Physical characteristics and aerosol performance of naringin dry powders for pulmonary delivery prepared by spray-drying

The aim of the present work was to develop dry powders containing naringin for a direct administration to the lung to combat oxidative stress. Naringin microparticles were prepared by spray-drying the neat flavonoid (2-5% w/v) from different water/ethanol co-solvents. The spray-dried powders were characterised for morphology, density, particle size distribution, residual humidity, crystallinity, solubility, thermal behaviour and respirable fraction.The fine fraction of the powders was measured by single-stage glass impinger and Andersen cascade impactor, using the Turbospin^® device for the deposition tests, wherein the dose to be aerosolised was premetered in a gelatine capsule.By increasing the ethanol content, the feed liquid turned from a suspension into a solution: the spray of flavonoid suspensions led to powders with high crystallinity degree, low water solubility and high bulk density, while the spray of drug solutions led to more amorphous particles, with higher solubility, lower density and improved aerodynamic behaviour.The optimisation of the operative parameters produced enhanced aerosol performance of the flavonoid powders containing only the active compound.     

Excipient-free nanoporous microparticles of budesonide for pulmonary delivery

The aim of this study was to investigate the application of a spray-drying process for the production of nanoporous microparticles (NPMPs) to budesonide, and to characterise the particles produced in terms of their suitability for pulmonary delivery.Budesonide was spray dried with and without ammonium carbonate from ethanol/water or methanol/water solutions. The solid-state characteristics and micromeritic (particle size, density, surface area) properties of spray dried powders were assessed. In vitro deposition studies were performed to assess aerosol performance.The densities of the NPMPs were significantly lower and the surface areas significantly higher than for non-porous spray dried or micronised material. NPMPs of budesonide demonstrated improved aerosolisation properties compared to spray dried non-porous, micronised material and two budesonide commercial products. All spray dried materials were amorphous in nature. The glass transition temperature (90 °C) was sufficiently high to suggest good physical stability at room temperature. When stored at 25 °C/60% RH NPMPs showed a reduced tendency to recrystallise compared to the equivalent non-porous spray dried powder. The physical stability and amorphous nature of NPMPs was retained, under these storage conditions for at least one year and the in vitro aerosolisation properties were not affected by the storage conditions.Excipient-free porous microparticles, prepared by the novel process described, show good potential for drug delivery by oral inhalation with improved in vitro deposition properties compared to non-porous particles.     

Lactose modifications enhance its drug performance in the novel multiple dose Taifun DPI

Drug–carrier particle interactions greatly affect the detachment of drug from the carrier in inhalation powders. In this study, a novel multiple dose, reservoir-based Taifun^® was used as a dry powder inhaler, and the effects of carrier physical properties were evaluated on the pulmonary deposition of budesonide, along with physical stability of the inhalation powder. In this study, untreated commercial preparation of -lactose monohydrate, highly amorphous spray dried lactose, crystallized spray dried lactose, Flowlac-100^® and Flowlac-100^® mixed with crystalline micronized lactose were used as carriers. Dry powder formulations were prepared by the suspension method, where the budesonide–carrier ratio was 1:15.1 (w/w). Carriers and formulations were initially characterized, and again after 1 month’s storage at 40 °C/75% RH. The physical properties of the carriers strongly affected the pulmonary deposition of budesonide and the physical stability of the inhalation powder. Initially, amorphous contents of the carriers were 0–64%, but spontaneous crystallisation of the amorphous lactose occurred during storage and, thus all carriers were 100% crystalline after storage. When compared to an untreated -lactose monohydrate, the highly amorphous spray dried lactose and Flowlac-100^® did not improve aerosol performance of the inhalation powder. When crystalline spray dried lactose was used as a carrier, the highest RF% values were achieved, and RF % values did not alter during storage but the emitted budesonide dose was lower than the theoretical dose. When Flowlac-100^® mixed with crystalline micronized lactose was used as a carrier, the emitted budesonide dose was close to the theoretical dose, and high RF % values were achieved but these changed during storage.     

