Journal of Aerosol Medicine and Pulmonary Drug Delivery最新文献

Background: Dry powders offer the potential to increase stability and reduce cold-chain requirements associated with the distribution of vaccines and other thermally sensitive products. The Alberta Idealized Nasal Inlet (AINI) is a representative geometry for in vitro characterization of nasal products that may prove useful in examining intranasal delivery of powders. Methods: Spray-dried trehalose powders were loaded at 10, 20, and 40 mg doses into active single-dose devices. Primary particle sizes (∼D_v50 = 10 µm for powder A and 25 µm for powder B), and sizes dispersed by devices, were evaluated using laser diffraction. The interior of the AINI was coated with a glycerol-surfactant mixture to mitigate particle bounce, and flow rates of 7.5 or 15 L/min were drawn through the AINI. Deposition of trehalose powder was determined in the four regions of the AINI (vestibule, turbinates, olfactory, and nasopharynx), a downstream preseparator, and an absolute filter (representing in vitro lung deposition) using liquid chromatography coupled with mass spectrometry. Results: Coating the AINI was effective in mitigating particle bounce for both trehalose powders. No difference in regional nasal deposition was observed when testing at a flow rate of 7.5 versus 15 L/min. A high fraction of both powders penetrated past the vestibule and deposited in the turbinates and nasopharynx for all loaded doses. For powder A, a non-negligible fraction of the recovered dose (up to 7%) is deposited on the filter, representing potential lung exposure. Conversely, a negligible fraction of the total recovered dose was deposited on the filter for powder B. Conclusion: Powders with a larger primary particle size showed reduced penetration through the nasal airways while maintaining high turbinate deposition. Optimized spray-dried powders offer the potential to target delivery to the peripheral nasal airways based on powder particle size while reducing lung exposure.

Background: It remains challenging to quantify lung pharmacokinetics (PK) of a drug administered and targeted to act in the lung. Exhaled breath particles (PEx), which are generated when collapsed distal airways reopen during inhalation, offer a noninvasive way to access undiluted epithelial lining fluid (ELF). Therefore, it was the aim of this study to investigate whether PK data can be derived from PEx. Methods: Six healthy volunteers received either an inhaled dose (400 µg) or an oral dose (8 mg) of salbutamol in a randomized, crossover design with 7-day washout between treatments. PEx were collected before and at nine time points after dosing (0-315 minutes [min]). Following each 15 min PEx sampling period, nasosorption and plasma samples were collected. Salbutamol was quantified by liquid chromatography-mass spectrometry. Results: After oral delivery and inhalation, salbutamol PK profiles could be obtained for plasma and nasal samples. In PEx samples, a PK profile could be obtained in 5 of 6 participants after inhalation, but the salbutamol concentration was often at or below detection limit after oral intake. After inhaled administration we found higher salbutamol concentrations in PEx as compared with nasal and plasma samples. Conclusion: This study provides proof of principle that PEx samples can be used to quantify drug levels in ELF.

Background: Asthma controller medications can be delivered via pressurized metered dose inhaler (pMDI) or dry powder inhaler (DPI) devices. Objective: This study aimed to evaluate the frequency of exacerbations and satisfaction rate with device use in asthmatics using pMDIs or DPIs. Methods: A multicenter, cross-sectional study was conducted in adults who used pMDIs or DPIs with correct inhaler technique and good adherence for asthma treatment. Demographic and asthma-related characteristics of the subjects and data regarding device satisfaction were collected through a face-to-face interview in the outpatient clinic. Rates of pMDI and DPI users and the data were compared between the two groups. Results: The study included 338 patients (mean age: 48.6 ± 14.5 years, 253 [74.9%] women). Among participants, 96 (28.4%) were using pMDI and 242 (71.6%) were using DPI. The age of patients using pMDI were significantly lower compared with DPI users. No significant difference was observed in terms of device satisfaction and clinical outcomes of asthma between pMDI and DPI users with good inhaler technique and good adherence. Conclusion: More asthmatics use DPIs, however, pMDIs are used in younger asthmatic patients. No significant difference in terms of device satisfaction and clinical outcomes of asthma was observed between pMDI and DPI users.

In contemporary times, there has been a rise in the utilization of dry powder inhalers (DPIs) in the management of pulmonary and systemic diseases. These devices underwent a swift advancement in terms of both the equipment utilized and the formulation process. In this review, the carrier physicochemical characteristics that influence DPI performance are discussed, focusing its shape, morphology, size distribution, texture, aerodynamic diameter, density, moisture, adhesive and detachment forces between particles, fine carrier particles, and dry powder aerosolization. To promote the deposition of the active principal ingredient deep within the pulmonary system, advancements have been made in enhancing these factors and surface properties through the application of novel technologies that encompass particle engineering. So far, the most used carrier is lactose showing some advantages and disadvantages, but other substances and systems are being studied with the intention of replacing it. The final objective of this review is to analyze the physicochemical and mechanical characteristics of the different carriers or new delivery systems used in DPI formulations, whether already on the market or still under investigation.

