Brian D. Kubiak

Peritoneal negative pressure therapy prevents multiple organ injury in a chronic porcine sepsis and ischemia/reperfusion model.

Sepsis and hemorrhage can result in injury to multiple organs and is associated with an extremely high rate of mortality. We hypothesized that peritoneal negative pressure therapy (NPT) would reduce systemic inflammation and organ damage. Pigs (n = 12) were anesthetized and surgically instrumented for hemodynamic monitoring. Through a laparotomy, the superior mesenteric artery was clamped for 30 min. Feces was mixed with blood to form a fecal clot that was placed into the peritoneum, and the abdomen was closed. All subjects were treated with standard isotonic fluid resuscitation, wide spectrum antibiotics, and mechanical ventilation, and were monitored for 48 h. Animals were separated into two groups 12 h (T12) after injury: for NPT (n = 6), an abdominal wound vacuum dressing was placed in the laparotomy, and negative pressure (−125 mmHg) was applied (T12 - T48), whereas passive drainage (n = 6) was identical to the NPT group except the abdomen was allowed to passively drain. Negative pressure therapy removed a significantly greater volume of ascites (860 ± 134 mL) than did passive drainage (88 ± 56 mL). Systemic inflammation (e.g. TNF-&agr;, IL-1&bgr;, IL-6) was significantly reduced in the NPT group and was associated with significant improvement in intestine, lung, kidney, and liver histopathology. Our data suggest NPT efficacy is partially due to an attenuation of peritoneal inflammation by the removal of ascites. However, the exact mechanism needs further elucidation. The clinical implication of this study is that sepsis/trauma can result in an inflammatory ascites that may perpetuate organ injury; removal of the ascites can break the cycle and reduce organ damage.

The role of time and pressure on alveolar recruitment

Inappropriate mechanical ventilation in patients with acute respiratory distress syndrome can lead to ventilator-induced lung injury (VILI) and increase the morbidity and mortality. Reopening collapsed lung units may significantly reduce VILI, but the mechanisms governing lung recruitment are unclear. We thus investigated the dynamics of lung recruitment at the alveolar level. Rats (n = 6) were anesthetized and mechanically ventilated. The lungs were then lavaged with saline to simulate acute respiratory distress syndrome (ARDS). A left thoracotomy was performed, and an in vivo microscope was placed on the lung surface. The lung was recruited to three recruitment pressures (RP) of 20, 30, or 40 cmH(2)O for 40 s while subpleural alveoli were continuously filmed. Following measurement of microscopic alveolar recruitment, the lungs were excised, and macroscopic gross lung recruitment was digitally filmed. Recruitment was quantified by computer image analysis, and data were interpreted using a mathematical model. The majority of alveolar recruitment (78.3 +/- 7.4 and 84.6 +/- 5.1%) occurred in the first 2 s (T2) following application of RP 30 and 40, respectively. Only 51.9 +/- 5.4% of the microscopic field was recruited by T2 with RP 20. There was limited recruitment from T2 to T40 at all RPs. The majority of gross lung recruitment also occurred by T2 with gradual recruitment to T40. The data were accurately predicted by a mathematical model incorporating the effects of both pressure and time. Alveolar recruitment is determined by the magnitude of recruiting pressure and length of time pressure is applied, a concept supported by our mathematical model. Such a temporal dependence of alveolar recruitment needs to be considered when recruitment maneuvers for clinical application are designed.

A Two-Compartment Mathematical Model of Endotoxin-induced Inflammatory and Physiologic Alterations in Swine

Objective:To gain insights into individual variations in acute inflammation and physiology. Design:Large-animal study combined with mathematical modeling. Setting:Academic large-animal and computational laboratories. Subjects:Outbred juvenile swine. Interventions:Four swine were instrumented and subjected to endotoxemia (100 µg/kg), followed by serial plasma sampling. Measurements and Main Results:Swine exhibited various degrees of inflammation and acute lung injury, including one death with severe acute lung injury (PaO2/FIO2 ratio &mgr;200 and static compliance &mgr;10 L/cm H2O). Plasma interleukin-1&bgr;, interleukin-4, interleukin-6, interleukin-8, interleukin-10, tumor necrosis factor-&agr;, high mobility group box-1, and NO2-/NO3- were significantly (p &mgr; .05) elevated over the course of the experiment. Principal component analysis was used to suggest principal drivers of inflammation. Based in part on principal component analysis, an ordinary differential equation model was constructed, consisting of the lung and the blood (as a surrogate for the rest of the body), in which endotoxin induces tumor necrosis factor-&agr; in monocytes in the blood, followed by the trafficking of these cells into the lung leading to the release of high mobility group box-1, which in turn stimulates the release of interleukin-1&bgr; from resident macrophages. The ordinary differential equation model also included blood pressure, PaO2, and FIO2, and a damage variable that summarizes the health of the animal. This ordinary differential equation model could be fit to both inflammatory and physiologic data in the individual swine. The predicted time course of damage could be matched to the oxygen index in three of the four swine. Conclusions:The approach described herein may aid in predicting inflammation and physiologic dysfunction in small cohorts of subjects with diverse phenotypes and outcomes.

