Value of Serum Cholinesterase Activity in the Diagnosis of Septic Shock Due to Bacterial Infections.

BACKGROUND: We aimed to investigate whether serum cholinesterase (SChE) activity can be helpful for the diagnosis of septic shock and to evaluate its usefulness in comparison with procalcitonin (PCT) and C-reactive protein (CRP). METHODS: A prospective single-blinded study conducted in an intensive care unit of university hospital. Patients were classified as having cardiogenic shock, septic shock, or hemorrhagic shock. We also included a control group without neither hemodynamic instability nor sepsis. For all included patients, SChE, PCT, and CRP were simultaneously sampled. RESULTS: The comparison of sepsis markers between all groups showed that the mean values of PCT and CRP were significantly higher in patients with septic shock. However, SChE activity was significantly lower in this group. The SChE activity was found to be more accurate than PCT and CRP for the diagnosis of septic shock. In fact, an SChE activity ≤ 4000 UI/L predicted the diagnosis of septic shock with a sensitivity of 78%, a specificity of 89%, a predictive negative value of 97%, and a predictive positive value of 65%. However, the prognostic value of SChE activity was poor in multivariate analysis. CONCLUSION: The SChE activity level was significantly decreased in patients with septic shock. However, its prognostic value is poor. Our results suggest that SChE activity is useful for the diagnosis of septic shock. Further studies are warranted to confirm our findings.

Fluid resuscitation with hemoglobin vesicles prevents Escherichia coli growth via complement activation in a hemorrhagic shock rat model.

Hemoglobin vesicles (HbVs) could serve as a substitute for red blood cells (RBCs) in resuscitation from massive hemorrhage. A massive transfusion of RBCs can increase the risk of infection, which is not caused by contaminating micro-organisms in the transfused RBCs but by a breakdown of the host defense system. We previously found that complement activity was increased after resuscitation with HbVs at a putative dose in a rat model of hemorrhagic shock. It is known that complement system plays a key role in host defense in the embryonic stage. Therefore, the objective of this study was to address whether the suppression of bacterial infections in hemorrhagic shock rats was a result of increased complement activity after massive HbV transfusion. For this purpose, Escherichia coli were incubated with plasma samples obtained from a rat model of hemorrhagic shock resuscitated by HbVs or RBCs, and bacterial growth was determined under ex vivo conditions. As a result, E. coli growth was found to be suppressed by increased complement activity, mediated by the production of IgM from spleen. However, this antibacterial activity disappeared when the E. coli were treated with complement-inactivated plasma obtained from splenoctomized rats. In addition, the resuscitation of HbVs from hemorrhagic shock increased the survival rate and viable bacterial counts in blood in cecum ligation and puncture rats, a sepsis model. In conclusion, the resuscitation of HbVs in the rat model of hemorrhagic shock suppresses bacterial growth via complement activation induced by IgM.

Stress-related changes in the gut microbiome after trauma.

BACKGROUND: The gut microbiome protects the host from infection by promoting epithelial integrity and providing basal immunologic stimulation. Disruption of this delicate ecosystem is linked to morbidity and mortality among critically ill patients, but the impact of traumatic injury on the gut microbiome is poorly understood. This study sought to identify alterations in gut microbiota following trauma and persistent stress in rodents without confounding antibiotics. METHODS: Male Sprague-Dawley rats aged 9 weeks to 11 weeks were randomized to naive, lung contusion with hemorrhagic shock (LCHS), and LCHS plus either 7 (LCHS/CS 7/7) or 14 days (LCHS/CS 14) of restraint cylinder stress for 2 hours daily. Stool was collected on Days 0, 3, 7, and 14 for bacterial whole genome DNA isolation. Alpha diversity, or the number and relative abundance of unique bacterial species within each cohort, was assessed using Chao1 indices. Beta diversity, or the measure of differences in biodiversity across cohorts, was assessed by principle coordinate analysis. False discovery rate correction was applied to all statistical analyses and corrected for cohousing effects. RESULTS: Rodent groups subject to restraint stress demonstrated a progressive increase in alpha diversity over time. These microbiota changes resolved after cessation of stress (LCHS/CS 7/7) but continued to increase among rats subjected to ongoing stress (LCHS/CS 14). The LCHS/CS 7/7 also demonstrated reductions in class Actinobacteria and increased abundance of the genus Bacteroides by Day 7, which resolved by Day 14. Increased abundance of Bacteroides was also noted in the LCHS/CS 14 cohort, suggesting the role of chronic stress in its destabilization. CONCLUSION: This study points to persistent stress as a potential source of the destabilization of microbial diversity seen after trauma. This lack of microbiota stability could be associated with worse long-term outcomes in critically ill trauma patients. Further studies are warranted to elucidate mechanistic pathways and potential therapeutic modalities.

