Expiratory flow-limitation in mechanically ventilated patients: A risk for ventilator-induced lung injury?

Expiratory flow limitation(EFL), that is the inability of expiratory flow to increase in spite of an increase of the driving pressure, is a common and unrecognized occurrence during mechanical ventilation in a variety of intensive care unit conditions. Recent evidence suggests that the presence of EFL is associated with an increase in mortality, at least in acute respiratory distress syndrome(ARDS) patients, and in pulmonary complications in patients undergoing surgery. EFL is a major cause of intrinsic positive end-expiratory pressure(PEEPi), which in ARDS patients is heterogeneously distributed, with a consequent increase of ventilation/perfusion mismatch and reduction of arterial oxygenation. Airway collapse is frequently concomitant to the presence of EFL.When airways close and reopen during tidal ventilation, abnormally high stresses are generated that can damage the bronchiolar epithelium and uncouple small airways from the alveolar septa, possibly generating the small airways abnormalities detected at autopsy in ARDS. Finally, the high stresses and airway distortion generated downstream the choke points may contribute to parenchymal injury, but this possibility is still unproven. PEEP application can abolish EFL, decrease PEEPi heterogeneity, and limit recruitment/derecruitment.Whether increasing PEEP up to EFL disappearance is a useful criterion for PEEP titration can only be determined by future studies.

Effects of dynamic ventilatory factors on ventilatorinduced lung injury in acute respiratory distress syndrome dogs

BACKGROUND:Mechanical ventilation is a double-edged sword to acute respiratory distress syndrome(ARDS) including lung injury,and systemic inflammatory response high tidal volumes are thought to increase mortality.The objective of this study is to evaluate the effects of dynamic ventilatory factors on ventilator induced lung injury in a dog model of ARDS induced by hydrochloric acid instillation under volume controlled ventilation and to investigate the relationship between the dynamic factors and ventilator-induced lung injuries(VILI) and to explore its potential mechanisms.METHODS:Thirty-six healthy dogs were randomly divided into a control group and an experimental group.Subjects in the experimental group were then further divided into four groups by different inspiratory stages of flow.Two mL of alveolar fluid was aspirated for detection of IL-8 and TNF-α.Lung tissue specimens were also extracted for total RNA,IL-8 by western blot and observed under an electronic microscope.RESULTS:IL-8 protein expression was significantly higher in group B than in groups A and D.Although the IL-8 protein expression was decreased in group C compared with group B,the difference was not statistically significant.The TNF-α ray degree of group B was significantly higher than that in the other groups(P<0.01),especially in group C(P>0.05).The alveolar volume of subjects in group B was significantly smaller,and cavity infiltration and cell autolysis were marked with a significant thicker alveolar septa,disorder of interval structures,and blurring of collagenous and elastic fiber structures.A large number of necrotic debris tissue was observed in group B.CONCLUSION:Mechanical ventilation with a large tidal volume,a high inspiratory flow and a high ventilation frequency can cause significant damage to lung tissue structure.It can significantly increase the expression of TNF-α and IL-8 as well as their mRNA expression.Furthermore,the results of our study showed that small tidal ventilation significantly reduces the release of proinflammatory media.This finding suggests that greater deterioration in lung injury during ARDS is associated with high inspiratory flow and high ventilation rate.

Driving pressure decoded:Precision strategies in adult respiratory distress syndrome management

Mechanical ventilation(MV)is an important strategy for improving the survival of patients with respiratory failure.However,MV is associated with aggravation of lung injury,with ventilator-induced lung injury(VILI)becoming a major concern.Thus,ventilation protection strategies have been developed to minimize complications from MV,with the goal of relieving excessive breathing workload,improving gas exchange,and minimizing VILI.By opting for lower tidal volumes,clinicians seek to strike a balance between providing adequate ventilation to support gas exchange and preventing overdistension of the alveoli,which can contribute to lung injury.Additionally,other factors play a role in optimizing lung protection during MV,including adequate positive end-expiratory pressure levels,to maintain alveolar recruitment and prevent atelectasis as well as careful consideration of plateau pressures to avoid excessive stress on the lung parenchyma.

