Effect of carrier shape and texture on drug availability of aerosolised particles

Robertson, Debra Louise Norton

January 1997

No description available.

615.1

Dry powder; Inhaler formulations

Computational modelling and optimization of dry powder inhalers

Kopsch, Thomas

January 2018

Dry powder inhalers (DPIs) are a common therapeutic modality for lung diseases such as asthma, but they are also used to treat systemic diseases such as diabetes. Advantages of DPIs include their portable design and low manufacturing costs. Another advantage of DPIs is their breath activation, which makes them popular among patients. In a passive DPI drug is only released when the patient inhales. When the patient inhales, air flows through the device. The flow of air entrains a dry powder formulation inside the device and carries it to the lung. Currently, no DPI exists which can deliver drug independent of the patient to the desired target site in the lung. This is because drug release depends on the patient’s inhalation manoeuvre. To maximize the effect of the treatment it is necessary to optimize DPIs to achieve drug delivery that (A) is independent of the inhalation manoeuvre and (B) is targeted to the correct site in the lung. Therefore, this thesis aims to apply numerical and experimental methods to optimize DPIs systematically. First, two clinically justifiable cost functions have been developed corresponding to the DPI design objectives (A) and (B). An Eulerian-Eulerian (EE) computational fluid dynamics (CFD) approach has then been used to optimize a DPI entrainment geometry. Three different optimized entrainment geometries have been found corresponding to three different therapeutic applications. Second, the CFD approach has been validated experimentally. This is the first experimental study to validate an EE CFD approach for DPI modelling. Third, a personalized medicine approach to DPI design has been proposed. The development of this approach makes it possible to achieve the design objectives for patients with highly different lung functions. Finally, an adaptive DPI with a variable bypass element has been developed. This DPI achieves design objectives (A) and (B) for patients with highly different lung functions with a single device. In contrast to the personalized medicine approach, there is no need to select the optimal amount of bypass, since the device adapts automatically.

The influence of crystallization on the mechanical and interfacial properties of active pharmaceutical ingredients

Kubavat, Harshal A.

January 2011

No description available.

615.1

Development of High Efficiency Dry Powder Inhalers for Use with Spray Dried Formulations

Farkas, Dale

01 January 2017

Dry powder inhalers (DPIs) are advantageous for delivering medication to the lungs for the treatment of respiratory diseases because of the stability of the powders, relative low cost, synchronization of inhalation and dose delivery, and many design options that can be used for optimization. However, currently marketed DPIs are very inefficient in delivering medications to the lungs. This study has developed multiple new high efficiency DPIs for use with spray dried excipient enhanced growth (EEG) powder formulations based on the following platforms: capsule-based for oral inhalation, high-dose for oral inhalation, inline with 3D rod array dispersion, and inline with capillary jet dispersion. The capsule-based DPIs for oral inhalation implemented a 3D rod array for aerosol dispersion with optimal designs producing mass median aerodynamic diameters (MMADs) in the range of 1.3-1.5 µm and emitted doses in the range of 79-81%. Keys to inhaler success were the orientation of the capsule and inclusion of the 3D rod array. For the high-dose oral inhaler, performance was similar to the optimized capsule-based devices, while aerosolizing a much larger mass of powder. Surprisingly, removal of the fluidized bed of spheres improved performance producing a simple high dose device containing only a single dose sphere. The inline device using the 3D rod array was effective in producing particles of approximately 1.5 µm, at flow rates consistent with high flow therapy using a 1 L ventilation bag as the delivery mechanism. Using a capillary jet as the dispersion mechanism, further advances were made to allow for both delivery using a low volume (LV) of air and delivery in low flow therapy. This easily adaptable platform was able to produce a high quality aerosol out of a nasal cannula with an ED greater than 60% and a size (~2 µm) that should produce minimal extrathoracic losses. In conclusion, this study demonstrates (i) the design and optimization of DPIs capable of delivering EEG aerosols to the lungs using oral inhalation, (ii) the ability to deliver EEG aerosols using N2L aerosol administration, and (iii) the design of a new flexible LV-DPI device that is easily adaptable to multiple patients and delivery platforms, which are greatly needed in clinical environments.

high efficiency dry powder inhaler

excipient enhanced growth

respiratory drug delivery

active dry powder inhaler

nose to lung aerosol delivery

pediatric aerosol delivery

Mechanical Engineering

Ex vivo and in vitro evaluation of the influence of the inhaler device and formulation on lung deposition of budesonide

Aloum, Fatima, Al Ayoub, Yuosef, Mohammad, Mohammad A., Obeed, Muthana, Paluch, Krzysztof J., Assi, Khaled H.

