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Abstract

BACKGROUND:

Aerosolized drug delivery via high-flow nasal cannula (HFNC) decreases as gas flow is increased. To improve aerosol delivery, breath-enhanced jet nebulizer may increase aerosol output. This study tested that hypothesis and compared breath-enhanced jet nebulizer to vibrating mesh nebulizer technology.

METHODS:

First, in an isolated circuit, breath-enhanced jet nebulizer and vibrating mesh nebulizer aerosol outputs were measured during simulated HFNC by using infused saline solution at rates of 5–60 mL/h. Limits were defined when nebulizer filling was detected. The devices were then tested by using ^99mTc/saline solution to measure maximum rates of aerosol production. After the output experiments, drug delivery was measured in vitro by using a model that consisted of an HFNC circuit interfaced to a realistic 3-dimensional printed head. The ^99mTc/saline solution was infused at rates of 5 to 60 mL/h for the breath-enhanced jet nebulizer and 5 to 20 mL/h for the vibrating mesh nebulizer with HFNC gas flows of 10 to 60 L/min. Aerosol delivery to the trachea was measured by using a shielded ratemeter, which defined the rate of drug delivery ( $µ$ g NaCl/min).

RESULTS:

With increasing gas flow, breath-enhanced jet nebulizer output increased to a maximum of 50 mL/h, the vibrating mesh nebulizer maximum was 12 mL/h. At HFNC gas flow of 60 L/min, breath-enhanced jet nebulizer delivered 3.16 to 316.8 $µ$ g NaCl/min, the vibrating mesh nebulizer delivered 23.5 to 61.7 $µ$ g NaCl/min. For infusion pump flows of 5 to 12 mL/h, the rate of drug delivery was independent of nebulizer type (P = .19) and dependent on infusion pump flow (P < .001) and gas flow (P < .001).

CONCLUSIONS:

Increasing gas flow increased breath-enhanced jet nebulizer output, which demonstrated the effects of breath enhancement. At 60 L/min, breath enhanced jet nebulizer delivered up to 5 times more aerosol compared with conventional vibrating mesh nebulizer technology. Breath-enhanced jet nebulizer delivered a wide range of dose rates at all high flows. In patients who are critically ill, breath-enhanced jet nebulizer technology may allow titration of bedside dosing based on clinical response by simple adjustment of the infusion rate.

Keywords

High flow nasal cannula continuous infusion aerosol nebulizer

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References

Spoletini

, Alotaibi

, Blasi

, Hill

. Heated humidified high-flow nasal oxygen in adults: mechanisms of action and clinical implications. Chest, 2015; 148(1):253–261.

Chiles

III , Vijaykumar

, Darby

, Goetz

, Kane

, Methukupally

, et al. Letter to the editor: “use of inhaled epoprostenol with high flow nasal oxygen in non-intubated patients with severe COVID-19.”. J Crit Care, 2022; 69:153989.

Drake

. High-flow nasal cannula oxygen in adults: an evidence-based assessment. Ann Am Thorac Soc, 2018; 15(2):145–155.

Réminiac

, Vecellio

, Heuzé-Vourc'h

, Petitcollin

, Respaud

, Cabrera

, et al. Aerosol therapy in adults receiving high flow nasal cannula oxygen therapy. J Aerosol Med Pulm Drug Deliv, 2016; 29(2):134–141.

Bennett

, Joyce

, Sweeney

, MacLoughlin

. In vitro determination of the main effects in the design of high-flow nasal therapy systems with respect to aerosol performance. Pulm Ther, 2018; 4(1):73–86.

Reminiac

, Vecellio

, Bodet-Contentin

, Gissot

, Le Pennec

, Salmon

, et al. Nasal high-flow bronchodilator nebulization: a randomized cross-over study. Ann Intensive Care, 2018; 8(1):128.

Dugernier

, Hesse

, Vanbever

, Depoortere

, Roeseler

, Michotte

J-B

, et al. SPECT-CT comparison of lung deposition using a system combining a vibrating-mesh nebulizer with a valved holding chamber and a conventional jet nebulizer: a randomized cross-over study. Pharm Res, 2017; 34(2):290–300.

Dugernier

, Reychler

, Vecellio

, Ehrmann

. Nasal high-flow nebulization for lung drug delivery: theoretical, experimental, and clinical application. J Aerosol Med Pulm Drug Deliv, 2019; 32(6):341–351.

McPeck

, Moon

, Jayakumaran

, Smaldone

. In vitro model for analysis of high-flow aerosol delivery during continuous nebulization. Respir Care, 2023; 68(9):1213–1220.

10.

Bennett

, Joyce

, Sweeney

, MacLoughlin

. In vitro study of the effect of breathing pattern on aerosol delivery during high-flow nasal therapy. Pulm Ther, 2019; 5(1):43–54.

11.

Smaldone

, Solomita

. Predicting in vivo deposition in vitro. J Aerosol Med Pulm Drug Deliv, 2009; 22(1):9–10.

12.

McPeck

, Smaldone

. Continuous infusion aerosol delivery of prostacyclins during mechanical ventilation: challenges, limitations, and recent advances. Expert Opin Drug Deliv, 2022; 19(5):465–474.

13.

, Augustynovich

, Gurnani

, Fink

. In-vitro and in-vivo comparisons of high versus low concentrations of inhaled epoprostenol to adult intubated patients. Respir Res, 2021; 22(1):231.

14.

Anderson

, Dubosky

, Fiorino

, Quintana

, Kaplan

, Vines

. The effect of nebulizer position on aerosolized epoprostenol delivery in an adult lung model. Respir Care, 2017; 62(11):1387–1395.

Enhanced Aerosol Delivery During High-Flow Nasal Cannula Therapy

Abstract

BACKGROUND:

METHODS:

RESULTS:

CONCLUSIONS:

Keywords

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References