Role of TLR5 in the Translocation and Dissemination of Commensal Bacteria in the Intestine after Traumatic Hemorrhagic Shock.

Enterogenous infection is a major cause of death during traumatic hemorrhagic shock (THS). It has been reported that Toll-like receptor 5 (TLR5) plays an integral role in regulating mucosal immunity and intestinal homeostasis of the microbiota. However, the roles played by TLR5 on intestinal barrier maintenance and commensal bacterial translocation post-THS are poorly understood. In this research, we established THS models in wild-type (WT) and Tlr5-/- (genetically deficient in TLR5 expression) mice. We found that THS promoted bacterial translocation, while TLR5 deficiency played a protective role in preventing commensal bacteria dissemination after THS. Furthermore, intestinal microbiota analysis uncovered that TLR5 deficiency enhanced the mucosal biological barrier by decreasing RegIIIγ-mediated bactericidal activity against G+ anaerobic bacteria. We then sorted small intestinal TLR5+ lamina propria dendritic cells (LPDCs) and analyzed TH1 differentiation in the intestinal lamina propria and a coculture system consisting of LPDCs and naïve T cells. Although TLR5 deficiency attenuated the regulation of TH1 polarization by LPDCs, it conferred stability to the cells during THS. Moreover, retinoic acid (RA) released from TLR5+ LPDCs could play a key role in modulating TH1 polarization. We also found that gavage administration of RA alleviated bacterial translocation in THS-treated WT mice. In summary, we documented that TLR5 signaling plays a pivotal role in regulating RegIIIγ-induced killing of G+ anaerobic bacteria, and LPDCs mediated TH1 differentiation via RA. These processes prevent intestinal bacterial translocation and enterogenous infection after THS, suggesting that therapeutically targeting LPDCs or gut microbiota can interfere with bacterial translocation after THS.

Rapid evolution and host immunity drive the rise and fall of carbapenem resistance during an acute Pseudomonas aeruginosa infection.

It is well established that antibiotic treatment selects for resistance, but the dynamics of this process during infections are poorly understood. Here we map the responses of Pseudomonas aeruginosa to treatment in high definition during a lung infection of a single ICU patient. Host immunity and antibiotic therapy with meropenem suppressed P. aeruginosa, but a second wave of infection emerged due to the growth of oprD and wbpM meropenem resistant mutants that evolved in situ. Selection then led to a loss of resistance by decreasing the prevalence of low fitness oprD mutants, increasing the frequency of high fitness mutants lacking the MexAB-OprM efflux pump, and decreasing the copy number of a multidrug resistance plasmid. Ultimately, host immunity suppressed wbpM mutants with high meropenem resistance and fitness. Our study highlights how natural selection and host immunity interact to drive both the rapid rise, and fall, of resistance during infection.

Effects of Hypertonic Saline and Hydroxyethyl Starch on Myeloid-Derived Suppressor Cells in Hemorrhagic Shock Mice under Secondary Bacterial Attack.

