在比较两种振荡器的高频振荡模型中,空气和氦氧混合气作为载气对二氧化碳传输的影响。
Effect of air and heliox as carrier gas on CO2 transport in a model of high-frequency oscillation comparing two oscillators.
作者信息
Mildner Reinout J, Frndova Helena, Cox Peter N
机构信息
Department of Critical Care Medicine, The Hospital for Sick Children, 555 University Avenue, Toronto, Ontario, Canada M5G 1X8.
出版信息
Crit Care Med. 2003 Jun;31(6):1759-63. doi: 10.1097/01.CCM.0000063048.52246.43.
OBJECTIVE
To study the effect of carrier gas on CO(2) transport during high-frequency oscillatory ventilation in a closed model.
DESIGN
In vitro model study.
SETTING
Respiratory research laboratory affiliated with a tertiary center for pediatric critical care.
SUBJECT
In vitro, closed-lung model consisting of a glass tube (9.8 x 1000 mm) covered at each end with balloons.
INTERVENTION
Air or heliox (80:20) at constant pressure was oscillated inside the model, comparing the Sensormedics 3100A and Hummingbird BMO-20N oscillators at equal amplitude.
MEASUREMENTS AND MAIN RESULTS
Tracer gas (CO(2)) was injected at one end of the model, and CO(2) concentration was measured at the opposite end. Speed of CO(2) transport was expressed as the time for the CO(2) concentration to reach 63% of the final concentration (the time constant). In room air, using the Hummingbird oscillator and increasing frequency stepwise from 5 to 20 Hz, the time constant decreased from 2813 to 457 secs (p =.05). Using the Sensormedics oscillator in room air at increasing frequency from 5 to 15 Hz, the time constant decreased from 1584 to 551 secs (p =.05). In heliox, using the Hummingbird oscillator, the speed of CO(2) transport increased by 85% (p =.029) at 5 Hz and by 28% (p =.05) at 15 Hz. With the Sensormedics oscillator using heliox, the speed of CO(2) transport increased by 16% at 5 Hz (p =.009) and 52% at 15 Hz (p =.008). Proportionally, the increase in CO(2) transport with heliox was greater at 5 Hz for the Hummingbird oscillator and at 15 Hz for the Sensormedics oscillator.
CONCLUSIONS
In a closed model, we showed that during high-frequency oscillatory ventilation in room air, CO(2) transport increases with increasing frequency for both ventilators. Using heliox as carrier gas significantly augmented CO(2) transport, but the increase is frequency and device dependent. The effect of heliox on oscillator performance and the clinical applicability of our findings require further study.
目的
在封闭模型中研究载气对高频振荡通气期间二氧化碳(CO₂)转运的影响。
设计
体外模型研究。
设置
隶属于三级儿科重症监护中心的呼吸研究实验室。
研究对象
体外封闭肺模型,由一根玻璃管(9.8×1000毫米)组成,两端各覆盖一个气球。
干预措施
在模型内部以恒定压力振荡空气或氦氧混合气(80:20),比较Sensormedics 3100A和蜂鸟BMO - 20N振荡器在相同振幅下的情况。
测量指标及主要结果
在模型一端注入示踪气体(CO₂),并在另一端测量CO₂浓度。CO₂转运速度以CO₂浓度达到最终浓度的63%所需时间(时间常数)表示。在室内空气中,使用蜂鸟振荡器并将频率从5Hz逐步增加到20Hz,时间常数从2813秒降至457秒(p = 0.05)。在室内空气中使用Sensormedics振荡器,频率从5Hz增加到15Hz时,时间常数从1584秒降至551秒(p = 0.05)。在氦氧混合气中,使用蜂鸟振荡器,CO₂转运速度在5Hz时增加85%(p = 0.029),在15Hz时增加28%(p = 0.05)。使用Sensormedics振荡器并采用氦氧混合气时,CO₂转运速度在5Hz时增加16%(p = 0.009),在15Hz时增加52%(p = 0.008)。按比例而言,对于蜂鸟振荡器,氦氧混合气在5Hz时使CO₂转运增加的幅度更大;对于Sensormedics振荡器,氦氧混合气在15Hz时使CO₂转运增加的幅度更大。
结论
在封闭模型中,我们发现,在室内空气中进行高频振荡通气时,两种通气机的CO₂转运均随频率增加而增加。使用氦氧混合气作为载气可显著增强CO₂转运,但增加幅度取决于频率和设备。氦氧混合气对振荡器性能的影响以及我们研究结果的临床适用性需要进一步研究。
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