Yosuke Aoki

Inhalable dry-emulsion formulation of cyclosporine A with improved anti-inflammatory effects in experimental asthma/COPD-model rats

The main purpose of the present study was to develop a novel respirable powder (RP) formulation of cyclosporine A (CsA) using a spray-dried O/W-emulsion (DE) system. DE formulation of CsA (DE/CsA) was prepared by spray-drying a mixture of erythritol and liquid O/W emulsion containing CsA, polyvinylpyrrolidone, and glyceryl monooleate as emulsifying agent. The DE/CsA powders were mixed with lactose carriers to obtain an RP formulation of DE/CsA (DE/CsA-RP), and its physicochemical, pharmacological, and pharmacokinetic properties were evaluated. Spray-dried DE/CsA exhibited significant improvement in dissolution behavior with ca. 4500-fold increase of dissolution rate, and then, nanoemulsified particles were reconstituted with a mean diameter of 317 nm. Laser diffraction analysis on the DE/CsA-RP suggested high dispersion of DE/CsA on the surface of the lactose carrier. Anti-inflammatory properties of the inhaled DE/CsA-RP were characterized in antigen-sensitized asthma/COPD-model rats, in which the DE/CsA-RP was more potent than the RP formulation of physical mixture containing CsA and erythritol in inhibiting inflammatory responses, possibly due to the improved dissolution behavior. Pharmacokinetic studies demonstrated that systemic exposure of CsA after intratracheal administration of the DE/CsA-RP at a pharmacologically effective dose (100 μg-CsA/rat) was 50-fold less than that of the oral CsA dosage form at a toxic dose (10 mg/kg). From these findings, use of inhalable DE formulation of CsA might be a promising approach for the treatment of airway inflammatory diseases with improved pharmacodynamics and lower systemic exposure.

Inhalable powder formulation of a stabilized vasoactive intestinal peptide (VIP) derivative: Anti-inflammatory effect in experimental asthmatic rats

Vasoactive intestinal peptide (VIP) exerts immunomodulating and anti-inflammatory activities through its specific receptors, such as VPAC1 and 2 receptors. Previously, a stabilized VIP derivative, [R(15,20,21), L(17)]-VIP-GRR (IK312532), was proposed as a candidate of anti-asthma drug, and a dry powder inhaler system of IK312532 was also developed for inhalation therapy with minimal systemic side-effects. In the present study, the anti-inflammatory properties of IK312532 respirable powder (RP) were characterized in an asthma/COPD-like animal model, with the use of newly developed ovalbumin (OVA)-RP for lung inflammation. Marked inflammatory events in the lung were observed after OVA-RP challenge in rats as evidenced by significant increase of inflammatory biomarkers such as eosinophil peroxidase (EPO), myeloperoxidase (MPO) and lactate dehydrogenase (LDH). However, intratracheal administration of IK312532-RP led to significant attenuation of plasma EPO, MPO and LDH activities, as well as significant reduction of recruited inflammatory cells in BALF, especially macrophages and eosinophils. In the rats pretreated with IK312532-RP, histochemical examinations revealed that the inflammatory cells infiltrating to the lung and the epithelial wall thickness decreased significantly by 85% and 58%, respectively. Thus, inhalable powder formulation of IK312532 exerts its anti-inflammatory activity by suppressing granulocyte recruitment to the lung and epithelial hyperplasia, followed by the reduction of cytotoxic peroxidases.

Development of Inhalable Nanocrystalline Solid Dispersion of Tranilast for Airway Inflammatory Diseases

Tranilast (TL), an antiallergic agent, has been clinically used in the treatment of bronchial asthma, although the clinical use of TL is limited because of its poor solubility and systemic side effects. To overcome these drawbacks, a novel respirable powder (RP) of TL for inhalation therapy was developed using nanocrystal solid dispersion of TL (CSD/TL). In the CSD/TL, wet-milled crystalline TL particles with a mean diameter of 122 nm were dispersed, and there was a marked improvement in dissolution behavior of the CSD/TL-RP compared with that of a physical mixture of TL and carrier. Laser diffraction and cascade impactor analyses on the CSD/TL-RP demonstrated high dispersibility and deposition in the respiratory organs with emitted dose and fine particle fraction of ca. 98 and 60%, respectively. Inhaled CSD/TL-RP could attenuate antigen-induced inflammatory events in rats, as evidenced by histochemical analyses and inflammatory biomarkers such as lactate dehydrogenase, eosinophil peroxidase, and myeloperoxidase. The CSD/TL-RP seemed to be more potent than the physical mixture in inhibiting inflammatory responses, possibly due to the improved dissolution behavior. Systemic exposure of TL after intratracheal administration of CSD/TL-RP at a pharmacologically effective dose (100 μg of TL/rat) was found to be fivefold less than that of the oral TL dosage form at clinical dose (1.67 mg/kg). Given the improved pharmacodynamics and lower systemic TL concentration, the inhalable TL formulation might provide an interesting alternative to oral therapy with a better safety margin for the treatment of asthma and other airway inflammatory diseases.

