrogen, the permeability measurements were 0.064 barrer and 0.043 barrer for the PEI and the SPEI, respectively, while the selectivity relative to C02 increased from 41.1 to 55.5. These results indicate that the predominant effect of sorption due to increased molecular interactions, thus reducing the free volume, made the membrane sulfonated more compact with lower permeability and higher selectivity. These results agree with the premise that the sulfonation is a promising process for the development of more efficient membranes.

Poliéter imida

sulfonaçao de polImeros

membrana para permeaçao de gases

Polyether imide

sulfonation of polymers

characterization of thick films

membrane permeation of gases

Desenvolvimento de membranas de poli(éter imida) sultonada para a permeacão de gases / Development of sulfonated poly(ether imide) membranes for gas permeation

Michelle Silva Vila Chã

21 December 2009

A busca por membranas com propriedades adequadas a separação de gases em escala industrial tem levado a modificação e sIntese de polImeros de engenharia, com objetivo de obter membranas com propriedades adequadas. Uma das modificaçoes que tem se apresentado promissora é a inserção de grupos sulfônicos em polImeros comerciais. Espera-se que o polImero sulfonado apresente um aumento na permeação de gases polares, em relação a gases apolares, devido a sua estrutura mais polar e flexIvel. Neste contexto, o objetivo do presente trabalho é a sIntese e caracterização de membranas de poli(éter imida) sulfonada para a permeação de gases. Um planejamento experimental foi desenvolvido, em diferentes condiçoes reacionais de temperatura, tempo e excesso de um dos reagentes (ácido acético), para a sIntese de poli(éter imida) sulfonada (SPEI). Através deste planejamento, constatou-se que as variáveis que mais influenciam o grau de sulfonação são a temperatura e o tempo. O polImero com o maior grau de sulfonação, determinado por capacidade de troca iônica (IEC= 92 mEq H+/g), foi utilizado para o preparo da membrana de SPEI, obtida pela técnica de inversão de fase por evaporação do solvente, utilizando-se clorofórmio como solvente. Este filme foi caracterizado a partir das seguintes análises: espectroscopia de infravermelho (FTIR), calorimetria diferencial de varredura (DSC), análise termogravimétrica (TGA) e microscopia eletrônica de varredura (MEV), a fim de avaliar a influência da inserção do grupo sulfônico na matriz polimérica. O espectro de infravermelho de SPEI apresentou bandas relacionadas as vibraçoes assimétricas em 1240 cm-1 (ligação O=S=O), ligação simétrica em 1171 cm-1 (O=S=O) e ligação S-O entre 1010-1024 cm-1. Isto indica a presença de grupos sulfônicos. A análise de DSC foi realizada entre 150-250C. Nesta faixa, não foram observadas alteraçoes na temperatura de transição vItrea (Tg) do polImero modificado (217C). Acredita-se que a decomposição do grupo sulfona aconteça antes da temperatura atingir o Tg do polImero. Esta suposição é confirmada na análise de TGA. As imagens de MEV mostraram que foram obtidos filmes livres de poros e defeitos. A membrana da SPEI foi utilizada no ensaio de permeaçao dos gases 02, N2 e C02, a fim de determinar a permeabilidade e seletividade da membrana. As permeabilidades encontradas para o gas oxigênio foram de 0,76 barrer para a PEI e 0,46 barrer para a SPEI. A seletividade do dióxido de carbono em relaçao ao oxigênio aumentou de 3,5, na membrana de PEI, para 4,83, na membrana de SPEI. Em relaçao ao nitrogênio, as permeabilidades medidas foram 0,064 barrer e 0,043 barrer, para a PEI e para a SPEI, respectivamente, enquanto a seletividade em relaçao ao C02 aumentou de 41,1 para 55,5. Estes resultados indicam que o efeito de sorçao predominou devido ao aumento das interaçöes moleculares, reduzindo assim o volume livre, o que tornou a membrana sulfonada mais compacta, com permeabilidade menor e maior seletividade. Estes resultados corroboram com a premissa de que a sulfonaçao é um processo promissor para o desenvolvimento de membranas mais eficientes. / The search for membranes with suitable properties for gas separation in industrial scale has led to the modification and synthesis of engineering polymers with the purpose of obtaining membranes with superior properties. 0ne of the modifications that have been considered promising is the insertion of sulfonic groups in commercial polymers. Due to its structure more polar and flexible, it is expected that the sulfonated polymer present an increase in polar gas permeation in relation to nonpolar gases. In this context, the objective of this work is the synthesis and characterization of membranes of poly (ether imide) sulfonated for the permeation of gases. An experimental design was developed in different reaction conditions of temperature, time and an excess of one of the reagents (acetic acid), for the synthesis of poly (ether imide) sulfonated, SPEI. Through this planning, it was found that the variables that most influenced the degree of sulfonation are temperature and time. The polymer with the highest degree of sulfonation, by ion exchange capacity (IEC = 92 mEq H+ I g), was used to prepare SPEI membrane obtained by the technique of solvent evaporation, using chloroform. This film was characterized from the following analysis: infrared spectroscopy (FTIR), differential scanning calorimetry (DSC), thermogravimetric analysis (TGA) and scanning electron microscopy (SEM) to evaluate the influence of insertion of the sulfonic group in the polymer matrix. The infrared spectrum showed bands of SPEI related to asymmetric vibrations at 1240cm- 1 (S = 0 = 0), in symmetric stretch at 1171 cm-1 (0 = S = 0) and S0 stretch between 1010-1024cm-1. This indicates the presence of sulfonic groups. The DSC analysis was carried out between 150-250C. In this range, there are no significant changes in glass transition temperature of the modified polymer (217C). It is believed that the decomposition of the sulfone group occurs before the temperature reaches the Tg of the polymer. This assumption is confirmed in the TGA analysis. The images of SEM showed that films were obtained free of pores and defects. The membrane SPEI obtained by the technique of solvent evaporation, was used for testing permeation of gases 02, N2 and C02 in order to determine the permeability and selectivity of the membrane. The permeabilities found for oxygen were 0.76 barrer for PEI and 0.46 barrer for SPEI. The selectivity of carbon dioxide relative to oxygen increased from 3.5 to 4.83. Regarding nitrogen, the permeability measurements were 0.064 barrer and 0.043 barrer for the PEI and the SPEI, respectively, while the selectivity relative to C02 increased from 41.1 to 55.5. These results indicate that the predominant effect of sorption due to increased molecular interactions, thus reducing the free volume, made the membrane sulfonated more compact with lower permeability and higher selectivity. These results agree with the premise that the sulfonation is a promising process for the development of more efficient membranes.