Molecular Mechanisms of Ventilator-Induced Lung Injury

Objective：Mechanical ventilation （MV） has long been used as a life-sustaining approach for several decades.However,researchers realized that MV not only brings benefits to patients but also cause lung injury if used improperly,which is termed as ventilator-induced lung injury （VILI）.This review aimed to discuss the pathogenesis of VILI and the underlying molecular mechanisms.Data Sources：This review was based on articles in the PubMed database up to December 2017 using the following keywords：＂ventilator-induced lung injury＂,＂pathogenesis＂,＂mechanism＂,and ＂biotrauma＂.Study Selection：Original articles and reviews pertaining to mechanisms of VILI were included and reviewed.Results：The pathogenesis of VILI was defined gradually,from traditional pathological mechanisms （barotrauma,volutrauma,and atelectrauma） to biotrauma.High airway pressure and transpulmonary pressure or cyclic opening and collapse of alveoli were thought to be the mechanisms of barotraumas,volutrauma,and atelectrauma.In the past two decades,accumulating evidence have addressed the importance of biotrauma during VILI,the molecular mechanism underlying biotrauma included but not limited to proinflammatory cytokines release,reactive oxygen species production,complement activation as well as mechanotransduction.Conclusions：Barotrauma,volutrauma,atelectrauma,and biotrauma contribute to VILI,and the molecular mechanisms are being clarified gradually.More studies are warranted to figure out how to minimize lung injury induced by MV.

Serum and lung endothelin-1 increased in a canine model of ventilator-induced lung injury

Background Nitric oxide （NO） plays an important role in acute lung injury （ALl）, acute respiratory distress syndrome （ARDS）, and in ventilator-induced lung injury （VILI）. A change in the balance of endothelin-1 （ET-1） and NO in the ALI/ARDS can also add to these problems. However, the profile of ET-1 and the balance of ET-1 and NO are still unknown in a VILI model. Methods Models of oleic acid induced ALl were established in dogs; these models were then randomized into three groups undergone different tidal volume （VT） mechanical ventilation, which included a VT6 group （VT equaled to 6 ml/kg body weight, positive end expiratory pressure （PEEP） equaled to 10 cmH20, n=-6）, a VT10 group （VT equaled to 10 ml/kg body weight, PEEP equaled to 10 cmH20, n=-4） and a VT20 group （VT equaled to 20 ml/kg body weight, PEEP equaled to 10 cmH20, n=-6） for 6-hour ventilation. The levels of ET-1 and NO in serum and tissue homogenates of lung were observed throughout the trial. Results PaO2 was increased after mechanical ventilation, but hypercapnia occurred in the VT6 group. The magnitudes of lung injury in the VT20 group were more severe than those in the VT6 group and the VT10 group. Serum levels of ET-1 and NO increased after ALl models were established and slightly decreased after a 6-hour ventilation in both the VT6 group and the VT20 group. The serum ET-1 level in the VT20 group was higher than that in the VT6 group and the VT10 group after the 6-hour ventilation （P 〈0.05） while the serum NO levels were similar in the three groups （all P 〉0.05）. There was no significant difference in serum ratio of ET-1/NO between any two out of three groups （P 〉0.05）, although there was a significant positive relationship between serum ET-1 and serum NO （r=0.80, P 〈0.01）. The levels of ET-1 and NO in the lung were increased after ventilation. The lung ET-1 level in the VT20 group was significantly higher than that in the VT6 group and VT10 group （both P 〈0.05） while there was no significant difference in lung NO levels between two groups （P〉0.05）. In the lung tissue, the ratio of ET-1/NO was significantly higher in the VT20 group than in the VT6 group and VT10 group after the 6-hour ventilation （P 〈0.05） as there was a significant positive relationship between ET-1 and NO in the lung （r=0.54, P 〈0.05）. Conclusions The production of ET-1 and NO was increased in serum and lung tissue in a VILI model. But the ET-1 levels increased much more than the NO levels in the lung, though there was a significant positive relationship between levels of ET-1 and NO. These results showed that there was an interaction between ET-1 and NO in a VILI model and changing the balance of ET-1 and NO levels might contribute to the pathophysiologic process of VILI.