OBJECTIVES: The primary target is to reveal whether the resuscitation with hypertonic saline (HTS) or hydroxyethyl starch (HES) would have different effects on the myeloid-derived suppressor cell (MDSC) count and monocytic MDSC (M-MDSC)/granulocytic/neutrophilic MDSC (G-MDSC) rate in the peripheral blood, spleen, and bone marrow nucleated cells (BMNC) in a controlled hemorrhagic shock mouse model under secondary Escherichia coli bacterial infection attack, comparing to resuscitation with normal saline (NS) in 72 hours. METHOD: After hemorrhagic shock with bacteremia, which is induced by Escherichia coli bacterial infection attack, comparing to resuscitation with normal saline (NS) in 72 hours. Method. After hemorrhagic shock with bacteremia, which is induced by Escherichia coli 35218 injection, the mice were distributed into control, NS, HTS, and HES groups. The peripheral blood nucleated cells (PBNC), spleen single-cell suspension, and bone marrow nucleated cells were collected. The flow cytometry was used to detect the MDSC, M-MDSC, and G-MDSC. RESULT: In PBNC, after resuscitation with NS, the MDSC was continuously higher, while the rate of M-MDSC/G-MDSC were continuously lower (P < 0.05). In HTS, the MDSC varied, higher at 24 and 72 hours (P < 0.05). In HTS, the MDSC varied, higher at 24 and 72 hours (P < 0.05). In HTS, the MDSC varied, higher at 24 and 72 hours (P < 0.05). In HTS, the MDSC varied, higher at 24 and 72 hours (P < 0.05). In HTS, the MDSC varied, higher at 24 and 72 hours (P < 0.05), the M-MDSC/G-MDSC were continuously lower (P < 0.05). In the spleen, resuscitation with HTS, the M-MDSC/G-MDSC were continuously lower (P < 0.05). In BMNC, after resuscitation with HES, the M-MDSC/G-MDSC were lower at 24 and 72 hours (P < 0.05). CONCLUSION: In mouse hemorrhagic shock model with bacterial infection, the resuscitation with NS, HTS, or HES induced difference changes in MDSC and M-MDSC/G-MDSC, which were time-dependent and organ-specific. Resuscitation with crystalloid, like NS or HTS, showed longer effects on the MDSC and M-MDSC/G-MDSC in peripheral blood; while HTS has a longer effect on M-MDSC/G-MDSC in the spleen, HES has a stronger impact on the differentiation regulation of MDSC to G-MDSC in the bone marrow.

[Protective effects of micro-encapsulated Bifidobacteria on gut barrier after hemorrhagic shock and resuscitation: experiment with rats].

OBJECTIVE: To investigate the effects of micro-encapsulated bifidobacteria on gut barrier and bacterial translocation after hemorrhagic shock and resuscitation. METHODS: Sprague-Dawley rats were divided into 6 groups: PBS+sham shock group fed with PBS for 7 days and then undergoing sham shock, bifidobacteria+sham shock group fed with bifidobacteria (10(9) cfu/d) for 7 days and then undergoing sham shock, micro-encapsulated bifidobacteria+sham shock group, fed with micro-encapsulated bifidobacteria (10(9) cfu/d) for 7 days and then undergoing sham shock, PBS+hemorrhagic shock group fed with PBS for 7 days and then undergoing hemorrhagic shock, bifidobacteria+shock group fed with bifidobacteria for 7 days and then undergoing hemorrhagic shock, and micro-encapsulated bifidobacteria+shock group, fed with micro-encapsulated bifidobacteria for 7 days and then undergoing hemorrhagic shock. Three hours after resuscitation laparotomy was performed, distal cecum was resected to undergo bacteriological analysis of the cecal content, mesenteric lymph nodes (MLNs), a liver lobe, and the middle part of spleen were resected to undergo bacterial culture for bacterial translocation, and the terminal ileum was resected to observe the villous damage. RESULTS: There was no significant difference in the amount of blood loss among the 3 hemorrhagic shock groups. The amounts of aerobes in cecum of the bifidobacteria+shock and micro-encapsulated bifidobacteria+shock groups, especially that of the latter group, were significantly lower than that of the PBS+shock group. The amounts of anaerobes and the amounts of bifidobacteria in cecum of the bifidobacteria+shock group and micro-encapsulated bifidobacteria+shock group, especially those of the latter group, were significantly higher than those of the PBS+shock group. No bacterial translocation to liver was observed in all groups. The magnitudes of total aerobes translocation in spleen of the bifidobacteria+shock and encapsulated bifidobacteria+shock groups were significantly lower than that of the PBS+shock group, however, there were not significant differences in the translocation in the MLN of total aerobes ad bifidobacteria among different groups. The percentage of ileal villous damage of the bifidobacteria+shock and encapsulated bifidobacteria+shock groups were significantly lower than that of the PBS+shock group. CONCLUSION: Bifidobacteria effectively protects the gut barrier, reduces bacterial translocation from the gut after hemorrhagic shock and resuscitation. And micro-encapsulated Bifidobacteria can enhance those effects further.