The effect of vehicle on physical properties and aerosolisation behaviour of disodium cromoglycate microparticles spray dried alone or with L-leucine

The aim of this study was to improve the aerosolisation behaviour of disodium cromogycate (DSCG), using spray drying technique. The effect of vehicle on the drug particle properties was investigated. L-leucine was selected as a natural antiadherent amino acid to improve the deagglomeration of DSCG particles. Spray dried samples of DSCG alone or with L-leucine were prepared from water and ethanol under the same conditions. The powder properties of the samples were examined by laser diffraction, helium densitometer, X-ray diffraction, differential scanning calorimetry and thermogravimetric analysis. The in vitro deposition was determined, using an Andersen cascade impactor with a Spinhaler at a flow rate of 60 l/min. An amorphous form of the drug was obtained when water was used. However, crystal transformation of original DSCG in the presence of ethanol during spray drying resulted in production of elongated particles. These particles exhibited improved aerodynamic properties, compared to the amorphous and commercial materials. Significant differences in fine particle fraction were observed using the two vehicles. Co-spray drying of DSCG and L-leucine improved the deposition profiles of the drug. These results indicated that the change in crystal structure of DSCG during spray drying process was susceptible to the nature of the vehicle. A crystalline form of DSCG with good aerodynamic properties was achieved during spray drying process. In addition, the processing of DSCG with L-leucine in a single step using ethanol resulted in an improvement in dispersion properties of the drug particles.     

Characterization and aerodynamic evaluation of spray dried recombinant human growth hormone using protein stabilizing agents

The effect of the protein stabilizers on the stability and aerosol performance of spray dried recombinant human growth hormone (SD rhGH) was investigated. rhGH solution was spray dried alone, with polysorbate 20 (at three concentrations of 0.05%, 0.01%, and 0.005%), Zn(2+) (by Zn(2+):rhGH molar ratio of 2:1 and 4:1), and/or lactose (by lactose:rhGH weight ratio of 2:1). Size exclusion chromatography (SEC) analysis of spray dried powders demonstrated that of all the potential protein stabilizers, the combination of polysorbate 20 (0.05%), Zn(2+) (Zn(2+):rhGH molar ratio of 2:1) and lactose (lactose:rhGH weight ratio of 2:1) was the most effective at protecting rhGH against aggregation during spray drying. The results of circular dichroism (CD) analysis revealed that using of polysorbate 20 (in all concentrations) and Zn(2+) (by Zn(2+):rhGH molar ratio of 2:1) together in the formulations would preserve rhGH conformational stability during the process. The particle size distribution data obtained by laser diffraction method showed all SD rhGH formulations had volume median diameter and mean diameter below 5mum. The characterization of the aerosol performance of the spray dried powders by Andersen cascade impactor (ACI) showed that by increasing the concentration of polysorbate 20 in the formulations the aerodynamic efficiency of the resultant particles was reduced. In conclusion, the optimum amounts of polysorbate 20, Zn(2+) and lactose satisfied both physical stability during spray drying process (2.37% aggregation) and good aerosol performance (fine particle fraction; FPF=38.52%).     

Aerosolisation of beclomethasone dipropionate using spray dried lactose/polyethylene glycol carriers.

The aim of this study was to characterize the physical properties of spray dried lactose in the presence of different polyethylene glycols (PEG 400, PEG 3000 and PEG 6000) and to evaluate their performance as carriers for dry powder inhaler (DPI) formulations. The efficiency of spray dried lactose/PEG carriers in aerosolisation of beclomethasone dipropionate (BD), a model hydrophobic drug, was compared to Pharmatose 325 M (L325), spray dried lactose alone (SDL), and also a sieved (< 38 microm) fraction of alpha-lactose monohydrate (SL). In vitro deposition analysis was performed using a twin stage liquid impinger at a flow rate of 60 l/min through a Spinhaler. The deposition profiles of the drug from binary formulations composed of BD and spray dried lactose/PEG carriers were also compared to ternary formulations containing large and fine lactose carriers. Differential scanning calorimetry and X-ray diffraction data showed the presence of alpha-anhydrous lactose in spray dried lactose/PEG crystalline powders. Spray drying of lactose in the presence of PEG 400 resulted in the production of a powder (SDL-PEG400) with lower alpha-lactose monohydrate content, and also smaller particle size distribution than those obtained in the presence of PEG 3000 (SDL-PEG3000) or PEG 6000 (SDL-PEG6000). All formulations showed different deposition profiles, except those containing SDL-PEG3000 or SDL-PEG6000 which exhibited similar data. The fine particle fraction of aerosolised BD varied from 6.26 +/- 1.07 (for L325) to 25.87 +/- 5.33 (for SDL-PEG3000). All deposition profiles of BD aerosolised from SDL-PEG3000 were significantly higher (P < 0.01) than those produced by binary and ternary formulations containing L325, a coarse lactose commercially available for DPI formulations. The differences observed in deposition data for various carriers were interpreted according to their physical properties. It was concluded that particle size distribution, morphology and specific surface texture of SDL-PEG3000 and SDL-PEG6000 were important factors influencing their efficiency as small carriers for DPI formulations.     

