Formulation development of inhalation powders for FK888 using the E-haler to improve the inhalation performance at a high dose, and its absorption in healthy volunteers.

FK888 is a candidate selective NK1 receptor antagonist, and it exhibits poor absorption from the gastrointestinal tract in healthy volunteers. In a previous study, the optimized dry powder inhaler (DPI) formulation with carrier lactose using the Spinhaler was developed, although the maximum dose per capsule was only 5mg because the fine particle fraction (FPF) was reduced at doses over 5mg. The objective of this study was to develop an optimized DPI formulation for higher doses, such as 40 mg, with proportional systemic absorption. The Spinhaler and E-haler were used as the inhalation devices, and the in vitro deposition was evaluated using a multistage cascade impactor at different flow rates (28.3 and 60 l/min). When hydroxypropyl methylcellulose (HPMC) capsules were used as the container, and spherical soft agglomerates of fine FK888 particles (soft pellets) and the E-haler were used, the fraction of particles emitted from the inhalation system (Em) was significantly improved, to over 80% of the nominal dose, and no significant difference was found between the airflow rates (84.3+/-2.3% for 28.3 l/min, 88.1+/-3.6% for 60 l/min). It was also found that the E-haler was an extremely suitable device for obtaining the higher respirable particle percentage of emitted particles (RP) in the 40 mg formulation with the soft pellets contained in HPMC capsules (35.0+/-1.8% for 28.3 l/min and 42.5+/-3.5% for 60 l/min), compared with the Spinhaler (13.8+/-3.0% for 28.3 l/min and 28.9+/-1.0% for 60 l/min). Using the formulations with the E-haler, proportional systemic absorption was achieved up to 40 mg FK888 in healthy volunteers (62.91+/-27.58, 103.70+/-40.19 and 254.79+/-85.01 ngh/ml as AUCs for 10, 20 and 40 mg FK888, respectively; R(2)=0.9641). It is also expected that the E-haler will act as an efficient device when a higher dose, such as 40 mg, is required in clinical situations.     

Critical characteristics for corticosteroid solution metered dose inhaler bioequivalence

Determining bioequivalence for solution pressurized metered dose inhalers (pMDI) is difficult because the critical characteristics of such products are poorly defined. The aim of this study was to elucidate the non-aerodynamic properties of the emitted aerosol particles from two solution pMDI products that determine their biopharmaceutical differences after deposition. Novel particle capture and analysis techniques were employed to characterize the physicochemical and biopharmaceutical properties of two beclomethasone dipropionate (BDP) products: QVAR and Sanasthmax. The BDP particles emitted from the Sanasthmax inhaler were discernibly different those emitted from QVAR in terms of size (50% larger, less porous), solid state (less crystalline) and dissolution (20-fold slower). When deposited onto the surface of respiratory epithelial cell layers, QVAR delivered ～50% more BDP across the cell layer in 60 min than Sanasthmax. Biopharmaceutical performance was not attributable to individual particle properties as these were manifold with summative and/or competing effects. The cell culture dissolution-absorption model revealed the net effect of the particle formed on drug disposition and was predictive of human systemic absorption of BDP delivered by the test inhalers. This illustrates the potential of the technique to detect the effect of formulation on the performance of aerosolized particles and contribute to assessment of bioequivalence.     

Comparison of beclomethasone dipropionate delivery by easyhaler dry powder inhaler and pMDI plus large volume spacer.