[Role of intestinal lymphatic pathway in pathogenesis of intestine-derived bacteria/endotoxin translocation in rats in shock].

OBJECTIVE: To observe the changes of toxic substances in mesenteric lymph and portal vein blood of rats in hemorrhagic shock, and the influence of mesenteric lymph duct ligation on level of endotoxin (ET) in organs and bacterial contents in mesenteric lymph nodes (MLN) and spleen in rats with hemorrhagic shock, and to evaluate the role of lymphatic pathway in pathogenesis of intestine-derived bacteria/endotoxin translocation (BET) in rats with shock. METHODS: Twenty-four male Wistar rats were randomly divided into the shock group and control group. A model of serious hemorrhagic shock was reproduced by blood shedding to maintain the blood pressure at 40 mm Hg (1 mm Hg=0.133 kPa) for 90 minutes under aseptic condition, and MLN and portal vein blood were harvested. The specimens were also obtained in control group. The contents of ET, tumor necrosis factor-alpha (TNF-alpha) and interleukin-6 (IL-6) were determined in them. Thirty male Wistar rats were randomly divided into the sham operation group, shock group and lymphatic duct ligation group. Mesenteric lymph ducts were ligated after resuscitation. All rats were sacrificed, and lung, liver, heart and kidney were removed and homogenized for determination of the content of ET. MLN and spleen homogenates were subjected to bacterial culture. RESULTS: The contents of ET, TNF-alpha and IL-6 in lymph were significantly higher than those of plasma in shock group, and also higher than that in normal plasma and normal lymph (all P<0.01). In shock group the contents of ET in lung, liver, heart and renal homogenate 3 and 6 hours after transfusion and resuscitation were significantly higher than those of sham operation group and ligation group (P<0.05 or P<0.01). Bacterial culture of MLN and spleen in shock group rats 3 and 6 hours after transfusion and resuscitation was positive, but it was not in ligation group. CONCLUSION: The results demonstrate that the intestinal lymphatic pathway plays an important role after compromise of gut barrier function in carrying out BET after hemorrhagic shock.

[Effects of gavage with lactococcus lactis recombinant heme oxygenase-1 gene on inflammation of intestine and bacterial translocation in rats with hemorrhagic shock].

OBJECTIVE: To evaluate the effects of gavage with lactococcus lactis (L. Lactis) recombinant heme oxygenase-1 (HO-1) gene on alleviation of intestinal inflammation and protection of the intestinal mucosa in rats with hemorrhagic shock. METHODS: A model of rats with hemorrhagic shock was reproduced in 30 healthy SD male rats. The rats were randomly divided into the L. Lactis recombinant HO-1 gene group (HO group, n=10), L. Lactis group (LL group, n=10) and phosphate buffer group (PBS group, n=10). These agents were respectively gavaged 24 hours before the experiment. Rats were re-anesthetized 1 hour after fluid resuscitation. The mortality, myeloperoxidase (MPO) activity, bacterial translocation, the pathologic changes, the contents of HO-1, tumor necrosis factor-alpha (TNF-alpha) and interleukin-10 (IL-10) in the intestine were determined and compared. RESULTS: Compared with LL group and PBS group, the mortality, Chiu's grade and the bacterial translocation rate of HO group were significantly decreased (all P<0.05) but the content of HO-1 and the level of IL-10 in HO group were markedly increased (both P<0.05). Compared with HO group and LL group, the MPO activity of PBS group was obviously increased (P<0.05). CONCLUSION: The recombinant L. Lactis has the effect to deliver HO-1, which has protective effect on the intestinal mucosa in lessening the inflammation of the intestine and the incidence of bacterial translocation.