Plateau and Transpulmonary Pressure With Elevated Intra-Abdominal Pressure or Atelectasis

BACKGROUND ARDSnet standards limit plateau pressure (Pplat) to reduce ventilator induced lung injury (VILI). Transpulmonary pressure (Ptp) [Pplat-pleural pressure (Ppl)], not Pplat, is the distending pressure of the lung. Lung distention can be affected by increased intra-abdominal pressure (IAP) and atelectasis. We hypothesized that the changes in distention caused by increases in IAP and atelectasis would be reflected by Ptp but independent of Pplat. METHODS In Yorkshire pigs, esophageal pressure (Pes) was measured with a balloon catheter as a surrogate for Ppl under two experimental conditions: (1) high IAP group (n=5), where IAP was elevated by CO2 insufflation in 5 mm Hg steps from 0 to 30 mm Hg; and (2) Atelectasis group (n=5), where a double lumen endotracheal tube allowed clamping and degassing of either lung by O2 absorption. Lung collapse was estimated by increases in pulmonary shunt fraction. RESULTS High IAP: Sequential increments in IAP caused a linear increase in Pplat (r2=0.754, P<0.0001). Ptp did not increase (r2=0.014, P=0.404) with IAP due to the concomitant increase in Pes (r2=0.726, P<0.0001). Partial Lung Collapse: There was no significant difference in Pplat between the atelectatic (21.83+/-0.63 cm H2O) and inflated lung (22.06+/-0.61 cmH2O, P<0.05). Partial lung collapse caused a significant decrease in Pes (11.32+/-1.11 mm Hg) compared with inflation (15.89+/-0.72 mm Hg, P<0.05) resulting in a significant increase in Ptp (inflated=5.97+/-0.72 mm Hg; collapsed=10.55+/-1.53 mm Hg, P<0.05). CONCLUSIONS Use of Pplat to set ventilation may under-ventilate patients with intra-abdominal hypertension and over-distend the lungs of patients with atelectasis. Thus, Ptp must be used to accurately set mechanical ventilation in the critically ill.

Chemically modified tetracycline 3 prevents acute respiratory distress syndrome in a porcine model of sepsis + ischemia/reperfusion-induced lung injury.

Experimental pharmacotherapies for the acute respiratory distress syndrome (ARDS) have not met with success in the clinical realm. We hypothesized that chemically modified tetracycline 3 (CMT-3), an anti-inflammatory agent that blocks multiple proteases and cytokines, would prevent ARDS and injury in other organs in a clinically applicable, porcine model of inflammation-induced lung injury. Pigs (n = 15) were anesthetized and instrumented for monitoring. A “2-hit” injury was induced: (a) peritoneal sepsis—by placement of a fecal clot in the peritoneum, and (b) ischemia/reperfusion—by clamping the superior mesenteric artery for 30 min. Animals were randomized into two groups: CMT-3 group (n = 7) received CMT-3 (200 mg/kg); placebo group (n = 9) received the same dose of a CMT-3 vehicle (carboxymethylcellulose). Experiment duration was 48 h or until early mortality. Animals in both groups developed polymicrobial bacteremia. Chemically modified tetracycline 3 treatment prevented ARDS as indicated by PaO2/FIO2 ratio, static compliance, and plateau airway pressure (P < 0.05 vs. placebo). It improved all histological lesions of ARDS (P < 0.05 vs. placebo). The placebo group developed severe ARDS, coagulopathy, and histological injury to the bowel. Chemically modified tetracycline 3 treatment prevented coagulopathy and protected against bowel injury. It significantly lowered plasma concentrations of interleukin 1&bgr; (IL-1&bgr;), tumor necrosis factor &agr;, IL-6, IL-8, and IL-10. This study presents a clinically relevant model of lung injury in which CMT-3 treatment prevented the development of ARDS due in part to reduction of multiple plasma cytokines. Treatment of sepsis patients with CMT-3 could significantly reduce progression from sepsis into ARDS. ABBREVIATIONS ARDS—acute respiratory distress syndrome BALF—bronchoalveolar lavage fluid MMP—matrix metalloproteinase CMT-3—chemically modified tetracycline 3 TNF-&agr;—tumor necrosis factor &agr; IL—interleukin RM ANOVA—repeated-measures analysis of variance

