Improvement in the bioavailability of poorly water-soluble drugs via pulmonary delivery of nanoparticles

Yang, Wei

23 October 2009

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

New highly effective dry powder tobramycin formulations for inhalation in the treatment of cystic fibrosis/Nouvelles formulations à poudre sèche pour inhalation à base de tobramycine pour le traitement de la mucoviscidose

Pilcer, Gabrielle

27 October 2008

Local delivery of medication to the lung is highly desirable as the principal advantages include reduced systemic side effects and higher dose levels of the applicable medication at the site of drug action. This administration could be particularly useful for patients with specifically chronic pulmonary infections or pulmonary diseases, such as cystic fibrosis, asthma or lung cancer. In order to deliver a high dose range of medication for highly-dosed drugs such as antibiotics, “carrier-free” DPI formulations of tobramycin were developed with the aim of minimizing the use of excipients. Briefly, dry powders were prepared by spray drying various suspensions of tobramycin in isopropanol. First, as particle size is a key parameter in defining drug deposition in the lungs, the new Spraytec® laser diffraction method specifically modified for measuring the PSD of aerosolized drug was evaluated. The dispersion properties of various dry powder formulations were investigated using different laser diffraction and impaction apparatuses at different flow rates and using different inhalator devices. Different correlations between geometric and aerodynamic size data were demonstrated in this study. As a potential application, for the flow rate, the different inhalation devices and the drug formulations examined, the tobramycin fine particle fraction could be predicted from measurements obtained from the Spraytec® using linear relationships. Correlations (R² > 0.9) between the MMAD and the percentage of particles with a diameter below 5 µm could be demonstrated between the results obtained from the laser diffraction technique and the impaction method. Consequently, the Spraytec® laser diffraction technique was proved to be an important tool for initial formulation and process screening during formulation development of DPIs. In order to modify the surface properties of the raw tobramycin powder, different powder compositions were formulated with the aim of studying the influence of the concentration of tobramycin in drug suspensions used for spray-drying, the lipid film composition (cholesterol:Phospholipon ratio) and the coating level (in percentage) on the physicochemical and aerodynamic characteristics of the antibiotic. The results indicated that the application of a lipid coating around the active particles allowed an improvement in particle dispersion from the inhalator, decreasing raw powder agglomeration and thus enhancing drug deposition deep in the lungs. Moreover, these results seemed to be influenced by the amount and composition of the lipids in the formulations. The evaluation of the influence of the coating level showed that the deposition of only 5% w/w lipids (on a dry basis) was sufficient to improve particle dispersion properties during inhalation. The FPF, which is around 36% for the uncoated micronized tobramycin, was increased to up to about 68% for the most effective lipid-coated formulation. Of particular importance, these results revealed the need to add sufficient amounts of covering material in order to significantly modify the particle surface properties and reduce their tendency to agglomeration, while limiting the lipid level in the formulations in order to avoid any undesirable sticking and to allow the delivery of more of the active drug to the deep lung. Another approach used to modify the surface properties of raw tobramycin was to coat the micronized particles with nanoparticles of the drug, produced by high pressure homogenization. The evaluation of the influence of the level of nanoparticle coating of the micronized particles showed that the presence of nanoparticles in the formulations improved the particle dispersion properties during inhalation. One microparticle was completely covered with a single layer or several layers of nanoparticles, in function of the percentage of nanoparticles in the mixture. Coating the fine drug particles with particles in the nanometer range was believed to reduce Van Der Waals forces and powder agglomeration. These various layers of nanoparticles also allowed a decrease in the cohesion of the powder by improving the slip between the particles. On the other hand, suspensions containing solely nanoparticles were spray dried with various concentrations of surfactant in order to produce easily dispersible and reproducible micron-size agglomerates of nanoparticles during inhalation. The evaluation of the influence of the concentration of surfactant showed that deposition of only 2% w/w (on a dry basis) of Na glycocholate is sufficient to improve particle dispersion properties during inhalation. Consequently, the use of nanoparticles in dry powder formulations increased the FPF from 36% for the uncoated micronized tobramycin to about 61% for this latter formulation. To modify the balance between the different forces of interactions without the need for any excipient, the influence of formulation components on the aerosolization characteristics of spray-dried tobramycin through the use of various proportions of water in the solvent used to prepare initial suspensions was investigated. These results showed that it is possible to modify the surface properties of the particles by coating the particles of drug with a homogeneously distributed film of the active compound dissolved in a solvent system containing a mixture of different solvents such as isopropanol and water. During nebulization of the suspension, droplets are composed of one or more particles in solid state surrounded with solvent containing the dissolved drug. It is hypothesized that during the drying step, dissolved tobramycin forms a coating of the amorphous drug around particles in suspension. The coating of drug particles can thus be used as an alternative approach that permits the modification of the surface properties of the particles, increasing the flowability, the desagglomeration tendency and the fine particle fraction deposited in the deep lung. So, the evaluation of the influence of the water content of the suspensions and the effect of the inlet temperature during spray-drying showed that the addition of 2% water v/v is sufficient to improve particle dispersion during inhalation. Of particular interest, as tobramycin is a very hygroscopic drug, the addition of water turned out to be a critical step. It was thus important to add a small amount of water to the solvent system and to process the drying step at a high temperature to produce formulations containing solely the active drug and showing a FPF of up to 50%. Moreover, stability studies demonstrated that these optimized formulations (lipid-coated formulation, nanoparticle formulation and amorphous drug-coated formulation) were stable over a long time period at various ICH temperature and relative humidity storage conditions (25°C/60% RH, 30°C/65% RH and 40°C/75% RH). The formulations were shown to keep their crystalline state, initial PSD, redispersion characteristics and deposition results for more than twelve months. In order to confirm these encouraging results, two optimized formulations (one with a lipid coating and another with amorphous drug coating) were selected and compared to the only commercially available tobramycin formulation for inhalation, Tobi® (nebulizer solution), by performing a combined in vivo scintigraphic and pharmacokinetic evaluation of tobramycin DPIs in nine CF patients. In comparison with Tobi®, it was estimated that lung deposition, expressed as a percentage of the nominal dose, was 7.0 and 4.5 times higher for the lipid-coated and amorphous tobramycin-coated formulations, respectively. Moreover, the pharmacokinetic data, adjusted to the same drug dose as that of the Tobi® deposited in the lungs, showed that the AUC values were found to be 1.6 times higher for Tobi® than for DPI formulations. So this evaluation confirmed the superiority of dry powder formulations in terms of drug deposition and reduced systemic exposure in comparison with the conventional comparator product, Tobi®. Thus, these new and orginal tobramycin DPI formulations based on the use of very low excipient levels and presenting very high lung deposition properties, were shown to offer very good prospects for improving the delivery of drugs to the pulmonary tract and to the widest possible patient population.