[Comparison of effects of two kinds of fluid for resuscitation on bacterial translocation and inflammation of small intestine in rats with hemorrhagic shock].

OBJECTIVE: To investigate the effects of Ringer's solution (RS) or 6% hydroxyethyl saline (HES) on bacterial translocation and inflammation of the small intestine in rats with hemorrhagic shock. METHODS: Fifty healthy male SD rats were randomly divided into the sham group (SHA group, n=10), the Ringer's solution group (RS group, n=20) and 6% hydroxyethyl saline group (HES group, n=20). Controlled hemorrhagic shock model was reproduced in RS and HES groups. Bacterial translocation to the liver, the content of tumor necrosis factor-alpha (TNF-alpha) in intestinal tissue, and the myeloperoxidase (MPO) activity in the intestinal tissue were determined and compared among the groups, and the pathologic changes in the small intestine were observed. RESULTS: The mortality rate, bleeding volume and Chiu's scores were same in HES and RS groups (all P>0.05). Compared to SHA group, bacterial count and TNF-alpha level were increased significantly in HES and RS groups, and they were higher at 1 hour and lower at 24 hours in HES group than those in RS group. Compared to the SHA group, MPO activity increased at 1 hour in RS and HES groups, but no significant difference between the groups was found at 24 hours. CONCLUSION: RS prevents compromise of the intestinal barrier function better than the HES at 1 hour after fluid resuscitation. However, HES seems to be better in protecting the intestinal barrier function compared with RS at 24 hours after fluid resuscitation.

Enhanced Innate Inflammation Induced by Anti-BTLA Antibody in Dual Insult Model of Hemorrhagic Shock/Sepsis.

Sepsis following hemorrhagic shock is a common clinical condition, in which innate immune system suffers from severe suppression. B and T lymphocyte attenuator (BTLA) is an immune-regulatory coinhibitory receptor expressed not only on adaptive, but also on innate immune cells. Our previous data showed that BTLA gene deficient mice were protected from septic mortality when compared with wild-type control C57BL/6 mice. Here, we extended our study by treating C57BL/6 mice with an anti-BTLA monoclonal antibody (clone 6A6; reported to have the ability to neutralize or agonize/potentiate BTLA signaling) in a mouse model of hemorrhagic shock (Hem) followed by sepsis induced by cecal ligation and puncture (CLP); positing initially that if BTLA engagement was neutralized, like gene deficiency, an anti-BTLA mAb would have the similar effects on the inflammatory response/morbidity in these mice after such insults. Here, we report that BTLA expression is elevated on innate immune cells after Hem/CLP. However, anti-BTLA antibody treatment increased cytokine (TNF-α, IL-12, IL-10)/chemokine (KC, MIP-2, MCP-1) levels and inflammatory cells (neutrophils, macrophages, dendritic cells) recruitment in the peritoneal cavity, which in turn aggravated organ injury and elevated these animals' mortality in Hem/CLP. When compared with the protective effects of our previous study using BTLA gene deficient mice in a model of lethal septic challenge, we further confirmed BTLA's contribution to enhanced innate cell recruitment, elevated IL-10 levels, and reduced survival, and that engagement of antibody with BTLA potentiates/exacerbates the pathophysiology in Hem/sepsis.

A comparison of survival at different degrees of hemorrhagic shock in germ-free and germ-bearing rats.

We have previously reported superior survival after one level of hemorrhagic shock in germ-free (GF) rats compared with germ-bearing (GB) rats. The objective of this study was to determine the effect of the GF state on survival at different degrees of hemorrhagic shock. GF and GB rats were bled to a mean arterial blood pressure of 30 mmHg. Shock was terminated after 10, 20, 40, or 80% of the maximum shed blood volume was reabsorbed spontaneously. Both shock time and time to decompensation were significantly longer in GF rats (p < .05). Comparative survival was greater for GF rats at most levels of shock (p < .01). This superiority in survival was greatest at moderate shock levels and decreased at severe shock levels. There may be several reasons for the increased tolerance of GF animals to hemorrhagic shock such as metabolic or immunologic variations. It is hard to avoid the fact, however, that the most notable difference between the GF and GB rat is the presence or absence of bacteria.