Mesenchymal Stem Cell Attenuates Neutrophil-predominant Inflammation and Acute Lung Injury in an In Vivo Rat Model of Ventilator-induced Lung Injury

Background： Subsequent neutrophil （polymorphonuclear neutrophil [PMN]）-predominant inflammatory response is a predominant feature of ventilator-induced lung injury （VILI）, and mesenchymal stem cell （MSC） can improve mice survival model of endotoxin-induced acute lung injury, reduce lung impairs, and enhance the repair inflammatory in the VILI is still unknown. This study aimed to inflammatory in the mechanical VILI. of VILI. However, whether MSC could attenuate PMN-predominant test whether MSC intervention could attenuate the PMN-predominate Methods： Sprague-Dawley rats were ventilated for 2 hours with large tidal volume （20 mL/kg）. MSCs were given before or after ventilation. The inflammatory chemokines and gas exchange were observed and compared dynamically until 4 hours after ventilation, and pulmonary pathological change and activation of PMN were observed and compared 4 hours after ventilation. Results： Mechanical ventilation （MV） caused significant lung injury reflected by increasing in PMN pulmonary sequestration, inflammatory chemokines （tumor necrosis factor-alpha, interleukin-6 and macrophage inflammatory protein 2） in the bronchoalveolar lavage fluid, and injury score of the lung tissue. These changes were accompanied with excessive PMN activation which reflected by increases in PMN elastase activity, production of radical oxygen series. MSC intervention especially pretreatment attenuated subsequent lung injury, systemic inflammation response and PMN pulmonary sequestration and excessive PMN activation initiated by injurious ventilation. Conclusions： MV causes profound lung injury and PMN-predominate inflammatory responses. The protection effect of MSC in the VILI rat model is related to the suppression of the PMN activation.

Respiratory mechanics in brain injury: A review

Several clinical and experimental studies have shown that lung injury occurs shortly after brain damage. The responsible mechanisms involve neurogenic pulmonary edema, inflammation, the harmful action of neurotransmitters, or autonomic system dysfunction. Mechanical ventilation, an essential component of life support in brain-damaged patients(BD), may be an additional traumatic factor to the already injured or susceptible to injury lungs of these patients thus worsening lung injury, in case that non lung protective ventilator settings are applied. Measurement of respiratory mechanics in BD patients, as well as assessment of their evolution during mechanical ventilation, may lead to preclinical lung injury detection early enough, allowing thus the selection of the appropriate ventilator settings to avoid ventilatorinduced lung injury. The aim of this review is to explore the mechanical properties of the respiratory system in BD patients along with the underlying mechanisms, and to translate the evidence of animal and clinical studies into therapeutic implications regarding the mechanical ventilation of these critically ill patients.

Experimental study on the protective effect of ulinastatin on lung tissue in rats with severe scalded

Objective:To explore the potential protective effects of ulinastatin on ventilation-induced lung injuries of severe burned rats.Methods:Ninety Wistar rats were randomly divided into three experimental groups:the control group(n=30),the ventilation group(n=30)and the ventilation-ulinastatin group(n=30).After establishing the severe burn model,the rats of latter two groups were mechanically ventilated for 1 hour with or without the pre-treatment of ulinastatin.After severe scald,the protective effect of ulinastatin on lung injury caused by mechanical ventilation was estimated through the observation of the tissues samples,and evaluation of the pathological changes of lung tissue by HE staining,ultrastructure change by electron microscopy,lung coefficient,and the expression levels of lung tissue cytokines TNF-α,IFN-γ,IL-2 by immunohistochemical staining.Results:Edema in lung tissues of the control group and the ventilation group was obvious,the hemorrhagic focus could be seen,and the cut surface was observed to be scattered and swelling;Edema in lung tissues of the ventilation-ulinastatin group was mild.HE staining revealed that the pathological changes of the ventilation-ulinastatin group were milder than the ventilation group.Under the electron microscope,the lung tissue organelles of the control group and the ventilation group were seriously damaged;the corresponding changes in the ventilation-ulinastatin group were lighter.The lung coefficient of the ventilation-ulinastatin group was significantly lower than that in the ventilation group.The immunohistochemical results showed that the intensity of TNF-α,IL-2 and IFN-γin lung tissue of the ventilation-ulinastatin group was significantly lower than that in the ventilation group.Conclusions:Ulinastatin has protective effects on lung injury caused by mechanical ventilation in severe scalded rats,whose mechanism may be related to the capacity of ulinastatin to reduce the expression of cytokines including TNF-α,IL-2 and IFN-γ.

