Role of alveolar macrophages in the regulation of local and systemic inflammation after lung contusion.

BACKGROUND: Blunt chest trauma is an injury that enhances the morbidity and mortality rate, particularly in the context of polytrauma. Our previous studies showed local and systemic inflammatory alterations after blunt chest trauma in mice. This study was designed to determine whether alveolar macrophages (AMΦ) have an alleviative role in this posttraumatic inflammation. METHODS: AMΦ of male C3H/HeN mice were depleted by instillation of clodronate liposomes into the lung before blunt chest trauma induced by a single blast wave. In bronchoalveolar lavage, lung homogenates, plasma, and cell culture supernatants of Kupffer cells, peripheral blood mononuclear cells, splenic macrophages, and splenocytes isolated 2 hours or 24 hours after chest trauma mediator concentrations were determined by multiplex assay or enzyme-linked immunosorbent assay. RESULTS: In bronchoalveolar lavage, AMΦ depletion led to increased monocyte chemoattractant protein 1 and regulated and normal T cell expressed and secreted (RANTES) concentrations as well as an attenuated increase of interleukin 6 concentrations after chest trauma. Bronchoalveolar lavage keratinocyte-derived chemokine concentrations increased in nontraumatized but AMΦ-depleted animals with no further change after chest trauma. Cytokine concentrations in lung homogenates were altered in the same way as in bronchoalveolar lavage early after trauma. In the plasma of AMΦ-depleted animals, interleukin 6 concentrations were slightly decreased after chest trauma. Depletion of AMΦ abrogated the trauma-induced decrease of Kupffer cell chemokine release. Cytokine concentrations of blood monocytes, splenic macrophages, and splenocyte supernatants were not influenced by AMΦ depletion. CONCLUSION: These depletion experiments show that AMΦ ameliorate the inflammatory response after blunt chest trauma. Taken together, this study gives relevant insights into the regulative role of AMΦ during the local and systemic inflammation after lung contusion.

Role of activated neutrophils in chest trauma-induced septic acute lung injury.

More than 50% of severely injured patients have chest trauma. Second insults frequently result in acute lung injury (ALI), with sepsis being the main underlying condition. We aimed to develop a standardized, reproducible, and clinically relevant double-hit mouse model of ALI induced by chest trauma and polymicrobial sepsis and to investigate the pathophysiologic role of activated neutrophils. Lung contusion was applied to C57Bl/6 mice via a focused blast wave. Twenty-four hours later, sepsis was induced by cecal ligation and puncture. For polymorphonuclear leukocyte (PMN) depletion, animals received intravenous injections of PMN-depleting antibody. In response to blunt chest trauma followed by sepsis as well as after sepsis alone, a significant local and systemic inflammatory response with increased cytokine/chemokine levels in lung and plasma was observed. In contrast, lung apoptosis was markedly elevated only after a double hit. Intra-alveolar neutrophils and total bronchoalveolar lavage protein concentrations were markedly increased following isolated chest trauma or the combined insult, but not after sepsis alone. Lung myeloperoxidase activity was enhanced only in response to the double hit accompanied by histological disruption of the alveolar architecture, lung congestion, and marked cellular infiltrates. Neutrophil depletion significantly diminished lung interleukin 1ß and interleukin 6 concentrations and reduced the degree of septic ALI. Here we have established a novel and highly reproducible mouse model of chest trauma-induced septic ALI characterizing a clinical relevant double-hit scenario. In particular, the depletion of neutrophils substantially mitigated the extent of lung injury, indicating a pathomechanistic role for neutrophils in chest trauma-induced septic ALI.

Divergent effects of activated neutrophils on inflammation, Kupffer cell/splenocyte activation, and lung injury following blunt chest trauma.

Polymorphonuclear granulocytes (PMNs) have been attributed a primarily deleterious role in the pathogenesis of acute lung injury (ALI). However, evidence exists that PMNs might also act beneficially in certain types of ALI. In this regard, we investigated the role of activated neutrophils in the pathophysiology of lung contusion-induced ALI. We used the model of blunt chest trauma accompanied by PMN-depletion in male C3H/HeN mice. Animals received 25 µg/g body weight PMN-depleting antibody Gr-1 intravenously 48 h before trauma. Bronchoalveolar lavage (BAL) and lung tissue interleukin 6 (IL-6) were similarly elevated in PMN-depleted and control animals after trauma, whereas macrophage inflammatory protein 2 and monocyte chemoattractant protein 1 in BAL and lungs, IL-10 in BAL, and lung keratinocyte chemoattractant (KC) were even further increased in the absence of PMNs. Plasma IL-6 and KC were also increased in response to the insult and even further in the absence of PMNs. Chest trauma induced an enhanced release of IL-6, tumor necrosis factor α, macrophage inflammatory protein 2, monocyte chemoattractant protein 1, and IL-10 from isolated KU, which was blunted in the absence of PMNs. In the presence of PMNs, BAL protein was further increased at 30 h when compared with the 3-h time point, which was not the case in the absence of PMNs. Taken together, in response to lung trauma, activated neutrophils control inflammation including mediator release from distant immune cells but simultaneously mediate pulmonary tissue damage. Thus, keeping in mind potential inflammatory adverse effects, modulation of neutrophil activation or trafficking might be a reasonable therapeutic approach in chest trauma-induced lung injury.