Background: Small airways disease (SAD) in severe asthma (SA) is associated with high disease burden. Effective treatment of SAD could improve disease control. Reduced end-expiratory flows (forced expiratory flow [FEF]_25-75 and FEF₇₅) are considered sensitive indicators of SAD. Inhaled medication should be delivered to the smaller peripheral airways to treat SAD effectively. Aerosol deposition is affected by structural airway changes. Little is known about the effect of SAD on aerosol delivery to the smaller peripheral airways. Functional respiratory imaging (FRI) is a validated technique using 3D reconstructed chest computed tomography (CT) and computational fluid dynamics to predict aerosol deposition in the airways. Aim: This study aims to compare central and peripheral (= small airways) deposition between children with SA and SAD and children with SA without SAD, with different inhaler devices and inhalation profiles. Methods: FRI was used to predict the deposition of beclomethasone/formoterol dry powder inhaler (DPI), beclomethasone/formoterol pressurized metered dose inhaler with valved holding chamber (pMDI/VHC), and salbutamol pMDI/VHC for different device-specific inhalation profiles in chest-CT of 20 children with SA (10 with and 10 without SAD). SAD was defined as FEF_25-75 and FEF₇₅ z-score < -1.645 and forced vital capacity (FVC) z-score > -1.645. No SAD was defined as forced expiratory volume (FEV)₁, FEF_25-75, FEF₇₅, and FVC z-score > -1.645. The intrathoracic, central, and peripheral airways depositions were determined. Primary outcome was difference in central-to-peripheral (C:P) deposition ratio between children with SAD and without SAD. Results: Central deposition was significantly higher (∼3.5%) and peripheral deposition was lower (2.9%) for all inhaler devices and inhalation profiles in children with SAD compared with children without SAD. As a result C:P ratios were significantly higher for all inhaler devices and inhalation profiles, except for beclomethasone administered through DPI (p = .073), in children with SAD compared with children without SAD. Conclusion: Children with SA and SAD have higher C:P ratios, that is, higher central and lower peripheral aerosol deposition, than children without SAD. The intrathoracic, central, and peripheral deposition of beclomethasone/formoterol using DPI was lower than using pMDI/VHC.

Introduction: In normal subjects, during tidal breathing, aerosols deposit by settling in small airways. With obstructive lung disease (OLD), collapse of airways during expiration causes turbulence and increased deposition in central airways. High-flow nasal cannula (HFNC) therapy, washing out dead space, may affect deposition mechanisms and drug delivery. This study compared aerosol deposition and airway responsiveness in OLD after traditional and HFNC nebulization therapy. Methods: Twelve subjects with moderate to severe OLD participated in a two-day study. Spirometry was measured pre- and post-aerosol inhalation. On Day 1 (D1) subjects tidally inhaled radiolabeled albuterol (^99mTc DTPA) by mouth via AeroTech II, (Biodex. Shirley, NY). Day 2 (D2) inhalation was via HFNC using i-AIRE (InspiRx, Inc. Somerset, NJ). The HFNC system (60 L/m) was infused by syringe pump at 50 mL/h. D2 lung deposition was monitored in real time by gamma camera to match D1. Pre and post heart rate, O₂ sat, and nasopharyngeal deposition (NP) were measured. Mechanistic contributions were modeled using multiple linear regression (MLR) of deposition rate (DR µg/m) as a function of breathing frequency, airway geometry (FEV₁), and parenchymal integrity (DLCO). Results: Albuterol lung depositions were matched (p = 0.13) with D1 central/peripheral (sC/P) ratios 1.99 ± 0.98. Following HFNC, peripheral deposition increased (31% ± 33%, sC/P = 1.51 ± 0.43, p = 0.01). D2/D1% change FVC increased by 16.1 ± 16.7% (p = 0.003). NP deposition averaged 333% of lung. Heart rate and O₂ sat were unaffected (p = 0.31, p = 0.63 respectively). DR analysis was markedly different between D1 (R² = 0.82) and D2 (R² = 0.12). Conclusion: In subjects with OLD, HFNC nebulization at 60 L/min was well tolerated and increased peripheral drug delivery. Spirometry significantly improved. Systemic effects were undetected indicating limited nasal absorption. MLR demonstrated that different mechanisms of deposition govern traditional vs HFNC aerosol delivery. Breath-enhanced nebulization via HFNC may provide controllable and effective aerosol therapy in OLD.

