Clavijo L C, Carter M B, Matheson P J, Wills-Frank L A, Wilson M A, Wead W B, Garrison R N
Department of Surgery, University of Louisville, Louisville, Kentucky 40206, USA.
J Surg Res. 2000 Feb;88(2):173-80. doi: 10.1006/jsre.1999.5748.
Acute lung injury is a common complication of gram-negative sepsis. Pulmonary hypertension and increased lung vascular permeability are central features of lung injury following experimental bacteremia. Platelet-activating factor is a prominent proinflammatory mediator during bacterial sepsis. Our previous studies have demonstrated that exogenous administration of platelet-activating factor (PAF) induces pulmonary edema without causing pulmonary hypertension. Interestingly, inhibition of PAF activity during Escherichia coli bacteremia prevents the development of both pulmonary hypertension and pulmonary edema. These data suggest that PAF contributes to pulmonary hypertension during sepsis, but that this is unlikely to be a direct vascular effect of PAF. The goal of the present study was to investigate the mechanism by which acute E. coli bacteremia induces pulmonary injury and to define the role that PAF plays in this injury. We hypothesized that the effects of PAF on pulmonary hypertension during bacteremia are due to the effects of PAF on other vascular mediators. Several studies suggest that PAF induces the expression of endothelin-1 (ET), a potent peptide vasoconstrictor. Further, our previous studies have implicated ET as a central mediator of systemic vasoconstriction during bacteremia. We therefore sought to assess whether ET is modulated by PAF. E. coli has also been demonstrated to increase endothelial production of nitric oxide (NO), which contributes to maintenance of basal vascular tone in the pulmonary circulation. We hypothesized that PAF might increase pulmonary vascular resistance during bacteremia by activating neutrophils, increasing expression of ET, and decreasing the tonic release of NO. Furthermore, we hypothesized that hypoxic vasoconstriction did not contribute to pulmonary vasoconstriction during the first 120 min of E. coli bacteremia.
Pulmonary artery pressure (PAP), blood pressure (BP), heart rate (HR), and arterial blood gases (ABG) were measured in anesthetized spontaneously breathing adult male Sprague-Dawley rats. E. coli (10(9) CFU/100 g body wt) was injected at t = 0, and hemodynamic data were obtained at 10-min intervals and ABG data at 30-min intervals for a total of 120 min. Sham animals were treated equally but received normal saline in place of E. coli. In treatment groups, a 2.5 mg/kg dose of WEB 2086, a PAF receptor antagonist, was administered intravenously 15 min prior to the onset of sepsis or sham sepsis. The groups were (1) intravenous E. coli (n = 5); (2) intravenous WEB 2086 pretreatment + intravenous E. coli (n = 5); (3) intravenous WEB 2086 alone (n = 5); and (4) intravenous normal saline (n = 6). Nitric oxide metabolites (NOx) and ET concentrations were assayed from arterial serum samples obtained at the end of the protocol. Lung tissue was harvested for measurement of myeloperoxidase (MPO) activity and pulmonary histology.
E. coli bacteremia increased HR, PAP, and respiratory rate early during sepsis (within 20 min), while hypoxemia, hypotension, and hemoconcentration were not manifest until the second hour. Pretreatment with WEB 2086 completely abrogated all of these changes. E. coli bacteremia increased the activity of serum ET, lung MPO, and neutrophil sequestration in the lung parenchyma via a PAF-dependent mechanism. However, the mechanism of increased production of NO appears to be PAF independent.
These data support the hypothesis that E. coli bacteremia rapidly induces pulmonary hypertension stimulated by PAF and mediated at least in part by endothelin-1 and neutrophil activation and sequestration in the lung. Microvascular injury with leak is also mediated by PAF during E. coli bacteremia, but the time course of resultant hypoxemia and hemoconcentration is slower than that of pulmonary hypertension. The contribution of hypoxic vasoconstriction in exacerbating pulmonary hypertension in gram-negative sepsis is probably a late
急性肺损伤是革兰氏阴性菌败血症的常见并发症。肺动脉高压和肺血管通透性增加是实验性菌血症后肺损伤的主要特征。血小板活化因子是细菌性败血症期间一种突出的促炎介质。我们之前的研究表明,外源性给予血小板活化因子(PAF)可诱发肺水肿但不会引起肺动脉高压。有趣的是,在大肠杆菌菌血症期间抑制PAF活性可预防肺动脉高压和肺水肿的发生。这些数据表明,PAF在败血症期间促成了肺动脉高压,但这不太可能是PAF的直接血管效应。本研究的目的是探究急性大肠杆菌菌血症诱发肺损伤的机制,并确定PAF在这种损伤中所起的作用。我们假设,PAF在菌血症期间对肺动脉高压的影响是由于PAF对其他血管介质的作用。多项研究表明,PAF可诱导内皮素-1(ET)的表达,内皮素-1是一种强效的肽类血管收缩剂。此外,我们之前的研究表明,ET是菌血症期间全身血管收缩的核心介质。因此,我们试图评估ET是否受PAF调节。大肠杆菌也已被证明可增加内皮细胞一氧化氮(NO)的生成,这有助于维持肺循环中的基础血管张力。我们假设,PAF可能通过激活中性粒细胞、增加ET的表达以及减少NO的持续性释放来增加菌血症期间的肺血管阻力。此外,我们假设在大肠杆菌菌血症的最初120分钟内,低氧性血管收缩对肺血管收缩没有影响。
在麻醉状态下自主呼吸的成年雄性Sprague-Dawley大鼠中测量肺动脉压(PAP)、血压(BP)、心率(HR)和动脉血气(ABG)。在t = 0时注射大肠杆菌(10⁹CFU/100g体重),每隔10分钟获取血流动力学数据,每隔30分钟获取ABG数据,共持续120分钟。假手术动物接受相同处理,但用生理盐水代替大肠杆菌。在治疗组中,在败血症或假败血症发作前15分钟静脉注射2.5mg/kg剂量的PAF受体拮抗剂WEB 2086。分组如下:(1)静脉注射大肠杆菌组(n = 5);(2)静脉注射WEB 2086预处理 + 静脉注射大肠杆菌组(n = 5);(3)单独静脉注射WEB 2086组(n = 5);(4)静脉注射生理盐水组(n = 6)。从实验结束时获取的动脉血清样本中测定一氧化氮代谢产物(NOx)和ET浓度。采集肺组织用于测量髓过氧化物酶(MPO)活性和进行肺组织学检查。
大肠杆菌菌血症在败血症早期(20分钟内)使HR、PAP和呼吸频率增加,而低氧血症、低血压和血液浓缩直到第二小时才出现。用WEB 2086预处理可完全消除所有这些变化。大肠杆菌菌血症通过PAF依赖机制增加血清ET活性、肺MPO活性以及肺实质中的中性粒细胞滞留。然而,NO生成增加的机制似乎与PAF无关。
这些数据支持以下假设,即大肠杆菌菌血症迅速诱发由PAF刺激、至少部分由内皮素-1以及肺内中性粒细胞激活和滞留介导的肺动脉高压。在大肠杆菌菌血症期间,PAF还介导伴有渗漏的微血管损伤,但由此导致的低氧血症和血液浓缩的时间进程比肺动脉高压的时间进程要慢。在革兰氏阴性菌败血症中,低氧性血管收缩在加重肺动脉高压方面的作用可能较晚。
