Systemic inflammatory response does not correlate with acute lung injury associated with mechanical ventilation strategies in normal lungs.

BACKGROUND: Mechanical ventilation (MV) can lead to ventilator-induced lung injury secondary to trauma and associated increases in pulmonary inflammatory cytokines. There is controversy regarding the associated systemic inflammatory response. In this report, we demonstrate the effects of MV on systemic inflammation. METHODS: This report is part of a previously published study (Hong et al. Anesth Analg 2010;110:1652-60). Female pigs were randomized into 3 groups. Group H-Vt/3 was ventilated with a tidal volume (Vt) of 15 mL/kg predicted body weight (PBW)/positive end-expiratory pressure (PEEP) of 3 cm H(2)O; group L-Vt/3 with a Vt of 6 mL/kg PBW/PEEP of 3 cm H2O; and group L-Vt/10 with a Vt of 6 mL/kg PBW/PEEP of 10 cm H(2)O, for 8 hours. Each group had 6 subjects (n = 6). Prelung and postlung sera were analyzed for inflammatory markers. Hemodynamics, airway mechanics, and arterial blood gases were monitored. RESULTS: There were no significant differences in systemic cytokines among groups. There were similar trends of serum inflammatory markers in all subjects. This is in contrast to findings previously published demonstrating increases in inflammatory mediators in bronchoalveolar lavage. CONCLUSION: Systemic inflammatory markers did not correlate with lung injury associated with MV.

Hypoxia-inducible factor plays a gut-injurious role in intestinal ischemia reperfusion injury.

Gut injury and loss of normal intestinal barrier function are key elements in the paradigm of gut-origin systemic inflammatory response syndrome, acute lung injury, and multiple organ dysfunction syndrome (MODS). As hypoxia-inducible factor (HIF-1) is a critical determinant of the physiological and pathophysiological response to hypoxia and ischemia, we asked whether HIF-1 plays a proximal role in the induction of gut injury and subsequent lung injury. Using partially HIF-1α-deficient mice in an isolated superior mesenteric artery occlusion (SMAO) intestinal ischemia reperfusion (I/R) injury model (45 min SMAO followed by 3 h of reperfusion), we showed a direct relationship between HIF-1 activation and intestinal I/R injury. Specifically, partial HIF-1α deficiency attenuated SMAO-induced increases in intestinal permeability, lipid peroxidation, mucosal caspase-3 activity, and IL-1ß mRNA levels. Furthermore, partial HIF-1α deficiency prevented the induction of ileal mucosal inducible nitric oxide synthase (iNOS) protein levels after SMAO and iNOS deficiency ameliorated SMAO-induced villus injury. Resistance to SMAO-induced gut injury was also associated with resistance to lung injury, as reflected by decreased levels of myeloperoxidase, IL-6 and IL-10 in the lungs of HIF-1α(+/-) mice. In contrast, a short duration of SMAO (15 min) followed by 3 h of reperfusion neither induced mucosal HIF-1α protein levels nor caused significant gut and lung injury in wild-type or HIF-1α(+/-) mice. This study indicates that intestinal HIF-1 activation is a proximal regulator of I/R-induced gut mucosal injury and gut-induced lung injury. However, the duration and severity of the gut I/R insult dictate whether HIF-1 plays a gut-protective or deleterious role.

MicroRNA-145, a novel smooth muscle cell phenotypic marker and modulator, controls vascular neointimal lesion formation.

Phenotypic modulation of vascular smooth muscle cells (VSMCs) plays a critical role in the pathogenesis of a variety of proliferative vascular diseases. Recently, we have found that microRNA (miRNA) miR-145 is the most abundant miRNA in normal vascular walls and in freshly isolated VSMCs; however, the role of miR-145 in VSMC phenotypic modulation and vascular diseases is currently unknown. Here we find that miR-145 is selectively expressed in VSMCs of the vascular wall and its expression is significantly downregulated in the vascular walls with neointimal lesion formation and in cultured dedifferentiated VSMCs. More importantly, both in cultured rat VSMCs in vitro and in balloon-injured rat carotid arteries in vivo, we demonstrate that the noncoding RNA miR-145 is a novel phenotypic marker and a novel phenotypic modulator of VSMCs. VSMC differentiation marker genes such as SM alpha-actin, calponin, and SM-MHC are upregulated by premiR-145 or adenovirus expressing miR-145 (Ad-miR-145) but are downregulated by the miR-145 inhibitor 2'OMe-miR-145. We have further identified that miR-145-mediated phenotypic modulation of VSMCs is through its target gene KLF5 and its downstream signaling molecule, myocardin. Finally, restoration of miR-145 in balloon-injured arteries via Ad-miR-145 inhibits neointimal growth. We conclude that miR-145 is a novel VSMC phenotypic marker and modulator that is able of controlling vascular neointimal lesion formation. These novel findings may have extensive implications for the diagnosis and therapy of a variety of proliferative vascular diseases.