Spray-dried carrier-free dry powder tobramycin formulations with improved dispersion properties

Tobramycin was spray dried at different temperatures from different water to isopropanol feed ratios (0:100-20:80) in order to obtain dry powder formulations for inhalation. The spray-dried powders were characterized for their physicochemical properties including crystallinity, morphology, density, water content, and particle size distribution using X-ray powder diffraction, scanning electron microscopy, tapped density measurements and laser diffraction. Aerosol performance was studied by dispersing the powders into a Multi-Stage Liquid Impinger with an Aerolizer device. The results indicate that formulations spray dried at temperatures below 200 degrees C exhibited poor powder flow properties and were therefore unlikely to display optimal aerosolization characteristics. Nevertheless, it is interesting to note that the presence of water in the suspensions used for spray-drying markedly enhanced the fine particle fraction, which was about 37% for the raw tobramycin and about 57% for a powder obtained from a suspension containing 2% (v/v) water. Overall, this latter formulation was shown to keep its initial particle size distribution and aerodynamic behaviour for 12 months of storage at 40 degrees C and 75% RH. These new carrier-free formulations provide an attractive alternative for delivering high doses of antibiotics directly to the site of infection while minimising systemic distribution.     

Preparation and characterization of spray dried inhalable powders containing chitosan nanoparticles for pulmonary delivery of isoniazid

The aim of this study was to prepare spray dried inhalable powders containing isoniazid-loaded chitosan/tripolyphosphate (TPP) nanoparticles for sustained delivery of the drug to the lung. Nanoparticles were prepared by ionic gelation method. In-vitro drug release study indicated that the rate of drug release from nanoparticles was decreased by increasing the amount of chitosan. Entrapment of isoniazid into chitosan/TPP nanoparticles decreased minimum inhibitory concentrations (MIC) of the drug against mycobacterium avium intracellulare. Nanoparticles were spray dried using excipients such as lactose, mannitol and maltodextrin alone or with leucine. Results showed that the obtained powders had different aerosolization property. It was observed that by adding leucine, the particle size of microparticles deceased and the process yield and fine particle fraction (FPF) increased significantly. The in-vitro deposition data indicated that spray drying of isoniazid-loaded nanoparticles with lactose in the presence of leucine resulted in the production of inhalable powders with the highest FPF (45%).     

Production of salbutamol sulfate for inhalation by high-gravity controlled antisolvent precipitation

The purpose of this study was to produce salbutamol sulfate (SS) as a model anti-asthmatic drug using high-gravity controlled precipitation (HGCP) through antisolvent crystallisation. An aqueous solution of SS was passed through a HGCP reactor with isopropanol as antisolvent to induce precipitation. Spray drying was employed to obtain dry powders. Scanning electron microscopy, X-ray powder diffraction (XRD), density measurement, thermal gravimetric analysis, and dynamic vapour sorption were carried out to characterise the powder physical properties. The aerosol performance of the powders was measured using an Aeroliser connected to a multiple stage liquid impinger operating at 60 L/min. The HGCP SS particles were elongated with 0.1 microm in width but varying length of several mum, which formed spherical agglomerates when spray dried. The particles showed the same XRD pattern and true density (1.3g/cm3) as the raw material, indicating that they belonged to the same crystalline form. However, the spray dried agglomerates had a much lower tapped density (0.1g/cm3) than the raw material (0.6g/cm3). Compared with the powder obtained by spray drying directly from an aqueous solution, the SS powders obtained from HGCP were much less hygroscopic (0.6% versus 10% water uptake at 90% RH). The in vitro aerosol performance showed a fine particle fraction FPFloaded and FPFemitted up to 54.5+/-4.9% and 71.3+/-10.0%, respectively. In conclusion, SS powder with suitable physical and aerosol properties can be obtained through antisolvent HGCP followed by spray drying.     

