影响双水平气道正压通气氧输送的因素。
Factors affecting oxygen delivery with bi-level positive airway pressure.
作者信息
Schwartz Andrew R, Kacmarek Robert M, Hess Dean R
机构信息
Respiratory Care, Ellison 401, Massachusetts General Hospital, 55 Fruit Street, Boston, MA 02114, USA.
出版信息
Respir Care. 2004 Mar;49(3):270-5.
INTRODUCTION
Portable pressure ventilators, or bi-level ventilators, do not typically have an oxygen control, and thus supplemental oxygen is usually administered by adding it into the mask or the circuit. We conducted this study to test the hypothesis that delivered oxygen concentration using this configuration is affected by the choice of leak port, oxygen injection site, and ventilator settings.
METHODS
A lung model simulating spontaneous breathing was connected to the head of a manikin. An oronasal mask was attached to the manikin. A single-limb circuit was attached to the mask and a bi-level ventilator. Three leak ports were compared: leak in the mask, plateau exhalation valve with mask leak port occluded, and leak port in the circuit with mask leak port occluded. Bi-level positive airway pressure (BiPAP) settings of 10/5, 15/5, 20/5, 15/10, 20/10, and 25/10 cm H(2)O were used at respiratory rates of 15 and 25 breaths/min. Oxygen was added into the mask or into the circuit at the ventilator outlet, using flows of 5 and 10 L/min. Carbon dioxide was added into the lung model to produce an end-tidal P(CO(2)) of either 40 or 75 mm Hg.
RESULTS
Delivered oxygen concentration was not affected by respiratory rate (p = 0.22) or end-tidal P(CO(2)) (p = 0.74). The oxygen concentration was greater when oxygen was added into the circuit with the leak port in the mask (p < 0.001), whereas oxygen concentration was greater when oxygen was added into the mask with the leak port in circuit (p = 0.005). Oxygen concentration was significantly lower with the leak port in the mask (p < 0.001), with a higher inspiratory positive airway pressure (p < 0.001), and with a higher expiratory positive airway pressure (p < 0.001). The highest oxygen concentration was achieved with oxygen added to the mask, with the leak port in the circuit, and with the lowest settings of inspiratory (10 cm H(2)O) and expiratory (5 cm H(2)O) positive airway pressure.
CONCLUSIONS
Delivered oxygen concentration during BiPAP is a complex interaction between the leak port type, the site of oxygen injection, the ventilator settings, and the oxygen flow. Because of this, it is important to continuously measure arterial oxygen saturation via pulse oximetry with patients in acute respiratory failure who are receiving noninvasive ventilation from a bi-level ventilator.
引言
便携式压力通气机,即双水平通气机,通常没有氧气控制装置,因此通常通过将氧气添加到面罩或回路中来给予补充氧气。我们进行了这项研究,以检验以下假设:使用这种配置时,输送的氧气浓度受泄漏口选择、氧气注入部位和通气机设置的影响。
方法
将模拟自主呼吸的肺模型连接到人体模型头部。在人体模型上连接口鼻面罩。将单肢回路连接到面罩和双水平通气机。比较了三个泄漏口:面罩泄漏、阻塞面罩泄漏口的平台呼气阀以及阻塞面罩泄漏口的回路中的泄漏口。在呼吸频率为15次/分钟和25次/分钟时,使用10/5、15/5、20/5、15/10、20/10和25/10厘米水柱的双水平气道正压(BiPAP)设置。以5升/分钟和10升/分钟的流量将氧气添加到面罩或通气机出口处的回路中。向肺模型中添加二氧化碳,以使呼气末P(CO₂)达到40或75毫米汞柱。
结果
输送的氧气浓度不受呼吸频率(p = 0.22)或呼气末P(CO₂)(p = 0.74)的影响。当氧气添加到面罩泄漏口位于回路中的回路中时,氧气浓度更高(p < 0.001),而当氧气添加到回路泄漏口位于面罩中的面罩中时,氧气浓度更高(p = 0.005)。当泄漏口位于面罩中时,氧气浓度显著降低(p < 0.001),吸气气道正压较高时(p < 0.001),呼气气道正压较高时(p < 0.001)。当氧气添加到面罩中、泄漏口位于回路中且吸气(10厘米水柱)和呼气(5厘米水柱)气道正压设置最低时,氧气浓度最高。
结论
BiPAP期间输送的氧气浓度是泄漏口类型、氧气注入部位、通气机设置和氧气流量之间的复杂相互作用。因此,对于接受双水平通气机无创通气的急性呼吸衰竭患者,通过脉搏血氧饱和度仪持续测量动脉血氧饱和度非常重要。
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