Recombinant factor XIII mitigates hemorrhagic shock-induced organ dysfunction.

BACKGROUND: Plasma factor XIII (FXIII) is responsible for stabilization of fibrin clot at the final stage of blood coagulation. Since FXIII has also been shown to modulate inflammation, endothelial permeability, as well as diminish multiple organ dysfunction (MOD) after gut ischemia-reperfusion injury, we hypothesized that FXIII would reduce MOD caused by trauma-hemorrhagic shock (THS). MATERIALS AND METHODS: Rats were subjected to a 90 min THS or trauma sham shock (TSS) and treated with either recombinant human FXIII A(2) subunit (rFXIII) or placebo immediately after resuscitation with shed blood or at the end of the TSS period. Lung permeability, lung and gut myeloperoxidase (MPO) activity, gut histology, neutrophil respiratory burst, microvascular blood flow in the liver and muscles, and cytokine levels were measured 3 h after the THS or TSS. FXIII levels were measured before THS or TSS and after the 3-h post-shock period. RESULTS: THS-induced lung permeability as well as lung and gut MPO activity was significantly lower in rFXIII-treated than in placebo-treated animals. Similarly, rFXIII-treated rats had lower neutrophil respiratory burst activity and less ileal mucosal injury. rFXIII-treated rats also had a higher liver microvascular blood flow compared with the placebo group. Cytokine response was more favorable in rFXIII-treated animals. Trauma-hemorrhagic shock did not cause a drop in FXIII activity during the study period. CONCLUSIONS: Administration of rFXIII diminishes THS-induced MOD in rats, presumably by preservation of the gut barrier function, limitation of polymorphonuclear leukocyte (PMN) activation, and modulation of the cytokine response.

Intravenous injection of mesenteric lymph produced during hemorrhagic shock decreases RBC deformability in the rat.

OBJECTIVE: To test the hypothesis that gut-derived factors carried in trauma-hemorrhagic shock (T/HS) lymph are sufficient to induce red blood cells (RBC) injury, to investigate their potential mechanisms of action, and to define the time post-T/HS that these factors appear in the lymph. METHODS: Mesenteric lymph collected from T/HS or trauma-sham shock (T/SS) rats over different time periods was injected intravenously into male rats at a rate of 1 mL/h for 3 hours. RBC deformability was measured using laser-assisted ektacytometer to calculate the elongation index. From the shear-stress elongation curve, the stress required for the erythrocytes to reach 50% of their maximal elongation was also determined. RBC deformability was measured before lymph infusion and at 1 hour and 3 hours after the initiation of lymph infusion. The effect of the lymph samples (5% v/v) was also determined in vitro by incubating naïve whole blood with the lymph samples. The potential role of T/HS lymph-induced RBC oxidant injury mediated by inducible nitric oxide synthase (iNOS)-generated oxidants and/or white blood cells (WBC) was investigated using iNOS inhibitors and WBC depletion, respectively. In all the in vivo studies, five to seven rats were studied per group. RESULTS: The intravenous injection of T/HS lymph but not T/SS lymph caused in vivo RBC injury. The biological activity of T/HS lymph varied over time with the RBC-injurious factors being produced only during the first 3 hours postshock. The in vivo inhibition of iNOS did not prevent lymph-induced RBC injury. T/HS lymph incubated in vitro with naïve whole blood resulted in RBC injury, but this injury was not observed in blood depleted of WBC. CONCLUSIONS: These results indicate that T/HS lymph produced during the initial 3-hour postshock period is sufficient to induce RBC injury in otherwise normal rats and that the lymph-induced RBC injury is not dependent on activation of the iNOS pathway but seems to require WBC.

The anatomic sites of disruption of the mucus layer directly correlate with areas of trauma/hemorrhagic shock-induced gut injury.