The role of bacterial translocation on neutrophil activation during hemorrhagic shock in rats.

Some biological responses to hemorrhage have been reported to be associated with bacterial translocation (BT). While the relationship between peripheral blood neutrophils and BT in the late phase of hemorrhagic shock or burn injury has been reported, this relationship in the early phase has not been fully elucidated. We investigate the role of BT in neutrophil activation and priming during hemorrhagic shock. The experimental rats were divided into three groups: a group with normal intestinal flora (NF group), an antibiotic-decontaminated group (AD group), and a sham shock group with normal intestinal flora (sham group). Hemorrhagic shock was induced in the NF and AD groups (MAP 30 mm Hg for 30-90 min). The rats were sacrificed at 30, 60, or 90 min following the shock induction. Cultures were taken from the liver, spleen, mesenteric lymph nodes (MLNs), and systemic blood to assess the occurrence of BT. Hydrogen peroxide generation and CD11b/c expression were assayed by flow cytometry to evaluate peripheral blood neutrophil activation and priming, respectively. In the NF group, significant BT to the MLNs and spleen was noted from 30 min after the shock induction, and significant hydrogen peroxide generation was also noted from 30 min. The expression of CD11b/c on neutrophils was significantly up-regulated at 90 min after the shock induction. Furthermore, BT, as also the aforementioned parameters of neutrophil function, was significantly suppressed in the AD group. We, therefore, concluded that neutrophil activation and priming during hemorrhagic shock might be closely related to BT, and that infectious factors possibly influence the host responses starting from the early phase of damage, even in noninfectious stress-inducing conditions.

Does intravenous glutamine prevent bacterial translocation in hemorrhagic shock?

Bacterial translocation across the gut wall may be associated with insult to the latter. In this situation, intestinal flora can enter the blood stream and lymph nodes and be transported to other organs. Glutamine is a nonessential amino acid not presently included in total parenteral nutrition (TPN) preparations. The use of glutamine-enriched TPN in the rat has resulted in a significant reduction in bacterial translocation. This study attempted to evaluate the role of glutamine in preventing bacterial translocation following hemorrhagic shock in a rat model. Forty Sprague-Dawley rats were equally divided into two groups. The controls were given TPN solution, while the treated group had glutamine instead of the standard alanine present in TPN. Hemorrhagic shock was induced in both groups and blood cultures were performed. Glutamine-treated rats did not show a significant difference in survival suggesting that it is of no particular value in severe hemorrhagic shock in rats.

Pure endotoxin does not pass across the intestinal epithelium in vitro.

Numerous reports suggest that endotoxin (LPS) may play a central role in triggering the inflammatory cascade that leads to the systemic inflammatory response syndrome. Although conditions that promote bacterial translocation in vivo may also facilitate direct translocation of LPS, the exact mechanisms by which LPS crosses the intestinal barrier to reach the systemic circulation are unknown. This study was designed to determine whether pure endotoxin could pass across injured rat ileal mucosa in the Ussing chamber. Sprague-Dawley rats were subjected to mild or severe hemorrhagic shock following carotid artery cannulation, and then resuscitated. Control animals underwent carotid artery cannulation only (sham-shock). Bacterial translocation to the mesenteric lymph nodes, liver, or spleen was measured after 24 h. Transmucosal passage of fluorescein isothiocyanate (FITC)-labeled E. coli C-25, or FITC-conjugated LPS was measured in the Ussing chamber. Intestinal membranes were examined by light and confocal laser microscopy. Severe hemorrhagic shock resulted in a 60% mortality rate and a 100% incidence of bacterial translocation in surviving animals. Sham-shock rats had a 100% survival rate and a 33% incidence of bacterial translocation. Transmucosal passage of FITC-E. coli C-25 was similar in both groups; however, passage of FITC-LPS was never detected. Histologic analysis confirmed mucosal injury to the intestinal epithelium of rats subjected to severe hemorrhagic shock, and confocal laser microscopy demonstrated passage of FITC-E. coil C-25, but not of FITC-LPS across the ileal membranes. Disruption of the intestinal epithelium with a potent mucolytic agent did not result in significant increase in transmucosal passage of FITC-LPS. We conclude that pure LPS does not pass across the intestinal mucosa in vitro. Transmucosal passage of LPS in vivo may be due, at least in part, to the release of bacterial cell wall fragments containing LPS from killed bacteria that had previously translocated.