气道压力释放通气在急性呼吸窘迫综合征中的应用

在小潮气量肺保护性通气时代,急性呼吸窘迫综合征(acute respiratory distress syndrome, ARDS)患者的病死率仍高,机械通气参数设置不当会进一步增加呼吸机相关性肺损伤风险。由于ARDS患者肺泡的黏弹性,气道压力释放通气(airway pressure release ventilation, APRV)长时间的吸气、较高的压力以及短暂的释放可能更适合ARDS肺泡病理生理学变化。APRV有肺复张、稳定肺泡结构等优势,已经显示出作为一种肺保护通气策略的巨大潜力,本文将对APRV相关研究进展进行综述。

肺上皮细胞线粒体功能障碍在机械通气肺损伤中的作用机制

目的 探讨肺上皮细胞线粒体功能障碍在机械通气肺损伤中的作用机制。方法 以RLE-6TN细胞和呼吸机所致肺损伤(VILI)模型大鼠为实验对象。体外培养RLE-6TN细胞至传代稳定,建立大鼠VILI模型,机械通气4 h后取出肺组织,采用ELISA法检测上清液中炎症因子浓度,采用透射电镜观察线粒体形态,采用Western blot法检测肺组织线粒体动力相关蛋白1(Drp1)、细胞质中Drp1和线粒体融合蛋白(Mfn2)的蛋白含量,采用琥珀酸脱氢酶(SDH)试剂盒检测SDH活力,采用荧光显微镜观察活性氧(ROS)水平和线粒体膜电位(MMP)水平。建立大鼠VILI模型,机械通气4 h后,取出肺组织,采用HE染色法观察肺组织病理学变化,测定肺组织湿干质量比值(W/D),其余方法和体外实验相同。结果 体外实验中,与对照组比较,机械牵张引起RLE-6TN细胞炎症因子表达、线粒体ROS水平升高,MMP下降,线粒体形态异常、线粒体嵴模糊,Drp1表达增加和Mfn2表达减少。体内实验中,与对照组比较,机械通气引起大鼠肺组织病理结构改变显著,肺损伤评分、W/D比值、炎症因子表达、线粒体ROS水平均显著增加,MMP下降,线粒体形态异常,Drp1表达增加和Mfn2表达减少。在体内实验和体外实验中采用SDH抑制剂丙二酸二甲酯(DMM)和ROS清除剂N-乙酰-半胱氨酸(NAC)后以上变化均有显著的逆转。结论 炎症反应、氧化应激和线粒体功能障碍参与了VILI的过程,VILI导致氧化应激以及诱导Drp1和Mfn2表达异常引起线粒体功能障碍,线粒体功能障碍的改善或许是VILI治疗的重点。

