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Pulmonary Therapy
Published in: Pulmonary Therapy 2/2020

Open Access 01-12-2020 | Tiotropium | Original Research

In Vitro Effect of Different Airflow Rates on the Aerosol Properties of Nebulized Glycopyrrolate in the eFlow® Closed System and Tiotropium Delivered in the HandiHaler®

Authors: Jill A. Ohar, Andrea Bauer, Sanjay Sharma, Shahin Sanjar

Published in: Pulmonary Therapy | Issue 2/2020

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Abstract

Introduction

Personalized therapy for patients with COPD requires appropriate choice of drug and delivery device. Inhalers and nebulizers vary in their drug delivery characteristics, particularly the need for passive or active patient inhalation for appropriate drug dispersal and delivery. In this in vitro analysis, we assessed the aerosol performance and drug delivery of two long-acting muscarinic antagonists, glycopyrrolate (GLY; 25 µg solution; 1 ml) and tiotropium (TIO; 18 µg powder) through their respective delivery systems: the eFlow® Closed System (CS) vibrating membrane nebulizer and the HandiHaler® dry-powder inhaler (DPI).

Methods

The aerosol performances of the eFlow® CS nebulizer and the HandiHaler® were determined using the Next Generation cascade Impactor. The delivered dose of GLY and TIO was determined using different breathing patterns, which varied in tidal volume and peak inspiratory flow rate, respectively, to simulate breathing conditions ranging from normal to severe obstruction.

Results

Aerodynamic particle analysis showed generally similar mass median aerodynamic diameter (MMAD, range, 3.6–4.6 µm) and fine particle fraction (FPF, range, 48.2%–63.7%) with GLY delivered using the eFlow® CS nebulizer under all breathing patterns tested. TIO, delivered via the HandiHaler®, showed variations in MMAD (range, 3.8–5.8 µm) and FPF (range, 16.1%–32.4%) under different inspiratory flow rates. The majority of GLY was deposited in stages 2–5 of the impactor, which corresponds with particle sizes in the respirable range (< 5 µm), whereas a large proportion of TIO was deposited in the throat/mouthpiece pre-separator, irrespective of test conditions. The median residual dose of GLY with eFlow® CS was notably lower compared to that of TIO with HandiHaler® (2.4%–4.4% vs. 40%–67%, respectively).

Conclusions

These simulation results highlight the different deposition patterns generated by a DPI device and a vibrating membrane nebulizer, which may help inform device selection and treatment decision in COPD management.
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Metadata
Title
In Vitro Effect of Different Airflow Rates on the Aerosol Properties of Nebulized Glycopyrrolate in the eFlow® Closed System and Tiotropium Delivered in the HandiHaler®
Authors
Jill A. Ohar
Andrea Bauer
Sanjay Sharma
Shahin Sanjar
Publication date
01-12-2020
Publisher
Springer Healthcare
Published in
Pulmonary Therapy / Issue 2/2020
Print ISSN: 2364-1754
Electronic ISSN: 2364-1746
DOI
https://doi.org/10.1007/s41030-020-00125-6

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WHO estimates that half of all patients worldwide are non-adherent to their prescribed medication. The consequences of poor adherence can be catastrophic, on both the individual and population level.

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