Inhaled hydrogen sulfide induces suspended animation, but does not alter the inflammatory response after blunt chest trauma.

The treatment of acute lung injury and septic complications after blunt chest trauma remains a challenge. Inhaled hydrogen sulfide (H2S) may cause a hibernation-like metabolic state, which refers to an attenuated systemic inflammatory response. Therefore, we tested the hypothesis that inhaled H2S-induced suspended animation may attenuate the inflammation after pulmonary contusion. Male Sprague-Dawley rats were subjected to blunt chest trauma (blast wave) or sham procedure and subsequently exposed to a continuous flow of H2S (100 ppm) or control gas for 6 h. Body temperature and activity were measured by an implanted transmitter. At 6, 24, or 48 h after trauma, animals were killed, and the cellular contents of bronchoalveolar lavage (BAL) as well as cytokine concentrations in BAL, plasma, and culture supernatants of blood mononuclear cells, Kupffer cells, splenic macrophages, and splenocytes were determined. Hydrogen sulfide inhalation caused a significant reduction in body temperature and activity. The trauma-induced increase in alveolar macrophage counts was abrogated 48 h after trauma when animals received H2S, whereas the trauma-induced increase in neutrophil counts was unaltered. Furthermore, H2S inhalation partially attenuated the mediator release in BAL and culture supernatants of Kupffer cells as well as splenic cells; it altered plasma cytokine concentrations but did not affect the trauma-induced changes in mononuclear cell culture supernatants. These findings indicate that inhaled H2S induced a reduced metabolic expenditure and partially attenuated inflammation after trauma. Nevertheless, in contrast to hypoxic- or pathogen-induced lung injury, H2S treatment appears to have no protective effect after blunt chest trauma.

Alveolar macrophage phagocytosis is enhanced after blunt chest trauma and alters the posttraumatic mediator release.

Blunt chest trauma is known to induce a pulmonary invasion of short-lived polymorphonuclear neutrophils and apoptosis of alveolar epithelial type 2 (AT2) cells. Apoptotic cells are removed by alveolar macrophages (AMΦ). We hypothesized that chest trauma alters the phagocytic response of AMΦ as well as the mediator release of AMΦ during phagocytosis. To study this, male Sprague-Dawley rats were subjected to blunt chest trauma. Phagocytosis assays were performed in AMΦ isolated 2 or 24 h after trauma with apoptotic cells or opsonized beads. Phagocytosis of apoptotic AT2 cells by unstimulated AMΦ was significantly increased 2 h after trauma. At 24 h, AMΦ from traumatized animals, stimulated with phorbol-12-myristate-13-acetate, ingested significantly more apoptotic polymorphonuclear neutrophils than AMΦ from sham animals. Alveolar macrophages after trauma released significantly higher levels of tumor necrosis factor α, macrophage inflammatory protein 1α, and cytokine-induced neutrophil chemoattractant 1 when they incorporated latex beads, but significantly lower levels of interleukin 1ß and macrophage inflammatory protein 1α when they ingested apoptotic cells. In vivo, phagocytosis of intratracheally instilled latex beads was decreased in traumatized rats. The bronchoalveolar lavage concentrations of the phagocytosis-supporting surfactant proteins A and D after blunt chest trauma were slightly decreased, whereas surfactant protein D mRNA expression in AT2 cells was significantly increased after 2 h. These findings indicate that chest trauma augments the phagocytosis of apoptotic cells by AMΦ. Phagocytosis of opsonized beads enhances and ingestion of apoptotic cells downregulates the immunologic response following lung contusion. Our data emphasize the important role of phagocytosis during posttraumatic inflammation after lung contusion.

Cardiopulmonary, histologic, and inflammatory effects of intravenous Na2S after blunt chest trauma-induced lung contusion in mice.