甲泼尼龙对大鼠呼吸机相关肺损伤时p38MAPK信号通路的影响

目的探讨甲泼尼龙预先静脉注射对大鼠呼吸机相关肺损伤（VILI）的影响。方法将60只SD大鼠随机分为三组：对照组（C组）、机械通气（H组）和甲泼尼龙组（P组）。C组不行机械通气，自然呼吸空气；H组：大潮气量机械通气4h，吸入氧浓度为2l％；P组：机械通气前10rain静脉注射甲泼尼龙20mr,／kg。4h后放血处死大鼠，检测支气管灌洗液（BALF）中总蛋白、TNF—d、巨噬细胞炎性蛋白-2（MIP-2）的浓度，测定肺组织髓过氧化物酶（MPO）活性，测定肺干湿质量比（W／D）；Westernblot法检测磷酸化p38丝裂原活化蛋白激酶（P-p38MAPK）、抗丝裂原活化蛋白激酶磷酸酶-1（MKP-1）的表达；观察各组肺组织病理变化和细胞凋亡情况。结果与C组比较，H组P-p38MAPK蛋白灰度值显著升高（F=4．26，P〈0．05），同时伴有BALF中总蛋白、TNF-α和MIP-2的浓度、MPO活性、肺组织细胞凋亡指数、W／D比均显著升高（均P〈0．05）；与H组比较，P组P-p38MAPK蛋白灰度值明显下降，MKP-1蛋白灰度值上升（F=4．26、3．95，均P〈0．05），同时伴有肺组织中BALF中总蛋白、TNF-α和MIP-2的浓度、MPO活性、肺组织细胞凋亡指数、W／D比均显著降低（均P〈0．05）。H组肺组织病理损伤较重。结论甲泼尼龙可抑制VILI发生、发展，其机制与增加MKP-1表达，抑制p38MAPK磷酸化，进而减轻肺组织炎症、水肿和细胞凋亡有关。

甲泼尼龙对呼吸机相关性肺损伤大鼠肺组织TRPV4/MMP-2/MMP-9信号通路的影响

目的评价甲泼尼龙对呼吸机相关性肺损伤(VILI)大鼠肺组织瞬时受体电位香草酸4 (TRPV4)/基质金属蛋白酶2/9(MMP-2/MMP-9)信号通路的影响。方法清洁级雄性SD大鼠100只,采用随机数字表法分为5组(n=20):对照组(C组)、机械通气组(V组)、甲泼尼龙组(Mp组)、甲泼尼龙+GSK1016790A组(MpG组)、HC-067047组(H组)。C组不行机械通气,自主呼吸空气4 h;V组机械通气(RR 40次/min,VT 40 m L/kg,I∶E 1∶1,PEEP 0,Fi O221%) 4 h;Mp组在机械通气前20 min静脉输注甲泼尼龙10.0 mg/kg;MpG组在给予甲泼尼龙前20 min静脉输注GSK1016790A 0.025 mg/kg;H组机械通气前30 min静脉输注HC-067047 10.0 mg/kg。机械通气4 h时,检测支气管肺泡灌洗液(BALF)中白细胞介素-1(IL-1)、肿瘤坏死因子-α(TNF-α)、总蛋白浓度,测定肺通透指数(LPI)、肺湿/干质量比(W/D),观察肺组织病理学结果。Western blot法检测肺组织TRPV4、MMP-2、MMP-9的表达水平。结果与C组比较,V组和MpG组BALF中IL-1(ng/m L:84.56±5.35 vs. 144.85±9.39、121.56±7.69)、TNF-α(ng/m L:179.65±45.73 vs. 486.18±94.79、316.93±69.71)、总蛋白(mg/m L:321.29±28.76 vs. 687.78±65.78、476.39±46.67)升高,肺组织LPI [(2.47±0.17)×10^(-3)vs.(6.19±0.29)×10^(-3)、(4.24±0.25)×10^(-3)]、W/D比值(4.42±0.19 vs. 8.83±0.61、6.32±0.41)升高,TRPV4(1.85±0.25 vs.5.81±0.92、3.87±0.65)、MMP-2 (0.44±0.06 vs. 1.16±0.23、0.85±0.11)、MMP-9(0.19±0.03 vs. 0.46±0.09、0.34±0.07)表达上调(P<0.05);与V组比较,Mp组、MpG组和H组BALF中IL-1(ng/m L:144.85±9.39 vs. 89.78±5.91、121.56±7.69、94.23±6.78)、TNF-α(ng/m L:486.18±94.79 vs. 186.42±49.37、316.93±69.71、193.71±51.41)、总蛋白(mg/m L:687.78±65.78 vs. 348.78±31.52、476.39±46.67、359.68±36.12)降低,肺组织LPI [(6.19±0.29)×10^(-3)vs.(2.85±0.14)×10^(-3)、(4.24±0.25)×10^(-3)、(2.97±0.21)×10^(-3)]、W/D比值(8.83±0.61 vs. 4.75±0.22、6.32±0.41、4.82±0.25)降低,TRPV4(5.81±0.92 vs. 2.13±0.29、3.87±0.65、2.35±0.37)、MMP-2 (1.16±0.23 vs. 0.48±0.08、0.85±0.11、0.52±0.08)、MMP-9(0.46±0.09 vs. 0.22±0.04、0.34±0.07、0.25±0.05)表达下调(P<0.05),肺组织病理损伤减轻;与Mp组比较,MpG组BALF中IL-1 (ng/m L:89.78±5.91 vs. 121.56±7.69)、TNF-α(ng/m L:186.42±49.37 vs. 316.93±69.71)、总蛋白(mg/m L:348.78±31.52 vs. 476.39±46.67)升高,肺组织LPI [(2.85±0.14)×10^(-3)vs.(4.24±0.25)×10^(-3)]、W/D比值(4.75±0.22 vs. 6.32±0.41)升高,TRPV4(2.13±0.29 vs. 3.87±0.65)、MMP-2(0.48±0.08 vs. 0.85±0.11)、MMP-9(0.22±0.04 vs. 0.34±0.07)表达上调(P<0.05)。结论甲泼尼龙可减轻大鼠VILI,与其抑制TRPV4/MMP-2/MMP-9信号通路有关。