Dry powder inhalers (DPIs) provide a means of delivering inhaled asthma drugs without the use of propellants. Easyhaler is a multidose DPI, delivering 200 doses of beclomethasone dipropionate (BDP), 200 microg/dose. A gamma scintigraphic study has been carried out in 10 healthy volunteers to compare the deposition of BDP from Easyhaler with that from a pressurized metered dose inhaler (pMDI) coupled to a Volumatic spacer device delivering 250 microg BDP per dose. The spacer was used without any pretreatment to reduce static charge on the spacer walls. The study was conducted according to an open, randomized, crossover design. The volunteers inhaled the study drug using optimal inhalation technique for both devices. Lung deposition of 99mTc-labeled BDP averaged 18.9% (SD 9.5%) of the metered dose for Easyhaler, and 11.2% (SD 5.3%) for pMDI plus spacer (p < 0.05); when the data were expressed as mass of BDP deposited in the lungs, the difference in lung deposition just failed to reach statistical significance (Easyhaler 37.8 microg; pMDI plus spacer 28.0 microg). Oropharyngeal deposition was significantly reduced by use of the spacer. The results of this study show that Easyhaler delivers drug more efficiently to the lungs than pMDI plus Volumatic spacer when no measures are taken to eliminate static charge on the spacer walls.     

Deposition of corticosteroid aerosol in the human lung by Respimat Soft Mist inhaler compared to deposition by metered dose inhaler or by Turbuhaler dry powder inhaler.

Fourteen mild-to-moderate asthmatic patients completed a randomized four-way crossover scintigraphic study to determine the lung deposition of 200 microg budesonide inhaled from a Respimat Soft Mist Inhaler (Respimat SMI), 200 microg budesonide inhaled from a Turbuhaler dry powder inhaler (Turbuhaler DPI, used with fast and slow peak inhaled flow rates), and 250 microg beclomethasone dipropionate inhaled from a pressurized metered dose inhaler (Becloforte pMDI). Mean (range) whole lung deposition of drug from the Respimat SMI (51.6 [46-57]% of the metered dose) was significantly (p < 0.001) greater than that from the Turbuhaler DPI used with both fast and slow inhaled flow rates (28.5 [24-33]% and 17.8 [14-22]%, respectively) or from the Becloforte pMDI (8.9 [6-12]%). The deposition pattern within the lungs was more peripheral for Respimat SMI than for Turbuhaler DPI. The results of this study showed that Respimat SMI deposited corticosteroid more efficiently in the lungs than either of two widely used inhaler devices, Turbuhaler DPI or Becloforte pMDI.     

The rejuvenated pressurised metered dose inhaler

The pressurised metered-dose inhaler (pMDI) has now been available for 50 years. Once regarded as an inefficient and difficult-to-use device, the technology has evolved significantly over the last few years, particularly since the introduction of novel formulations containing hydrofluoroalkane (HFA) propellants. Many modern HFA pMDIs deposit drug more efficiently in the lungs, impact less forcefully on the back of the throat and feel less cold than their chlorofluorocarbon pMDI counterparts. An improved understanding of technical factors makes it possible to design HFA pMDIs to have specific spray properties, particularly in terms of fine particle dose and spray velocity. Device technology has also progressed with the introduction of compact and convenient breath-actuated, breath-coordinated and velocity-modifying devices, which help patients to achieve a reliable lung dose. Although it faces competition from dry powder inhalers and possibly from novel soft-mist inhalers containing liquid formulations, the rejuvenated HFA pMDI is a device with a significant future for asthma, chronic obstructive pulmonary disease and wider treatment indications.     

Influence of micronization method on the performance of a suspension triamcinolone acetonide pressurized metered-dose inhaler formulation

The purpose of this study was to investigate the influence of micronization technique on performance and stability of the model drug formulated in a suspension-based pressurized metered-dose inhaler (pMDI). The model drug, triamcinolone acetonide (TAA), was subjected to ball milling or air-jet milling prior to formulation of the pMDI. The dose delivery characteristics of the emitted aerosol cloud were monitored for the ball-milled, air-jet-milled, and unmicronized TAA pMDI formulations prior to and after storage at 25 and 40 degrees C. Cascade impaction was used to determine the aerodynamic particle size distribution of the emitted dose. Both micronization techniques reduced the drug particle size distribution and the polydispersity of the drug particles to a similar extent, but the ball-milling technique reduced the crystallinity of the drug to a greater degree compared to the air-jet-milling technique. The air-jet-milled and unmicronized TAA pMDI displayed similar aerodynamic particle size distributions of the emitted aerosol and respirable fractions over the storage period. The ball-milled TAA resulted in a pMDI formulation with the smallest aerodynamically sized particles and the highest respirable fraction compared to the air-jet-milled or unmicronized TAA pMDI formulations. The micronization techniques significantly influenced the dose delivery characteristics as a result of different initial particle size distributions, amorphous contents, and surface energies.     

