The gut as a portal of entry for bacteremia. Role of protein malnutrition.

The current studies were performed to determine the influence of malnutrition alone or in combination with endotoxemia in promoting bacterial translocation from the gastrointestinal tract. Bacterial translocation did not occur in control, starved (up to 72 hours), or protein-malnourished (up to 21 days) mice not receiving endotoxin. Bacterial translocation to the mesenteric lymph nodes (MLNs) occurred in 80% of control mice 24 hours after receiving endotoxin (p less than 0.01). However, the combination of malnutrition plus endotoxin was associated with a higher incidence of translocation to the systemic organs (p less than 0.01), and higher numbers of bacteria per organ (p less than 0.01), than was seen in normally nourished mice receiving endotoxin. Additionally, mice that were protein malnourished were more susceptible to the lethal effects of endotoxin than were control animals, and the mortality rate was directly related to the degree of malnutrition (R2 = 0.93) (p less than 0.05). Histologically, endotoxin in combination with protein malnutrition resulted in mechanical damage to the gut mucosal barrier to bacteria. Thus, in the mice that were protein malnourished the spread of bacteria from the gut could not be controlled nor could translocated bacteria be cleared as well as normally nourished mice receiving endotoxin. These results support the concept that under certain circumstances the gut may serve as a clinically important portal of entry for bacteria.     

A study of the relationship among survival, gut-origin sepsis, and bacterial translocation in a model of systemic inflammation.

Several factors, including uncontrolled inflammation, gut barrier failure, and sepsis, have been implicated in the development of multiple organ failure. To investigate the relative importance and interrelationships among some of these factors, increasing doses of the inflammatory agent zymosan were used to induce a systemic inflammatory state in mice. At nonlethal doses (0.1 and 0.5 mg/g body weight), zymosan caused injury to the intestinal mucosa, increased intestinal xanthine oxidase activity, and promoted bacterial translocation in a dose-dependent fashion. Inhibition or inactivation of xanthine oxidase activity was effective in reducing mucosal injury and bacterial translocation when zymosan was injected at 0.1 mg/g but not at 0.5 mg/g body weight. At a dose of 1 mg/g, the lethal effects of zymosan appeared to be related to gut-origin sepsis, since cefoxitin (1 mg/g) reduced the seven-day mortality rate from 100% to 20% (p less than 0.01). However, at a zymosan dose of 2 mg/g, antibiotics did not improve survival. Zymosan thus induced gut barrier failure and systemic infection in a dose-dependent fashion. Additionally, the mechanism of zymosan-induced bacterial translocation and the relationship of gut-origin sepsis to survival appeared to be related to the magnitude of the inflammatory insult (the dose of zymosan).     

Role of bacterial adherence and the mucus barrier on bacterial translocation: effects of protein malnutrition and endotoxin in rats.

OBJECTIVE: The purpose of the study was to investigate the potential relations between mucosal bacterial adherence, intestinal mucus and mucin content, and bacterial translocation. SUMMARY BACKGROUND DATA: The attachment of bacteria to mucosal surfaces is the initial event in the pathogenesis of most bacterial infections that originate at mucosal surfaces, such as the gut. The intestinal mucus layer appears to function as a defensive barrier limiting micro-organisms present in the intestinal lumen from colonizing enterocytes. Consequently, studies focusing on the biology of bacterial adherence to the intestinal mucosa likely are to be important in clarifying the pathogenesis of gut origin sepsis. METHODS: To explore the relations between intestinal bacterial adherence, mucus bacterial binding, and bacterial translocation, two models were used. One (protein malnutrition) in which profound alterations in intestinal morphology occurs in the absence of significant translocation and one (endotoxin challenge) in which bacterial translocation occurs and intestinal morphology is relatively normal. RESULTS: Protein malnutrition was not associated with bacterial translocation and measurement of enteroadherent, mucosally associated bacterial population levels documented that the total number of gram-negative enteric bacilli adherent to the ileum and cecum was less in the protein-malnourished rats than in the normally nourished animals (p < 0.01). Furthermore, there was an inverse relation between the duration of protein malnutrition and bacterial adherence to the intestinal mucosa (r = 0.62, p < 0.002). In contrast, after endotoxin challenge, the level of enteroadherent bacteria was increased and bacterial translocation was observed. The binding of Escherichia coli to immobilized ileal mucus in vitro was decreased significantly in protein-malnourished rats, whereas E. coli binding to insoluble ileal mucus was increased in the rats receiving endotoxin. CONCLUSIONS: This study indicates that the adherence of bacteria to the intestinal mucosal surface is an important factor in bacterial translocation, that intestinal mucus modulates bacterial adherence, and that increased levels of mucosally associated bacteria are associated with a loss intestinal barrier function to bacteria.     