Effects of Moisture-Induced Crystallization on the Aerosol Performance of Spray Dried Amorphous Ciprofloxacin Powder Formulations

Purpose

This study aims to investigate the influence of different storage humidity conditions on crystallization and aerosol performance of inhalable spray dried amorphous powder formulations (Ciprofloxacin hydrochloride as the model drug).

Methods

The spray dried samples were stored at 20%, 55% and 75% relative humidity (RH). Crystallinity was monitored by Powder X-ray diffraction (PXRD), and particle morphology was measured by scanning electron microscopy (SEM) and atomic force microscopy (AFM). Aerosol performance was evaluated using a multi-stage liquid impinger (MSLI).

Results

PXRD diffractograms showed the spray dried Ciprofloxacin stored at 20% RH for three weeks were amorphous; whereas those stored at 55% RH and 75% RH started crystallizing after one hour. Fine particle fraction (FPF) of the particles was improved from 28% to 42% after storage at 55% RH for three days. Such improvement was attributed to the crystallization of amorphous powders, which led to increased particle roughness and reduced particulate contact area, as visualized by SEM and quantified by AFM. A linear relationship was observed between degree of crystallinity/crystallite size and FPF (R²?=?0.94 and R²?=?0.96, respectively). However, deterioration in aerosol performance was observed after storage at 75% RH due to formation of inter-particulate liquid/solid bridges, as confirmed by SEM.

Conclusions

This study provides a fundamental understanding in moisture-induced physical and aerosol instability of the spray dried powder formulations.

     

Immobilization of fine particles on lactose carrier by precision coating and its effect on the performance of dry powder formulations

The feasibility of immobilization of fine particles on a lactose carrier by precision coating and producing carrier particles of different surface roughness from the same core was explored. A relationship between the resultant surface roughness of the carrier and the in vitro deposition pattern of salbutamol sulfate was established. Lactose carrier particles in the precision coating chamber were spray coated with liquid suspensions consisting of micronized lactose dispersed in isopropyl alcohol (IPA) and/or water mixtures. The surface-modified lactose particles were fractionated and then characterized by laser diffraction for size, image analysis for shape, and scanning probe microscopy for surface roughness. The in vitro deposition pattern of salbutamol sulfate from the drug-lactose mixtures was determined with the twin-stage glass impinger and expressed as the fine particle fraction and dispersibility of the drug. Immobilization of fine particles on carrier particles was feasible by the precision coating process as shown by the scanning probe topographs and the roughness values of the carrier particles. Generally, more discrete fine particles were deposited on the carrier surface and a higher surface roughness was seen when the spray suspension consisting of a higher proportion of IPA was used. A significant correlation was found between the fine particle fraction of salbutamol sulfate with the roughness of lactose. This relationship established between the in vitro drug deposition pattern and the microscopic surface roughness of the carrier would be helpful in the optimization of drug delivery to targeted areas in the lungs.     