BACKGROUND: When used as a pretreatment, hydrogen sulfide (H2S) either attenuated or aggravated lung injury. Therefore, we tested the hypothesis whether posttreatment intravenous Na2S (sulfide) may attenuate lung injury. METHODS: After blast wave blunt chest trauma or sham procedure, anesthetized and instrumented mice received continuous intravenous sulfide or vehicle while being kept at 37°C or 32°C core temperature. After 4 hours of pressure-controlled, thoracopulmonary compliance-titrated, lung-protective mechanical ventilation, blood and tissue were harvested for cytokine concentrations, heme oxygenase-1, IκBα, Bcl-Xl, and pBad expression (western blotting), nuclear factor-κB activation (electrophoretic mobility shift assay), and activated caspase-3, cystathionine-ß synthase and cystathionine-γ lyase (immunohistochemistry). RESULTS: Hypothermia caused marked bradycardia and metabolic acidosis unaltered by sulfide. Chest trauma impaired thoracopulmonary compliance and arterial Po2, again without sulfide effect. Cytokine levels showed inconsistent response. Sulfide increased nuclear factor-κB activation during normothermia, but this effect was blunted during hypothermia. While histologic lung injury was variable, both sulfide and hypothermia attenuated the trauma-related increase in heme oxygenase-1 expression and activated caspase-3 staining, which coincided with increased Bad phosphorylation and Bcl-Xl expression. Sulfide and hypothermia also attenuated the trauma-induced cystathionine-ß synthase and cystathionine-γ lyase expression. CONCLUSIONS: Posttreatment sulfide infusion after blunt chest trauma did not affect the impaired lung mechanics and gas exchange but attenuated stress protein expression and apoptotic cell death. This protective effect was amplified by moderate hypothermia. The simultaneous reduction in cystathionine-ß synthase and cystathionine-γ lyase expression supports the role of H2S-generating enzymes as an adaptive response during stress states.

Of mice and men (and sheep, swine etc.): the intriguing hemodynamic and metabolic effects of hydrogen sulfide (H2S).

Whether the hydrogen sulfide (H2S)-induced metabolic depression observed in awake rodents exists in larger species is controversial. Therefore, Derwall and colleagues exposed anesthetized and ventilated sheep to incremental H2S concentrations by means of an extracorporeal membrane oxygenator. H2S caused pulmonary vasoconstriction and metabolic acidosis at the highest concentration studied. Oxygen uptake and carbon dioxide production remained in the physiological range. The authors concluded that, beyond the effect of temperature, H2S hardly modifies metabolism at all. Since the highest H2S concentration caused toxic side effects (possibly due to an inhibition of mitochondrial respiration), the therapeutic use of inhaled H2S should be cautioned.

Altered expression of Fas receptor on alveolar macrophages and inflammatory effects of soluble Fas ligand following blunt chest trauma.

Blunt chest trauma impairs the outcome of multiply-injured patients. Lung contusion induces inflammatory alterations and Fas-dependent apoptosis of alveolar type 2 epithelial (AT2) cells has been described. The Fas/Fas ligand (FasL) system seems to exhibit a proinflammatory potential. We aimed to elucidate the involvement of the Fas/FasL system in the inflammatory response after lung contusion. Chest trauma was induced in male rats by a pressure wave. Soluble FasL concentrations were determined in bronchoalveolar lavage fluids and alveolar macrophage (AMΦ) supernatants. Alveolar macrophages and AT2 cells were isolated to determine the surface expression (FACS) of Fas/FasL, the mRNA expression (reverse transcriptase-polymerase chain reaction) of Fas, FasL, TNF-α, IL-6, and IL-10 and to measure the release of IL-6 and IL-10 after culture with or without stimulation with FasL. After chest trauma, FasL concentration was increased in bronchoalveolar lavage fluid, and AMΦ supernatants and Fas and FasL protein were downregulated on AMΦs and unchanged on AT2 cells. The mRNA expression of Fas was increased in AMΦs and AT2 cells and that of FasL only in AMΦs isolated after lung contusion. Fas ligand stimulation further enhanced IL-6 and suppressed IL-10 release in AMΦs after trauma.The results indicate that the Fas/FasL system is activated after chest trauma, and FasL is associated with the inflammatory response after lung contusion. The proinflammatory response of AMΦs is enhanced by FasL stimulation. Both AMΦs and AT2 cells seem to contribute to the mediator release after lung contusion. These results confirm the importance of the Fas/FasL system in the inflammatory response after chest trauma.

Inflammatory effects of hypothermia and inhaled H2S during resuscitated, hyperdynamic murine septic shock.