Loss of Airway Pressure During HFOV Results in an Extended Loss of Oxygenation: A Retrospective Animal Study

BACKGROUND Patients with acute respiratory distress syndrome (ARDS) are often ventilated with high airway pressure. Brief loss of airway pressure may lead to an extended loss of oxygenation. While using high frequency oscillatory ventilation (HFOV) in a porcine acute lung injury model, two animals became disconnected from the ventilator with subsequent loss of airway pressure. We compared the two disconnected animals to the two animals that remained connected to determine causes for the extended reduction in oxygenation. METHODS ARDS was induced using 5% Tween. Thirty min of nonprotective ventilation (NPV) followed before placing the pigs on HFOV. Measurements were made at baseline, after lung injury, and every 30min during the 6-h study. Disconnections were treated by hand-ventilation and a recruitment maneuver before being placed back on HFOV. The lungs were histologically analyzed and wet/dry weights were measured to determine lung edema. RESULTS Hemodynamics and lung function were similar in all pigs at baseline, after injury, and following NPV. The animals that remained connected to the oscillator showed a continued improvement in PaO(2)/FiO(2) (P/F) ratio throughout the study. The animals that experienced the disconnection had a significant loss of lung function that never recovered. The disconnect animals had more diffuse alveolar disease on histologic analysis. CONCLUSIONS A significant fall in lung function results following disconnection from HFOV, which remains depressed for a substantial period of time despite efforts to reopen the lung. Dispersion of edema fluid is a possible mechanism for the protracted loss of lung function.

Titration of Mean Airway Pressure and FiO2 During High Frequency Oscillatory Ventilation in a Porcine Model of Acute Lung Injury

BACKGROUND High frequency oscillatory ventilation (HFOV) is frequently utilized for patients with acute lung injury (ALI) and acute respiratory distress syndrome (ARDS). However, precise criteria to titrate mean airway pressure (mPaw) and FiO(2) as the patients condition improves are lacking. We hypothesized that reducing mPaw and FiO(2) too quickly after reaching target arterial oxygen saturation levels would promote ventilator induced lung injury (VILI). MATERIALS AND METHODS ALI was induced by instilling 3% Tween 20. Pigs were placed supine and received 30 min of nonprotective ventilation. Pigs were separated into two groups: HFOV constant (HFOVC, n = 3) = constant mPaw and FiO(2) for the duration; HFOV titrated (HFOVT, n = 4) = FiO(2) and/or mPaw were reduced every 30 min if the oxygen saturation remained between 88%-95%. Hemodynamic and pulmonary measurements were made at baseline, after lung injury, and every 30 min during the 6-h study. Lung histopathology was determined by quantifying alveolar hyperdistension, fibrin, congestion, atelectasis, and polymorphonuclear leukocyte (PMN) infiltration. RESULTS Oxygenation was significantly lower in the HFOVT group compared to the HFOVC group after 6 h. Lung histopathology was significantly increased in the HFOVT group in the following categories: PMN infiltration, alveolar hyperdistension, congestion, and fibrin deposition. CONCLUSIONS Rapid reduction of mPaw and FiO(2) in our ALI model significantly reduced oxygenation, but, more importantly, caused VILI as evidenced by increased lung inflammation and alveolar hyperdistension. Specific criteria for titration of mPaw and inspired oxygen are needed to maximize the lung protective effects of HFOV while maintaining adequate gas exchange.

Protective Mechanical Ventilation: Lessons Learned From Alveolar Mechanics

Acute respiratory distress syndrome (ARDS) is a serious pulmonary disease characterized by respiratory failure with marked hypoxemia secondary to diffuse bilateral non-hydrostatic pulmonary edema and atelectasis. A formal definition of ARDS and acute lung injury (ALI) was introduced by an American-European Consensus Conference [1]. ALI has a devastating clinical impact, and current data estimates 190,600 new cases of ALI per year with 74,500 annual deaths in the United States alone [2]. The majority of patients with ALI, and in particular ARDS, require supportive therapy with mechanical ventilation. It has been shown, both clinically and experimentally, that improper mechanical ventilation causes ventilator-induced lung injury (VILI), which exacerbates the underlying ALI, leading to an increase in mortality [3].