Formulation design and in vivo evaluation of dry powder inhalation system of new vasoactive intestinal peptide derivative ([R15, 20, 21, L17, A24,25, des-N28]-VIP-GRR) in experimental asthma/COPD model rats

Vasoactive intestinal peptide (VIP) has been considered as a promising drug candidate for asthma and COPD because of its potent immunomodulating and anti-inflammatory activities. Recently, our group developed a new VIP derivative, [R(15, 20, 21), L(17), A(24,25), des-N(28)]-VIP-GRR (IK312548), with improved chemical and metabolic stability. In the present study, a dry powder inhaler system of IK312548 was designed for inhalation therapy with minimal systemic side effects, the physicochemical properties of which were also evaluated with a focus on morphology, particle size distribution, inhalation performance, and peptide stability. Laser diffraction and cascade impactor analysis suggested high dispersion and deposition in the respiratory organs with a fine particle fraction of 31.2%. According to UPLC/ESI-MS and circular dichroic spectral analyses, no significant changes in the purity and structure of VIP derivative were observed during preparation of respirable formulation. Anti-inflammatory properties of IK312548 respirable powder (RP) were characterized in antigen-sensitized asthma/COPD-model rats. There were marked inflammatory cells infiltrated into the lung tissues of experimental asthma/COPD-model rats; however, intratracheal administration of IK312548-RP led to significant reductions of recruited inflammatory cells in lung tissues and BALF by 72 and 78%, respectively. Thus, respirable powder formulation of IK312548 might be a promising medication for asthma, COPD, and other airway inflammatory diseases.

Stable dry powder inhaler formulation of tranilast attenuated antigen-evoked airway inflammation in rats.

Tranilast (TL) has been clinically used for the treatment of airway inflammatory diseases, although the clinical use of TL is limited because of its poor solubility and systemic side effects. To overcome these drawbacks, a novel respirable powder of TL (CSD/TL-RP) for inhalation therapy was developed using nanocrystal solid dispersion of TL (CSD/TL). Stability study on CSD/TL-RP was carried out with a focus on inhalation performance. Even after 6 months of storage at room temperature, there were no significant morphological changes in micronized particles on the surface of carrier particles as compared with that before storage. Cascade impactor analyses on CSD/TL-RP demonstrated high inhalation performance with emitted dose and fine particle fraction (FPF) of ca. 98% and 60%, respectively. Long-term storage of CSD/TL-RP resulted in only a slight decrease in FPF value (ca. 54%). Inhaled CSD/TL-RP could attenuate antigen-induced inflammatory events in rats, as evidenced by marked reduction of granulocytes in bronchoalveolar lavage fluid and inflammatory biomarkers such as eosinophil peroxidase, myeloperoxidase, and lactate dehydrogenase. These findings were consistent with decreased expression levels of mRNAs for nuclear factor-kappa B and cyclooxygenase-2, typical inflammatory mediators. Given these findings, inhalable TL formulation might be an interesting alternative to oral therapy for the treatment of asthma and other airway inflammatory diseases with sufficient dispersing stability.

Inhalable powder formulation of vasoactive intestinal peptide derivative, [R15,20,21, L17]-VIP-GRR, attenuated neutrophilic airway inflammation in cigarette smoke-exposed rats

Cigarette smoke (CS) has been identified as a predominant causative factor for chronic obstructive pulmonary disease (COPD), so CS-exposed rodent model of COPD has drawn considerable interest and attention for fundamental study and drug discovery. In the present study, using experimental COPD model rats, the therapeutic potential of a newly prepared respirable powder (RP) formulation of a long-acting VIP derivative, [Arg(15,20,21), Leu(17)]-VIP-GRR (IK312532), was assessed with a focus on pro-inflammatory biomarkers, morphological and histochemical changes, and infiltrated cells in the respiratory system. CS exposure of rats for 11 days led to the marked infiltration of inflammatory cells, except for eosinophils, in bronchiolar epithelium, followed by goblet cell metaplasia and hyperplasia. However, inhalation of IK312532-RP (50μg/rat) in the CS-exposed rats resulted in 74 and 71% reductions of granulocyte recruitment in bronchoalveolar lavage fluids and lung tissues, respectively, with 68% decrease of goblet cells. Biomarker study demonstrated that the inhaled IK312532-RP could suppress the CS-evoked increase of myeloperoxidase in both plasma and lung by 87 and 70%, respectively, possibly leading to potent suppression of neutrophilic inflammatory symptoms. The results from TUNEL staining were indicative of apoptotic damage in respiratory tissues of the CS-exposed rats, and there appeared to be marked decrease of TUNEL-positive cells in the CS-exposed rat with inhaled IK312532-RP. The present findings suggest that an inhalable formulation of IK312532 might be efficacious as a therapy for COPD or other airway inflammatory diseases because of its potent immunomodulating activities.