10 August 2020

Yes / Two different types of dry powder inhalers (Easyhaler® and RS01®) were used in this work to evaluate the ex vivo and in vitro performance of a budesonide inhaled formulation with recrystallised mannitol, commercial DPI-grade mannitol, or lactose. The aerodynamic performance of the budesonide formulation with recrystallised mannitol was superior when RS01® was used (FPF = 45.8%) compared to Easyhaler® (FPF = 14%). However, the aerodynamic profile was very poor in both devices when commercial mannitol was used. Interestingly, the aerosol performance of the marketed budesonide formulation significantly improved when RS01® was used compared to Easyhaler® (the original device for the formulation). Due to the significant increases in the surface energy of the commercial mannitol formulation, the aerodynamic performance of the formulation was very poor. This work demonstrates the impact of inhaler devices on the performance of inhaled formulations and considers the particle surface energy during formulation development.

Budesonide

DPI formulation

Lung deposition

Dry powder inhaler

Ex vivo

Surface energy

In-check DIAL

Rapid preformulation screening of drug candidates for dry powder inhaler preparation

Harris, Haggis

January 2008

Candidate active pharmaceutical ingredients (APIs) are routinely tested to determine such parameters as physical stability, chemical stability, and bioavailability. Preformulation analysis of APIs does not currently attemept to determine whether they will perform to an acceptable level once they have been formulated. In practice, the APIs are subjected to extensive in vitro testing of their performance in a formulation, combined with optimisation of the formulation. This formulation testing is both time-consuming and expensive. In the field of pulmonary drug delivery from dry powder inhalers (DPIs), the API has to be aerosolized effectively in order to penetrate the lunfs and reach its deposition target. In a conventional ternary DPI fromulation, the API is combined with carrier lactose and fine lactose particles. The inter-particle forces between these three components and the bulk properties of the formulation determine the structure of the formulation and the aerolization performance of the API. In this study, physicochemical properties of salbutamol base and several of its salts were investigated both quantitatively and qualitatively. The in vitro deposition characteristics of the formulated APIs were also determined. The relationship between these parameters and the deposition was analysed to establish if a rapid preformulation screening technique could be applied to the APIs with respect to predicting the deposition performance of the formulated API. A clear relationship between the deposition of the unformulated API and the formulated API was observed that could be exploited as a screening technique.

615.19

Dry Powders Inhalers (DPI) obtidos a partir de nanocápsulas de núcleo lipídico contendo budesonida : caracterização, avaliação in vivo em modelo animal de asma e da toxicidade in vitro em cultura celular