lipides

nanoparticules

mucoviscidose

atomisation

poudre sèche pour inhalation

administration pulmonaire

nanoparticles/antibiotique

spray drying

lipids

cystic fibrosis

pulmonary delivery

dpi

antibiotic

DESENVOLVIMENTO DE NANOCÁPSULAS POLIMÉRICAS PARA LIBERAÇÃO PULMONAR DO DIPROPIONATO DE BECLOMETASONA / DEVELOPMENT OF POLYMERIC NANOCAPSULES FOR PULMONARY DELIVERY OF BECLOMETHASONE DIPROPIONATE

Chassot, Janaíne Micheli

22 March 2013

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Polymeric nanocapsules have been studied extensively for drug delivery by various routes of administration. Currently, the nanoencapsulation of drugs is considered the most efficient means of ensuring controlled release, specific targeting and reduction of adverse effects. In this context, the aim of this work was to develop polymeric nanocapsules for pulmonary delivery of beclomethasone dipropionate (BD). Nanocapsules have been prepared from 2 polymers, poly(-caprolactone) (PCL) and ethyl cellulose (EC). To quantify the drug in the nanostructures, the analytical method was developed and validated. This method showed to be specific, linear, precise, accurate and robust. Nanocapsules were prepared by interfacial deposition of preformed polymers and were evaluated as to pH, particle diameter, polydispersity index, drug content, encapsulation efficiency and zeta potential. All samples showed encapsulation efficiency greater than 98%, negative zeta potential, pH value in the range of neutrality and drug contents close to their theoretical values. The size distribution was nanometric (158-270 nm) with polydispersity index lower than 0.2. The results of the photodegradation study showed that polymeric nanocapsules were able to protect BD from UVC radiation when compared to the free drug solution. In vitro release experiments were performed using the dialysis bag technique, which showed, for all formulations, a prolonged drug release mediated by anomalous transport and first order kinetics. Free drug in solution took between 24 and 36 h to reach 100% of release, whereas nanocapsules were able to control the drug release for up to 108 h, depending on the polymer employed. Nanocapsules of EC and PCL were evaluated for in vitro and in vivo toxicity and the results suggest that the proposed formulations are safe. In the final stage of the work, pullulan was proposed as stabilizer agent for PCL nanocapsules and the results obtained for the zeta potential and the drug content suggested that these formulations have become more stable. Thus, the nanocapsules developed in this work represent a promising alternative for the pulmonary delivery of BD in the treatment of asthma and other respiratory disorders. / Nanocápsulas poliméricas vem sendo estudadas extensivamente para liberação de fármacos por diversas vias de administração. Atualmente a nanoencapsulação de fármacos é considerada o meio mais eficiente de assegurar liberação controlada, direcionamento específico e redução dos efeitos adversos. Neste contexto, o objetivo do presente trabalho foi desenvolver nanocápsulas poliméricas para a liberação pulmonar do dipropionato de beclometasona (DB). Nanocápsulas foram preparadas a partir de 2 polímeros, a poli(-caprolactona) (PCL) e a etilcelulose (EC). Para a quantificação do fármaco nas nanoestruturas, o método analítico foi desenvolvido e validado. Este mostrou ser específico, linear, preciso, exato e robusto. As nanocápsulas foram preparadas por deposição interfacial do polímero pré-formado e avaliadas quanto ao pH, diâmetro de partícula, índice de polidispersão, teor, eficiência de encapsulamento e potencial zeta. Todas as amostras apresentaram eficiência de encapsulamento maior que 98%, valor de potencial zeta negativo, valor de pH na faixa da neutralidade e teores próximos aos teóricos. A distribuição de tamanho foi nanométrica (158-270 nm) com