Carriers in drug powder delivery

The performance of dry powder inhaler (DPI) systems depends on the design of the powder formulation, the dose-metering system, and the device used to disperse the powder as an aerosol. Multiple factors associated with drug and carrier particles are known to influence dry powder performance. Elucidation of a mechanistic understanding of particulate system properties and how these relate to powder performance and the disruption of inter-particulate forces that cause aggregation has not yet been achieved. However, the complexity of interactions within dry powder formulations has not restricted research in this area. Various strategies of overcoming inter-particulate forces have been devised, ranging from active inhaler designs to powder engineering approaches. The influence of the interactive carrier system’s physicochemical properties (i.e. size, shape, chemical properties, surface roughness, electrostatics, humidity, and ternary excipients) on the performance of carrier-based systems has been examined extensively in the literature. In addition, matrix carriers, which contain drug and functional excipients for promotion of powder performance, control of pharmacokinetics, stability, controlled release of active drug and enhanced control of drug targeting, have also been investigated. Both the interactive carrier and matrix carrier approaches are attempts to develop DPI systems that perform as device-independent formulations and/or provide patient-independent delivery (controlled carrier systems). It seems likely that the future of DPI systems will combine both of these strategies with future developments in device design (formulation independency).     

Understanding the effect of lactose particle size on the properties of DPI formulations using experimental design

Medicines for delivering therapeutic agents to the lung as dry powders primarily consist of a carrier and a micronised active pharmaceutical ingredient (API). The performance of an inhaled formulation will depend on a number of factors amongst which the particle size distribution (PSD) plays a key role. It is suggested that increasing the number of fine particles in the carrier can improve the aerosolisation of the API. In addition the effect of PSD upon a bulk powder is also broadly understood in terms of powder flow. Other aspects of functionality that different size fractions of the carrier affect are not clearly understood; for example, it is not yet clearly known how different size fractions contribute to the different functionalities of the carrier. It is the purpose of this investigation to examine the effects of different lactose size fractions on fine particle dose, formulation stability and the ability to process and fill the material in the preferred device. In order to understand the true impact of the size fractions of lactose on the performance of dry powder inhaled (DPI) products, a statistically designed study has been conducted. The study comprised various DPI blend formulations prepared using lactose monohydrate carrier systems consisting of mixtures of four size fractions. Interactive mixtures were prepared containing 1% (w/w) salbutamol sulphate. The experimental design enabled the evaluation of the effect of lactose size fractions on processing and performance attributes of the formulation. Furthermore, the results of the study demonstrate that an experimental design approach can be used successfully to support dry powder formulation development.     

Lactose characteristics and the generation of the aerosol

The delivery efficiency of dry-powder products for inhalation is dependent upon the drug formulation, the inhaler device, and the inhalation technique. Dry powder formulations are generally produced by mixing the micronised drug particles with larger carrier particles. These carrier particles are commonly lactose. The aerosol performance of a powder is highly dependent on the lactose characteristics, such as particle size distribution and shape and surface properties. Because lactose is the main component in these formulations, its selection is a crucial determinant of drug deposition into the lung, as interparticle forces may be affected by the carrier-particle properties. Therefore, the purpose of this article is to review the various grades of lactose, their production, and the methods of their characterisation. The origin of their adhesive and cohesive forces and their influence on aerosol generation are described, and the impact of the physicochemical properties of lactose on carrier-drug dispersion is discussed in detail.     

影响干粉吸入剂雾化和沉积性能的制剂因素

干粉吸入剂是近年来肺部给药制剂研发的热点。随着微粉化技术不断成熟,新型给药装置日益涌现,干粉吸入剂的应用范围越来越广。本文从微粉化的药物、载体和干粉吸入器等3个方面综述了干粉吸入剂的处方组成,并重点介绍了影响药物粉末雾化和沉积性能的几个关键因素。     

Novel alternative methods for the delivery of drugs for the treatment of asthma

Successful delivery of dry powder aerosols to the lung requires careful consideration of the powder production process, formulation and inhaler device. Newer production methods are emerging to prepare powders with desirable characteristics for inhalational administration. The conventional formulation approach of adding coarse lactose carriers to the drug to form binary powder systems to enhance powder flow and dispersion properties has been expanded to using finer carrier particles and hydrophobic materials, as well as ternary systems. Particle morphology and surface properties have also been explored to enhance powder performance. For the inhaler device, the new generation inhalers are designed to reduce or completely decouple the influence of air flow on the aerosol generation. Each of these determinants for powder aerosol delivery is reviewed with a strong focus on the patent literature that contains enormous information about the latest development in this field.     