Inhaling hydrogen sulfide (H2S) reduced energy expenditure resulting in hypothermia. Because the inflammatory effects of either hypothermia alone or H2S per se still are a matter of debate, we tested the hypothesis whether inhaled H2S amplifies the hypothermia-related modulation of the inflammatory response. Fifteen hours after cecal ligation and puncture or sham laparotomy, anesthetized and mechanically ventilated normothermic and hypothermic mice (core temperature kept at 38°C and 27°C, respectively) received either 100 ppm H2S or vehicle. In the sham-operated animals, inhaled H2S and hypothermia alone comparably reduced the plasma chemokine and IL-6 levels, but combining hypothermia and inhaled H2S had no additional effect. The lung tissue cytokine and chemokine patterns revealed a similar response. During sepsis, inhaled H2S reduced the blood cytokine concentrations only, without effects on the plasma chemokine or the lung tissue levels. Again, inhaled H2S had no major additional effect during hypothermia. With or without sepsis, inhaled H2S and hypothermia alone comparably reduced the lung tissue heme oxygenase 1 expression, whereas inhaled H2S had no additional effect during hypothermia. Lung tissue nuclear transcription factor κB activation was reduced by combining H2S with hypothermia in the sham-operated animals, whereas it was increased by inhaled H2S during sepsis. Hypothermia amplified this response. Hence, during anesthesia and mechanical ventilation, inhaled H2S exerted anti-inflammatory effects, which were, however, not amplified by adding deliberate hypothermia. Sepsis attenuated these anti-inflammatory effects of inhaled H2S, which were at least in part independent of the nuclear transcription factor κB pathway.

Is the function of alveolar macrophages altered following blunt chest trauma?

PURPOSE: The purpose of this study was to characterize the local pulmonary inflammatory environment and to elucidate alterations of alveolar macrophage (AMØ) functions after blunt chest trauma. METHODS: Wistar rats were subjected to blunt chest trauma. AMØ were isolated, stimulated, and cultured. Bronchoalveolar lavage (BAL) was collected. Cytokines/chemokines were quantified in the BAL and in AMØ supernatants via ELISA. AMØ phagocytic and chemotactic activity and respiratory burst capacity were assessed. RESULTS: Following chest trauma, a significant increase of IL-1ß (at 6 and 24 h) and IL-6 (at 24 h) in BAL was observed, whereas IL-10 and TNF-α concentrations were not altered. MIP-2 and CINC were substantially increased as early as 6 h and PGE2 early at 10 min, whereas BAL MCP-1 was not elevated until 24 h after trauma. MIP-2 release by AMØ isolated form trauma animals was markedly increased as early as 10 min after injury. IL-1ß and IL-10 exhibited a late increase at 24 h. AMØ TNF-α release was increased at 6 h. At 6 or 24 h, AMØ from trauma animals incorporated significantly more opsonized latex beads than their sham controls, and their chemotactic activity was substantially enhanced at 24 h. AMØ oxidative burst capacity remained largely unchanged. CONCLUSIONS: Already very early after chest trauma, inflammatory mediators are present in the intraalveolar compartment. Additionally, AMØ are primed to release cytokines and chemokines. Blunt chest trauma also changes the phagocytic and chemotactic activity of AMØ. These functional changes of AMØ might enable them to better ward off potential pathogens in the course after trauma.

Inflammatory alterations in a novel combination model of blunt chest trauma and hemorrhagic shock.

BACKGROUND: Chest trauma frequently occurs in severely injured patients and is often associated with hemorrhagic shock. Immune dysfunction contributes to the adverse outcome of multiple injuries. The aims of this study were to establish a combined model of lung contusion and hemorrhage and to evaluate the cardiopulmonary and immunologic response. METHODS: Male mice were subjected to sham procedure, chest trauma, hemorrhage (35 mm Hg±5 mm Hg, 60 minutes), or the combination. Respiratory rate, heart rate, and blood pressure were monitored. Plasma, Kupffer cells, blood monocytes, splenocytes, and splenic macrophages were isolated after 20 hours. Tumor necrosis factor-alpha (TNF-α), interleukin (IL)-6, 10, 12, 18, and macrophage inflammatory protein-2 levels in plasma and culture supernatants were determined. RESULTS: Heart rate and blood pressure dropped in all groups, and after chest trauma and the double hit, these values remained reduced until the end of observation. Blood pressure was lower after the double hit than after the single hits. Plasma and Kupffer cell TNF-α concentrations were increased after lung contusion but not further enhanced by subsequent hemorrhage. Peripheral blood mononuclear cell (PBMC) TNF-α and IL-6 release were suppressed after the combined insult. IL-18 concentrations were increased in PBMC supernatants after chest trauma and in splenic macrophage supernatants of all groups. CONCLUSIONS: Although physiologic readouts were selectively altered in response to the single or double hits, the combination did not uniformly augment the changes in inflammation. Our results suggest that the leading insult regarding the immunologic response is lung contusion, supporting the concept that lung contusion represents an important prognostic factor in multiple injuries.