Alterations in mucosal morphology and permeability, but no bacterial or endotoxin translocation takes place after intestinal ischemia and early reperfusion in pigs.

Ischemia and reperfusion of the gut may be an important etiological factor in the development of multiple organ failure. We have used a hemorrhagic and a superior mesenteric artery (SMA) occlusion shock model in pigs to estimate the effect of ischemia and reperfusion on intestinal morphology, mucosal permeability, and the occurrence of bacterial or endotoxin translocation. Mucosal ulceration and necrosis were found in the SMA shock model, while the morphological changes were less pronounced in the hemorrhagic shock model. Scanning electron microscopy showed shrinkage of the villi and plugging of the colonic crypts in both shock models. Enterocyte cell kinetics was investigated using 5-bromo-2'-deoksyuridine (BrdU) incorporation and immunovisualization by anti-BrdU antibodies. Cell renewal was almost completely lost from the jejunum to the rectum in both shock models. Intramucosal pH was measured using a tonometer placed in the terminal ileum. Segments of intestinal mucosa were mounted in Ussing chambers, and permeability was measured using radiolabeled probe molecules of differing molecular weights. Augmented molecular flux of inulin (M(r) 5.000) and mannitol (M(r) 182) and loss of short circuit current (Isc) and transepithelial potential difference (PD) were found in mucosae from both shock models. Endotoxin was demonstrated in the ascitic fluid in both shock models; 9.5 (2.7-14.3) (median and 95% confidence interval) EU/mL in the SMA occlusion model and 16.0 (4.9-29.4) EU/mL in the hemorrhagic shock model), but the levels were not significantly higher than in the control model 6.5 (4.3-34.0) EU/mL.(ABSTRACT TRUNCATED AT 250 WORDS)

Influence of hypertonic saline on bacterial translocation in controlled hemorrhagic shock.

Translocation of enteric bacteria has been described in rats following hemorrhagic shock (HS). The aim of the present study was to evaluate the effect of hypertonic saline (HTS) on bacterial translocation (BT) in the setting of controlled HS in rats. The study included 2 arms. Arm I was a qualitative assessment of translocation. Sixty-eight anesthetized animals were studied. The rats were divided into 5 groups. Group I (n = 10) was sham shock controls. In groups II-V, HS was induced by arterial bleeding to mean arterial pressure (MAP) of 35-45 mmHg, which was maintained for 30 min. The animals were then allocated into 4 groups: group II (n = 19) untreated HS; group III (n = 13) normal saline (NS) treated; group IV (n = 13) HTS-treated; and group V (n = 13) HTS and blood treated. Mesenteric lymph nodes, liver, spleen, portal, and systemic blood were sent for culture after 24 h. Translocation occurred if enteric bacteria were cultured from at least one site. Arm II was a quantitative assessment of translocation. Two groups were studied: untreated HS (n = 7) and HTS treated (n = 6). In the qualitative arm, the 24-h mortality in untreated rats (group II) was 31.5% compared to 5.1% in treated animals (groups II-V) (P = 0.01). No BT was detected in control animals (group I). BT after HS was not different between groups II, III, and IV (92.3%, 91.6%, and 100%, respectively). Group V showed fewer translocations than groups II-IV, a difference that was especially significant compared with group IV (P = 0.039). However, BT to distant sites (systemic blood and spleen) was significantly lower in group V than in groups II-IV (P < 0.05). In the quantitative arm, the mortality rate was 16.7% in the untreated group. Although no qualitative significant difference in the translocation rate was found between the two groups (67% in untreated animals vs. 50% in HTS treated), there was significant quantitative difference: in HTS-treated group a significantly lesser bacteria translocated than in untreated animals (0.4 x 10(5) cfu/g vs. 4.2 x 10(5) cfu/g, respectively [P = 0.001]). We concluded that whereas assessed qualitatively, in this model of severe HS in rats, the hemorrhagic insult itself resulted in BT in most animals and treatment with NS, HTS, and blood resulted in reduced early mortality but did not alter significantly the translocation rate. Only the combination of HTS and blood resulted in reduced BT to distant sites. However, quantitative assessment showed that HTS significantly reduced the number of translocating bacteria.