Preparation and characterization of spray dried inhalable powders containing chitosan nanoparticles for pulmonary delivery of isoniazid

The aim of this study was to prepare spray dried inhalable powders containing isoniazid-loaded chitosan/tripolyphosphate (TPP) nanoparticles for sustained delivery of the drug to the lung. Nanoparticles were prepared by ionic gelation method. In-vitro drug release study indicated that the rate of drug release from nanoparticles was decreased by increasing the amount of chitosan. Entrapment of isoniazid into chitosan/TPP nanoparticles decreased minimum inhibitory concentrations (MIC) of the drug against mycobacterium avium intracellulare. Nanoparticles were spray dried using excipients such as lactose, mannitol and maltodextrin alone or with leucine. Results showed that the obtained powders had different aerosolization property. It was observed that by adding leucine, the particle size of microparticles deceased and the process yield and fine particle fraction (FPF) increased significantly. The in-vitro deposition data indicated that spray drying of isoniazid-loaded nanoparticles with lactose in the presence of leucine resulted in the production of inhalable powders with the highest FPF (45%).     

Spray Dried Powders and Powder Blends of Recombinant Human Deoxyribonuclease (rhDNase) for Aerosol Delivery

Purpose. We have used rhDNase to investigate the feasibility of developing a dry protein powder aerosol for inhalation delivery. Methods. Powders of rhDNase alone and with sodium chloride were prepared by spray drying. Powder blends were obtained by mixing (tumbling and sieving) pure rhDNase powder with 'carrier' materials (lactose, mannitol or sodium chloride). The weight percent of drug in the blends was between 5 and 70%. The particle size distributions and crystallinity of the spray dried powders were obtained by laser diffraction and X-ray powder diffraction, respectively. Particle morphology was examined by scanning electron microscopy. The ability of the powders and powder blends to be dispersed into respirable aerosols was measured using a Rotahaler connected to a multistage liquid impinger operating at 60 L/min. Results. Pure rhDNase powder was quite cohesive with a fine particle fraction (FPF or 'respirable fraction': % wt. of particles < 7 m in the aerosol cloud) of about 20%. When particles also contained NaCl, the powders were dispersed better to form aerosols. A linear relationship was observed between the NaCl content and FPF for a similar primary size (~3 m volume median diameter) of particles. The particle morphology of these powders varied systematically with the salt content. For the blends, SEM revealed a monolayer-like adhesion of the fine drug particles to the carriers at drug contents 50 % wt. An overall 2-fold increase in FPF of rhDNase in the aerosol cloud was obtained for all the blends compared to the pure drug aerosols. Conclusions. The aerosol properties of spray dried rhDNase powders can be controlled by incorporation of a suitable excipient, such as NaCl, and its relative proportion. Coarse carriers can also enhance the performance of rhDNase dry powder aerosols.     

Spray drying of budesonide, formoterol fumarate and their composites-II. Statistical factorial design and in vitro deposition properties

The aim of this study was to investigate the effect of changing spray drying parameters on the production of a budesonide/formoterol fumarate 100:6 (w/w) composite. The systems were spray dried as solutions from 95% ethanol/5% water (v/v) using a Büchi 191-Mini Spray Dryer. A 2(5-1) factorial design study was undertaken to assess the consequence of altering spray drying processing variables on particle characteristics. The processing parameters that were studied were inlet temperature, spray drier airflow rate, pump rate, aspirator setting and feed concentration. Each batch of the resulting powder was characterised in terms of thermal and micromeritic properties as well as an in vitro deposition by twin impinger analysis. Overall, the parameter that had the greatest influence on each response investigated was production yield - airflow (higher airflow giving greater yields), median particle size - airflow (higher airflow giving smaller particle sizes) and Carr's compressibility index - feed concentration (lower feed concentration giving smaller Carr's indices). A six- to seven-fold difference in respirable fraction can be observed by changing the spray drying process parameters. The co-spray dried composite system which displayed best in vitro deposition characteristics, showed a 2.6-fold increase in respirable fraction in the twin impinger experiments and better dose uniformity compared with the physical mix of micronised powders.     