BACKGROUND: The intestinal mucus layer is an important but understudied component of the intestinal barrier. Consequently, we tested the hypothesis that the anatomic sites of loss of the mucus layer would directly correlate with sites of intestinal villous injury after trauma-hemorrhagic shock (T/HS) and may, therefore, serve as loci of gut barrier failure. Consequently, to investigate this hypothesis, we used Carnoy's fixative solution to prepare fixed tissue blocks where both the gut morphology and the mucus layer could be assessed on the same tissues slides. METHODS: Male Sprague-Dawley rats were subjected to a laparotomy (trauma) and 90 minutes of sham shock (T/SS) or 35 mm Hg × 90 minutes of actual shock (T/HS). Three hours after resuscitation, the rats were killed, and samples of the terminal ileum were processed by fixation in Carnoy's solution. Gut injury was evaluated by determining the percentage of villi injured. The status of the intestinal mucus layer was quantified by determining the percentage of the villi covered by the mucus and the mucus thickness. RESULTS: Histologic analysis of gut injury showed that the incidence of gut injury was ∼10-fold higher in the T/HS than the T/SS rats (T/SS=2.5% ± 0.5% vs. T/HS=22.4% ± 0.5% of injured villi; p<0.01). The T/SS rats had 98% of their ileal mucosa covered with a mucus layer, and this was decreased after T/HS to 63% ± 3% (T/HS vs. T/SS; p<0.001). Furthermore, loss of the mucus layer was found to directly correlate with villous injury with a regression coefficient of r=0.94 (p<0.001). CONCLUSION: This study shows that T/HS significantly reduces the intestinal mucus layer and causes villous injury and that a correlation exists between specific anatomic sites of T/HS-induced loss of the mucus layer and gut injury.

Testosterone depletion or blockade in male rats protects against trauma hemorrhagic shock-induced distant organ injury by limiting gut injury and subsequent production of biologically active mesenteric lymph.

BACKGROUND: We tested the hypothesis that testosterone depletion or blockade in male rats protects against trauma hemorrhagic shock-induced distant organ injury by limiting gut injury and subsequent production of biologically active mesenteric lymph. METHODS: Male, castrated male, or flutamide-treated rats (25 mg/kg subcutaneously after resuscitation) were subjected to a laparotomy (trauma), mesenteric lymph duct cannulation, and 90 minutes of shock (35 mm Hg) or trauma sham-shock. Mesenteric lymph was collected preshock, during shock, and postshock. Gut injury was determined at 6 hours postshock using ex vivo ileal permeability with fluorescein dextran. Postshock mesenteric lymph was assayed for biological activity in vivo by injection into mice and measuring lung permeability, neutrophil activation, and red blood cell deformability. In vitro neutrophil priming capacity of the lymph was also tested. RESULTS: Castrated and flutamide-treated male rats were significantly protected against trauma hemorrhagic shock (T/HS)-induced gut injury when compared with hormonally intact males. Postshock mesenteric lymph from male rats had a higher capacity to induce lung injury, Neutrophil (PMN) activation, and loss of red blood cell deformability when injected into naïve mice when compared with castrated and flutamide-treated males. The increase in gut injury after T/HS in males directly correlated with the in vitro biological activity of mesenteric lymph to prime neutrophils for an increased respiratory burst. CONCLUSIONS: After T/HS, gut protective effects can be observed in males after testosterone blockade or depletion. This reduced gut injury contributes to decreased biological activity of mesenteric lymph leading to attenuated systemic inflammation and distant organ injury.

HIF-1 mediates pathogenic inflammatory responses to intestinal ischemia-reperfusion injury.

Acute lung injury (ALI) and the development of the multiple organ dysfunction syndrome (MODS) are major causes of death in trauma patients. Gut inflammation and loss of gut barrier function as a consequence of splanchnic ischemia-reperfusion (I/R) have been implicated as the initial triggering events that contribute to the development of the systemic inflammatory response, ALI, and MODS. Since hypoxia-inducible factor (HIF-1) is a key regulator of the physiological and pathophysiological response to hypoxia, we asked whether HIF-1 plays a proximal role in the induction of gut injury and subsequent lung injury. Utilizing partially HIF-1α-deficient mice in a global trauma hemorrhagic shock (T/HS) model, we found that HIF-1 activation was necessary for the development of gut injury and that the prevention of gut injury was associated with an abrogation of lung injury. Specifically, in vivo studies demonstrated that partial HIF-1α deficiency ameliorated T/HS-induced increases in intestinal permeability, bacterial translocation, and caspase-3 activation. Lastly, partial HIF-1α deficiency reduced TNF-α, IL-1ß, cyclooxygenase-2, and inducible nitric oxide synthase levels in the ileal mucosa after T/HS whereas IL-1ß mRNA levels were reduced in the lung after T/HS. This study indicates that prolonged intestinal HIF-1 activation is a proximal regulator of I/R-induced gut mucosal injury and gut-induced lung injury. Consequently, these results provide unique information on the initiating events in trauma-hemorrhagic shock-induced ALI and MODS as well as potential therapeutic insights.