Ortiz, Manoel

January 2016

A asma é definida como uma doença inflamatória crônica de caráter multifatorial, caracterizada pela obstrução reversível das vias aéreas, denso infiltrado inflamatório e hiper-reatividade brônquica a estímulos externos. Clinicamente, a doença é marcada por sintomas episódicos de dispneia, sibilo, tosse seca e sensação de aperto no peito. A terapia convencional da asma compreende o uso de anti-inflamatórios e broncodilatadores. A budesonida é um glicocorticoide esteroide e é dos fármacos mais utilizados na terapêutica da asma. No entanto, a budesonida apresenta baixa biodisponibilidade oral e o uso prolongado pode levar a efeitos adversos graves como afinamento da pele e supressão adrenocortical. No desenvolvimento de novas formulações, a avaliação da toxicidade é de extrema importância. Por conseguinte, o uso de cultura celular é de grande valia no desenvolvimento de protocolos para avaliação da toxicidade de novas formulações. Adicionalmente, a nanotecnologia é uma ferramenta importante para resolver problemas de biodisponibilidade e para contornar efeitos adversos da terapêutica convencional. Desta forma, o objetivo desta tese foi desenvolver um novo sistema nanoestruturado na forma de pó seco para inalação (Dry powders inhalers – DPI), obtido por aspersão contendo budesonida encapsulada, visando o tratamento da asma aguda e crônica. Essa proposta foi baseada na obtenção de um sistema pulverulento nanoestruturado com tamanho reduzido e controlado, visando a entrega pulmonar da budesonida. Na etapa de pré-formulação foi realizado um estudo fatorial avaliando diferentes métodos de preparação das nanocápsulas e os adjuvantes de secagem utilizados. As análises de tamanho de partícula, da formulação selecionada (nanocápsulas contendo budesonida e secas por aspersão com leucina) mostraram um tamanho reduzido e adequado para a administração pulmonar (2,7 μm). A morfologia demonstrou que estas partículas possuem um tamanho reduzido, forma esférica e superfície irregular, características importantes para a administração pulmonar. Quando analisada a distribuição pulmonar in vitro, em Impactador de Andersen, a formulação apresentou uma fração de partículas finas (Fine Particle Fraction – FPF) de 28%. Analisando os resultados dos experimentos em modelos de asma aguda e crônica induzidos por ovalbumina, os resultados da mecânica respiratória e função pulmonar mostraram uma diminuição na resistência e na elastância pulmonar, quando a budesonida nanoencapsulada foi utilizada, quando comparada com uma formulação comercial de budesonida, nas duas doses utilizadas (0,5 e 1,0 mg/Kg). Esse tratamento com nanocápsulas também mostrou eficiência na redução da inflamação, pela redução do número de leucócitos totais no fluido de lavagem bronco alveolar (Broncho Alveolar Lavage Fluid – BALF) e, principalmente, redução significativa no número dos eosinófilos no infiltrado pulmonar. Corroborando esses resultados, a quantificação da eotaxina – 1 e das citocinas pró-inflamatórias foram reduzidas, quando comparadas ao tratamento comercial. A análise histopatológica mostrou que quando o tratamento com as nanocápsulas foi utilizado, a produção de muco foi reduzida, bem como a produção de fibrose sub-epitelial, sugerindo um possível efeito sobre o remodelamento tecidual. Os resultados de toxicidade utilizando linhagem celular epitelial pulmonar (H441) mostrou uma redução na toxicidade da budesonida, quando encapsulada nas nanopartículas, tanto na forma de suspensão como na forma pulverulenta. Essa redução da toxicidade foi de 75% e de 50%, na dose de 100 μg/mL, para a suspensão e para o DPI, respectivamente. O conjunto dos resultados obtidos mostrou a potencial aplicabilidade da budesonida nanoencapsulada para o tratamento da asma, utilizando esse novo sistema DPI. / Asthma is characterized as a chronic inflammatory disease developed by multifactorial aspects such as genetic predisposition and exposure to environmental factors such as pollution, smoke and microorganisms. The conventional asthma therapy comprises the use of bronchodilators and anti-inflammatory. Budesonide is a glucocorticoid and is the most frequently used therapy in the treatment of asthma. However, this drug has low oral bioavailability and long term use may lead to adverse effects such as skin thinning and adrenal suppression. The evaluation of the toxicity of new formulation has critical role in the pharmaceutical development. The use of cell culture experiments can help this aspect. Additionally, nanotechnology is an important tool to solve problems regarding bioavailability and to circumvent adverse effects of conventional therapy. The aim of this work was to develop a nanostructured system as dry powder inhaler (DPI) containing budesonide loaded, obtained by spray-drying, targeting the treatment of acute and chronic asthma. This proposal was based on obtaining a nanostructured powder system with reduced and controlled size, aiming an alternative to treatment of asthma. A factorial study comparing different methods to produce the nanocapsules as well as the type of drying adjuvants was performed. The particle size of the selected formulation was 2.7 μm, an adequate reduced size suitable for pulmonary administration. The morphology of these particles showed a small size, spherical shape and irregular surface. All these characteristics are important for pulmonary administration. When analyzed the in vitro pulmonary distribution of the DPI, using an Andersen Cascade Impactor, showed a fine particle fraction (FPF) of 28%. Analyzing the results of the biological experiments, the mechanical respiratory and pulmonary function showed a decrease in lung elastance and resistance when budesonide was used nanoencapsulated compared with a commercial formulation of budesonide in two doses (0.5 and 1.0 mg / kg). Both treatments also showed nanocapsules efficiency in reduction of inflammation by reducing the total of leukocytes in the bronchial alveolar lavage fluid (BALF) and especially significant reduction in eosinophil infiltration in the lung tissue. Corroborating with these results, the quantification of eotaxin - 1 and proinflammatory cytokines was reduced when compared to commercial budesonide treatment. Histopathological analysis showed that when treatment with the nanocapsules was used, mucus production was reduced and reversed the phenomena of airway remodeling. The cytotoxicity assay by Alamar blue using the bronchial epithelium cell line (H441) showed a reduction on the toxicity of budesonide when the nanocapsules were used even in suspension or in the DPI. The cytotoxicity reduction were 75 and 50%, at 100 μg/mL, for the suspension and the DPI, respectively. All these results show that budesonide-loaded nanocapsules in dry powder inhaler is a promising approach for the treatment of asthma.