Improved aerosolization performance of salbutamol sulfate formulated with lactose crystallized from binary mixtures of ethanol-acetone

It has been shown that dry powder inhaler (DPI) formulations typically achieve low fine particle fractions (poor performance). A commonly held theory is that this is due, at least in part, to low levels of detachment of drug from lactose during aerosolization as a result of strong adhesion of drug particles to the carrier surfaces. Therefore, the purpose of the present study is to overcome poor aerosolization performance of DPI formulation by modification of lactose particles. Lactose particles were crystallized by adding solution in water to different ratios of binary mixtures of ethanol-acetone. The results showed that modified lactose particles had exceptional aerosolization performance that makes them superior to commercial lactose particles. Morphology assessment showed that crystallized lactose particles were less elongated, more irregular in shape, and composed of smaller primary lactose particles compared with commercial lactose. Solid-state characterization showed that commercial lactose particles were α-lactose monohydrate, whereas crystallized lactose particles were a mixture of α-lactose monohydrate and β-lactose according to the ratio of ethanol-acetone used during crystallization process. The enhanced performance could be mainly due to rougher surface and/or higher amounts of fines compared with the lactose crystallized from pure ethanol or commercial lactose.     

Engineered Mannitol Ternary Additives Improve Dispersion of Lactose–Salbutamol Sulphate Dry Powder Inhalations

The aim of this study was to evaluate the influence of novel engineered fine mannitol particles (4.7%, w/w) on the performance of lactose–salbutamol sulphate dry powder inhaler (DPI) formulations to obtain promising aerosolisation properties. The results showed that the more elongated the fine mannitol particles, the weaker the drug–carrier adhesion, the better the drug content homogeneity, the higher the amount of drug expected to be delivered to the lower airways and the higher the total DPI formulation desirability. Linear relationships were established showing that mannitol particles with a more elongated shape generated powders with broader size distributions and that were less uniform in shape. The weaker the drug–carrier adhesion, the higher the fine particle fraction of the drug is upon aerosolisation. It is believed that more elongated fine mannitol particles reduce the number of drug–carrier and drug–drug physical contact points and increase the ability of the drug particles to travel into the lower airways. Additionally, a lower drug–carrier contact area, lower drug–carrier press-on forces and easier drug–carrier detachment are suggested in the case of formulations containing more elongated fine mannitol particles. Ternary ‘drug-coarse carrier-elongated fine ternary component’ DPI formulations were more favourable than both ‘drug-coarse carrier’ and ‘drug-elongated coarse carrier’ binary formulations. This study provides a comprehensive approach for formulators to overcome the undesirable properties of dry powder inhalers, as both improved aerosolisation performance and reasonable flow characteristics were obtained using only a small amount of elongated engineered fine mannitol particles.     

Effect of milling and sieving on functionality of dry powder inhalation products

Alpha-lactose monohydrate is the standard excipient used as diluent or carrier in dry powder inhaler (DPI) formulations. Earlier studies have already revealed that raw materials for the production of inhalation grade lactose have to be carefully selected in order to avoid batch-to-batch variability. In the present study, the effect of milling and milling intensity on the flow properties and the physico-chemical characteristics of lactose crystals has been determined. The milled lactoses were then further processed by sieving to give lactose qualities with identical size distribution data, but different batch history (non-milled and milled at different conditions). These were then used to manufacture low concentration (0.25%) drug blends with the model drugs salbutamol sulphate (SBS) and beclometasonedipropionate (BDP); the blends were analysed with a Multistage Liquid Impinger (MLI) after delivery from an Easyhaler and an Aerolizer device. It could be shown that gentle milling already results in surface defects on the lactose crystal which are further enhanced by using a higher milling intensity. Produced fine lactose particles during the milling process strongly adhere to the lactose surface and cannot be removed by compressed air which is used for the particle sizing. By trend, a higher milling intensity resulted in higher fine particle fractions (FPF) with both devices. Also, SBS was found to generally give higher fine particle fractions than BDP, independent from the device used. In conclusion, lactose pre-treatment by gentle or strong milling affects the carrier surface and thereby the aerosolization properties of drug/lactose blends produced.     

