Primary break-up and atomization characteristics of a nasal spray.

Kendra Shrestha,Kiao Inthavong,James Van Strien,Narinder Singh,Josué Sznitman

doi:10.1371/journal.pone.0236063

Kendra Shrestha, Kiao Inthavong + Show 3 more

Open Access

https://doi.org/10.1371/journal.pone.0236063

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Journal: PloS one	Publication Date: Aug 5, 2020
Citations: 19	License type: CC BY 4.0

Affiliation: RMIT University, Westmead Hospital, University of Sydney

Abstract

The primary objective of this research was to extract the essential information needed for setting atomization break up models, specifically, the Linear Instability Sheet Atomization (LISA) breakup model, and alternative hollow cone models. A secondary objective was to gain visualization and insight into the atomization break up mechanism caused by the effects of viscosity and surface tension on primary break-up, sheet disintegration, ligament and droplet formation. High speed imaging was used to capture the near-nozzle characteristics for water and drug formulations. This demonstrated more rapid atomization for lower viscosities. Image processing was used to analyze the near-nozzle spray characteristics during the primary break-up of the liquid sheet into ligament formation. Edges of the liquid sheet, spray break-up length, break-up radius, cone angle and dispersion angle were obtained. Spray characteristics pertinent for primary breakup modelling were determined from high speed imaging of multiple spray actuations. The results have established input data for computational modelling involving parametrical analysis of nasal drug delivery.

Highlights

Nasal sprays are commonly used to treat conditions such as nasal congestion and allergic rhinitis
The primary objective of this study was to extract the essential information from spray atomization using high speed filming, that is needed for setting atomization break up models
There is a clear difference in penetration length of the liquid sheet between the drug formulation and water as the liquid ejects from the nozzle with high momentum to overcome the surface tension

Summary

Introduction

Nasal sprays are commonly used to treat conditions such as nasal congestion and allergic rhinitis They are used as an alternate route of administration for systemic therapy in place of intravenous and oral routes. Droplet formation occurs due to instabilities in the liquid sheet produced from competing forces between fluid inertia and surface tension (characterized by the Weber number and nozzle geometry).

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