Budesonida

Nanocapsulas

Asma

Asthma

Budesonide

Dry powder inhaler (DPI)

Nanocapsules

Cell culture

H441

Dry powder antibiotics for inhaled anti-tuberculosis therapy

Son, Yoen Ju

09 February 2011

The aim of this research was to develop and fully investigate a novel method of antibiotic drug delivery to the lung that will address problems with current therapeutic regimens for treatment of airway infections. To demonstrate the performance of prepared formulations, the design of suitable characterization methods were also aimed. A novel dissolution method for evaluating the in vitro dissolution behavior of inhalation formulations was developed. The membrane holder was designed to enclose previously air-classified formulations so that they could be uniformly tested in the dissolution apparatus. Dissolution procedures, the apparatus, the dose collection, the medium, and test conditions were developed and the dissolution behaviors of test compounds were evaluated by experimental and mathematical analysis. It was proved that the aerodynamic separation of formulation prior to dissolution assessment have a significant influence on the dissolution profiles. The optimized test method using the membrane holder was applied to evaluate in vitro dissolution profiles of the manufactured formulations of rifampicin (RF). The carrier/excipient-free RF dry powder formulation was investigated. The rifampicin dihydrate (RFDH) powders having MMAD of 2.2 um were prepared using a simple recrystallization process. The RFDH powders have a thin flaky structure, and this unique morphology provides improved aerosolization properties at maximal API loading. The manufactured RFDH formulation showed 80% drug release within 2 hours. To retard the release rate of RF, the prepared RFDH crystals were coated with hydrophobic polymer, PLA or PLGA, using spray-dryer equipped with multi-channel spray nozzles. The multi-channel spray nozzle used in this study has two separate nozzles for aqueous solution and one for gas fluid. The RFDH crystals and the coating solutions were sprayed through the two separate liquid nozzles at the same time. The coated RFDH formulations were prepared using multi-channel spray nozzles. The coated formulations contained at least 50% w/w of RF with no change of their flaky morphology. The initial RF release was lowered by coating; the lowest initial RF release was observed from the coated powders with PLA polymer as 32% among the coated formulations. Overall, the 80% of RF was released within 8 hours. The RFDH and coated RFDH formulations delivered via the pulmonary route would be anticipated to provide higher local (lung) drug concentrations than that of orally delivered powders. Particularly, the coated RFDH powders deposited in the alveolar region may prolong the drug residence time in the site of infections. Additionally, it was proved that the RFDH and coated RFDH formulations provided much better stability than the amorphous RF. / text

Pulmonary drug delivery

Anti-tuberculosis

Rifampicin

Dry powder inhaler

Pulmonary tuberculosis

Sustained release

Dissolution

Dry Powders Inhalers (DPI) obtidos a partir de nanocápsulas de núcleo lipídico contendo budesonida : caracterização, avaliação in vivo em modelo animal de asma e da toxicidade in vitro em cultura celular