Applicability of DPI formulations for novel neurokinin receptor antagonist

A novel triple neurokinin receptor antagonist (TNRA) could have pharmaceutical efficacy for asthma and/or chronic obstructive pulmonary disease. TNRA is potentially developed as inhalation medicine. The aim of this investigation was to evaluate the applicability of dry powder inhaler (DPI) formulation for TNRA. DPI formulation containing lactose was used for this feasibility study. Mechanofusion process for surface modification was applied on lactose particles to prepare four different DPI formulations. The mixture of TNRA and lactose was administered to rats intratracheally using an insufflator. The deposition pattern and blood concentration profile of TNRA were evaluated. Although there was no significant difference in deposition on deep lungs between the four formulations, DPI formulations containing mechanofusion-processed lactose showed longer T(max) and t(1/2) and higher AUC(0-infinity) and MRT compared to that containing intact lactose. On the other hand, the contact angle measurement showed that the mechanofusion process decreased the polar part of the surface energy of the lactose. Therefore, the prolongation of the wetting of the formulated powder mixture seemed to delay the dissolution of TNRA deposited in respiratory tract. It was concluded that DPI formulation containing mechanofusion-processed lactose could be suitable for inhalation of TNRA.     

Predicting the behavior of novel sugar carriers for dry powder inhaler formulations via the use of a cohesive-adhesive force balance approach

The aim of this work was to utilize the recently developed cohesive-adhesive balance (CAB) technique for analyzing quantitative AFM measurements to compare the relative forces of interaction of micronized salbutamol sulfate particles and a selection of specifically grown sugar substrates (beta cyclodextrin, lactose, raffinose, trehalose and xylitol). The interfacial behavior was subsequently related to the in-vitro delivery performance of these sugars as carrier particles in dry powder inhalation (DPI) formulations. The CAB analysis indicated that the rank order of adhesion between salbutamol sulfate and the sugars was beta cyclodextrin < lactose < trehalose < raffinose < xylitol. The beta cyclodextrin was the only substrate with which salbutamol sulfate demonstrated a greater cohesive behavior. All other sugars exhibited an adhesive dominance. In-vitro deposition performance of the salbutamol sulfate based carrier DPI formulations showed that the rank order of the fine particle fraction (FPF) was beta cyclodextrin > lactose > raffinose > trehalose > xylitol. A linear correlation (R(2) = 0.9572) was observed between the FPF and cohesive-adhesive ratios of the AFM force measurements. The observed link between CAB analysis of the interactive forces and in-vitro performance of carrier based formulations suggested a fundamental understanding of the relative balance of the various forces of interaction within a dry powder formulation may provide a critical insight into the behavior of these formulations.     

Formulation of novel dry powder inhalation for fluticasone propionate and salmeterol xinafoate with capsule-based device

The aim of this study was to develop a novel fluticasone propionate (FP) and salmeterol xinafoate (SX)-loaded dry powder inhaler (DPI) system, which was composed of powder formulation and performance. The air flow resistances were determined with various types of DPI device, showing that the modified RS01 device gave the specific resistance similar to the commercial DPI device. The particle properties of FP, SX, and inhalation grade lactose particles, such as particle size, size distribution, and fine content, were assessed. Subsequently, the aerodynamic behaviors of the DPI powder formulations were evaluated by the in vitro deposition of drugs in the DPI products using Andersen cascade impactor. Amongst the DPI powder formulations tested, the formulation composed of FP, SX, Respitose^® SV003, Respitose^® SV010, and Respitose^® ML006 at the weight ratio of 0.5/0.145/19/19/2 gave depositions, emitted dose, fine particle dose, fine particle fraction, and mass median aerodynamic diameter of drugs similar to the commercial product, suggesting that they had similar aerodynamic behaviors. Furthermore, it gave excellent content uniformity. Thus, this DPI using the modified RS01 device would be recommended as a candidate for FP and SX-loaded pharmaceutical DPI products.     

乳糖在干粉吸入剂中的应用

目的综述了乳糖在干粉吸入剂(dry powder inhalers,DPI)中的应用,为DPI的研究和开发提供思路。方法查阅国内外相关文献,综述了载体乳糖(coarse carrier)的不同性质及加入微粉化乳糖(fine particles)对DPI肺部沉积的影响。结果 DPI中的药物经微粉化后,其雾化性能下降。乳糖应用于DPI中的研究分析表明,乳糖可以有效改善DPI中药物的雾化性能,从而提高药物在肺部的沉积效率,发挥最佳药效。结论加入不同性质的载体乳糖和微粉化乳糖可以有效改善药物在肺部的沉积效率。     

Effect of separation characteristics between salbutamol sulfate (SS) particles and model carrier excipients on dry powder for inhalation]