甲泼尼龙对机械通气相关性肺损伤大鼠肺泡内液体清除的影响

目的 评价甲泼尼龙对机械通气相关性肺损伤(VILI)大鼠肺泡内液体清除的影响.方法 清洁级雄性SD大鼠60只,采用随机数字表法分为三组(n=20):对照组(C组)、机械通气组(V组)和甲泼尼龙组(Mp组).C组不行机械通气,自主呼吸空气4h;V组机械通气(RR40次/min,VT 40 mL/kg,I∶E1∶1,PEEP0,FiO2 21%)4h;Mp组机械通气前20 min静注甲泼尼龙10 mg/kg.机械通气4h时,取血标本和肺组织,测定肺湿/干质量(W/D)比值与肺通透指数(LPI),观察肺组织病理学结果,测定肺泡内液体清除率(AFC).Western blot法检测肺组织细胞外信号调节激酶(ERK)、磷酸化细胞外信号调节激酶(p-ERK)、肺泡上皮细胞钠离子通道(ENaC)、钠钾三磷酸腺苷酶(Na^+-K^+-ATPase)的表达水平.结果 与C组比较,V组大鼠肺组织LPI和W/D比值升高[(2.17±0.07) ×10^-3 vs.(6.46±0.31)×10^-3,4.32±0.18 vs.8.74±0.53],AFC降低(%:30.56±5.35 vs.13.85 ±2.39),p-ERK表达上调(0.51 ±0.03 vs.1.19±0.13),ENaC和Na+-K+-ATPase表达下调(1.86±0.23 vs.0.71 ±0.08,1.82±0.21 vs.0.65±0.05),P均<0.05,Mp组上述指标差异无统计学意义(P>0.05);与V组比较,Mp组大鼠肺组织LPI和W/D比值降低[(6.46±0.31) ×10^-3 vs.(2.67±0.11) ×10^-3,8.74±0.53 vs.4.77±0.21],AFC升高(%:13.85 ±2.39 vs.28.23 ±4.78),p-ERK表达下调(1.19±0.13 vs.0.86±0.08),ENaC和Na^+-K^+-ATPase表达上调(0.71 ±0.08 vs.1.71 ±0.18,0.65 ±0.05 vs.1.65±0.14),P均<0.05.结论 甲泼尼龙可通过促进肺泡内液体清除来减轻大鼠VILI,其机制与抑制ERK磷酸化,上调ENaC和Na^+-K^+-ATPase表达有关.

体外膜肺氧合支持下ARDS患者的机械通气管理策略

尽管对急性呼吸窘迫综合征(ARDS)深入研究和机械通气技术的不断进步,但ARDS患者的病死率仍高达40%,难治性低氧血症及呼吸机相关性肺损伤(VILI)是导致ARDS患者死亡的重要原因.体外膜肺氧合(ECMO)可维持氧合、改善通气,起到“肺休息”的作用.但目前国际上对ECMO支持下最佳机械通气策略仍没有统一、明确的共识,本文旨在对近年来ECMO支持下ARDS患者机械通气策略进行综述.