Poliéter imida

sulfonaçao de polImeros

membrana para permeaçao de gases

Polyether imide

sulfonation of polymers

characterization of thick films

membrane permeation of gases

Adsorption and Transport of Drug-Like Molecules at the Membrane of Living Cells Studied by Time-Resolved Second-Harmonic Light Scattering

Sharifian Gh., Mohammad

January 2018

Understanding molecular interactions at the surfaces of cellular membranes, including adsorption and transport, is of fundamental importance in both biological and pharmaceutical studies. At present, particularly with respect to small and medium size (drug-like) molecules, it is desirable to gain an understanding of the mechanisms that govern membrane adsorption and transport. To characterize drug-membrane interactions and mechanisms governing the process of molecular uptake at cellular membranes in living organisms, we need to develop effective experimental techniques to reach quantitative and time-resolved analysis of molecules at the membrane surfaces. Also, we preferably want to develop label-free optical techniques suited for single-cell and live cell analysis. Here, I discuss the nonlinear optical technique, second-harmonic light scattering (SHS), for studying molecule-membrane interactions and transport of molecules at the membrane of living cells with real-time resolution and membrane surface-specificity. Time-resolved SHS can quantify adsorption and transport of molecules, with specific nonlinear optical properties, at living organisms without imposing any mechanical stress onto the membrane. This label-free and surface-sensitive technique can even differentiate molecular transport at individual membranes within a multi-membrane cell (e.g., bacteria). In this dissertation, I present our current research and accomplishments in extending the capabilities of the SHS technique to study molecular uptake kinetics at the membranes of living cells, to monitor bacteria membrane integrity, to characterize the antibacterial mechanism-of-action of antibiotic compounds, to update the molecular mechanism of the Gram-stain protocol, to pixel-wise mapping of the membrane viscosity of the living cells, and to probe drug-induced activation of bacterial mechanosensitive channels in vitro. / Chemistry

Chemistry, Physical

Biophysics

Medicine

Cell Membrane

Membrane-specific Antimicrobial Response

Method Development

Second-harmonic Light Scattering

Selectivity, Regulation, and Inhibition of Aquaporin Channels. A Molecular Dynamics Study / Selektivität, Regulation und Inhibition von Aquaporinkanälen. Eine Untersuchung mittels Molekulardynamiksimulationen

Hub, Jochen Sebastian

28 January 2008

No description available.

530 Physik

WCC 000

Mathematics and Natural Science

Aquaporin

Aquaglyceroporin

Membran

Permeation

Molekulardynamik

Simulation

Selektivität

aquaporin

aquaglyceroporin

membrane permeation

molecular dynamics simulation

selectivity

potential of mean force

umbrella sampling

33 Physik

42.12 Biophysik

Transfer of small molecules across membrane-mimetic interfaces

Velicky, Matej

January 2011

The presented thesis investigates the transfer of drug molecules across interfaces that mimic biological membrane barriers. The permeability of drug molecules across biological membrane mimics has been investigated in a novel artificial membrane permeation assay configuration using an in situ time-dependent approach and reproducible rotation of the membrane. A method to determine the membrane permeability from the knowledge of measured permeability and the applied stirring rate is presented. The initial transient of the permeation response, previously not observed in situ, is investigated and its importance in data evaluation is discussed. The permeability coefficients of 31 drugs are optimised for the conditions found in vivo and a correlation with the fraction absorbed in humans is presented. The evidence for ionic and/or ion-pair flux across the artificial membrane obtained from measurement of permeability at different pH is supported by the investigation of the permeation assay with external membrane polarisation. The permeability coefficient of the solute's anionic form is determined. Liquid/liquid electrochemistry has been used to study the transfer of ionized species across the interface between water and 1,2-dichloroethane. An alternative method to study the transfer of partially ionised drug molecules employing a rotating liquid/liquid interface is presented. In addition, a bipolar electrochemical cell with a rotating-disc electrode is developed and its properties investigated in order to verify the hydrodynamics of the rotating artificial membrane configuration. Finally, in support of the electrochemical techniques used is this thesis, a detailed preparation and evaluation of the silver/silver sulphate reference electrode is presented.

571.64