Most often dry powder for inhalation are formulated as ordered mixtures of a carrier excipient and a micronized drug substance. In the present study, model powder blends were prepared from a mixture of lactose alpha-monohydrate, micro-crystalline cellulose pellets or synthesized sugar as carrier particles, and micronized salbutamol sulfate (SS). These ordered mixtures were aerosolized by the multidose JAGO dry powder inhaler (DPI) and their in vitro deposition properties were evaluated by a twin impinger (TI). The separation force between SS particles and carrier particles was investigated by the centrifuge method. In addition, the use of the air jet sieve (AJS) method was investigated to assess the separation behavior of drug particles from carrier excipient. Powder blends were sieved through a 325 mesh wire screen of an air jet sieve at an air pressure of 1500 Pa. The amount of drug deposited at the carrier surface was analysed before and after the sieving to calculate the percentage of the drug retained. A relationship was found between in vitro deposition properties (fine particle fraction, FPF) and the separation characteristics obtained by the centrifuge method and by the AJS method. The AJS method might be a suitable alternative for evaluating separation of a drug particle from carrier particles and hence can be used for the formulation screening of the dry powder inhalation.     

Physical characterization of component particles included in dry powder inhalers. II. Dynamic characteristics

Characteristics of particles included in dry powder inhalers is extended from our previous report (in this journal) to include properties related to their dynamic performance. The performance of dry powder aerosols for pulmonary delivery is known to depend on fluidization and dispersion which reflects particle interactions in static powder beds. Since the solid state, surface/interfacial chemistry and static bulk properties were assessed previously, it remains to describe dynamic performance with a view to interpreting the integrated database. These studies result in complex data matrices from which correlations between specific properties and performance may be deduced. Lactose particles were characterized in terms of their dynamic flow, powder and aerosol electrostatics, and aerodynamic performance with respect to albuterol aerosol dispersion. There were clear correlations between flow properties and aerosol dispersion that would allow selection of lactose particles for formulation. Moreover, these properties can be related to data reported earlier on the morphological and surface properties of the carrier lactose particles. The proposed series of analytical approaches to the evaluation of powders for inclusion in aerosol products has merit and may be the basis for screening and ultimately predicting particle performance with a view to formulation optimization.     

扫描电子显微镜-能谱仪在吸入式干粉制剂表征中的应用进展

目的 综述扫描电子显微镜-能谱仪在吸入式干粉制剂表征中的重要应用。方法 通过文献调研与归纳,扫描电子显微镜-能谱仪法表征吸入式干粉制剂,自动颗粒粒形粒径分析软件统计分析载体颗粒,对扫描电子显微镜在吸入式干粉制剂的研发过程中的4个广泛应用场景进行论证和总结。结果 吸入式干粉制剂学是高度依赖颗粒工程学的制剂类型,其性能和治疗功效很大程度上取决于原料药与辅料的微观特性。载体颗粒的尺寸、形状对高效肺部输送起决定性作用。而载体颗粒的表面粗糙度直接影响原料药与载体颗粒之间的黏附-脱附平衡,最终直接影响制剂雾化性能。扫描电子显微镜可以很直观地对颗粒的粒径、粒形以及表面粗糙情况进行快速评估。此外,也可通过扫描电子显微镜图像结合能谱分析判断原料药在载体颗粒上的负载情况,还可用来直接评估原料药颗粒的脱附能力。结论 扫描电子显微镜-能谱仪在吸入式干粉制剂的研发中具有广泛的应用意义,为该类型制剂的研发提供了先进的表征工具。     

Influence of the lactose grade within dry powder formulations of fluticasone propionate and terbutaline sulphate

Dry powder formulations are often composed of fine drug particles and coarser carrier particles, typically alpha-lactose monohydrate. However, the performance of a powder formulation may be highly dependent on the lactose quality and source. This study investigated the characteristics of lactose that influence the drug-to-carrier interaction and the performance of lactose-based dry powder inhaler formulations. The selected lactoses differed in the preparation processes and the content of fine lactose particles. Efficiency testing was done using fluticasone propionate and terbutaline sulphate as model drugs. Inverse gas chromatography was used to determine the surface heterogeneity distribution of different energy sites of the lactose and to understand the mechanism by which the fine carrier particles can improve the performance of dry powder inhalers. To assess the adhesion of respirable-sized drug to carrier particles, a simple method was developed based on aspiration and considering the whole blend as it is used in dry powder inhalers. When the percentage of fine lactose is high, a lower quantity of drug adheres to the lactose and/or the adhesion force is also lower. This was confirmed by the aerosolization assays done in the TSI (twin stage impinger). A correlation was observed between adhesion characteristics and inertial impaction. For both drugs, the fine particle fractions were highest in blends that present a greater proportion of lactose fine particles. A fairly good correlation between the fine particle fractions of both drugs and the peak max value and the AUC (area under curve) were found by inverse gas chromatography. With higher fine particle fraction values, which correspond to higher content of fines, the peak maxima determined by inverse gas chromatography were shifted to higher adsorption potentials, which supports the agglomeration hypothesis.     