Efficacy of prone position in acute respiratory distress syndrome patients: A pathophysiology-based review

Acute respiratory distress syndrome(ARDS) is a syndrome with heterogeneous underlying pathological processes. It represents a common clinical problem in intensive care unit patients and it is characterized by high mortality. The mainstay of treatment for ARDS is lung protective ventilation with low tidal volumes and positive end-expiratory pressure sufficient for alveolar recruitment. Prone positioning is a supplementary strategy available in managing patients with ARDS. It was first described 40 years ago and it proves to be in alignment with two major ARDS pathophysiological lung models; the "sponge lung"- and the "shape matching"-model. Current evidence strongly supports that prone positioning has beneficial effects on gas exchange, respiratory mechanics, lung protection and hemodynamics as it redistributes transpulmonary pressure, stress and strain throughout the lung and unloads the right ventricle. The factors that individually influence the time course of alveolar recruitment and the improvement in oxygenation during prone positioning have not been well characterized. Although patients' response to prone positioning is quite variable and hard to predict, large randomized trials and recent meta-analyses show that prone position in conjunction with a lung-protective strategy, when performed early and in sufficient duration, may improve survival in patients with ARDS. This pathophysiology-based review and recent clinical evidence strongly support the use of prone positioning in the early management of severe ARDS systematically and not as a rescue maneuver or a last-ditch effort.

气道压力释放通气对急性呼吸窘迫综合征患者呼吸机相关性肺损伤的影响

目的通过测定机械通气对急性呼吸窘迫综合征(Acute Respiratory Distress Syndrome,ARDS)患者支气管肺泡灌洗液(BronchoAlveolar Lavage Fluid,BALF)与血清中肺损伤标记物的变化,明确气道压力释放通气(Airway Pressure Release Ventilation,APRV)与小潮气量保护性通气(Low Tidal Volume Protective Ventilation,LTV)对ARDS患者呼吸机相关性肺损伤(Ventilator-Induced Lung Injury,VILI)的影响。方法收集深圳大学总医院及海南省人民医院2018-01至2019-05内ARDS住院患者40例,以随机数字法分为两组:A组21例,B组19例,A组先予APRV通气24 h,随后转为LTV 24 h;B组先予LTV 24 h,再转为APRV 24 h,比较干预治疗0 h、24 h、48 h两组患者氧合指数、呼吸力学、BALF及血清中肺泡表面活性蛋白(Pulmonary Surfactant Protein D,SP-D)、重组人晚期糖基化终末产物特异性受体(SolubleReceptor for Advanced Glycation end Products,sRAGE)、血管内皮生长因子(Vascular Endothlial Growth Factor,VEGF)、促血管生成素-2(Angiopopietin-2,Ang-2)浓度的变化。结果两组各监测时间点、氧合指数与气道平均压比较差异无统计学意义(P>0.05);干预治疗24 h,A组患者BALF中SP-D浓度高于B组(359.6±80.5μg/L vs 296.2±82.5μg/L),sRAGE浓度低于B组(2113.0±374.2 ng/L vs2358.1±337.3 ng/L),两组比较具有统计学意义(P<0.05);两组患者VEGF和Ang-2浓度比较,差异无统计学意义(P>0.05);同时,A组患者治疗24 h血清中SP-D浓度低于同一时间段B组(101.4±26.4μg/L VS 158.4±34.1μg/L,P<0.05),但两组患者血清中sRAGE、VEGF、Ang-2浓度差异无统计学意义(P>0.05)。A组干预治疗48 h,患者BALF中SP-D值较24 h下降(359.6±80.5μg/L vs 211.9±74.7μg/L,P<0.05),sRAGE值升高(2113.0±374.2ng/L vs 2833.7±488.0 ng/L,P<0.05);血清中SP-D值(101.4±26.4μg/L vs 160.8±23.7μg/L,P<0.05)和sRAGE值升高(829.0±192.7 ng/L vs 1070.3±245.5 ng/L,P<0.05)。B组干预治疗48h,患者BALF中SP-D值较24 h升高(296.2±82.5μg/L vs 331.9±92.1μg/L,P<0.05),sRAGE值下降(2358.1±337.3 ng/L vs2090.9±288.1 ng/L,P<0.05);血清中SP-D值(158.4±34.1μg/L vs 136.6±50.8μg/L,P<0.05)和sRAGE值下降(896.1±215.4ng/L vs 782.0±245.7 ng/L,P<0.05);VEGF与Ang-2值变化均无统计学差异(P>0.05)。结论与LTV相比,APRV时BALF中SP-D浓度较高,sRAGE浓度较低,血清SP-D及sRAGE升高,提示APRV可能减少ARDS患者的VILI,为ARDS机械通气选择APRV通气模式提供依据。