The effect of hypertonic saline resuscitation on bacterial translocation after hemorrhagic shock in rats.

Translocation of enteric bacteria occurs in rats after hemorrhagic shock. A proposed mechanism involves intestinal mucosal injury by hypoperfusion. Recent work suggests that moderate hypovolemia causes gut arteriolar constriction, which is ameliorated by hypertonic saline resuscitation. Bacterial translocation should, therefore, be reduced when hypertonic saline (HS) is used as the resuscitative fluid. Seventy-eight Sprague-Dawley rats were anesthetized and subjected to 30 minutes of hemorrhagic shock (systolic blood pressure 30 to 50 mm Hg) through a modified Wigger's model. Resuscitation was performed with either shed blood (B), 3% HS + 1/2B (1:1), or with 7.5% HS + 1/2B (1:1). Spleen, liver, and mesenteric lymph nodes were sent for quantitative culture 24 hours later. Translocation occurred if enteric organisms were cultured from at least one organ. Statistical analysis used the Fisher exact test. Compared to autotransfusion, hemodilutional resuscitation from hemorrhagic shock with hypertonic saline resulted in a significant reduction in bacterial translocation (p values were 0.03 and 0.04 for 3% and 7.5% hypertonic saline, respectively). The reduction in translocation after hypertonic saline resuscitation may be the consequence of microcirculatory alterations preventing gut hypoperfusion.

The effects of bacterial overgrowth and hemorrhagic shock on mucosal immunity.

Impairment in systemic and mucosal immune function is noted after hemorrhagic shock (HS). Overgrowth of gut microflora is common after shock insults and may act as a reservoir for intensive care unit-acquired infections and subsequent remote organ failure. Secretory immunoglobulin A (IgA), the principle immunoglobulin in intestinal secretions, is the first line of defense of mucosal surfaces. Although HS and gut bacterial overgrowth are often temporarily related, their combined effect on IgA is unknown and served as the basis for this study. After sham or HS, self-filling blind loops (SFBL) were created to affect bacterial overgrowth. Intestinal secretions were obtained 7 days later from SFBL and jejunal segments for quantitative culture. Gut washings were also obtained and secretory IgA levels determined by enzyme-linked immunosorbent assay. Bacterial overgrowth in the SFBL was associated with significant increases in IgA levels in the sham group only. IgA levels were depressed in both jejunal and SFBL segments in the HS group. Impaired humoral mucosal defense may be important mechanistically in the development of nosocomial infections and organ failure after HS, particularly with concurrent gut bacterial overgrowth.

Hyperoxic condition prevents bacterial translocation and elevation of plasma microorganism components during hemorrhagic shock.

To evaluate the influence of hyperoxic conditions on bacterial translocation (BT) and microorganism components during hemorrhagic shock, rats were divided into a group breathing 100% oxygen and a group breathing room air. The groups were then subjected to hemorrhagic shock. Systemic blood and mesenteric lymph nodes were cultured for BT, and systemic plasma concentrations of microorganism components were measured by the silkworm larvae plasma (SLP) test and the endotoxin test. Hyperoxic conditions prevented both BT and plasma SLP-reactive substance (peptidoglycan and beta-glucan) elevation during hemorrhagic shock. Our findings suggest that hyperoxic treatment might improve host conditions during hemorrhagic shock.