Delivery of Agarose-aided Sprays to the Posterior Nose for Mucosa Immunization and Short-term Protection Against Infectious Respiratory Diseases

Overview

Journal Curr Pharm Biotechnol

Publisher Bentham Science Publishers

Specialties Biotechnology
Pharmacology

Date 2023 Aug 3

PMID 37533243

Authors

Amr Seifelnasr

Mohamed Talaat

Xiuhua April Si

Jinxiang Xi

Affiliations

Soon will be listed here.

Abstract

Aim: The study aimed to deliver sprays to the posterior nose for mucosa immunization or short-term protection.

Background: Respiratory infectious diseases often enter the human body through the nose. Sars- Cov-2 virus preferentially binds to the ACE2-rich tissue cells in the Nasopharynx (NP). Delivering medications to the nose, especially to the NP region, provides either a short-term protective/ therapeutic layer or long-term mucosa immunization. Hydrogel-aided medications can assist film formation, prolong film life, and control drug release. However, conventional nasal sprays have failed to dispense mediations to the posterior nose, with most sprays lost in the nasal valve and front turbinate.

Objective: The objective of the study was to develop a practical delivery system targeting the posterior nose and quantify the dosimetry distribution of agarose-saline solutions in the nasal cavity.

Methods: The solution viscosities with various hydrogel concentrations (0.1-1%) were measured at different temperatures. Dripping tests on a vertical plate were conducted to understand the hydrogel concentration effects on the liquid film stability and mobility. Transparent nasal airway models were used to visualize the nasal spray deposition and liquid film translocation.

Results: Spray dosimetry with different hydrogel concentrations and inhalation flow rates was quantified on a total and regional basis. The solution viscosity increased with decreasing temperature, particularly in the range of 60-40oC. The liquid viscosity, nasal spray atomization, and liquid film mobility were highly sensitive to the hydrogel concentration. Liquid film translocations significantly enhanced delivered doses to the caudal turbinate and nasopharynx when the sprays were administered at 60oC under an inhalation flow rate of 11 L/min with hydrogel concentrations no more than 0.5%. On the other hand, sprays with 1% hydrogel or administered at 40oC would significantly compromise the delivered doses to the posterior nose.

Conclusion: Delivering sufficient doses of hydrogel sprays to the posterior nose is feasible by leveraging the post-administration liquid film translocation.

Citing Articles

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Effects of Nozzle Retraction Elimination on Spray Distribution in Middle-Posterior Turbinate Regions: A Comparative Study.

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Verma S, Sharma P, Malviya R, Das S Curr Pharm Biotechnol. 2024; 25(15):1939-1951.

PMID: 38251702 DOI: 10.2174/0113892010275613231120031855.

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