
Abstract
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This review discusses how advances in formulation and device design can be utilized to dramatically improve lung targeting and dose consistency relative to current marketed dry powder inhalers (DPIs). Central to the review is the development of engineered particles that effectively bypass deposition in the upper respiratory tract (URT). This not only reduces the potential for off-target effects but it also reduces variability in dose delivery to the lungs resulting from anatomical differences in the soft tissue in the mouth and throat. Low-density porous particles are able to largely bypass URT deposition due to the fact that both the primary particles and their agglomerates are respirable. The low-density particles also exhibit dose delivery to the lungs that is largely independent of inspiratory flow rate across a range of flow rates that most subjects achieve with portable DPIs. Coupling this with delivery devices that are breath actuated, simple to operate (open-inhale-close), and have adherence-tracking capability enables drug delivery that is largely independent of how a subject inhales, with a user experience that is close to that of an “
Airway remodeling is considered an important factor in refractory and uncontrollable asthma. Previous studies have confirmed that anti-nerve growth factor (NGF) antibody can ameliorate airway remodeling. However, whether nebulized inhalation of anti-NGF microspheres (NANM) can inhibit airway remodeling is not clear. The purpose of this study was to investigate the effects of NANM on ovalbumin (OVA)-induced airway remodeling, and the mechanisms involved.
Anti-NGF microspheres were produced using a polymer alloy method. OVA was used to establish a rat model of asthma airway remodeling. Rats were treated with inhalation atomized anti-NGF antibody or NANM. Airway inflammation, airway reactivity, and airway remodeling were measured. Lung tissue P-Smad3 and tumor growth factor (TGF)-β1 mRNA and protein expression were also measured.
The anti-NGF antibody microsphere encapsulation rate was high, and the release time was long. NANM markedly attenuated OVA-induced airway remodeling, such as collagen deposition, average pulmonary resistance, the WAm/Pbm, WAt/Pbm, and Wcol/Pbm ratios (WAt, bronchial wall area; Pbm, perimeter of basement membrane; WAm, smooth muscle wall area; Wcol, airway collagen fiber area). Compared with the anti-NGF antibody group and the OVA group, the expression of TGF-β1 mRNA, TGF-β1 protein, and P-Smad3 in the NANM group were markedly decreased.
NANM ameliorated OVA-induced airway remodeling, partly through regulation of the TGF-β1/Smad3 pathway.
Inhalable pulmonary delivery of isoniazid (INH) may improve the efficacy and reduce drug resistance.
INH-loaded chitosan microparticles (Cs-Mps-1-3) were prepared as an inhalable carrier for the previously prepared INH-loaded polyvinylpyrrolidone/polyitaconic acid nanoparticles (NPs) using spray-drying technique. Here, Cs-Mps-1-3 are composed of Cs: INH-loaded NPs: Free INH at w/w ratios (1:1:0), (1: 0:1), and (1:1:1), respectively. Subsequently, the prepared Cs-Mps-1-3 characterizations were studied.
Cs-Mps-1-3 showed a spherical, smooth, positively charged surface (ζ-potential values +20.2, +28.7, and +22.6) and a size range 1.52–3.12 μm. In addition, Carr's compressibility indices of Cs-Mps-1-3 were 32.5%, 24.8%, and 28.02%, respectively. The
The promising potential of Cs-Mps-3 as an inhalable carrier for pulmonary delivery of INH is recommended.
The Easyhaler® device-metered dry powder inhaler containing Salmeterol and Fluticasone propionate (S/F) has been developed for the treatment of patients with asthma and chronic obstructive pulmonary disease (COPD). We report two studies which evaluated the
A randomized controlled trial (RCT) assessed inspiratory flow parameters of S/F Easyhaler and Seretide Diskus in subgroups of patients with asthma (children, adolescents and adults, and elderly) and in COPD patients. The 10th, 50th, and 90th percentile airflow rates were determined and utilized
Overall, 227 patients were enrolled and randomized; 216 completed the RCT. In total, 55.5% of patients were female, and the mean age was 46.3 years. Clinically relevant airflow rates (46, 68, and 85 L/min for S/F Easyhaler and 44, 71, and 96 L/min for Seretide Diskus) were carried forward into the
Similar
Inhaled chemotherapeutics may enhance pulmonary drug exposure to malignant lesions in the lung without substantially contributing to systemic toxicities. The pharmacokinetic profile of inhaled submicron particle paclitaxel (NanoPac®) in healthy rodent plasma and lung tissue is evaluated here to determine administration proof-of-principle.
Healthy male Sprague Dawley rats received paclitaxel in one of three arms: intravenous nab-paclitaxel at 2.9 mg/kg (IVnP), inhaled NanoPac low dose (IHNP-LD) at 0.38 mg/kg, or inhaled NanoPac high dose (IHNP-HD) at 1.18 mg/kg. Plasma and lung tissue paclitaxel concentrations were determined using ultraperformance liquid chromatography tandem mass spectrometry from animals sacrificed at 10 time points ranging up to 2 weeks after administration. Peak concentration (Cmax), apparent residence half-life (T1/2), exposure (AUC(last)), and dose-normalized exposure (AUCD(last)) were determined. Pulmonary histopathology was performed on rats sacrificed at the 336-hour time point.
Paclitaxel was detectable and quantifiable in the rat lung for both inhaled NanoPac arms sampled at the final necropsy, 336 hours postadministration. Substantial paclitaxel deposition and retention resulted in an order of magnitude increase in dose-normalized pulmonary exposure over IVnP. Inhaled NanoPac arms had an order of magnitude lower plasma Cmax than IVnP, but followed a similar plasma T1/2 clearance (quantifiable only to 72 hours postadministration). Pulmonary histopathology found all treated animals indistinguishable from treatment-naive rats.
In the rodent model, inhaled NanoPac demonstrated substantial deposition and retention of paclitaxel in sampled lung tissue. Further research to determine NanoPac's toxicity profile and potential efficacy as lung cancer therapy is underway.
Pulmonary surfactant spreads rapidly over the airway epithelium, a property that could be harnessed to transport drugs into the lungs. For efficient drug delivery, an interaction between pulmonary surfactant and the drug to be administered is likely needed. On the other hand, the interaction should not compromise the activity of surfactant or the drug once delivered
The bactericidal activity of polymyxin E, but not of gentamicin, against
The results suggest that polymyxin E interacts with poractant alfa, which reduces the antibacterial effect