Low tidal volume and high positive end-expiratory pressure mechanical ventilation results in increased inflammation and ventilator-associated lung injury in normal lungs.

BACKGROUND: Protective mechanical ventilation with low tidal volume (Vt) and low plateau pressure reduces mortality and decreases the length of mechanical ventilation in patients with acute respiratory distress syndrome. Mechanical ventilation that will protect normal lungs during major surgical procedures of long duration may improve postoperative outcomes. We performed an animal study comparing 3 ventilation strategies used in the operating room in normal lungs. We compared the effects on pulmonary mechanics, inflammatory mediators, and lung tissue injury. METHODS: Female pigs were randomized into 3 groups. Group H-Vt/3 (n = 6) was ventilated with a Vt of 15 mL/kg predicted body weight (PBW)/positive end-expiratory pressure (PEEP) of 3 cm H(2)O, group L-Vt/3 (n = 6) with a Vt of 6 mL/kg PBW/PEEP of 3 cm H(2)O, and group L-Vt/10 (n = 6) with a Vt of 6 mL/kg PBW/PEEP of 10 cm H(2)O, for 8 hours. Hemodynamics, airway mechanics, arterial blood gases, and inflammatory markers were monitored. Bronchoalveolar lavage (BAL) was analyzed for inflammatory markers and protein concentration. The right lower lobe was assayed for mRNA of specific cytokines. The right lower lobe and right upper lobe were evaluated histologically. RESULTS: In contrast to groups H-Vt/3 and L-Vt/3, group L-Vt/10 exhibited a 6-fold increase in inflammatory mediators in BAL (P < 0.001). Cytokines in BAL were similar in groups H-Vt/3 and L-Vt/3. Group H-Vt/3 had a significantly lower lung injury score than groups L-Vt/3 and L-Vt/10. CONCLUSION: Comparing intraoperative strategies, ventilation with high PEEP resulted in increased production of inflammatory markers. Low PEEP resulted in lower levels of inflammatory markers. High Vt/low PEEP resulted in less histologic lung injury.

Estrogenic hormone modulation abrogates changes in red blood cell deformability and neutrophil activation in trauma hemorrhagic shock.

BACKGROUND: Decreased red blood cell (RBC) deformability and activation of neutrophils (polymorphonuclear leukocytes [PMN]) after trauma-hemorrhagic shock (T/HS) have been implicated in the development of multiple organ dysfunction. Experimentally, female animals seemed to be protected from the effects of T/HS, at least in part, because of elevated estrogen levels. Thus, we examined the relative role of estrogen receptor (ER)-alpha and -beta in this protective response. METHODS: To accomplish this goal, RBC deformability and neutrophil respiratory burst activity were measured in several groups of hormonally intact or ovariectomized (OVX) female rats subjected to T/HS (laparotomy plus hemorrhage to an MAP of 30 mm Hg to 35 mm Hg for 90 minutes) or trauma-sham shock (T/SS) and 3 hours of reperfusion. These groups included rats receiving vehicle, estradiol, or either an ER-alpha agonist or an ER-beta agonist administered at the end of the shock period just before volume resuscitation. RESULTS: RBC deformability and neutrophil activation were similar among all the T/SS groups and were not different from that observed in the non-OVX female rats subjected to T/HS. In contrast, RBC deformability was reduced and neutrophil activation was increased in the OVX, T/HS female rats as compared with the T/SS groups or the non-OVX, T/HS rats. The administration of estrogen to the T/HS, OVX rats returned RBC and neutrophil function to normal. Both the ER-alpha and -beta agonist partially, but not completely, protected the OVX rats from T/HS-induced loss of RBC deformability, whereas only the ER-beta agonist prevented the increase in neutrophil activation. CONCLUSIONS: The protective effects of estrogen on T/HS-induced RBC deformability are mediated, at least in part, via activation of both ER-alpha and -beta, whereas ER-beta activation is involved in limiting T/HS-induced neutrophil activation.

Intestinal mucus layer preservation in female rats attenuates gut injury after trauma-hemorrhagic shock.