Novel vasoactive intestinal peptide derivatives with improved stability protect rat alveolar L2 cells from cigarette smoke-induced cytotoxicity and apoptosis

Vasoactive intestinal peptide (VIP) has been thought to be a promising candidate for asthma/chronic obstructive pulmonary disease (COPD), and our group previously developed several long-lasting VIP derivatives. The objective of the present study was to clarify the therapeutic potential of new VIP derivatives with improved chemical and metabolic stability. Exposure of rat alveolar L2 cells to cigarette smoke extract (CSE) for 1h led to release of lactate dehydrogenase (LDH) and decreased viability in a CSE concentration-dependent manner. There appeared to be marked induction of apoptosis after CSE exposure, as demonstrated by 59% elevation of caspase-3 activity and TUNEL staining. In contrast, a stabilized VIP derivative, [R(15,20,21), L(17)]-VIP-GRR (IK312532), at a concentration of 10(-7)M, exhibited 71% attenuation of LDH release and 85% decrease of the number of apoptotic cells. In addition to IK312532, new VIP derivatives also showed anti-apoptotic effects against CSE toxicity and marked reduction of nitric oxide production. In terms of cytoprotective effects, [R(15,20,21), L(17), A(24,25), des-N(28)]-VIP-GRR was more effective than VIP and IK312532, possibly due to the improved stability. Thus, the present study is the first to demonstrate that novel stabilized VIP derivatives exert anti-apoptotic and cytoprotective effects on CSE-induced cytotoxicity.

Respirable Dry Powder Formulation of Bleomycin for Developing a Pulmonary Fibrosis Animal Model

The main purpose of the present study was to develop a respirable powder (RP) formulation of bleomycin (BLM) as a research tool for developing a pulmonary fibrosis animal model. The BLM-RP was prepared with a jet-milling system, the physicochemical properties of which were characterized focusing on morphology, stability, particle size distribution, and inhalation performance. Under an accelerated condition, the BLM-RP was superior to BLM solution in terms of its stability. Cascade impactor analyses demonstrated high inhalation performance with emitted dose and fine particle fraction of approximately 99% and 46%, respectively. Intratracheal administration of the BLM-RP (3 mg BLM/kg) in rats led to significant increases in collagen production and recruitment of inflammatory cells in lung by approximately 1.5- and 29-fold, respectively. The collagen overexpression was consistent with the results from picrosirius red staining of lung tissues in the rats treated with BLM-RP. Inhaled tranilast (TL; 100 μg/rat), an antifibrotic agent, could ameliorate inflammatory/fibrotic responses with reductions of recruited inflammatory cells and collagen content by 32% and 59%, respectively, validating the pulmonary fibrosis animal model. From these findings, the BLM-RP with improved stability could be a beneficial research tool for developing a pulmonary fibrosis model in drug discovery for antifibrotic drug candidates.

Self-assembled micellar formulation of chafuroside A with improved anti-inflammatory effects in experimental asthma/COPD-model rats

Chafuroside A (CFA), a poorly water-soluble flavone C-glycoside, was firstly isolated from oolong tea, and it acts as a potent anti-inflammatory agent. The present study was undertaken to develop a water-soluble formulation of CFA using a self-assembled micellar (SAM) system, with the aim of improved dissolution behavior and potent anti-inflammatory effects. The SAM formulation of CFA (CFA/SAM) was characterized in terms of its morphology, particle size distribution, crystallinity, and dissolution behavior. In dissolution testing, the CFA/SAM exhibited marked improvement in dissolution behavior when compared with crystalline CFA, and then, nano-micellar particles were constituted with a mean diameter of 84 nm. The therapeutic potential of the crystalline CFA and CFA/SAM was assessed using an experimental asthma/chronic obstructive pulmonary disease (COPD)-like model. Orally-administered CFA at 0.5mg/kg or higher could attenuate inflammatory symptoms in a dose-dependent manner, as evidenced by decreases of infiltrated granulocytes, including macrophages and neutrophils, and myeloperoxidase, a specific biomarker for neutrophilia. Biomarker profiling demonstrated that the CFA/SAM at 0.1mg CFA/kg was equipotent to CFA at 1.0mg/kg in ameliorating antigen-induced airway inflammation, suggesting the better pharmacological effect of CFA/SAM due to improved dissolution behavior. From these observations, the SAM formulation might be an efficacious approach for enhancing the therapeutic potential of CFA for treatment of inflammatory diseases.