índice de polidispersão menor que 0,2. Os resultados do estudo de fotodegradação mostraram que as nanocápsulas poliméricas foram capazes de proteger o DB da radiação UVC quando comparadas com uma solução do fármaco. Os experimentos de liberação in vitro foram realizados empregando a técnica de sacos de diálise, a qual mostrou, para todas as formulações, uma liberação prolongada do DB, mediada por transporte anômalo e cinética de primeira ordem. A solução etanólica de DB levou entre 24 e 36 h para alcançar 100% de liberação, enquanto que as nanocápsulas foram capazes de controlar a liberação do fármaco por até 108 h, dependendo do polímero empregado. Nanocápsulas de EC e PCL foram avaliadas quanto à toxicidade in vitro e in vivo e os resultados obtidos sugerem que as formulações propostas são seguras. Na etapa final do trabalho, o pullulan foi proposto como agente estabilizador de nanocápsulas de PCL e os resultados obtidos para o potencial zeta e o teor de fármaco sugerem que estas formulações tornaram-se mais estáveis. Desta forma, as nanocápsulas desenvolvidas neste trabalho representam uma alternativa promissora para a liberação pulmonar do DB no tratamento da asma e de outras desordens do trato respiratório.

Dipropionato de beclometasona

Nanocápsulas

Liberação pulmonar

Pullulan

Beclomethasone dipropionate

Nanocapsules

Pulmonary delivery

Pullulan

CNPQ::CIENCIAS BIOLOGICAS::FARMACOLOGIA

Improved inhalation therapies of brittle powders

Carvalho, Simone Raffa

03 March 2015

Advancements in pulmonary drug delivery technologies have improved the use of dry powder inhalation therapy to treat respiratory and systemic diseases. Despite remarkable improvements in the development of dry powder inhaler devices (DPIs) and formulations in the last few years, an optimized DPI system has yet to be developed. In this work, we hypothesize that Thin Film Freezing (TFF) is a suitable technology to improve inhalation therapies to treat lung and systemic malignancies due to its ability to produce brittle powder with optimal aerodynamic properties. Also, we developed a performance verification test (PVT) for the Next Generation Cascade Impactor (NGI), which is one of the most important in vitro characterization methods to test inhalation. In the first study, we used TFF technology to produce amorphous and brittle particles of rapamycin, and compared the in vivo behavior by the pharmacokinetic profiles, to its crystalline counterpart when delivered to the lungs of rats via inhalation. It was found that TFF rapamycin presented higher in vivo systemic bioavailability than the crystalline formulation. Subsequently, we investigated the use of TFF technology to produce triple fixed dose therapy using formoterol fumarate, tiotropium bromide and budesonide as therapeutic drugs. We investigated applications of this technology to powder properties and in vitro aerosol performance with respect to single and combination therapy. As a result, the brittle TFF powders presented superior properties than the physical mixture of micronized crystalline powders, such as excellent particle distribution homogeneity after in vitro aerosolization. Lastly, we developed a PVT for the NGI that may be applicable to other cascade impactors, by investigating the use of a standardized pressurized metered dose inhaler (pMDI) with the NGI. Two standardized formulations were developed. Formulations were analyzed for repeatability and robustness, and found not to demonstrate significant differences in plate deposition using a single NGI apparatus. Variable conditions were introduced to the NGI to mimic operator and equipment failure. Introduction of the variable conditions to the NGI was found to significantly adjust the deposition patterns of the standardized formulations, suggesting that their use as a PVT could be useful and that further investigation is warranted. / text

