Development of Otsuka dry powder inhalation system using technology of freeze-drying

Systemic Delivery of hGhrelin Derivative by Lyophilizate for Dry Powder Inhalation System in Monkeys

Ghrelin is the peptide that increases the hunger sensation and food intake and is expected to be clinically applied for treatment of diseases such as cachexia and anorexia nervosa. In the clinical application of ghrelin, injections are problematic in that they are invasive and inconvenient. Thus, we aimed to develop a formulation that can eliminate the need for injections and can be applied clinically. We prepared formulations of an hGhrelin derivative, in which the octanoyl group essential for expression of activity is modified to avoid rapid des-acylation, using lyophilizate for a dry powder inhalation (LDPI) system. The formulation of hGhrelin derivative was optimized by the addition of phenylalanine, of which the fine particle fraction of 5 µm or less was 41.7 ± 3.8%. We also performed pharmacokinetic/pharmacodynamic tests in monkeys using the optimum formulation that can be applied clinically. The absolute bioavailability of inhaled hGhrelin derivative with respect to that intravenously injected was 16.9 ± 2.6%. An increase in growth hormone was shown as an effect of the inhaled hGhrelin derivative similar to intravenous injection. The LDPI formulation can deliver the hGhrelin derivative systemically, and it is expected to be applied clinically as a substitute for injections.

Simple Method to Measure the Aerodynamic Size Distribution of Porous Particles Generated on Lyophilizate for Dry Powder Inhalation

Recently, statistical techniques such as design of experiments are being applied for efficient optimization of oral formulations. To use these statistical techniques for inhalation formulations, efficient methods for rapid determination of the aerodynamic particle size distribution of many samples are needed. Therefore, we aimed to develop a simple method to measure aerodynamic particle size distribution that closely agrees with the results of inhalation characteristic tests. We added attachments for dispersion to the aerodynamic particle sizer (APS) so that formulations could be dispersed under the same condition as for multi-stage liquid impinger (MSLI) measurement. Then, we examined the correlation between MSLI and APS using lyophilizate for dry powder inhalation formulations that generate porous particles just on inhalation. It is difficult to obtain the accurate aerodynamic particle size distribution of porous particles by APS because the particle density is difficult to estimate accurately. However, there was a significant correlation between MSLI and APS when the particle density settings for APS measurement was calculated by a conversion factor based on the result of MSLI. The APS with dispersion attachments and this conversion factor can measure a number of samples in a short time, thereby enabling more efficient optimization of dry powder inhalers.

Efficient optimization of high-dose formulation of novel lyophilizates for dry powder inhalation by the combination of response surface methodology and time-of-flight measurement

Inhalation of proteins/peptides has recently received attention as various biopharmaceuticals have emerged on the market. Novel lyophilisates for dry powder inhalation (LDPIs), which are aerosolized by air impact, have been reported and LDPIs are considered an attractive option for the pulmonary administration of biopharmaceuticals. However, desirable disintegration and aerosolization properties have been unavailable in high-dose formulations, which has been a critical issue. This study aimed to investigate high-dose LDPIs and their optimization. In the present study, lysozyme (Lysoz) was used as a stable model protein and formulated with various amino acids. Furthermore, response surface methodology (RSM) and time-of-flight measurement were applied for efficient optimization. Superior disintegration and aerosolization properties were confirmed in the LDPIs with phenylalanine (Phe) and leucine (Leu). RSM results revealed that 0.5 mg/vial of Phe and 1.0 mg/vial of Leu are the optimal quantities for high-dose formulation. Based on these optimum quantities, high-dose LDPI formulations were prepared and the maximum formulable quantity of Lysoz with acceptable inhalation performance was confirmed to be 3.0 mg/vial. The results suggest that LDPI can cover the milligram-order pulmonary administration of proteins/peptides. LDPIs are expected to have biopharmaceutical applications.