Blunt chest trauma induces mediator-dependent monocyte migration to the lung.

OBJECTIVE: This study was designed to determine whether lung contusion induces an increased pulmonary recruitment of monocytes as a source of alveolar macrophages and which mediators are involved. SETTING AND DESIGN: Prospective animal study. SUBJECTS AND INTERVENTIONS: Male Sprague-Dawley rats were subjected to chest trauma by a single blast wave. MEASUREMENTS: Chemokine concentrations in bronchoalveolar lavage fluids and supernatants of alveolar macrophages, chemokine and chemokine receptor mRNA expressions in monocytes, pulmonary interstitial macrophages, and alveolar macrophages isolated after trauma or sham procedure were evaluated. Immigration of monocytes was determined by staining alveolar macrophages with the fluorescent marker PKH26 before chest trauma. Chemotaxis of naïve monocytes in response to bronchoalveolar lavage or supernatants from alveolar macrophages isolated after trauma or sham procedure and the migratory response of monocytes isolated after trauma/sham to recombinant chemokines were measured. MAIN RESULTS: Chemokine levels in bronchoalveolar lavage and alveolar macrophage supernatants and the percentage of monocytes migrated to the lungs were increased after chest trauma. Lung contusion enhanced the mRNA expression for CCR2 in monocytes and interstitial macrophages and for monocyte chemotactic protein-1 in alveolar macrophages. Migration of naïve monocytes vs. bronchoalveolar lavage or alveolar macrophage supernatants from traumatized animals was increased when compared with samples from shams. Monocytes isolated 2 hrs after trauma showed a reduced migration to CINC-1 or monocyte chemotactic protein-1 compared with sham. CONCLUSIONS: Alveolar macrophages seem to contribute to increased chemokine concentrations in alveoli of animals subjected to blunt chest trauma. Mediators released by alveolar macrophage are potent stimuli for monocyte migration. Monocytes alter their chemokine receptor expression and are recruited to the lungs.

Cardiac and metabolic effects of hypothermia and inhaled hydrogen sulfide in anesthetized and ventilated mice.

OBJECTIVE: To test the hypothesis whether inhaled hydrogen sulfide amplifies the effects of deliberate hypothermia during anesthesia and mechanical ventilation as hypothermia is used to provide organ protection after brain trauma or circulatory arrest. Awake mice inhaling hydrogen sulfide exhibit reduced energy expenditure, hypothermia, and bradycardia despite unchanged systolic heart function. In rodents, anesthesia alone causes decreased metabolic rate and thus hypothermia and bradycardia. DESIGN: Prospective, controlled, randomized study. SETTING: University animal research laboratory. SUBJECTS: Male C57/B6 mice. INTERVENTIONS: After surgical instrumentation (central venous, left ventricular pressure-conductance catheters, ultrasound flow probes on the portal vein and superior mesenteric artery), normo- or hypothermic animals (core temperature = 38 degrees C and 27 degrees C) received either 100 ppm hydrogen sulfide or vehicle over 5 hrs (3 hrs hydrogen sulfide during normothermia). MEASUREMENTS AND MAIN RESULTS: During normothermia, hydrogen sulfide had no hemodynamic or metabolic effect. With or without hydrogen sulfide, hypothermia decreased blood pressure, heart rate, and cardiac output, whereas stroke volume, ejection fraction, and end-diastolic pressure remained unaffected. Myocardial and hepatic oxidative deoxyribonucleic acid damage (comet assay) and endogenous glucose production (rate of appearance of 1,2,3,4,5,6-13C6-glucose) were similar in all groups. Hypothermia comparably decreased CO2 production with or without inhaled hydrogen sulfide. During hypothermia, inhaled hydrogen sulfide increased the glucose oxidation rate (derived from the expiratory 13CO2/12CO2 ratio). This shift toward preferential carbohydrate utilization coincided with a significantly attenuated responsiveness of hepatic mitochondrial respiration to stimulation with exogenous cytochrome-c-oxidase (high-resolution respirometry). CONCLUSIONS: In anesthetized and mechanically ventilated mice, inhaled hydrogen sulfide did not amplify the systemic hemodynamic and cardiac effects of hypothermia alone. The increased aerobic glucose oxidation together with the reduced responsiveness of cellular respiration to exogenous cytochrome-c stimulation suggest that, during hypothermia, inhaled hydrogen sulfide improved the yield of mitochondrial respiration, possibly via the maintenance of mitochondrial integrity. Hence, inhaled hydrogen sulfide may offer metabolic benefit during therapeutic hypothermia.