The rejuvenated pressurised metered dose inhaler

The pressurised metered-dose inhaler (pMDI) has now been available for 50 years. Once regarded as an inefficient and difficult-to-use device, the technology has evolved significantly over the last few years, particularly since the introduction of novel formulations containing hydrofluoroalkane (HFA) propellants. Many modern HFA pMDIs deposit drug more efficiently in the lungs, impact less forcefully on the back of the throat and feel less cold than their chlorofluorocarbon pMDI counterparts. An improved understanding of technical factors makes it possible to design HFA pMDIs to have specific spray properties, particularly in terms of fine particle dose and spray velocity. Device technology has also progressed with the introduction of compact and convenient breath-actuated, breath-coordinated and velocity-modifying devices, which help patients to achieve a reliable lung dose. Although it faces competition from dry powder inhalers and possibly from novel soft-mist inhalers containing liquid formulations, the rejuvenated HFA pMDI is a device with a significant future for asthma, chronic obstructive pulmonary disease and wider treatment indications.     

Drug delivery from the Turbuhaler and Nebuhaler pressurized metered dose inhaler to various age groups of children with asthma.

A total of 198 children aged 3 to 15 years inhaled a single dose of 200 micrograms budesonide from a Nebuhaler pressurized metered dose inhaler (pMDI) and a Turbuhaler dry powder inhaler in a randomized crossover study. The budesonide dose delivered to a patient was assessed by measuring the amount of drug deposited on a filter inserted between the inhaler outlet and the patient's mouth. The dose of budesonide deposited on the filter and the estimated dose of particles with a mass median aerodynamic diameter (MMAD) of 5 microns or less after inhalation from the Turbuhaler were both approximately twice the values inhaled from the pMDI Nebuhaler in children less than 5 years of age (P < 0.01). The variation in the dose delivered to the patient was similar for the two inhalers in children over 5 years old. In 3- to 4-year-old children, dose delivery to the patient was higher and/or more consistent from the pMDI Nebuhaler than from the Turbuhaler. Filter dose after Turbuhaler treatment varied significantly from peak inspiratory flow rate through the Turbuhaler (PIFTbh) (P < 0.01). The percentage of children producing a PIFTbh greater than 50 L/min decreased with age (89%, 45%, and 14% in 5-, 4-, and 3-year-old children, respectively). It is concluded that drug delivery to a child with asthma varies with age and inhalation device. Further studies are needed to assess the clinical importance of this finding.     

Scintigraphic assessment of drug delivery from the Ultrahaler dry powder inhaler.

A new dry powder inhaler, the Ultrahaler, has been developed to deliver nedocromil sodium for the prophylaxis of asthma. This study was performed to compare the lung deposition of nedocromil sodium inhaled from the Ultrahaler at two different inhaled flow rates with that from a pressurised metered dose inhaler (MDI). A scintigraphic study was conducted in 12 healthy volunteers. On each study day, volunteers received a single 4.2 mg dose of nedocromil sodium from the Ultrahaler, using either an optimal (fast) inhaled flow rate or a suboptimal (slow) inhaled flow rate, or two doses of 2 mg nedocromil sodium from an MDI using an optimal (slow) inhaled flow rate. Used optimally, the Ultrahaler deposited significantly more (p < 0.05) of the metered dose in the lungs than either the Ultrahaler used suboptimally or the MDI used optimally [mean (SD) lung deposition values of 13.3 (4.8)%, 9.8 (3.5)%, and 7.5 (2.9)%, respectively]. Oropharyngeal deposition averaged over 80% of the dose for all three treatment regimens. This scintigraphic study demonstrated in vivo proof of concept for the Ultrahaler dry powder inhaler, and provided quantitative data on the relationship in lung deposition between the Ultrahaler and MDI which differed from that predicted by the in vitro fine particle fraction.     