BACKGROUND: We tested the hypothesis that females are more resistant to trauma-hemorrhagic shock (T/HS)-induced gut injury than males, and this is related to better preservation of their intestinal mucus layer, which is influenced in turn by the estrus cycle stage at the time of injury. METHODS: Male, proestrus and diestrus female rats underwent a laparotomy (trauma) and 90 minutes of shock ( approximately 35 mm Hg). At 3 hours after reperfusion, terminal ileum was harvested and stained with Carnoy's Alcian Blue for mucus assessment, hematoxylin and eosin, and periodic acid schiff for villous and goblet cell morphology and injury. Ileal permeability was measured in separate intestinal segments using the ex vivo everted gut sac technique. RESULTS: When compared with males, proestrus female rats were significantly more resistant to T/HS-induced morphologic gut injury, as reflected in both a lower incidence of villous injury (14% vs. 22%; p < 0.05) and a lesser grade of injury (1.0 vs. 2.8; p < 0.05) as well as preservation of gut barrier function (17.9 vs. 32.2; p < 0.05). This resistance to gut injury was associated with significant preservation of the mucus layer (87% vs. 62%; p < 0.05) and was influenced by the estrus cycle stage of the female rats. There was a significant inverse correlation between mucus layer coverage and the incidence (r = 0.9; p < 0.0001) and magnitude (r = 0.89; p < 0.0001) of villous injury and gut permeability (r = 0.74; p < 0.001). CONCLUSIONS: The resistance of female rats to T/HS-induced intestinal injury and dysfunction was associated with better preservation of the intestinal mucus barrier and was to some extent estrus cycle-dependent. Preservation of the mucus barrier may protect against shock-induced gut injury and subsequent distant organ injury by limiting the ability of luminal contents such as bacteria and digestive enzymes from coming into direct contact with the epithelium.

Trauma-hemorrhagic shock-induced red blood cell damage leads to decreased microcirculatory blood flow.

OBJECTIVE: To test the hypothesis that trauma-hemorrhagic shock (T/HS)-induced changes in red blood cells (RBC) contribute to the reduction of blood flow in distant organs. DESIGN: Laboratory study. SETTING: Academic medical center laboratory. SUBJECTS: Specific pathogen-free male Sprague-Dawley rats weighing between 250 and 350 g. INTERVENTIONS: Rats were transfused with trauma-sham shock (T/SS), or T/HS whole blood, or RBC-depleted blood (blood with the RBC removed and consisting of white blood cells and plasma). MEASUREMENTS AND MAIN RESULTS: Cardiac output and organ blood flow were measured by the radioactive microsphere technique. RBC tissue trapping, deformability, and RBC aggregation and adhesion were studied. Measurements of RBC adenosine triphosphate (ATP) and plasma fibrinogen were performed. Exchange transfusion with T/SS blood did not alter cardiac output or organ blood flow. However, cardiac output and blood flow in several organs were decreased when T/HS whole blood was used and RBCs were trapped in the organs that evidenced decreased blood flow. T/HS also increased RBC aggregation and adhesion, and decreased deformability. The ability of T/HS exchange transfusion to decrease microcirculatory blood flow did not appear to be due to plasma factors or non-RBC elements (i.e., white blood cell), because organ blood flow was not reduced after exchange transfusion with T/HS RBC-depleted blood. Likewise, neither decreased RBC ATP nor increased plasma fibrinogen explained the T/HS-induced changes that were observed. There was no change in fibrinogen levels during or after shock. Although there was a transient decrease in T/HS erythrocyte ATP levels during the early shock period, in contrast to RBC function, the ATP levels had returned to normal with resuscitation. CONCLUSIONS: T/HS induces significant changes in RBC functions and the injection of T/HS, but not T/SS, RBC leads to decreased organ blood flow. These findings confirm the hypothesis that T/HS-induced RBC alterations will directly cause organ hypoperfusion and suggest that T/HS-induced RBC damage contributes to this process. Thus, T/HS-induced changes in RBC function may contribute to the development of shock-induced multiple organ failure.

Hydrophobicity of mucosal surface and its relationship to gut barrier function.