Pulmonary contusion induces alveolar type 2 epithelial cell apoptosis: role of alveolar macrophages and neutrophils.

Alveolar type 2 (AT-2) cell apoptosis is an important mechanism during lung inflammation, lung injury, and regeneration. Blunt chest trauma has been shown to activate inflammatory cells such as alveolar macrophages (AMs) or neutrophils (polymorphonuclear granulocytes [PMNs]), resulting in an inflammatory response. The present study was performed to determine the capacity of different components/cells of the alveolar compartment (AMs, PMNs, or bronchoalveolar lavage [BAL] fluids) to induce apoptosis in AT-2 cells following blunt chest trauma. To study this, male Sprague-Dawley rats were subjected to either sham procedure or blunt chest trauma induced by a single blast wave. Various time points after injury (6 h to 7 d), the lungs were analyzed by immunohistochemistry, for AT-2 cells, or with antibodies directed against caspase 3, caspase 8, Fas, Fas ligand (FasL), BAX, and BCL-2. Bronchoalveolar lavage concentrations of TNF-alpha, IL-1beta, and soluble FasL were determined by enzyme-linked immunosorbent assay. Furthermore, cultures of AT-2 cells isolated from healthy rats were incubated with supernatants of AMs, PMNs, or BAL fluids obtained from either trauma or sham-operated animals in the presence or absence of oxidative stress. Annexin V staining or TUNEL (terminal deoxynucleotidyl transferase) assay was used to detect apoptotic AT-2 cells. Histological evaluation revealed that the total number of AT-2 cells was significantly reduced at 48 h following trauma. Fas, FasL, active caspase 8, and active caspase 3 were markedly up-regulated in AT-2 cells after chest trauma. BAX and BCL-2 did not show any significant changes between sham and trauma. IL-1beta, but not TNF-alpha, levels were markedly increased at 24 h after the injury, and soluble FasL concentrations were significantly enhanced at 6, 12, 24, and 48 h after the insult. Apoptosis of AT-2 cells incubated with supernatants from cultured AMs, isolated at 48 h following chest trauma was markedly increased when compared with shams. In contrast, no apoptosis was induced in AT-2 cells incubated with supernatants of activated PMNs or BAL fluids of traumatized animals. In summary, blunt chest trauma induced apoptosis in AT-2 cells, possibly involving the extrinsic death receptor pathway. Furthermore, mediators released by AMs appeared to be involved in the induction of AT-2 cell apoptosis.

The pulmonary and hepatic immune microenvironment and its contribution to the early systemic inflammation following blunt chest trauma.

OBJECTIVE: Blunt chest trauma is accompanied by an early increase in plasma cytokine concentrations. However, the local sources of these mediators are poorly defined. We investigated the impact of blunt chest trauma on the inflammatory mediator milieu in different compartments (lung tissue, bronchoalveolar lavage, liver tissue, Kupffer cells, plasma) along with the time course of trauma-induced pulmonary endothelial barrier dysfunction to elucidate potential relationships. In addition, the correlation between intratracheally instilled interleukin-6 and its systemic release were studied. DESIGN: Prospective, randomized, controlled animal study. SETTING: Basic science laboratory of a university affiliated level 1 trauma center. SUBJECTS: Male C3H/HeN mice, 8-9 wks old, n = 141. INTERVENTIONS: Blunt chest trauma induced by a focused blast wave, intravenous injection of Evans blue, and intratracheal instillation of recombinant human interleukin-6. MEASUREMENTS AND MAIN RESULTS: Two hours after blunt chest trauma, plasma interleukin-6 was markedly increased. Simultaneously, interleukin-6, tumor necrosis factor-alpha, macrophage inflammatory protein-2, monocyte chemotactic polypeptide-1 and neutrophil/monocyte accumulation in bronchoalveolar lavage and interleukin-6, monocyte chemotactic polypeptide-1, and myeloperoxidase activity in lung tissue were significantly increased. This was accompanied by a coinciding elevation in the Evans blue lung-plasma ratio. Recombinant human interleukin-6, instilled intratracheally before blunt chest trauma, was detected in a dose-dependent manner in the plasma of the mice. Additionally, Kupffer cell interleukin-6, tumor necrosis factor-alpha, and interleukin-10 production was significantly augmented as early as 30 mins after the insult. CONCLUSIONS: These results indicate that early increased cytokine concentrations in the lung, particularly interleukin-6, are important mediator sources as their local peak coincides with the systemic inflammatory response and is accompanied by a simultaneous impaired function of the pulmonary endothelial barrier. A direct relationship between their local and systemic concentrations can be established. Furthermore, this is the first study to show that Kupffer cells are activated early after blunt chest trauma.