Ortiz, Manoel

January 2016

A asma é definida como uma doença inflamatória crônica de caráter multifatorial, caracterizada pela obstrução reversível das vias aéreas, denso infiltrado inflamatório e hiper-reatividade brônquica a estímulos externos. Clinicamente, a doença é marcada por sintomas episódicos de dispneia, sibilo, tosse seca e sensação de aperto no peito. A terapia convencional da asma compreende o uso de anti-inflamatórios e broncodilatadores. A budesonida é um glicocorticoide esteroide e é dos fármacos mais utilizados na terapêutica da asma. No entanto, a budesonida apresenta baixa biodisponibilidade oral e o uso prolongado pode levar a efeitos adversos graves como afinamento da pele e supressão adrenocortical. No desenvolvimento de novas formulações, a avaliação da toxicidade é de extrema importância. Por conseguinte, o uso de cultura celular é de grande valia no desenvolvimento de protocolos para avaliação da toxicidade de novas formulações. Adicionalmente, a nanotecnologia é uma ferramenta importante para resolver problemas de biodisponibilidade e para contornar efeitos adversos da terapêutica convencional. Desta forma, o objetivo desta tese foi desenvolver um novo sistema nanoestruturado na forma de pó seco para inalação (Dry powders inhalers – DPI), obtido por aspersão contendo budesonida encapsulada, visando o tratamento da asma aguda e crônica. Essa proposta foi baseada na obtenção de um sistema pulverulento nanoestruturado com tamanho reduzido e controlado, visando a entrega pulmonar da budesonida. Na etapa de pré-formulação foi realizado um estudo fatorial avaliando diferentes métodos de preparação das nanocápsulas e os adjuvantes de secagem utilizados. As análises de tamanho de partícula, da formulação selecionada (nanocápsulas contendo budesonida e secas por aspersão com leucina) mostraram um tamanho reduzido e adequado para a administração pulmonar (2,7 μm). A morfologia demonstrou que estas partículas possuem um tamanho reduzido, forma esférica e superfície irregular, características importantes para a administração pulmonar. Quando analisada a distribuição pulmonar in vitro, em Impactador de Andersen, a formulação apresentou uma fração de partículas finas (Fine Particle Fraction – FPF) de 28%. Analisando os resultados dos experimentos em modelos de asma aguda e crônica induzidos por ovalbumina, os resultados da mecânica respiratória e função pulmonar mostraram uma diminuição na resistência e na elastância pulmonar, quando a budesonida nanoencapsulada foi utilizada, quando comparada com uma formulação comercial de budesonida, nas duas doses utilizadas (0,5 e 1,0 mg/Kg). Esse tratamento com nanocápsulas também mostrou eficiência na redução da inflamação, pela redução do número de leucócitos totais no fluido de lavagem bronco alveolar (Broncho Alveolar Lavage Fluid – BALF) e, principalmente, redução significativa no número dos eosinófilos no infiltrado pulmonar. Corroborando esses resultados, a quantificação da eotaxina – 1 e das citocinas pró-inflamatórias foram reduzidas, quando comparadas ao tratamento comercial. A análise histopatológica mostrou que quando o tratamento com as nanocápsulas foi utilizado, a produção de muco foi reduzida, bem como a produção de fibrose sub-epitelial, sugerindo um possível efeito sobre o remodelamento tecidual. Os resultados de toxicidade utilizando linhagem celular epitelial pulmonar (H441) mostrou uma redução na toxicidade da budesonida, quando encapsulada nas nanopartículas, tanto na forma de suspensão como na forma pulverulenta. Essa redução da toxicidade foi de 75% e de 50%, na dose de 100 μg/mL, para a suspensão e para o DPI, respectivamente. O conjunto dos resultados obtidos mostrou a potencial aplicabilidade da budesonida nanoencapsulada para o tratamento da asma, utilizando esse novo sistema DPI. / Asthma is characterized as a chronic inflammatory disease developed by multifactorial aspects such as genetic predisposition and exposure to environmental factors such as pollution, smoke and microorganisms. The conventional asthma therapy comprises the use of bronchodilators and anti-inflammatory. Budesonide is a glucocorticoid and is the most frequently used therapy in the treatment of asthma. However, this drug has low oral bioavailability and long term use may lead to adverse effects such as skin thinning and adrenal suppression. The evaluation of the toxicity of new formulation has critical role in the pharmaceutical development. The use of cell culture experiments can help this aspect. Additionally, nanotechnology is an important tool to solve problems regarding bioavailability and to circumvent adverse effects of conventional therapy. The aim of this work was to develop a nanostructured system as dry powder inhaler (DPI) containing budesonide loaded, obtained by spray-drying, targeting the treatment of acute and chronic asthma. This proposal was based on obtaining a nanostructured powder system with reduced and controlled size, aiming an alternative to treatment of asthma. A factorial study comparing different methods to produce the nanocapsules as well as the type of drying adjuvants was performed. The particle size of the selected formulation was 2.7 μm, an adequate reduced size suitable for pulmonary administration. The morphology of these particles showed a small size, spherical shape and irregular surface. All these characteristics are important for pulmonary administration. When analyzed the in vitro pulmonary distribution of the DPI, using an Andersen Cascade Impactor, showed a fine particle fraction (FPF) of 28%. Analyzing the results of the biological experiments, the mechanical respiratory and pulmonary function showed a decrease in lung elastance and resistance when budesonide was used nanoencapsulated compared with a commercial formulation of budesonide in two doses (0.5 and 1.0 mg / kg). Both treatments also showed nanocapsules efficiency in reduction of inflammation by reducing the total of leukocytes in the bronchial alveolar lavage fluid (BALF) and especially significant reduction in eosinophil infiltration in the lung tissue. Corroborating with these results, the quantification of eotaxin - 1 and proinflammatory cytokines was reduced when compared to commercial budesonide treatment. Histopathological analysis showed that when treatment with the nanocapsules was used, mucus production was reduced and reversed the phenomena of airway remodeling. The cytotoxicity assay by Alamar blue using the bronchial epithelium cell line (H441) showed a reduction on the toxicity of budesonide when the nanocapsules were used even in suspension or in the DPI. The cytotoxicity reduction were 75 and 50%, at 100 μg/mL, for the suspension and the DPI, respectively. All these results show that budesonide-loaded nanocapsules in dry powder inhaler is a promising approach for the treatment of asthma.

