高流量鼻导管治疗时增强的气溶胶输送。
Enhanced Aerosol Delivery During High-Flow Nasal Cannula Therapy.
机构信息
Pulmonary, Critical Care and Sleep Medicine Division, Department of Medicine, Stony Brook University Medical Center, Stony Brook, New York.
出版信息
Respir Care. 2023 Sep;68(9):1221-1228. doi: 10.4187/respcare.10644. Epub 2023 May 30.
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 Tc/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 Tc/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 (µg 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 µg NaCl/min, the vibrating mesh nebulizer delivered 23.5 to 61.7 µg NaCl/min. For infusion pump flows of 5 to 12 mL/h, the rate of drug delivery was independent of nebulizer type ( = .19) and dependent on infusion pump flow ( < .001) and gas flow ( < .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.
背景
通过高流量鼻导管(HFNC)输送的雾化药物随着气体流量的增加而减少。为了提高雾化输送效果,呼吸增强式射流雾化器可能会增加雾化输出。本研究通过模拟 HFNC 测试了这一假设,并比较了呼吸增强式射流雾化器和振动网孔雾化器技术。
方法
首先,在一个隔离回路中,使用注入的生理盐水溶液以 5-60 mL/h 的速率测量呼吸增强式射流雾化器和振动网孔雾化器在模拟 HFNC 期间的雾化输出。当检测到雾化器填充时,会定义限制。然后使用 Tc/生理盐水溶液测量最大雾化生产速率,对设备进行测试。在输出实验之后,通过使用由 HFNC 回路接口到现实的 3 维打印头的模型,进行体外药物输送测量。以 5 至 60 mL/h 的速率为呼吸增强式射流雾化器注入 Tc/生理盐水溶液,以 5 至 20 mL/h 的速率为振动网孔雾化器注入 Tc/生理盐水溶液,HFNC 气体流量为 10 至 60 L/min。使用屏蔽速率计测量到气管的雾化输送,定义药物输送速率(µg NaCl/min)。
结果
随着气体流量的增加,呼吸增强式射流雾化器的输出增加到最大 50 mL/h,振动网孔雾化器的最大输出为 12 mL/h。在 HFNC 气体流量为 60 L/min 时,呼吸增强式射流雾化器输送 3.16 至 316.8 µg NaCl/min,振动网孔雾化器输送 23.5 至 61.7 µg NaCl/min。对于输注泵流量为 5 至 12 mL/h,药物输送速率与雾化器类型无关(=.19),而与输注泵流量(<.001)和气体流量(<.001)有关。
结论
增加气体流量会增加呼吸增强式射流雾化器的输出,从而显示出呼吸增强的效果。在 60 L/min 时,与传统的振动网孔雾化器技术相比,呼吸增强式射流雾化器输送的雾化药物增加了 5 倍。在所有高流量下,呼吸增强式射流雾化器都能输送广泛的剂量率。在危重症患者中,呼吸增强式射流雾化器技术可以通过简单调整输注速度,根据临床反应来滴定床边给药剂量。
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