Performance of large- and small-volume valved holding chambers with a new combination long-term bronchodilator/anti-inflammatory formulation delivered by pressurized metered dose inhaler.

The treatment of both the bronchoconstriction and inflammatory aspects of asthma simultaneously by a single pressurized metered dose inhaler (pMDI) represents a significant advance in convenience to the patient. However, a valved holding chamber (VHC) may still be needed to reduce the coarse component of the dose that is likely to deposit in the oropharyngeal region, and a small sized device may offer significant advantages to the patient from the standpoint of compliance with therapy. VHCs representing small (adult AeroChamber Plus with mouthpiece, 149-mL) and large (Volumatic, 750-mL) devices have been compared in an in vitro evaluation with Seretide/Advair (hydro-fluoro alkane [HFA]-formulated fluticasone propionate [FP = 125 microg/dose] and salmeterol xinafoate [SX = 25 microg/dose]) by Andersen Mark-II eight-stage impactor operated at 28.3 L/min following compendial methodology. Fine particle fraction, based on the size range from 1.1 to 4.7 microm aerodynamic diameter, from either large or small VHCs with either component (69-79%) was similar [p > or = 0.08], and significantly greater than that from the pMDI alone (approximately 40%) [p < 0.001]. Fine particle dose emitted by the VHCs for SX (8.2 +/- 0.8 microg for the AeroChamber Plus and 7.7 +/- 0.5 microg for the Volumatic) were comparable, and also similar to the fine particle dose delivered by the pMDI when used without a VHC (7.6 +/- 0.6 microg). Fine particle doses for the FP component delivered by the two VHCs (46.4 +/- 3.4 microg for the AeroChamber Plus and 46.3 +/- 2.7 microg for the Volumatic) were equivalent, but were slightly greater than the corresponding fine particle dose from the pMDI alone (39.1 +/- 2.6 microg). However, this difference (approximately 20%) is close to the limit of resolution based on intermeasurement variability and is unlikely to have clinical significance, given the interpatient variability seen with inhaled drug therapy. It is therefore concluded that either of these VHCs has equivalent in vitro performance with this combination formulation in terms of the portion of the dose emitted from the pMDI that is likely to reach the receptors in the lungs.     

Clinical pharmacokinetics of inhaled budesonide

The corticosteroid budesonide is a 1:1 racemic mixture of 2 epimers, (22R)- and (22S)-, and is available in 3 different inhaled formulations for the management of asthma: a pressurised metered dose inhaler (pMDI), a dry powder inhaler (DPI) and a solution for nebulised therapy. Inhaled corticosteroids such as budesonide reach the systemic circulation either by direct absorption through the lungs (a route that is much more important than previously recognised) or via gastrointestinal absorption of drug that is inadvertently swallowed. Although the pharmacokinetics of budesonide have been extensively investigated following oral and intravenous administration, relatively few studies have defined the systemic disposition of budesonide after inhalation. Drug deposition in the lungs depends on the inhaler device: 15% of the metered dose of budesonide reached the lung with a pMDI compared with 32% with a breath-actuated DPI. In patients with asthma (n = 38) receiving different doses of budesonide by DPI (Turbuhaler), the pharmacokinetic parameters peak plasma concentration (Cmax) and area under the concentration-time curve (AUC) were dose-dependent after both single dose and repeat dose (3 weeks) administration: time to Cmax (tmax) was short (0.28 to 0.40 hours) and the elimination half-life approximately 3 hours. Both AUC and Cmax were linearly related to budesonide dose. In a small group of healthy male volunteers (n = 9), the pharmacokinetics of budesonide 1,600 microg twice daily via pMDI were assessed on the fifth day of administration. Mean model-independent parameters for (22R)-budesonide were as follows: Cmax 1.8 microg/L, tmax 0.46 hours, elimination half-life 2.3 hours and oral clearance 163 L/h, and there were no enantiomer-specific differences in drug disposition. Budesonide undergoes fatty acid conjugation within the lung, but very limited pharmacokinetic data are available to define the pulmonary absorption characteristics. There is evidence from a population analysis that the pulmonary absorption of budesonide is prolonged and shows wide interindividual variation. Further pharmacokinetic studies are required to define the time-course of budesonide absorption through the lung in specific patient groups, and to investigate the effect of new inhaler devices (especially chlorofluorocarbon-free pMDIs) on the pharmacokinetic profile and systemic drug exposure.     

