Objective: On the basis of preliminarily verifying the use of ultra-fast reaction polymer matrix optical fiber oxygen sensor and its measuring system to record the continuous and dynamic changes of carotid artery oxygen partial pressure (PaO2), in order to analyze and discuss the influence of lung ventilation on the continuous and dynamic changes of PaO2, we designed a whole animal experimental study in vivo. Methods: Four hybrid goats were selected, and the skin was cut and exposed directly under general anesthesia and tracheal intubation. The oxygen sensor, connected with the measuring system, was inserted directly into the left carotid artery to continuously record the dynamic changes of PaO2. With normal minute ventilation,mechanical ventilation is implemented through three tidal volumes: normal tidal volume (VT=15 ml/kg, Rf=20 bpm), half tidal volume (halved VT, doubled Rf) and double tidal volume (doubled VT, halved Rf). Each tidal volume was stable for 10~15 min respectively. We analyzed and calculated the average values of PaO2, the fluctuation magnitudes of PaO2 changes between breaths of last 180 s and the delay times of lung-carotid artery were. We analyzed the effects of different tidal volumes. Results: The heart rate and blood pressure of living goats were maintained stable during the mechanical ventilation experiment with normal ventilation volume Lung-carotid artery delay time is 1.4~1.8 s (about 3 heartbeats at this time). Under normal tidal volume of mechanical ventilation, the average value of PaO2 was (102.94±2.40, 99.38~106.16) mmHg, and the fluctuation range was (21.43±1.65, 19.21~23.59) mmHg, accounting for (20.80± 1.34, 18.65~22.22)% of the average value. Under the condition of halving tidal volume, the average value of PaO2 was maintained at (101.01±4.25, 94.09~105.66) mmHg, which was slightly decreased but not significant (P>0.05 compared with normal mechanical ventilation), but the fluctuation range of PaO2 was significantly reduced to (18.14±1.43, 16.46~20.05) mmHg, accounting for 17.5% of the average value. Under double tidal volume mechanical ventilation, although the average value of PaO2 increased slightly remained at (106.42±4.74, 101.19~114.08) mmHg (P>0.05 compared with normal mechanical ventilation and P<0.05 compared with half tidal volume mechanical ventilation), the fluctuation magnitude of PaO2 increased significantly to (26.58±1.88, 23.46~28.46)mmHg. Conclusion: Inspiration and expiration of normal lung ventilation are the initial factors for the increase and decrease of PaO2 in carotid artery. Under normal ventilation, halving tidal volume and doubling tidal volume significantly changed the fluctuation magnitude of PaO2, but the average value of PaO2 changed only slightly, while the lung-carotid delay time was similar.
目的: 在初步验证超快反应聚合物基质光纤氧传感器及其测定系统记录颈动脉氧分压(PaO2)连续动态变化使用基础上,为了分析探讨肺通气对PaO2连续动态变化的影响,我们设计本活体整体动物实验观察研究。方法: 选择杂种山羊4只,全身麻醉气管插管空气机械通气下,切皮直接暴露把后接测定系统的氧传感器直接插入左侧颈动脉连续记录PaO2动态变化。正常分钟通气量机械通气分别通过三种潮气量实施:正常潮气量(潮气量VT=15 ml/kg、呼吸频率Rf=20 bpm)、减半潮气量(VT减半、Rf加倍)和加倍潮气量(VT加倍、Rf减半)。三种潮气量通气时间分别稳定10~15 min,选取后180 s分析计算PaO2平均值、呼吸间PaO2变化的升降幅度和肺-颈动脉延迟时间。以ANOVA及两两比较统计学差异分析不同潮气量的影响。结果: 活体山羊正常通气量机械通气实验时心率和血压均稳定;肺-颈动脉延迟时间为1.4~1.8 s(约为此时的3次心跳)。机械通气正常潮气量下PaO2平均值在(102.94±2.40,99.38~106.16)mmHg,升降幅度是(21.43±1.65,19.21~23.59)mmHg,占平均值的(20.80±1.34,18.65~22.22)%;减半潮气量下,PaO2平均值维持在(101.01±4.25,94.09~105.66)mmHg,虽略降但不显著(与正常机械通气比较P>0.05),但PaO2升降变化幅度却显著降低为(18.14±1.43,16.46~20.05) mmHg,占平均值的(17.95±1.07,16.16~18.98)%(与正常机械通气比较P<0.01);加倍潮气量机械通气下,虽仅略升的PaO2平均值维持在(106.42±4.74,101.19~114.08)mmHg(与正常机械通气比较P>0.05,与减半潮气量机械通气比较P<0.05),但PaO2升降幅度却显著增大为(26.58±1.88,23.46~28.46)mmHg,占平均值的24.99%±1.58%(与正常机械通气和减半潮气量比较P均<0.01)。结论: 正常肺通气的吸气和呼气是颈动脉PaO2上升和下降的始动因素。正常通气量机械通气下减半潮气量和倍增潮气量显著改变PaO2升降幅度,但PaO2平均值仅小幅改变,而肺-颈动脉延迟时间相近。.
Keywords: fluctuation magnitude of arterial oxygen partial pressure; holistic integrative physiology and medicine; living goat; lung-carotid artery time delay; mean arterial oxygen partial pressure; oxygen partial pressure in carotid artery; respiratory control and regulation; tidal volume; ultra-fast reaction polymer optical fiber oxygen sensor.