Pulmonary delivery

Inhalation

Particle engineering

Dry powder formulation

Rapamycin

Budesonide

Triotropium bromide

Formoterol fumarate

Pharmacokinetics

Fixed-dose combination

Triple combo formulation

Performance verification test

Cascade impactor

Calibration

Dry powder inhaler

Thin film freezing

Lyophilization

Brittle powder

New highly effective dry powder tobramycin formulations for inhalation in the treatment of cystic fibrosis / Nouvelles formulations à poudre sèche pour inhalation à base de tobramycine pour le traitement de la mucoviscidose

Pilcer, Gabrielle

27 October 2008

Local delivery of medication to the lung is highly desirable as the principal advantages include reduced systemic side effects and higher dose levels of the applicable medication at the site of drug action. This administration could be particularly useful for patients with specifically chronic pulmonary infections or pulmonary diseases, such as cystic fibrosis, asthma or lung cancer.<p>In order to deliver a high dose range of medication for highly-dosed drugs such as antibiotics, “carrier-free” DPI formulations of tobramycin were developed with the aim of minimizing the use of excipients. Briefly, dry powders were prepared by spray drying various suspensions of tobramycin in isopropanol.<p><p>First, as particle size is a key parameter in defining drug deposition in the lungs, the new Spraytec® laser diffraction method specifically modified for measuring the PSD of aerosolized drug was evaluated. The dispersion properties of various dry powder formulations were investigated using different laser diffraction and impaction apparatuses at different flow rates and using different inhalator devices. Different correlations between geometric and aerodynamic size data were demonstrated in this study. As a potential application, for the flow rate, the different inhalation devices and the drug formulations examined, the tobramycin fine particle fraction could be predicted from measurements obtained from the Spraytec® using linear relationships. Correlations (R² > 0.9) between the MMAD and the percentage of particles with a diameter below 5 µm could be demonstrated between the results obtained from the laser diffraction technique and the impaction method. Consequently, the Spraytec® laser diffraction technique was proved to be an important tool for initial formulation and process screening during formulation development of DPIs.<p><p>In order to modify the surface properties of the raw tobramycin powder, different powder compositions were formulated with the aim of studying the influence of the concentration of tobramycin in drug suspensions used for spray-drying, the lipid film composition (cholesterol:Phospholipon ratio) and the coating level (in percentage) on the physicochemical and aerodynamic characteristics of the antibiotic.<p>The results indicated that the application of a lipid coating around the active particles allowed an improvement in particle dispersion from the inhalator, decreasing raw powder agglomeration and thus enhancing drug deposition deep in the lungs. Moreover, these results seemed to be influenced by the amount and composition of the lipids in the formulations. The evaluation of the influence of the coating level showed that the deposition of only 5% w/w lipids (on a dry basis) was sufficient to improve particle dispersion properties during inhalation. The FPF, which is around 36% for the uncoated micronized tobramycin, was increased to up to about 68% for the most effective lipid-coated formulation. Of particular importance, these results revealed the need to add sufficient amounts of covering material in order to significantly modify the particle surface properties and reduce their tendency to agglomeration, while limiting the lipid level in the formulations in order to avoid any undesirable sticking and to allow the delivery of more of the active drug to the deep lung. <p><p>Another approach used to modify the surface properties of raw tobramycin was to coat the micronized particles with nanoparticles of the drug, produced by high pressure homogenization. The evaluation of the influence of the level of nanoparticle coating of the micronized particles showed that the presence of nanoparticles in the formulations improved the particle dispersion properties during inhalation. One microparticle was completely covered with a single layer or several layers of nanoparticles, in function of the percentage of nanoparticles in the mixture. Coating the fine drug particles with particles in the nanometer range was believed to reduce Van Der Waals forces and powder agglomeration. These various layers of nanoparticles also allowed a decrease in the cohesion of the powder by improving the slip between the particles.