驱动压导向机械通气用于治疗急性呼吸窘迫综合征的研究进展

急性呼吸窘迫综合征(ARDS)是常见的重症医学科(ICU)危重症,是致使ICU患者死亡的主要病因之一。过去的几十年我们对ARDS的病理生理学特点有了更深化的理解,但是现在治疗ARDS的方式仍以机械通气为主,并且各项呼吸机参数对患者生存率的影响仍不明确。现在有研究者认为相较于潮气量(VT)和呼气末正压(PEEP),驱动压(ΔP)是更能精确评估预后的重要参数。驱动压可以是一项无创且易得的评估工具,能够指导设定呼吸机相关参数、辅助肺复张,降低呼吸机相关肺损伤(VILI)的发生率,可以改善病变肺脏的不均一性及呼吸力学特点。

呼吸机相关性肺损伤小鼠血清EMPs和NGAL的变化及意义

目的:研究小鼠血清内皮细胞微粒(EMPs)、中性粒细胞明胶酶相关脂质运载蛋白(NGAL)水平对呼吸机相关性肺损伤(VILI)的预测价值。方法:40只SPF级昆明种小鼠均分为高吸气末峰压组、低吸气末峰压组、大潮气量组、小潮气量组及对照组,分别采用相应的机械通气(MV)策略构建急性VILI模型,对照组小鼠仅切开气管;造模通气2 h时,比较5组小鼠血清EMPs、NGAL水平,采用Pearson法分析EMPs、NGAL的相关性;观察4组MV模型小鼠肺损伤程度,采用受试者工作特征曲线(ROC曲线)下面积(AUC)评价EMPs、NGAL对重度肺损伤的预测价值。结果:造模通气2 h时,5组小鼠血清EMPs、NGAL水平比较,高吸气末峰压组>低吸气末峰压组>大潮气量组及小潮气量组,差异有统计学意义(P <0. 05);Pearson相关性分析结果显示,EMPs与NGAL有正相关关系(r=0. 515,P=0. 003);4组MV小鼠肺损伤程度比较,差异有统计学意义(P <0. 05),轻度肺损伤、中度肺损伤小鼠血清EMPs水平低于重度肺损伤小鼠,差异有统计学意义(P <0. 05);轻度肺损伤小鼠血清NGAL水平低于重度肺损伤小鼠,差异有统计学意义(P <0. 05);ROC曲线分析结果显示,EMPs与NGAL联合预测重度肺损伤小鼠价值较高(AUC=0. 910、敏感度为98. 0%、特异度为76. 9%)。结论:EMPs与NGAL有望作为诊断及判断VILI严重程度的生物标志物。

Driving pressure:A useful tool for reducing postoperative pulmonary complications

The operating room is a unique environment where surgery exposes patients to non-physiological changes that can compromise lung mechanics.Therefore,raising clinicians’awareness of the potential risk of ventilator-induced lung injury(VILI)is mandatory.Driving pressure is a useful tool for reducing lung complications in patients with acute respiratory distress syndrome and those undergoing elective surgery.Driving pressure has been most extensively studied in the context of single-lung ventilation during thoracic surgery.However,the awareness of association of VILI risk and patient positioning(prone,beach-chair,parkbench)and type of surgery must be raised.