Metered-dose inhaler add-on devices: an in vitro evaluation of the BronchoAir inhaler and several spacer devices.

Spacer devices minimize the drug deposition in the oropharyngeal region as they retain between 30% and 50% of the nominal drug dose. Additionally, they should increase the fine particle fraction of the emitted aerosol. A new effort to increase the lung deposition was the design of a new actuator, the BronchoAir inhaler, (BronchoAir Medizintechnik GmbH, Munich, Germany). This study was carried out to evaluate the usefulness of this new actuator device by comparing its fine particle fraction with that emitted with the standard actuators and with spacer devices. The fine particle fraction's of commercially available metered dose inhalers (MDIs) marketed with specific spacers were determined using a multistage liquid impinger (MSLI). The effect of the BronchoAir inhaler on fine particle fractions was quite dependent on the formulation causing a decrease as great as 43% with Beclomet forte (beclomethasone-17, 21-dipropionate [BDP]) and an increase as great as 35% with Arubendol (salbutamol) but causing a difference of less than 20% with the other six tested formulations. Deposition in the upper stages of the impinger was sometimes higher than it was for the standard actuator. Spacer devices decreased the deposition in the upper stages of the impinger significantly, and in some cases, the fine particle fractions were also decreased. Varying the spacer design showed the superiority of large-volume open spacers compared with spacers with other designs.     

Influence of flow rate on aerosol particle size distributions from pressurized and breath-actuated inhalers.

Particle size distribution of delivered aerosols and the total mass of drug delivered from the inhaler are important determinants of pulmonary deposition and response to inhalation therapy. Inhalation flow rate may vary between patients and from dose to dose. The Andersen Sampler (AS) cascade impactor operated at flow rates of 30 and 55 L/min and the Marple-Miller Impactor (MMI) operated at flow rates of 30, 55, and 80 L/min were used in this study to investigate the influence of airflow rate on the particle size distributions of inhalation products. Total mass of drug delivered from the inhaler, fine particle mass, fine particle fraction, percentage of nonrespirable particles, and amount of formulation retained within the inhaler were determined by ultraviolet spectrophotometry for several commercial bronchodilator products purchased in the marketplace, including a pressurized metered-dose inhaler (pMDI), breath-actuated pressurized inhaler (BAMDI), and three dry powder inhalers (DPIs), two containing salbutamol sulphate and the other containing terbutaline sulphate. Varying the flow rate through the cascade impactor produced no significant change in performance of the pressurized inhalers. Increasing the flow rate produced a greater mass of drug delivered and an increase in respirable particle mass and fraction from all DPIs tested.     

A comparison of dry powder inhaler dose delivery characteristics using a power criterion

A novel method is described that compares the in vitro drug delivery characteristics of different dry powder inhalers (DPIs) based on the power supplied by the air flow. Power is defined as the rate at which work is done by the air flow and is equal to the product of pressure gradient and air flow rate through the inhaler. Tests were conducted to compare the emitted dose and fine particle fraction of the total dose (FPFTD) of the Diskus, Diskhaler, and a proprietary powder dispersion device (PDD) containing fluticasone propionate/lactose powder blends. Three power levels were selected: 1, 2, and 3 W, representing a range of inspiratory efforts. The Diskus and PDD were independent of power, delivering consistent doses and fine particle fractions over the range of powers evaluated. Diskhaler was dependent on power, the emitted dose and FPFTD significantly decreasing at the lower power level (1W) (p < 0.005). Diskus and Diskhaler are trademarks of the Glaxo Wellcome group of companies.     