<p>On the other hand, suspensions containing solely nanoparticles were spray dried with various concentrations of surfactant in order to produce easily dispersible and reproducible micron-size agglomerates of nanoparticles during inhalation. The evaluation of the influence of the concentration of surfactant showed that deposition of only 2% w/w (on a dry basis) of Na glycocholate is sufficient to improve particle dispersion properties during inhalation. Consequently, the use of nanoparticles in dry powder formulations increased the FPF from 36% for the uncoated micronized tobramycin to about 61% for this latter formulation.<p>To modify the balance between the different forces of interactions without the need for any excipient, the influence of formulation components on the aerosolization characteristics of spray-dried tobramycin through the use of various proportions of water in the solvent used to prepare initial suspensions was investigated. These results showed that it is possible to modify the surface properties of the particles by coating the particles of drug with a homogeneously distributed film of the active compound dissolved in a solvent system containing a mixture of different solvents such as isopropanol and water. During nebulization of the suspension, droplets are composed of one or more particles in solid state surrounded with solvent containing the dissolved drug. It is hypothesized that during the drying step, dissolved tobramycin forms a coating of the amorphous drug around particles in suspension. The coating of drug particles can thus be used as an alternative approach that permits the modification of the surface properties of the particles, increasing the flowability, the desagglomeration tendency and the fine particle fraction deposited in the deep lung. So, the evaluation of the influence of the water content of the suspensions and the effect of the inlet temperature during spray-drying showed that the addition of 2% water v/v is sufficient to improve particle dispersion during inhalation. Of particular interest, as tobramycin is a very hygroscopic drug, the addition of water turned out to be a critical step. It was thus important to add a small amount of water to the solvent system and to process the drying step at a high temperature to produce formulations containing solely the active drug and showing a FPF of up to 50%.<p><p>Moreover, stability studies demonstrated that these optimized formulations (lipid-coated formulation, nanoparticle formulation and amorphous drug-coated formulation) were stable over a long time period at various ICH temperature and relative humidity storage conditions (25°C/60% RH, 30°C/65% RH and 40°C/75% RH). The formulations were shown to keep their crystalline state, initial PSD, redispersion characteristics and deposition results for more than twelve months.<p><p>In order to confirm these encouraging results, two optimized formulations (one with a lipid coating and another with amorphous drug coating) were selected and compared to the only commercially available tobramycin formulation for inhalation, Tobi® (nebulizer solution), by performing a combined in vivo scintigraphic and pharmacokinetic evaluation of tobramycin DPIs in nine CF patients.<p>In comparison with Tobi®, it was estimated that lung deposition, expressed as a percentage of the nominal dose, was 7.0 and 4.5 times higher for the lipid-coated and amorphous tobramycin-coated formulations, respectively. Moreover, the pharmacokinetic data, adjusted to the same drug dose as that of the Tobi® deposited in the lungs, showed that the AUC values were found to be 1.6 times higher for Tobi® than for DPI formulations. So this evaluation confirmed the superiority of dry powder formulations in terms of drug deposition and reduced systemic exposure in comparison with the conventional comparator product, Tobi®.<p><p>Thus, these new and orginal tobramycin DPI formulations based on the use of very low excipient levels and presenting very high lung deposition properties, were shown to offer very good prospects for improving the delivery of drugs to the pulmonary tract and to the widest possible patient population. <p><p> / Doctorat en Sciences biomédicales et pharmaceutiques / info:eu-repo/semantics/nonPublished

Sciences pharmaceutiques

Powders (Pharmacy)

Respiratory therapy

Tobramycin

Cystic fibrosis -- Chemotherapy

Pulmonary pharmacology

Poudres (Pharmacie)

Inhalothérapie

Tobramycine

Mucoviscidose -- Chimiothérapie

Pharmacologie pulmonaire

lipides

nanoparticules

mucoviscidose

atomisation

poudre sèche pour inhalation

administration pulmonaire

nanoparticles/antibiotique

spray drying

lipids

cystic fibrosis

pulmonary delivery

dpi

antibiotic