In vitro assessment of small charged pharmaceutical aerosols in a model of a ventilated neonate

• Published in: Journal of aerosol science Vol. 110; pp. 25 - 35
• Main Authors: Holbrook, Landon, Hindle, Michael, Longest, P. Worth
• Format: Journal Article
• Language: English
• Published: England Elsevier Ltd 01.08.2017
• Subjects: Endotracheal tube; Induction charger; Infants; Mechanical ventilation; Pharmaceutical aerosols; Respiratory drug delivery; Infants; Endotracheal tube; Pharmaceutical aerosols; Induction charger; Mechanical ventilation; Respiratory drug delivery; induction charger; infants; mechanical ventilation; respiratory drug delivery; pharmaceutical aerosols; endotracheal tube
• ISSN: 0021-8502; 1879-1964
• DOI: 10.1016/j.jaerosci.2017.05.006

Aerosolized medications may benefit infants receiving mechanical ventilation; however, the lung delivery efficiency of these aerosols is unacceptably low. In vitro experiments were conducted to evaluate aerosol delivery through conventional and modified ventilation systems to the end of a 3mm endotracheal tube (ETT) under steady state and realistic cyclic flow conditions. System modifications were employed to investigate the use of small charged particles and included streamlined components, a reduction in nebulizer liquid flow rate, synchronization with inspiration, and implementation of a previously designed low-flow induction charger (LF-IC), which was further modified in this study. Cyclic flow experiments implemented a modern ventilator with bias airflow and an inline flow meter, both of which are frequently excluded from in vitro tests but included in clinical practice. The modified LF-IC system demonstrated superior delivery efficiency to the end of the ETT (34%) compared with the commercial system (~1.3%) operating under cyclic ventilation conditions. These findings indicate that commercial systems still provide very low lung delivery efficiencies despite decades of innovation. In contrast, the modified system increased dose delivery to the end of the ETT by 26-fold. Despite initial concerns, the charged aerosol could be efficiently delivered through the small diameter ETT and reach the lungs. Future studies will be required to determine if the applied particle charge can eliminate expected high exhalation aerosol loss and will require the development of a realistic lung model. •Aerosol delivery to an infant lung model using a modern ventilator.•Lung aerosol delivery efficiency for a commercial system was 1.3%.•Modifications included streaming and synchronization.•Modifications increased lung delivery efficiency to 34%.•The small charged aerosol could be efficiently delivered to the lungs.