Loss of the gut barrier has been implicated in the pathogenesis of the multiple organ dysfunction syndrome, and, thus, understanding the intestinal barrier is of potential clinical importance. An important, but relatively neglected, component of the gut barrier is the unstirred mucus layer, which through its hydrophobic and other properties serves as an important barrier to bacterial and other factors within the gut lumen. Thus, the goal of this study was to establish a reproducible method of measuring mucosal hydrophobicity and test the hypothesis that conditions that decrease mucosal hydrophobicity are associated with increased gut permeability. Hydrophobicity was measured in various segments of normal gut by measuring the contact angle of an aqueous droplet placed on the mucosal surface using a commercial goniometer. Second, the effect of the mucolytic agent N-acetyl cysteine on mucosal hydrophobicity and gut permeability was measured, as was the effects of increasing periods of in vivo gut ischemia on these parameters. Gut ischemia was induced by superior mesenteric artery occlusion, and gut permeability was measured by the mucosal-to-serosal passage of fluoresceine isothiocyanate-dextran (4.3 kDa) (FD4) across the everted sacs of ileum. Intestinal mucosal hydrophobicity showed a gradual increase from the duodenum to the end of the ileum and remained at high level in the cecum, colon, and rectum. Both N-acetyl cysteine treatment and ischemia caused a dose-dependent decrease in mucosal hydrophobicity, which significantly correlated increased gut permeability. Mucosal hydrophobicity of the intestine can be reproducibly measured, and decreases in mucosal hydrophobicity closely correlate with increased gut permeability. These results suggest that mucosal hydrophobicity can be a reliable method of measuring the barrier function of the unstirred mucus layer and a useful parameter in evaluating the pathogenesis of gut barrier dysfunction.

Trauma-shock-induced gut injury and the production of biologically active intestinal lymph is abrogated by castration in a large animal porcine model.

Although small animal rodent studies indicate that there is a sexual dimorphism in the resistance to organ injury after trauma-hemorrhagic shock (T/HS), confirmatory studies are largely lacking in more clinically relevant large animal species. Thus, we tested the hypothesis that castration would reduce the susceptibility of adult minipigs to gut injury and abrogate the production of biologically active intestinal (mesenteric) lymph after T/HS. The hemodynamic response to T/HS was similar between castrated and noncastrated minipigs. Mesenteric lymph collected during the preshock period and in the trauma-sham shock (T/SS) animals did not have increased biological activity. However, T/HS-lymph from the noncastrated males increased the respiratory burst of normal neutrophils, increased endothelial cell monolayer permeability, and was cytotoxic for endothelial cells. Castration abrogated the T/HS-induced neutrophil-activating and endothelial-injurious activities of mesenteric lymph, and the biological activity of the T/HS-lymph from the castrated minipigs was not different from the T/SS animals. As compared with the T/SS minipigs, T/HS increased ileal mucosal injury and intestinal permeability. This increase in gut permeability after T/HS was manifest by in vivo bacterial translocation and by the increased passage of bacteria as well as permeability probes across intestinal segments when tested in the Ussing chamber system. In contrast, neither mucosal injury nor increased intestinal permeability was observed in the castrated minipigs subjected to T/HS. In summary, this large animal porcine study validates the notion that castration limits gut injury and the production of biologically active intestinal lymph after T/HS.

Calcium entry inhibition during resuscitation from shock attenuates inflammatory lung injury.

Trauma and hemorrhagic shock (T/HS) induce a systemic inflammatory response syndrome (SIRS). Neutrophils (polymorphonuclear leukocytes [PMN]) and other cells involved in acute lung injury (ALI) are activated by Ca2+ entry. Thus, inhibiting Ca2+ entry might attenuate post-traumatic lung injury. Inhibiting voltage-operated (L-type) Ca2+ channels during shock could cause cardiovascular collapse, but PMN are "nonexcitable" cells, lack L-type channels, and mobilize Ca2+ via nonspecific channels. We previously showed that PMN Ca2+ entry requires sphingosine 1-phosphate synthesis by sphingosine kinase and that both sphingosine kinase inhibition and blockade of nonspecific channels attenuate ALI when begun before shock. Pretreatment for clinical injuries, however, is impractical. Therefore, we now studied whether Ca2+ entry inhibition that begun during resuscitation from T/HS could attenuate SIRS and ALI without causing hemodynamic compromise. Male Sprague-Dawley rats underwent laparotomy and fixed-pressure shock (mean arterial pressure, 35 +/- 5 mmHg; 90 min). Sphingosine kinase inhibition or nonspecific Ca2+ channel inhibition was begun after resuscitation with 10% of shed blood. We then studied in vivo PMN activation and associated lung injury in the presence or absence of Ca2+ entry inhibition. Neither treatment worsened shock. Each treatment decreased CD11b expression, respiratory burst, PMN p38 MAP-kinase phosphorylation, PMN sequestration, and lung capillary leak in vivo. The similar results seen with two different forms of inhibition strengthen the conclusion that the biological effects seen were specific for calcium entry inhibition. Ca2+ entry inhibition is a candidate therapy for management of lung injury after shock.