Preparation and characterisation of novel spray-dried nano-structured para-aminosalicylic acid particulates for pulmonary delivery: impact of ammonium carbonate on morphology, chemical composition and solid state

Objectives The objective of this work was to spray dry p‐aminosalicylic acid (PAS) and its ammonium salt and to investigate the impact of the pore‐forming agent, ammonium carbonate (AC), on the morphological, aerodynamic and physicochemical properties of the resulting powders. Methods Microparticles were prepared by spray drying from ethanol/water solvent systems. Their solid‐state properties were evaluated by scanning electron microscopy, powder X‐ray diffraction, differential scanning calorimetry, thermogravimetric analysis and in‐vitro deposition, using the twin impinger. Key Findings The physicochemical properties of PAS were altered on spray drying with AC and a new solid state was produced. The solution composition impacted on the morphology of the resulting powders, which ranged from irregular crystal agglomerates to spherical crystal clusters and porous microparticles. The chemical composition, structure and morphology were dependent on process inlet temperature, low inlet temperatures resulting in a novel solid of stoichiometry; PAS : ammonia : water, 2 : 1 : 0.5. At higher temperatures pure PAS was obtained. In‐vitro deposition studies showed an increase in emitted dose from spray dried drug, relative to the micronised PAS. Conclusions Under appropriate process conditions AC interacts with the acidic PAS, resulting in the formation of a novel solid‐state drug phase. Spray‐dried PAS powders have potential for pulmonary delivery.     

The influence of drug morphology on aerosolisation efficiency of dry powder inhaler formulations

The physicochemical properties of two forms of spray dried bovine serum albumin (BSA) have been investigated using particle sizing, surface energy measurement, atomic force microscopy (AFM) and colloid probe microscopy. The BSA powder had similar particle size distributions and surface energy but significantly different morphologies and roughness, classified as smooth and corrugated BSA. Adhesion forces between the corrugated BSA and alpha-lactose monohydrate indicated median adhesion forces were significantly less than for smooth/carrier interaction forces. These observations correlated well with aerosolisation from BSA/carrier blends, where the corrugated BSA particles gave a higher fine particle fraction than the smooth BSA, suggesting reduced BSA/carrier adhesion and increased drug liberation. The use of corrugated drug particle morphology in drug carrier DPI systems may lead to improved aerosol performance through reduced drug carrier contact area.     

Physicochemical and in vitro deposition properties of salbutamol sulphate/ipratropium bromide and salbutamol sulphate/excipient spray dried mixtures for use in dry powder inhalers

The physicochemical and aerodynamic properties of spray dried powders of the drug/drug mixture salbutamol sulphate/ipratropium bromide were investigated. The in vitro deposition properties of spray dried salbutamol sulphate and the spray dried drug/excipient mixtures salbutamol sulphate/lactose and salbutamol sulphate/PEG were also determined. Spray drying ipratropium bromide monohydrate resulted in a crystalline material from both aqueous and ethanolic solution. The product spray dried from aqueous solution consisted mainly of ipratropium bromide anhydrous. There was evidence of the presence of another polymorphic form of ipratropium bromide. When spray dried from ethanolic solution the physicochemical characterisation suggested the presence of an ipratropium bromide solvate with some anhydrous ipratropium bromide. Co-spray drying salbutamol sulphate with ipratropium bromide resulted in amorphous composites, regardless of solvent used. Particles were spherical and of a size suitable for inhalation. Twin impinger studies showed an increase in the fine particle fraction (FPF) of spray dried salbutamol sulphate compared to micronised salbutamol sulphate. Co-spray dried salbutamol sulphate:ipratropium bromide 10:1 and 5:1 systems also showed an increase in FPF compared to micronised salbutamol sulphate. Most co-spray dried salbutamol sulphate/excipient systems investigated demonstrated FPFs greater than that of micronised drug alone. The exceptions to this were systems containing PEG 4000 20% or PEG 20,000 40% both of which had FPFs not significantly different from micronised salbutamol sulphate. These two systems were crystalline unlike most of the other spray dried composites examined which were amorphous in nature.     