Pulmonary contusion causes impairment of macrophage and lymphocyte immune functions and increases mortality associated with a subsequent septic challenge.

OBJECTIVE AND DESIGN: Pulmonary contusion is frequently followed by acute respiratory distress syndrome, pneumonia, and sepsis. However, immunologic alterations of circulating and resident immune cell populations contributing to the posttraumatic immunosuppression are poorly understood. We therefore characterized the influence of pulmonary contusion on peripheral blood mononuclear cells, peritoneal macrophages, splenocytes, and splenic macrophages. To address the significance of the immunosuppression associated with lung contusion, we investigated how the consecutive addition of moderate or severe sepsis affected survival after blunt chest trauma. SUBJECTS: Male C3H/HeN mice (n = 10 per group) were anesthetized and subjected to chest trauma or sham procedure. MEASUREMENTS: The cytokine release of cultured peripheral blood mononuclear cells, peritoneal macrophages, splenocytes, and splenic macrophages and plasma levels of tumor necrosis factor-alpha and interleukin-6 from those animals were quantified. Sepsis was induced via cecal ligation and puncture 24 hrs after lung contusion. MAIN RESULTS: Two hours after blunt chest trauma, plasma tumor necrosis factor-alpha and interleukin-6 were markedly increased, as was peripheral blood mononuclear cell cytokine production, lung myeloperoxidase activity, and lung chemokine concentrations. At 24 hrs and, in part, already at 2 hrs, cytokine release from peritoneal macrophages, splenic macrophages, and splenocytes was significantly suppressed. Furthermore, pulmonary contusion when followed by moderate sepsis significantly diminished survival rate when compared with chest trauma or moderate sepsis alone. CONCLUSIONS: These results indicate that pulmonary contusion causes severe immunodysfunction of splenocytes, macrophages, and monocytes in different local compartments and systemically. Moreover, this immunosuppression is associated with an increased susceptibility to infectious complications, which results in a decreased survival rate if blunt chest trauma is followed by a septic insult.

Blunt chest trauma induces delayed splenic immunosuppression.

Severe blunt chest trauma is frequently associated with multiple organ failure and sepsis. Posttraumatic immunosuppression seems to play a major role in their development. However, the immunologic alterations following pulmonary contusion are insufficiently elucidated. Specifically, it remains unknown whether immunocompetent cells located distant from the site of the impact are affected. We therefore aimed to characterize the influence of pulmonary contusion on lymphocytes and splenic macrophages. Male C3H/HeN mice (n = 8-10/group) were anesthetized and subjected to trauma or sham procedure. Blunt chest trauma was induced by a blast wave focused on the thorax. Two or 24 h later, splenocytes and splenic macrophages were isolated and stimulated for 48 h. The cytokine release (IFN-gamma, IL-2, IL-3, IL-10, IL-12, IL-18) from splenocytes as well as from splenic macrophages (TNF-alpha, IL-10, IL-12, IL-18) and plasma levels of TNF-alpha and IL-6 were quantified by ELISA. The results indicate that at 2 h after blunt chest trauma, plasma TNF-alpha and IL-6 were markedly increased. At the same time, no differences in splenocyte cytokine production were detectable. However, at 24 h a significantly depressed cytokine release was observed in trauma animals. Furthermore, splenic macrophages showed a significantly decreased production of TNF-alpha, IL-10, and IL-12 at 24 h and markedly increased release of IL-18 at 2 h after trauma. These results indicate that blunt chest trauma causes severe immunodysfunction of lymphocytes and splenic macrophages. Thus, lung contusion as a localized type of trauma causes dysfunction of immunocompetent cell populations, which are located distant from the site of injury.

Induction of apoptosis following blunt chest trauma.

