@ARTICLE{Dorosz_Agata_Dynamics_2023, author={Dorosz, Agata and Moskal, Arkadiusz and Sosnowski, Tomasz R.}, volume={vol. 44}, number={No 4 (24th Polish Conference of Chemical and Process Engineering, 13-16 June 2023, Szczecin, Poland. Guest editor: Prof. RafaƂ Rakoczy)}, journal={Chemical and Process Engineering: New Frontiers}, pages={e39}, howpublished={online}, year={2023}, publisher={Polish Academy of Sciences Committee of Chemical and Process Engineering}, abstract={Chemical and process engineering offers scientific tools for solving problems in the biomedical field, including drug delivery systems. This paper presents examples of analyzing the dynamics of dispersed systems (aerosols) in medical inhalers to establish a better relationship between the test evaluation results of these devices and the actual delivery of drugs to the lungs. This relationship is referred to as in vitro-in vivo correlation (IVIVC). It has been shown that in dry powder inhalers (DPls), the aerosolization process and drug release times are determined by the inhalation profile produced by the patient. It has also been shown that inspiratory flow affects the size distribution of aerosols generated in other inhalation devices (vibrating mesh nebulizers, VMNs), which is due to the evaporation of droplets after the aerosol is mixed witha dditional air taken in by the patient. The effects demonstrated in this work are overlooked in standard inhaler testing methods, leading to inaccurate information about the health benefits of aerosol therapy, thus limiting the development of improved drug delivery systems.}, type={Article}, title={Dynamics of aerosol generation and flow during inhalation for improved in vitro-in vivo correlation (IVIVC) of pulmonary medicines}, URL={http://ochroma.man.poznan.pl/Content/129339/e39_int.pdf}, doi={10.24425/cpe.2023.147398}, keywords={aerosol dynamics, inhalation, resuspension, nebulization, drug delivery systems}, }