Budesonida

Nanocapsulas

Asma

Asthma

Budesonide

Dry powder inhaler (DPI)

Nanocapsules

Cell culture

H441

Dry Powders Inhalers (DPI) obtidos a partir de nanocápsulas de núcleo lipídico contendo budesonida : caracterização, avaliação in vivo em modelo animal de asma e da toxicidade in vitro em cultura celular

Ortiz, Manoel

January 2016

A asma é definida como uma doença inflamatória crônica de caráter multifatorial, caracterizada pela obstrução reversível das vias aéreas, denso infiltrado inflamatório e hiper-reatividade brônquica a estímulos externos. Clinicamente, a doença é marcada por sintomas episódicos de dispneia, sibilo, tosse seca e sensação de aperto no peito. A terapia convencional da asma compreende o uso de anti-inflamatórios e broncodilatadores. A budesonida é um glicocorticoide esteroide e é dos fármacos mais utilizados na terapêutica da asma. No entanto, a budesonida apresenta baixa biodisponibilidade oral e o uso prolongado pode levar a efeitos adversos graves como afinamento da pele e supressão adrenocortical. No desenvolvimento de novas formulações, a avaliação da toxicidade é de extrema importância. Por conseguinte, o uso de cultura celular é de grande valia no desenvolvimento de protocolos para avaliação da toxicidade de novas formulações. Adicionalmente, a nanotecnologia é uma ferramenta importante para resolver problemas de biodisponibilidade e para contornar efeitos adversos da terapêutica convencional. Desta forma, o objetivo desta tese foi desenvolver um novo sistema nanoestruturado na forma de pó seco para inalação (Dry powders inhalers – DPI), obtido por aspersão contendo budesonida encapsulada, visando o tratamento da asma aguda e crônica. Essa proposta foi baseada na obtenção de um sistema pulverulento nanoestruturado com tamanho reduzido e controlado, visando a entrega pulmonar da budesonida. Na etapa de pré-formulação foi realizado um estudo fatorial avaliando diferentes métodos de preparação das nanocápsulas e os adjuvantes de secagem utilizados. As análises de tamanho de partícula, da formulação selecionada (nanocápsulas contendo budesonida e secas por aspersão com leucina) mostraram um tamanho reduzido e adequado para a administração pulmonar (2,7 μm). A morfologia demonstrou que estas partículas possuem um tamanho reduzido, forma esférica e superfície irregular, características importantes para a administração pulmonar. Quando analisada a distribuição pulmonar in vitro, em Impactador de Andersen, a formulação apresentou uma fração de partículas finas (Fine Particle Fraction – FPF) de 28%. Analisando os resultados dos experimentos em modelos de asma aguda e crônica induzidos por ovalbumina, os resultados da mecânica respiratória e função pulmonar mostraram uma diminuição na resistência e na elastância pulmonar, quando a budesonida nanoencapsulada foi utilizada, quando comparada com uma formulação comercial de budesonida, nas duas doses utilizadas (0,5 e 1,0 mg/Kg). Esse tratamento com nanocápsulas também mostrou eficiência na redução da inflamação, pela redução do número de leucócitos totais no fluido de lavagem bronco alveolar (Broncho Alveolar Lavage Fluid – BALF) e, principalmente, redução significativa no número dos eosinófilos no infiltrado pulmonar. Corroborando esses resultados, a quantificação da eotaxina – 1 e das citocinas pró-inflamatórias foram reduzidas, quando comparadas ao tratamento comercial. A análise histopatológica mostrou que quando o tratamento com as nanocápsulas foi utilizado, a produção de muco foi reduzida, bem como a produção de fibrose sub-epitelial, sugerindo um possível efeito sobre o remodelamento tecidual. Os resultados