The respiratory tract with its vast surface area and very thin air-blood tissue barrier presents an extremely large interface for potential interaction with xenobiotics such as inhaled pathogens or medicaments. To protect its large and vulnerable surface, the lung is populated with several different types of immune cells. Pulmonary epithelial cells, macrophages and dendritic cells are key players in shaping the innate and adaptive immune response. Due to their localization, they represent a frontline of cell populations that are among the first to come in contact with inhaled xenobiotics. Furthermore, depending on the lung compartment they populate, these cells show a large variety in morphology, phenotype, and function. These unique characteristics make those cell populations ideal targets for specific immunomodulators that are designed for inhalation. Depending on cell population or lung compartment targeting, a specific immune response may be triggered or modulated. The purpose of a potent carrier for pulmonary immunomodulation is, first, to efficiently target a specific immunocompetent cell and, second, to affect its role in generating an immune response. Immunomodulation may occur at different levels of immune cell-antigen interaction, i.e. antigen uptake, trafficking, processing and presentation. Inhalation of nanosized carriers for drugs or vaccines shows great potential for both prophylactic and therapeutic approaches in order to modulate immune responses locally or systemically, due to the specific deposition and targeting properties of nanoparticles. Immune responses triggered by nanosized particles may be either immunostimulatory or immunosuppressive and depending on the specific purpose, stimulation or suppression may either be desired or unwanted. Meticulous analysis of immunomodulatory potential, pharmacologic and toxicologic testing of inhalable nanocarriers is required in order to find novel and optimal approaches for prophylaxis and therapy of pulmonary diseases. The design and characterization of such nanoparticles requires well-coordinated interdisciplinary research among engineers, biologists and clinicians.

Background: The lack of visual dynamic spray characterization has made the understanding of the physical processes governing atomization and drug particle formation difficult. This study aimed to investigate the changes in the spray plume morphology and aerodynamic particle size of solution-based pressurized metered-dose inhalers (pMDIs) under different conditions to achieve better drug deposition. Methods: Solution-based pMDIs were studied, and the effects of various factors, such as propellant concentration, orifice diameters, and atomization chamber volume, on drug deposition were examined by analyzing the characteristics of spray plume and aerodynamic particle size. Results: Reducing the actuator orifice and spray area led to a concentrated spray plume and increased duration and speed. Moreover, the aerodynamic particle sizes D50 and D90 decreased, whereas D10 remained relatively unchanged. Decreasing the atomization chamber volume of the actuator led to reduced spray area and an increased duration but a decreased plume velocity. D90 exhibited a decreasing trend, whereas D10 and D50 remained relatively unchanged. Reducing the propellant concentration in the prescription, the spray area and the plume velocity first decreased and then increased. The duration initially increased and then decreased. The values of D50 and D90 showed an initial decreasing followed by an increasing trend, whereas D10 remained relatively unchanged. Conclusions: During the development process, attention should be paid to the changes in the spray area, spray angle, duration, and speed of the spray plume. This study recommended analyzing the characteristics of the spray plume and combining the data of two or more aerodynamic particle size detection methods to verify the deposition in vitro to achieve rapid screening and obtain high lung deposition in vivo.

Traditional vaccines have played an important role in the prevention and treatment of infectious diseases, but they still have problems such as low immunogenicity, poor stability, and difficulty in inducing lasting immune responses. In recent years, the nucleic acid vaccine has emerged as a relatively cheap and safe new vaccine. Compared with traditional vaccines, nucleic acid vaccine has some unique advantages, such as easy production and storage, scalability, and consistency between batches. However, the direct administration of naked nucleic acid vaccine is not ideal, and safer and more effective vaccine delivery systems are needed. With the rapid development of nanocarrier technology, the combination of gene therapy and nanodelivery systems has broadened the therapeutic application of molecular biology and the medical application of biological nanomaterials. Nanoparticles can be used as potential drug-delivery vehicles for the treatment of hereditary and infectious diseases. In addition, due to the advantages of lung immunity, such as rapid onset of action, good efficacy, and reduced adverse reactions, pulmonary delivery of nucleic acid vaccine has become a hot spot in the field of research. In recent years, lipid nanocarriers have become safe, efficient, and ideal materials for vaccine delivery due to their unique physical and chemical properties, which can effectively reduce the toxic side effects of drugs and achieve the effect of slow release and controlled release, and there have been a large number of studies using lipid nanocarriers to efficiently deliver target components into the body. Based on the delivery of tuberculosis (TB) nucleic acid vaccine by lipid carrier, this article systematically reviews the advantages and mechanism of liposomes as a nucleic acid vaccine delivery carrier, so as to lay a solid foundation for the faster and more effective development of new anti-TB vaccine delivery systems in the future.