Efficacy and safety of budesonide and formoterol in one pressurised metered-dose inhaler in adults and adolescents with moderate to severe asthma: a randomised clinical trial

BACKGROUND: Inhaled corticosteroids (ICSs) are the preferred maintenance therapy for adults and children with mild, moderate and severe persistent asthma, with the addition of a long-acting beta(2)-adrenoceptor agonist to ICS therapy recommended for patients with moderate or severe persistent asthma. The efficacy and safety of the combination of budesonide and formoterol delivered via dry powder inhaler (DPI) is well documented. OBJECTIVE: To compare the efficacy and safety of budesonide/formoterol pressurised metered-dose inhaler (budesonide/formoterol pMDI; Symbicort pMDI, AstraZeneca LP, Wilmington, DE, USA) with budesonide pMDI (Pulmicort pMDI, Astra [corrected] Zeneca, Lund, Sweden), formoterol DPI (Oxis Turbuhaler, AstraZeneca, Lund, Sweden), budesonide plus formoterol in separate inhalers (budesonide pMDI + formoterol DPI) and placebo. STUDY DESIGN: This was a 12-week randomised, double-blind, double-dummy, placebo-controlled study. SETTING: This multicentre study was conducted in the respiratory specialty clinical practice setting. PATIENTS: The study included 596 patients > or =12 years of age with moderate to severe persistent asthma previously receiving ICSs. INTERVENTIONS: After 2 weeks on budesonide pMDI 80 microg x two inhalations (160 microg) twice daily, patients received budesonide/formoterol pMDI 160 microg/4.5 microg x two inhalations (320 microg/9 microg); budesonide pMDI 160 microg x two inhalations (320 microg) + formoterol DPI 4.5 microg x two inhalations (9 microg); budesonide pMDI 160 microg x two inhalations (320 microg); formoterol DPI 4.5 microg x two inhalations (9 microg); or placebo twice daily. MAIN OUTCOME MEASURES: There were two prespecified primary efficacy variables: mean change from baseline in morning predose forced expiratory volume in 1 second (FEV(1)), obtained approximately 12 hours after the most recent administration of study medication at home and immediately before the next administration of study medication at the clinic; and mean change from baseline in 12-hour FEV(1), assessed as the average change in FEV(1) from serial spirometry over the 12-hour period after administration of the morning dose of study medication at the clinic. RESULTS: Mean changes from baseline in morning predose FEV(1) at end of treatment were greater (p < or = 0.049) with budesonide/formoterol pMDI (0.19L) versus budesonide pMDI (0.10L), formoterol DPI (-0.12L) and placebo (-0.17L). Mean changes from baseline in 12-hour FEV(1) were greater (p < or = 0.001) with budesonide/formoterol pMDI after 1 day (0.37L), 2 weeks (0.34L) and at end of treatment (0.37L) versus budesonide pMDI (0.11, 0.15 and 0.15L) and placebo (0.09, -0.03 and -0.03L), and after 2 weeks and at end of treatment versus formoterol DPI (0.19 and 0.17L). Fewer (p < or = 0.025) patients receiving budesonide/formoterol pMDI versus monoproducts or placebo met worsening asthma criteria. Results were similar in the budesonide/formoterol pMDI group and the budesonide pMDI + formoterol DPI group on all measures. All treatments were well tolerated with similar safety profiles. CONCLUSIONS: In this population, twice-daily budesonide/formoterol pMDI provides asthma control significantly greater than the monocomponents or placebo and comparable with budesonide pMDI + formoterol DPI. Safety profiles were similar for all treatments.     

Intra-subject variability in lung dose in healthy volunteers using five conventional portable inhalers.

