Development of nitric oxide generators to produce high-dose nitric oxide for inhalation therapy

IF 3.2 2区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Nitric oxide : biology and chemistry Pub Date : 2023-09-01 DOI:10.1016/j.niox.2023.05.007

Binglan Yu , Hatus V. Wanderley , Stefano Gianni , Ryan W. Carroll , Fumito Ichinose , Warren M. Zapol , Lorenzo Berra

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引用次数: 0

Abstract

Background

Several nitric oxide (NO) generating devices have been developed to deliver NO between 1 part per million (ppm) and 80 ppm. Although inhalation of high-dose NO may exert antimicrobial effects, the feasibility and safety of producing high-dose (more than 100 ppm) NO remains to be established. In the current study, we designed, developed, and tested three high-dose NO generating devices.

Methods

We constructed three NO generating devices: a double spark plug NO generator, a high-pressure single spark plug NO generator, and a gliding arc NO generator. The NO and NO₂ concentrations were measured at different gas flows and under various atmospheric pressures. The double spark plug NO generator was designed to deliver gas through an oxygenator and mixing with pure oxygen. The high-pressure and gliding arc NO generators were used to deliver gas through a ventilator into artificial lungs to mimic delivering high-dose NO in the clinical settings. The energy consumption was measured and compared among the three NO generators.

Results

The double spark plug NO generator produced 200 ± 2 ppm (mean ± SD) of NO at gas flow of 8 L/min (or 320 ± 3 ppm at gas flow of 5 L/min) with electrode gap of 3 mm. The nitrogen dioxide (NO₂) levels were below 3.0 ± 0.1 ppm when mixing with various volumes of pure oxygen. The addition of a second generator increased the delivered NO from 80 (with one spark plug) to 200 ppm. With the high-pressure chamber, the NO concentration reached 407 ± 3 ppm with continuous air flow at 5 L/min when employing the 3 mm electrode gap under 2.0 atmospheric pressure (ATA). When compared to 1 ATA, NO production was increased 22% at 1.5 ATA and 34% at 2 ATA. The NO level was 180 ± 1 ppm when connecting the device to a ventilator with a constant inspiratory airflow of 15 L/min, and NO₂ levels were below 1 (0.93 ± 0.02) ppm. The gliding arc NO generator produced up to 180 ± 4 ppm of NO when connecting the device to a ventilator, and the NO₂ level was below 1 (0.91 ± 0.02) ppm in all testing conditions. The gliding arc device required more power (in watts) to generate the same concentrations of NO when compared to double spark plug or high-pressure NO generators.

Conclusions

Our results demonstrated that it is feasible to enhance NO production (more than 100 ppm) while maintaining NO₂ level relatively low (less than 3 ppm) with the three recently developed NO generating devices. Future studies might include these novel designs to deliver high doses of inhaled NO as an antimicrobial used to treat upper and lower respiratory tract infections.

查看原文本刊更多论文

开发一氧化氮发生器，生产用于吸入治疗的高剂量一氧化氮。

背景：已经开发了几种一氧化氮（NO）产生装置，可输送百万分之一（ppm）至80ppm之间的NO。尽管吸入高剂量NO可能产生抗菌作用，但产生高剂量（超过100ppm）NO的可行性和安全性仍有待确定。在目前的研究中，我们设计、开发并测试了三种高剂量NO产生装置。方法：我们构建了三个NO产生装置：双火花塞NO发生器、高压单火花塞NO发电机和滑动电弧NO发生器。在不同的气流和不同的大气压力下测量NO和NO2浓度。双火花塞NO发生器设计用于通过充氧器输送气体并与纯氧混合。高压和滑动电弧NO发生器用于通过呼吸机将气体输送到人工肺中，以模拟在临床环境中输送高剂量NO。测量并比较了三种NO发生器的能耗。结果：双火花塞NO发生器在8 L/min的气体流量下产生200±2ppm（平均值±SD）的NO（或在5 L/min的气体流速下产生320±3ppm），电极间隙为3mm。当与不同体积的纯氧混合时，二氧化氮（NO2）水平低于3.0±0.1 ppm。添加第二个发生器将输送的NO从80（带一个火花塞）增加到200 ppm。在高压室中，当在2.0大气压（ATA）下使用3mm电极间隙时，在5L/min的连续气流下，NO浓度达到407±3ppm。与1 ATA相比，1.5 ATA时NO产量增加了22%，2 ATA时增加了34%。当将设备连接到吸气流量为15 L/min的呼吸机时，NO水平为180±1 ppm，NO2水平低于1（0.93±0.02）ppm。将设备连接到呼吸机时，滑动电弧NO发生器产生高达180±4 ppm的NO，在所有测试条件下，NO2水平均低于1（0.91±0.02）ppm。与双火花塞或高压NO发生器相比，滑动电弧装置需要更多的功率（瓦特）才能产生相同浓度的NO。结论：我们的研究结果表明，使用三种最新开发的NO产生装置，在提高NO产生（超过100ppm）的同时保持相对较低的NO2水平（低于3ppm）是可行的。未来的研究可能包括这些新的设计，以提供高剂量的吸入NO作为用于治疗上呼吸道和下呼吸道感染的抗菌药物。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Nitric oxide : biology and chemistry 生物-生化与分子生物学

CiteScore

7.50

自引率

7.70%

发文量

审稿时长

52 days

期刊介绍： Nitric Oxide includes original research, methodology papers and reviews relating to nitric oxide and other gasotransmitters such as hydrogen sulfide and carbon monoxide. Special emphasis is placed on the biological chemistry, physiology, pharmacology, enzymology and pathological significance of these molecules in human health and disease. The journal also accepts manuscripts relating to plant and microbial studies involving these molecules.