A Novel Trans-Tracheostomal Retrograde Inhalation Technique Increases Subglottic Drug Deposition Compared to Traditional Trans-Oral Inhalation

Allon, Raviv; Bhardwaj, Saurabh; Sznitman, Josué; Shoffel‐Havakuk, Hagit; Pinhas, Sapir; Zloczower, Elchanan; Shapira‐Galitz, Yael; Lahav, Yonatan

doi:10.3390/pharmaceutics15030903

Cited by 2 publications

(1 citation statement)

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“…Engineers and scientists have employed computational fluid dynamics (CFD) to study the airflow, transportation, and deposition (TD) of medicinal aerosols and particulate matter in polluted air through the complex pathways of the human respiratory system. − The number of numerical studies conducted on unhealthy lungs in comparison to healthy lungs is less in the existing literature. CFD can assist researchers in understanding the flow physics of unhealthy lungs and how aerosols move within them for better treatment of pulmonary diseases.…”

Section: Introductionmentioning

confidence: 99%

Optimal Treatment of Tumor in Upper Human Respiratory Tract Using Microaerosols

Riaz,

Munir,

Farooq

et al. 2024

ACS Omega

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Lung cancer is a frequently diagnosed respiratory disease caused by particulate matter in the environment, especially among older individuals. For its effective treatment, a promising approach involves administering drug particles through the inhalation route. Multiple studies have investigated the flow behavior of inhaled particles in the respiratory airways of healthy patients. However, the existing literature lacks studies on the precise understanding of the transportation and deposition (TD) of inhaled particles through age-specific, unhealthy respiratory tracts containing a tumor, which can potentially optimize lung cancer treatment. This study aims to investigate the TD of inhaled drug particles within a tumorous, age-specific human respiratory tract. The computational model reports that drug particles within the size range of 5–10 μm are inclined to deposit more on the tumor located in the upper airways of a 70-year-old lung. Conversely, for individuals aged 50 and 60 years, an optimal particle size range for achieving the highest degree of particle deposition onto upper airway tumor falls within the 11–20 μm range. Flow disturbances are found to be at a maximum in the airway downstream of the tumor. Additionally, the impact of varying inhalation flow rates on particle TD is examined. The obtained patterns of airflow distribution and deposition efficiency on the tumor wall for different ages and tumor locations in the upper tracheobronchial airways would be beneficial for developing an efficient and targeted drug delivery system.

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