Resistance of the female, as opposed to the male, intestine to I/R-mediated injury is associated with increased resistance to gut-induced distant organ injury.

We tested the hypothesis that the female intestine is more resistant to gut I/R injury than the male intestine by comparing the effects of the isolated pure gut I/R superior mesenteric artery occlusion (SMAO) model on gut morphology and whether SMAO-induced distant organ injury (lung, bone marrow [BM], neutrophils, and red blood cells [RBCs]) would differ between male and proestrus female rats. At 6 or 24 h after SMAO or sham SMAO, gut injury, lung permeability, pulmonary neutrophil sequestration, RBC deformability, and BM RBC and white blood cell progenitor growth were measured, as was the ability of the plasma from these rats to activate naive rat neutrophils. At both 6 and 24 h after SMAO, the female rats had significantly less intestinal injury and reduced gut-induced lung injury, BM suppression, RBC dysfunction, and neutrophil activation than male rats subjected to SMAO. These results indicate that the resistance of proestrus female rats to gut injury and gut-induced distant organ injury is greater than that observed in male rats.

Organ blood flow and the central hemodynamic response are better preserved in female, as opposed to the male rats, after trauma-hemorrhagic shock.

The objective of this study was to test the hypotheses that the better resistance of proestrus female than male rats to trauma-hemorrhagic shock (T/HS)-induced gut and other organ injury, and it is associated with better preservation of central hemodynamics and organ blood flow including blood flow to the intestine. Male and female proestrus rats were subjected to T/HS (laparotomy and 90 minutes of shock at a mean arterial blood pressure of 35-40 mm Hg) or trauma sham-shock after that cardiac index, systemic vascular resistance, and organ blood flow was measured 15 minutes before the end of the shock period and at 15 minutes, 60 minutes, and 180 minutes after volume resuscitation. The hemodynamic response to T/HS was better preserved during the shock period in the female than male rats and this was manifest as better maintenance of central hemodynamics (cardiac output and systemic vascular resistance) and intestinal as well as other organ microcirculatory blood flow. Cardiac output had returned toward normal at 15 minutes after volume resuscitation in both the male and female rats, however only in the female rats was there a consistent increase in organ blood flow after volume resuscitation. In contrast, in the male T/HS rats, the level of organ blood flow, especially to the splanchnic organs, remained similar to that observed during the shock period. These results indicate that the greater resistance of female than male rats to gut and other organ injury after T/HS is associated with better preservation of central hemodynamics and organ blood flow during the shock and postshock periods.

The influence of the type of resuscitation fluid on gut injury and distant organ injury in a rat model of trauma/hemorrhagic shock.

BACKGROUND: Recognition that resuscitation with Ringers lactate (RL) potentiates trauma-hemorrhagic shock (T/HS)-induced organ injury and systemic inflammation has led to a search for improved initial fluid resuscitation regimens. However, one relatively neglected component in the search for new and novel resuscitation strategies is a determination of what fluid resuscitation therapy (i.e., control group) the new experimental regimen of interest should be tested against. Thus, we tested the effects of three commonly used resuscitation strategies on trauma-shock-induced gut and lung injury, as well as neutrophil activation and red blood cell (RBC) function. METHODS: Male Sprague Dawley rats were subjected to a laparotomy (trauma) and 90 minutes of sham shock (trauma-sham shock [T/SS]) or a laparotomy plus hemorrhagic shock (T/HS), followed by a reperfusion period of 3 hours. The T/HS groups were resuscitated either with their shed blood (SB), or half the SB and 1.5 times the SB volume as RL (SB/RL), or 3 times the SB volume as RL (3RL). The T/SS groups received either no resuscitation or RL at 1.5 times the SB volume of the T/HS rats. Gut injury was quantified by measuring intestinal permeability to flourescein dextran (FD-4), as well as by histologic analysis of the terminal ileum. Lung injury was assessed histologically and by the magnitude of neutrophil sequestration as reflected in myeloperoxidase levels. Neutrophil activation was measured by quantitating the level of CD11b expression using flow cytometry. RBC injury was analyzed by measuring the RBC deformability. RESULTS: As compared with the T/SS groups, all three T/HS resuscitation regimens were associated with morphologic evidence of gut and lung injury, increased gut permeability, pulmonary leukosequestration, systemic neutrophil activation, and decreased RBC deformability (p < 0.05). However, the effect of the resuscitation regimens varied based on the tissues and cells tested. Morphologically, gut and lung injury as well as pulmonary neutrophil sequestration was worse in the 3RL T/HS group than the other two T/HS groups. As compared with the other two T/HS resuscitation regimens, resuscitation with the SB/RL combination was associated with less of an increase in gut permeability, systemic neutrophil activation, and RBC rigidification (p < 0.05). CONCLUSIONS: The type of resuscitation regimen used influenced the extent of organ injury and cellular activation or dysfunction observed after T/HS with different resuscitation regimens showing varying effects depending on the cell or organ tested. Thus, when testing novel fluid resuscitation regimen, attention must be paid to the control resuscitation regimen used.