Sustained release of insulin from insoluble inhaled particles

Conventional slow‐acting insulin preparations for subcutaneous injection, e.g., suspensions of the complex with protamine and/or zinc, were reformulated as dry powders for inhalation and the insoluble aerosol tested for providing sustained insulin plasma levels. Large porous particles made of lactose, albumin, and dipalmitoylphosphatidylcholine, and incorporating insulin, protamine, and/or zinc chloride were prepared using spray‐drying. Integrity of insulin after spray‐drying and insulin insolubilization in spray‐dried particles was verified in vitro. The pharmacokinetic profile of the formulation delivered by inhalation and subcutaneous injection was assessed in vivo in the rat. The formulation process of insulin as dry powders did not alter insulin integrity and did not impede, in most cases, insulin insolubilization by protamine and/or zinc. Large porous insulin particles presented 7 μm mass mean geometric particle diameters, 0.1 g/cm³ bulk powder tap densities and theoretical aerodynamic diameters suitable for deep lung deposition (in the range of 2.2–2.5 μm). The dry powders exhibited 40% respirable fractions in the Andersen cascade impactor and 58–75% in the Aero‐Breather™. Insoluble inhaled insulin provided sustained insulin plasma levels for half a day, similar to injected insulin, and exhibited a bioavailability of 80.5% relative to subcutaneous injection of the same formulation. Drug Dev. Res. 48:178–185, 1999. ©1999 Wiley‐Liss, Inc.     

Crystallization of progesterone for pulmonary drug delivery

The purpose of this study is to investigate the suitability of the crystallization process to produce microcrystals of progesterone for respiratory drug delivery. Crystallization of progesterone was carried out from water–isopropanol (IPA) mixture. The antisolvent (water) was added at two different addition rates (10 and 100 mL/min). The mass percentage of antisolvent was varied between (50% and 75%), and the initial drug concentration was adjusted at (0.5 and 1 g/L). The effect of crystallization method (antisolvent precipitation or combined cooling and antisolvent) was also examined. These operating conditions were investigated in a 2⁴ factorial design in an effort to optimize the process. Different solid‐state and surface characterization techniques were applied in conjunction with measurements of powder flow properties using aerodynamic particle sizer (APS). Powder dispersibility and aerosol performance were analyzed using Anderson Cascade Impactor (ACI). Antisolvent addition rate, initial drug concentration and dynamic solvent composition are shown to have a significant effect on the aerosol characteristics of progesterone microcrystals. An increase of 38.73% in the fine particle fraction (FPF) was demonstrated for some powders produced by combined cooling and antisolvent crystallization. In conclusion, it was possible to control particle size and hence, pulmonary deposition using process parameters alone, and produce particles with a narrow particle size distribution and a mean particle size of 5 µm with nearly no particles larger than 10 µm by direct crystallization. The suitability of deep pulmonary deposition was proved by the platelet‐like morphology of processed microcrystals and greater surface‐to‐volume ratio than spherical particles. © 2009 Wiley‐Liss, Inc. and the American Pharmacists Association J Pharm Sci 99: 1123–1137, 2010     

Ultrasonic nebulization system for respiratory drug delivery

An ultrasonic spray system was tested for the production of aerosols for ultimate use in the respiratory delivery of drug to animals. A Sono-Tek ultrasonic spray system was mounted on top of a baffle to entrain aerosol particles within the carrier gas. Solvent was removed from the aerosol cloud by passing the droplets through drying columns composed of either charcoal or silica. The efficiency of removing ethanol and water were determined by measuring the outflow concentrations. Sodium fluorescein and sodium cromolyn dissolved in water were tested, and the effect of the liquid flow rate and drug concentration entering the atomizer on the output, and particle size distribution, were determined by the filter capture method, and by cascade impactor, respectively. Similar studies were conducted with budesonide and indomethacin dissolved in ethanol. The theoretical count median size distribution was calculated and compared with the experimental values calculated from the observed mass median aerodynamic diameter. The output rate expressed as the mass of aerosol collected in unit time increased nearly proportionately with the liquid flow rate (0.18-0.7 ml/min) and with the concentration of drug (0.19-12 mg/ml) entering the nebulizer. The mean particle size increased with solute concentration, but not by liquid flow rate. The calculated count median diameters were dependent on the type of solvent, but were independent of solute. At the high dose of cromolyn, there was very good agreement between the theoretical and observed. At lower doses, the observed size was larger than predicted, which was also true for the ethanol soluble solutes. The system has the potential of providing a wide range of dose levels for testing of drug delivery to animals including high doses with a controlled and relatively narrow particle size distribution.