High intra-subject variability in lung dose achieved when using aerosol delivery systems may impact on the efficacy of treatment in clinical practice. While the dose delivered by metered dose inhalers (pMDIs) is highly reproducible when tested in vitro, the variability in dose delivered to the lungs is known to be high. It has been suggested that newer delivery systems such as dry powder inhalers (DPIs) or breath actuated pMDIs significantly reduce the intra-subject variability in lung dose, but this remains untested. The 30-min urinary salbutamol technique was used to assess intra-subject variability in lung dose for five portable inhaler devices. Thirteen healthy adult subjects inhaled salbutamol from five different devices. Each device was used at five separate study days, a total of 25 visits. The devices studied were the Evohaler pMDI, a pMDI with Volumatic (pMDI + HC), the Easibreath, the Accuhaler and the Turbohaler. Subjects inhaled 400 microg of salbutamol and produced a urine sample exactly 30 min later. Quantities of salbutamol contained in the urine were determined using an HPLC technique. The mean coefficient of variation (CV% and range) for lung dose were 31.8% (20.1-87.4) for the pMDI + HC, Easi-breathe 35.9% (10.4-66.2), Accuhaler 40.4% (15.6-75.2), Turbohaler 42.4% (20.7-74.2), and 52.0% (27.1-49.3) for the pMDI alone. There was no significant statistical significant difference between any of the devices. In seven of 13 subjects, the greatest lung dose was achieved with the Volumatic. The observed intra-subject in health volunteers is similar to the reported intra-subject variability of bioavailability for a number of oral medications. Though there was trend towards higher variability when using the pMDI, this was not statistically significant and was largely attributable to one subject in with a poor technique.     

Comparison of bronchoprotective and bronchodilator effects of a single dose of formoterol delivered by hydrofluoroalkane and chlorofluorocarbon aerosols and dry powder in a double blind, placebo-controlled, crossover study

BACKGROUND: In response to the phasing out of chlorofluorocarbon (CFC) inhalers, a metered dose hydrofluoroalkane (HFA) formulation, Modulite (Chiesi Farmaceutici S.p.A, Parma, Italy), to be delivered with a pressurized metered dose inhaler (pMDI), has been developed. Modulite is a HFA formulation technology that has been designed to provide stable and uniform dose delivery of HFA-based formulations to enable an easy transition from CFC to HFA inhalers. OBJECTIVES: The aim of this study was to compare the bronchoprotective and bronchodilator effects of a single dose of 12 microg of formoterol from the HFA Modulite inhaler with the Foradil Aerolizer (dry powder inhaler, DPI) and the Foradil CFC inhalers (Novartis Health Consumer, Basel, Switzerland). METHODS: This was a double blind, double dummy, randomized, placebo-controlled, crossover study conducted in 38 subjects with mild to moderate asthma (mean forced expiratory volume in 1 s [FEV1] 87.5% predicted). The primary endpoint was methacholine challenge provocative dose required for 20% fall in the FEV1 (PD20) 90 min post dose. Bronchodilation was assessed with spirometry (FEV1, FVC, FEF25-75) and impulse oscillometry (resistance at 5 and 20 Hz, reactance at 5 Hz and resonant frequency) over the 90 min post dose. In a subset of 12 subjects formoterol plasma levels, serum potassium and glucose were determined up to 480 min post dose. RESULTS: The three formoterol formulations demonstrated significant (P < or = 0.05) improvements in bronchoprotection compared to placebo and non-inferiority of the HFA preparation compared to the CFC and DPI preparations was demonstrated. Geometric mean PD20 values were 0.51 mg with HFA, 0.62 mg with DPI, 0.62 mg with CFC and 0.2 mg with placebo. The log transformed mean differences in PD20 doubling dose between HFA and (a) DPI was -0.28 (95% CI -0.84-0.29, P = 0.57) (b) CFC was -0.28 (95% CI -0.84-0.28, P = 0.57) and (c) placebo was 1.38 (95% CI 0.82-1.94, P < 0.001). Serum potassium, glucose and formoterol plasma profiles were comparable for the CFC, HFA and DPI devices. CONCLUSION: Our findings of similar efficacy, pharmacokinetics and systemic effects of the HFA formoterol inhaler compared to the CFC and DPI preparations supports the potential use of this novel formulation in the treatment of asthma.     

