呼气端口的位置和面罩设计会影响无创正压通气期间的二氧化碳重复吸入。

Position of exhalation port and mask design affect CO2 rebreathing during noninvasive positive pressure ventilation.

作者信息

Schettino Guilherme P P, Chatmongkolchart Sunisa, Hess Dean R, Kacmarek Robert M

机构信息

Department of Anesthesia and Critical Care and Respiratory Care, Massachusetts General Hospital, Harvard Medical School, Boston, 02214, USA.

出版信息

Crit Care Med. 2003 Aug;31(8):2178-82. doi: 10.1097/01.CCM.0000081309.71887.E9.

DOI:10.1097/01.CCM.0000081309.71887.E9

PMID:12973177

Abstract

OBJECTIVE

Noninvasive positive pressure ventilation may be considered a first line intervention to treat patients with hypercapnic respiratory failure. However, CO2 rebreathing from the ventilator circuit or mask may impair CO2 elimination and load the ventilatory muscles. This study was conducted to evaluate the effect of exhalation port location and mask design on CO2 rebreathing during noninvasive positive pressure ventilation.

DESIGN

Lung model evaluation.

SETTING

Experimental laboratory of a large university-affiliated hospital.

SUBJECTS

A dual-chamber test lung was used to simulate the ventilatory mechanics of a patient with obstructive lung disease.

INTERVENTION

Hypercapnic respiratory failure (end-tidal CO2 of 75 mm Hg) and obstructive lung disease were simulated in a double-chamber lung model. A facial mask (inner volume of 165 mL) with exhalation port within the mask (Facial-MEP) or the same mask with exhalation port in the ventilator circuit (Facial-WS) and a total face mask with exhalation port within the mask (inner volume 875 mL, Total Face) were tested during continuous positive airway pressure and pressure support ventilation provided by a single-limb circuit ventilator at the same frequency and tidal volume.

MEASUREMENTS AND MAIN RESULTS

A capnometer and a flow transducer were placed in the lung model upper airway to measure the volume of CO2 rebreathed and tidal volume (Vt). The inspiratory load was estimated from the pressure variation in the lung model driving chamber (PDR). Volume of CO2 rebreathed was smaller during Facial-MEP compared with the other masks in all tested conditions (p <.001). The Vt and PDR necessary to decrease end-tidal CO2 20% (from 75 to 60 mm Hg) was different among the tested masks (Facial-MEP, Vt 701 +/- 9 mL, PDR 8.1 +/- 0.1 cm H2O/sec; Facial-WS, Vt 745 +/- 9 mL, PDR 10.2 +/- 0.1 cm H2O/sec; Total Face, Vt 790 +/- 12 mL, PDR 11.4 +/- 0.2 cm H2O/sec, p <.001).

CONCLUSION

Facial-MEP with its exhalation port within the mask and the smallest mask volume demonstrated less rebreathed CO2 and a lower PDR than either the Facial-WS or Total Face masks. Additional studies are necessary to confirm if mask design can clinically affect patient's inspiratory effort during noninvasive positive pressure ventilation.

摘要

目的

无创正压通气可被视为治疗高碳酸血症性呼吸衰竭患者的一线干预措施。然而，呼吸机回路或面罩中的二氧化碳重复吸入可能会损害二氧化碳的排出，并增加呼吸肌的负担。本研究旨在评估呼气口位置和面罩设计对无创正压通气期间二氧化碳重复吸入的影响。

设计

肺模型评估。

设置

大型大学附属医院的实验实验室。

研究对象

使用双腔测试肺来模拟阻塞性肺疾病患者的通气力学。

干预措施

在双腔肺模型中模拟高碳酸血症性呼吸衰竭（呼气末二氧化碳分压为75mmHg）和阻塞性肺疾病。在单回路呼吸机以相同频率和潮气量提供持续气道正压通气和压力支持通气期间，测试了面罩内部有呼气口的面罩（面罩-平均呼气压力，内部容积165mL）、呼气口在呼吸机回路中的相同面罩（面罩-湿化系统）以及面罩内部有呼气口的全面罩（内部容积875mL）。

测量指标和主要结果

在肺模型上气道放置二氧化碳分析仪和流量传感器，以测量重复吸入的二氧化碳量和潮气量（Vt）。根据肺模型驱动腔的压力变化（PDR）估算吸气负荷。在所有测试条件下，与其他面罩相比，面罩-平均呼气压力期间重复吸入的二氧化碳量较少（p<.001）。不同测试面罩降低呼气末二氧化碳20%（从75降至60mmHg）所需的Vt和PDR不同（面罩-平均呼气压力，Vt 701±9mL，PDR 8.1±0.1cmH₂O/秒；面罩-湿化系统，Vt 745±9mL，PDR 10.2±0.1cmH₂O/秒；全面罩，Vt 790±12mL，PDR 11.4±0.2cmH₂O/秒，p<.001）。