de toxicidade utilizando linhagem celular epitelial pulmonar (H441) mostrou uma redução na toxicidade da budesonida, quando encapsulada nas nanopartículas, tanto na forma de suspensão como na forma pulverulenta. Essa redução da toxicidade foi de 75% e de 50%, na dose de 100 μg/mL, para a suspensão e para o DPI, respectivamente. O conjunto dos resultados obtidos mostrou a potencial aplicabilidade da budesonida nanoencapsulada para o tratamento da asma, utilizando esse novo sistema DPI. / Asthma is characterized as a chronic inflammatory disease developed by multifactorial aspects such as genetic predisposition and exposure to environmental factors such as pollution, smoke and microorganisms. The conventional asthma therapy comprises the use of bronchodilators and anti-inflammatory. Budesonide is a glucocorticoid and is the most frequently used therapy in the treatment of asthma. However, this drug has low oral bioavailability and long term use may lead to adverse effects such as skin thinning and adrenal suppression. The evaluation of the toxicity of new formulation has critical role in the pharmaceutical development. The use of cell culture experiments can help this aspect. Additionally, nanotechnology is an important tool to solve problems regarding bioavailability and to circumvent adverse effects of conventional therapy. The aim of this work was to develop a nanostructured system as dry powder inhaler (DPI) containing budesonide loaded, obtained by spray-drying, targeting the treatment of acute and chronic asthma. This proposal was based on obtaining a nanostructured powder system with reduced and controlled size, aiming an alternative to treatment of asthma. A factorial study comparing different methods to produce the nanocapsules as well as the type of drying adjuvants was performed. The particle size of the selected formulation was 2.7 μm, an adequate reduced size suitable for pulmonary administration. The morphology of these particles showed a small size, spherical shape and irregular surface. All these characteristics are important for pulmonary administration. When analyzed the in vitro pulmonary distribution of the DPI, using an Andersen Cascade Impactor, showed a fine particle fraction (FPF) of 28%. Analyzing the results of the biological experiments, the mechanical respiratory and pulmonary function showed a decrease in lung elastance and resistance when budesonide was used nanoencapsulated compared with a commercial formulation of budesonide in two doses (0.5 and 1.0 mg / kg). Both treatments also showed nanocapsules efficiency in reduction of inflammation by reducing the total of leukocytes in the bronchial alveolar lavage fluid (BALF) and especially significant reduction in eosinophil infiltration in the lung tissue. Corroborating with these results, the quantification of eotaxin - 1 and proinflammatory cytokines was reduced when compared to commercial budesonide treatment. Histopathological analysis showed that when treatment with the nanocapsules was used, mucus production was reduced and reversed the phenomena of airway remodeling. The cytotoxicity assay by Alamar blue using the bronchial epithelium cell line (H441) showed a reduction on the toxicity of budesonide when the nanocapsules were used even in suspension or in the DPI. The cytotoxicity reduction were 75 and 50%, at 100 μg/mL, for the suspension and the DPI, respectively. All these results show that budesonide-loaded nanocapsules in dry powder inhaler is a promising approach for the treatment of asthma.

Budesonida

Nanocapsulas

Asma

Asthma

Budesonide

Dry powder inhaler (DPI)

Nanocapsules

Cell culture

H441