The cause for the high morbidity of blunt chest trauma is not fully understood. It is still unclear if and to what extent a second insult, e.g., apoptotic tissue damage initiated by the primary insult itself, may contribute to the development of serious complications. This study was done to elucidate whether a pulmonary contusion may induce programmed cell death. Sixty-four Wistar rats were evenly randomized to eight experimental groups: four sets were subjected to a standardized blast wave injury and sacrificed 6, 24, 48, and 72 h after the trauma; four groups served as controls for the same time points. Lung and liver samples were stained (H & E; TUNEL), and PMN infiltration was determined by myeloperoxidase (MPO) activity. Caspase 8 was analyzed by Western blot, and TNF-alpha plasma levels by ELISA. Postmortem examination revealed bilateral pulmonary contusion in trauma animals with higher (P < 0.05) numbers of apoptotic cells in lung but not in liver tissue as early as 6 h after the injury. This amount gradually increased and reached a maximum after 48 h: 6.8 +/- 1.1 apoptotic cells/hpf vs. 0.6 +/- 0.06 in controls. Chest trauma caused an increased expression of active caspase 8 in lung but not in liver tissue at 48 and 72 h. TNF-alpha plasma levels were not different. MPO activity in lung tissue of trauma animals increased (P < 0.05) after 6 h and peaked at 72 h. This study has provided the first evidence that apoptotic cell death in lung tissue is initiated following (experimental) pulmonary contusion. The exact mechanism remains, however, unclear and has to be elucidated further.

Cardiopulmonary, histological, and inflammatory alterations after lung contusion in a novel mouse model of blunt chest trauma.

Severe blunt chest trauma remains an important injury with high morbidity and mortality. However, the associated immunological alterations are poorly understood. Existing big animal models require large-scale settings, are often too expensive, and research products for immunological studies are limited. In this study we aimed to establish a new model of blunt, isolated and bilateral chest trauma in mice and to characterize its effects on physiological and inflammatory variables. Male C3H/HeN mice (n = 9-10/group) were anesthetized and a femoral artery was catheterized. The animals were subjected to trauma or sham procedure and monitored for 180 min. Blunt chest trauma was induced by a blast wave focused on the thorax. Trauma intensity was optimized by varying the exposure distance. Blood pressure, heart rate, respiratory rate, arterial blood gases and plasma cytokine levels were measured. Macroscopic and microscopic examinations were performed. In addition, outcome was evaluated in a 10-day survival study. Chest trauma caused a drop (P < 0.05) in blood pressure and heart rate, which partly recovered. Blood gases revealed hypoxemia and hypercarbia (P < 0.05) 180 min after trauma. There was marked damage to the lungs but none to abdominal organs. Histologically, the characteristic signs of a bilateral lung contusion with alveolar and intrabronchial hemorrhage were found. Plasma interleukin-6 and tumor necrosis factor alpha were considerably increased after 180 min. Blunt chest trauma resulted in an early mortality of 10% without subsequent death. On the basis of these findings, this novel mouse model of blunt chest trauma appears suitable for detailed studies on immunological effects of lung contusion.

Sex-specific p38 MAP kinase activation following trauma-hemorrhage: involvement of testosterone and estradiol.

Although immune functions are markedly depressed in males and not in proestrous females following trauma-hemorrhage (T-H), the mechanisms responsible for the divergent responses remain unknown. Because sex steroids modulate the activation of p38, our aim was to determine whether differences in the activation of p38 by phosphorylation (p38-P) might contribute to the sex-dimorphic immune response following T-H. The effects of testosterone and estradiol on the activation of p38 were also examined. Intact male mice (C3H/HeN), castrated males treated with vehicle, 5alpha-dihydrotestosterone (DHT), or 17beta-estradiol, and proestrous females were subjected to trauma (i.e., midline laparotomy) and hemorrhagic shock (35 +/- 5 mmHg for 90 min and resuscitation) or sham operation. At 2 h thereafter, splenic (SMphi) and peritoneal macrophages (PMphi) were harvested and cultured (with 10 microg/ml LPS), and Western blot analysis was carried out for quantification of p38 and p38-P. Sex, testosterone and estradiol plasma levels, and T-H did not alter the constitutive expression of p38 in SMphi and PMphi. In contrast, the activated form of p38 (p38-P) was markedly increased in SMphi and PMphi from female shams compared with male shams. Moreover, the phosphorylation of p38-P increased in males after T-H, whereas it decreased in females under those conditions. Castration before T-H prevented the increase in p38-P in males. Castrated animals treated with DHT displayed increased p38-P following T-H, whereas 17beta-estradiol had no effect on p38-P in castrated mice. Thus 1) sex influences the activation of p38 MAP kinase, 2) DHT is responsible for the increased activation of p38 in male mice, and 3) this sex-specific activation of p38 might be responsible for the sexually dimorphic immune response following T-H.