The Role of Fines in the Modification of the Fluidization and Dispersion Mechanism Within Dry Powder Inhaler Formulations

PURPOSE: To investigate the role of in situ generated fine excipient particles on the fluidization and aerosolization properties of dry powder inhaler (DPI) formulations. MATERIALS AND METHODS: Carrier based DPI formulations were prepared under low and high shear blending. Powder rheometery was utilized to measure bulk powder properties in a consolidated and aerated state. Powder fluidization and aerosolization characteristics were related to bulk powder properties using high speed imaging and inertial impaction measurements. RESULTS: High shear blending of formulations resulted in the in situ generation of excipient fines, which corresponded to an increase in aerosolization efficiency. The generation of fines were shown to increase the tensile strength and free volume of the carrier, which resulted in a characteristic change in the fluidization properties, as observed by high speed imaging. The increase in minimum fluidization velocity and aerodynamic drag forces required to aerate the powder may provide the source of energy for the increase in fine particle re-suspension. CONCLUSIONS: The in situ generation of excipient fines affect bulk powder properties of DPI formulations, which directly affects fluidization and aerosolization behaviour of DPI formulations. The study suggests an alternative mode of action by which fines increase DPI formulation performance.     

Adhesion forces in interactive mixtures for dry powder inhalers--evaluation of a new measuring method.

Dry powder inhalers mostly contain carrier based formulations where micronized drug particles are adhered to coarse carrier particles. The performance of the dry powder inhaler depends on the inhaler device, the inhalation manoeuvre and the formulation. The most important factor influencing the behaviour of the formulation is the adhesion force acting between the active ingredient and the carrier particles, which can be measured using different methods, for example the centrifuge technique or atomic force microscopy. In this study the tensile strength method, usually applied to determine cohesion forces between powder particles of one material, is optimized for adhesion force measurements between powder particles of unlike materials. Adhesion force measurements between the carrier materials lactose or mannitol and the drug substance salbutamol sulphate using the tensile strength method and the atomic force microscopy show higher values with increasing relative humidity. Consequently, the fine particle fraction determined using the Next Generation Impactor decreases with increasing relative humidity as a result of the enhanced interparticle interactions.     

Dry powder inhaler formulation of lipid-polymer hybrid nanoparticles via electrostatically-driven nanoparticle assembly onto microscale carrier particles

Lipid-polymer hybrid nanoparticles have emerged as promising nanoscale carriers of therapeutics as they combine the attractive characteristics of liposomes and polymers. Herein we develop dry powder inhaler (DPI) formulation of hybrid nanoparticles composed of poly(lactic-co-glycolic acid) and soybean lecithin as the polymer and lipid constituents, respectively. The hybrid nanoparticles are transformed into inhalable microscale nanocomposite structures by a novel technique based on electrostatically-driven adsorption of nanoparticles onto polysaccharide carrier particles, which eliminates the drawbacks of conventional techniques based on controlled drying (e.g. nanoparticle-specific formulation, low yield). First, we engineer polysaccharide carrier particles made up of chitosan cross-linked with tripolyphosphate and dextran sulphate to exhibit the desired aerosolization characteristics and physical robustness. Second, we investigate the effects of nanoparticle to carrier mass ratio and salt inclusion on the adsorption efficiency, in terms of the nanoparticle loading and yield, from which the optimal formulation is determined. Desorption of the nanoparticles from the carrier particles in phosphate buffer saline is also examined. Lastly, we characterize aerosolization efficiency of the nanocomposite product in vitro, where the emitted dose and respirable fraction are found to be comparable to the values of conventional DPI formulations.     

干粉吸入剂的研究进展

干粉吸入剂（DPI）具有独特的吸收方式和药动学特点,与定量气雾剂相比优点突出。粉体工学性质和给药装置设计一直是制约该剂型发展的重要因素。近十几年来随着药物微粉化技术和新型给药装置研究的不断进步,其应用范围越来越广,在国际药物制剂研发方面呈快速发展趋势。现参考国内外研究文献,对DPI给药方式的药物作用特点、DPI药物及载体粉末性质以及目前吸入装置的种类及主要特点等进行综述。