儿童哮喘缓解期吸入性糖皮质激素用药依从性现况调查

目的：探讨儿童哮喘缓解期吸入性糖皮质激素（Inhaled Corticosteroids，ICS）用药依从性及影响因素。方法：对90名哮喘患儿家长进行问卷调查，分析患儿近3个月哮喘缓解期内ICS的使用情况、用药依从性、吸入装置掌握情况及相关影响因素。结果：患儿近3个月内使用最多的ICS为BUD （48.89%），其次是FP （35.56%）、BDP （6.67%）及其他（8.89%）。使用吸入装置最多的是雾化器（24.44%）和干粉吸入剂（都保）（24.44%），其次是压力定量气雾剂（加储物罐）（23.33%）、干粉吸入剂（准纳器）（14.44%）及压力定量气雾剂（无储物罐）（13.33%）。Morisky用药依从性量表调查结果显示，调查对象对于ICS的用药依从性平均得分为5.39，总体判定为依从性差（<6分）。影响依从性的主要影响因素是担心长期用药不良反应、病情好转后停药、各种原因引起的漏用、孩子治疗不配合、吸入装置复杂、用药后无效、用药方案复杂、家庭经济原因以及医师指导不到位等。结论：儿科临床医师和药师应进一步加强诊疗管理，强化吸入技术的使用培训，通过多种途径不断深化哮喘控制宣传、教育和培训工作，提高哮喘患儿长期用药依从性。     

Practical,regulatory and clinical considerations for development of inhalation drug products

The formulation and device collectively constitute an inhalation drug product. Development of inhaled drugs must consider the compatibility between formulation and device in order to achieve the intended pharmaceutical performance and usability of the product to improve patient compliance with treatment instruction. From the points of formulation, device and patient use, this article summarizes the inhalation drugs, including pressurized metered dose inhaler (pMDI), dry powder inhaler (DPI), and nebulizer that are currently available in the US and UK markets. It also discusses the practical considerations for the development of inhalers and provides an update on the corresponding regulations of the FDA (U.S. Food and Drug Administration) and the EMA (European Medicines Agency).     

Drug delivery performance of the mometasone furoate dry powder inhaler.

The mometasone furoate dry powder inhaler (MF-DPI) is a multiple-dose, breath-actuated inhaler that uses agglomerates of micronized MF and lactose. In vitro analyses evaluated dose uniformity, variability, and particle size distribution of the MF-DPI. Tests of first, middle, and end doses from 10 inhalers each of the 200-microg MF/inhalation and 400-microg MF/inhalation dose sizes found that delivered doses (doses emitted from the inhaler) ranged from 91% to 112% of claimed doses for all tested DPIs. The mean MF doses delivered at 28.3 L/min were 100% and 94% of the doses delivered at 60 L/min for the 200-microg and 400-microg dose sizes, respectively; the relative standard deviation of doses was < or = 6.1% within this range of inhalation rates. At a flow rate of 60 L/min, the mean delivered doses, compared to claimed doses for inspiration times of 1-3 sec, were 102-104% for the 200-microg dose size and 98.8-102% for the 400-microg dose size. The mean cumulative fraction of dose delivered at 60 L/min for 2 sec which consisted of particles of <6.5 microm in diameter was 39.9% (+/-2.5 SD; n = 9) for the 200-microg dose size and 35.6% (+/-3.4 SD; n = 9) for the 400-microg dose size. All MF-DPI inhalers tested were well within U.S. and European compendial standards and regulatory guidelines for dose uniformity. An appropriate and reproducible fraction of the delivered dose was within the optimal particle size range for therapeutic effectiveness.