In Vitro Model for Analysis of High-Flow Aerosol Delivery During Continuous Nebulization

Michael McPeck; Jane Moon; Jeyanthan Jayakumaran; Gerald C Smaldone

doi:10.4187/respcare.10643

In Vitro Model for Analysis of High-Flow Aerosol Delivery During Continuous Nebulization

Respir Care. 2023 Sep;68(9):1213-1220. doi: 10.4187/respcare.10643. Epub 2023 May 30.

Authors

Michael McPeck¹, Jane Moon¹, Jeyanthan Jayakumaran¹, Gerald C Smaldone²

Affiliations

¹ Pulmonary, Critical Care and Sleep Medicine Division, Department of Medicine, Stony Brook University Medical Center, Stony Brook, New York.
² Pulmonary, Critical Care and Sleep Medicine Division, Department of Medicine, Stony Brook University Medical Center, Stony Brook, New York. gerald.smaldone@stonybrook.edu.

PMID: 37253606
PMCID: PMC10468165 (available on 2024-09-01)
DOI: 10.4187/respcare.10643

Abstract

Background: To understand the fate of aerosols delivered by high-flow nasal cannula using continuous nebulization, an open-source anatomical model was developed and validated with a modified real-time gamma ratemeter technique. Mass balance defined circuit losses. Responsiveness to infusion rate and device technology were tested.

Methods: A nasal airway cast derived from a computed tomography scan was converted to a 3-dimensional-printed head and face structure connected to a piston ventilator (breathing frequency 30 breaths/min, tidal volume 750 mL, duty cycle 0.50). For mass balance experiments, saline mixed with Technetium-99m was infused for 1 h. Aerosol delivery was measured using a gamma ratemeter oriented to an inhaled mass filter at the hypopharynx of the model. Background and dead-space effects were minimized. All components were imaged by scintigraphy. Continuous nebulization was tested at infusion rates of 10-40 mL/h with gas flow of 60 L/min using a breath-enhanced jet nebulizer (BEJN), and a vibrating mesh nebulizer. Drug delivery rates were defined by the slope of ratemeter counts/min (CPM/min) versus time (min).

Results: The major source of aerosol loss was at the nasal interface (∼25%). Significant differences in deposition on circuit components were seen between nebulizers. The nebulizer residual was higher for BEJN (P = .006), and circuit losses, including the humidifier, were higher for vibrating mesh nebulizer (P = .006). There were no differences in delivery to the filter and head model. For 60 L/min gas flow, as infusion pump flow was increased, the rate of aerosol delivery (CPM/min) increased, for BEJN from 338 to 8,111; for vibrating mesh nebulizer, maximum delivery was 2,828.

Conclusions: The model defined sites of aerosol losses during continuous nebulization and provided a realistic in vitro system for testing aerosol delivery during continuous nebulization. Real-time analysis can quantify effects of multiple changes in variables (nebulizer technology, infusion rate, gas flow, and ventilation) during a given experiment.

Keywords: aerosol; continuous nebulization; high-flow nasal cannula; nasal deposition.

MeSH terms

Administration, Inhalation
Aerosols
Albuterol*
Bronchodilator Agents*
Drug Delivery Systems
Equipment Design
Humans
Nebulizers and Vaporizers

Substances

Bronchodilator Agents
Albuterol
Aerosols