Mesenteric lymph duct ligation attenuates lung injury and neutrophil activation after intraperitoneal injection of endotoxin in rats.

BACKGROUND: The release of injurious factors into the mesenteric lymph from the ischemic intestine has been shown to contribute to lung injury and systemic inflammation after shock and trauma. Since endotoxemia is also associated with gut injury, we tested the hypothesis that mesenteric lymph contributes to the lung injury seen in endotoxemia and that the ligation of the mesenteric lymph duct will attenuate this injury. METHODS: To test this hypothesis, male Sprague-Dawley rats were given intraperitoneal injections (i.p.) of lipopolysaccharide (LPS) (10 mg/kg) with or without mesenteric lymph duct ligation (LDL). At 6 hours after injection of LPS, gut and lung injury, lung permeability, and neutrophil CD11b expression were measured. Lung permeability was quantified by calculating the percentage of Evan's Blue dye and the total protein concentration in the bronchoalveolar lavage fluid (BALF) when compared with the plasma and gut and lung injury were assessed morphologically. RESULTS: LDL attenuated LPS- induced lung injury, lung permeability, and rat PMN CD11b expression but not villous injury. The magnitude of lung permeability as measured by Evan's Blue was approximately twofold greater in the LPS rats when compared with the LPS-treated rats with LDL. The expression of CD11b was greater in the LPS rats when compared with LPS rats with LDL or to sham controls (582 +/- 106 vs. 364 +/- 29 vs. 224 +/- 12 mean fluorescence intensity p < 0.001). CONCLUSION: Based on the attenuation of lung injury and CD11b expression, these results suggest that LPS-induced lung injury and neutrophil activation is partially mediated through the release of factors from the injured gut into mesenteric lymph.

Relationship between disruption of the unstirred mucus layer and intestinal restitution in loss of gut barrier function after trauma hemorrhagic shock.

BACKGROUND: The factors involved in shock-induced loss of gut barrier function remain to be defined fully and studies investigating gut injury have focused primarily on the systemic side of the intestine. METHODS: Male Sprague-Dawley rats were subjected to a laparotomy (trauma) and 90 minutes of trauma sham shock (T/SS) or actual trauma (laparotomy) hemorrhagic shock (T/HS) (30 mm Hg). At 0, 30, 60, or 180 minutes after the end of shock and volume resuscitation (reperfusion), the animals were killed and samples of the ileum were collected for intestinal morphologic analysis, analysis of the unstirred mucus layer, and for barrier function by measuring permeability to flourescein dextran. RESULTS: T/HS-induced morphologic evidence of mucosal injury as well as epithelial apoptosis was present at the end of the shock period and maximal after 60 minutes of reperfusion. At 3 hours after reperfusion, the degree of villous injury and enterocyte apoptosis had decreased. In contrast to the morphologic appearance of the villi, disruption of the mucus layer became progressively more severe over time and was manifest as a decrease in mucus thickness, progressive loss of coverage of the luminal surface by the mucus layer, and a change in mucus appearance from a dense to a loose structure. Studies of intestinal permeability documented that T/HS-induced loss of gut barrier function persisted throughout the 3-hour reperfusion period and were associated with injury to the mucus layer as well as the villi. CONCLUSIONS: T/HS leads to changes in the intestinal mucus layer as well as increased villous injury, apoptosis, and gut permeability. Additionally, increased gut permeability was associated with loss of the intestinal mucus layer suggesting that T/HS-induced injury to the mucus layer may contribute to the loss of gut barrier function.