Endotoxin but not malnutrition promotes bacterial translocation of the gut flora in burned mice

Previously we have shown that under certain conditions, bacteria can pass through the intact epithelial mucosa to the mesenteric lymph nodes (MLN), liver, spleen, and bloodstream to cause infection, a process termed bacterial translocation. To extend these studies, we determined the influence of protein malnutrition and endotoxemia on bacterial translocation in burned (25% TBSA) and unburned mice. The results of these experiments documented that protein malnutrition did not promote bacterial translocation from the gut in either burned or unburned animals, although it did disrupt the normal indigenous gut flora. In contrast, a nonlethal dose of endotoxin (IP) promoted bacterial translocation to the mesenteric lymph nodes in burned and unburned mice, but only in burned mice did the bacteria translocate from the gut to other systemic organs (p less than 0.01). Furthermore, the mortality rate of mice receiving only endotoxin or burn was less than 10%, while the combination of endotoxin plus a thermal injury increased the mortality rate to 100% (p less than 0.01). These studies support the concept that bacteria may translocate from the gut to other organs and be a potential source of lethal infections after thermal injury.     

Effect of stress and trauma on bacterial translocation from the gut

Previously, we established that bacteria contained within the gut can cross the GI mucosal barrier and spread systemically, a process termed bacterial translocation. Three models were used to extend this work: cold exposure (up to 16 hr at 4 degrees C), a nontissue injury stress model; femoral fracture-amputation, a trauma model; and thermal injury (30% third-degree burn), a trauma model with retained necrotic tissue. CD-1 mice either with a normal GI microflora or who were monoassociated with Escherichia coli C-25 were subjected to sham or actual stress or trauma. The animals were sacrificed at various times postinsult and the ceca, mesenteric lymph nodes (MLN), spleens, and livers were quantitatively cultured. Neither the incidence nor the magnitude of bacterial translocation was increased in the cold-exposed animals compared to control mice. The incidence of bacterial translocation to the systemic organs was higher in the animals with a normal flora receiving femoral fracture amputation (11%) (P less than 0.02) than in animals receiving a thermal injury (1%) or sham-injured control mice (0%). In contrast, the incidence of translocation to the liver or spleen was higher in burned mice monoassociated with E. coli C-25 (60%) (P less than 0.01) than in E. coli monoassociated mice sustaining femoral fracture amputation (17%). Stress alone (cold exposure) does not promote bacterial translocation; however, trauma, especially in combination with retained necrotic tissue, promotes bacterial translocation. Thus bacteria colonizing the gut can invade systemic organs after trauma, especially when the normal ecology of the gut flora has been disrupted.     

Effect of starvation, malnutrition, and trauma on the gastrointestinal tract flora and bacterial translocation

We have previously shown, in an animal model, that viable indigenous bacteria will cross the intact gastrointestinal (GI) mucosa and spread systemically, a process termed bacterial translocation, if the normal bacterial ecology of the gut was sufficiently disrupted to allow bacterial overgrowth or if the animals were severely immunosuppressed. Starvation or protein malnutrition disrupts the normal indigenous GI tract microflora and impairs host antibacterial defenses. Consequently, we tested the effect of the combination of starvation or protein malnutrition plus burn trauma in promoting bacterial translocation from the GI tract. Bacterial translocation was measured by quantitatively culturing the mesenteric lymph nodes, spleens, livers, blood, and peritoneal cavities of normal or burned (30% of total body surface area) CD1 mice deprived of food for three days or fed a low-protein (0.03%) diet. The effect of starvation or protein malnutrition on the gut microflora was determined by quantitatively measuring the levels of bacteria present in the ceca. Both starvation and protein malnutrition increased the cecal levels of gram-negative enteric bacilli and decreased the levels of lactobacilli and strict anaerobes. Surprisingly, neither starvation nor protein malnutrition promoted bacterial translocation, even though these animals lost over 20% of their body weight and the ecology of the gut microflora was disrupted. In fact, the protein-malnourished animals exhibited lower incidences of bacterial translocation than normally nourished animals when both groups were monoassociated with Escherichia coli C-25 or monoassociated and burned. Thus, it appears that protein malnutrition does not promote bacterial translocation, even when combined with burn trauma.     

Role of intestinal bifidobacteria in the pathogenesis of gut-derived bacteria/endotoxin translocation and the effect of bifidobacterial supplement on gut barrier function following burns

Early multiple organ dysfunction syndrome appears to be facilitated with bacterial translocation in severely burn injury, yet the mechanisms of bacterial translocation remains in dispute. The aim of this study was to investigate the potential role of intestinal bifidobacteria in the pathogenesis of gut-derived bacteria/endotoxin translocation following burns and the effects of bifidobacterial supplement on gut barrier. Methods: Wistar rats were randomly divided into burn group (Burn, n=60),sham burn group (SB, n=10) in experiment Ⅰ , and burn + saline group (BS, n=30), burn + bifidobacteria group (BB, n=30), and sham-burn + saline group (SS, n= 10) in experiment Ⅱ. Animals in BB group were fed bifidobacterial preparation (5 × 109 CFU/ml) after burns, 1.5ml,twice daily. Animals in BS and SS were fed saline. Samples were taken on days 1, 3, and 5 in burn groups, and on day 3 in sham-burn groups. The incidence of bacteria/endotoxin translocation and counts of Bifidobacterium, Fungi and Escherichia coli in gut mucosa were determined with standard methods. The levels of sIgA in mucus of small intestine were measured by RIA. The positive sIgA expression in lamina propria and ileum mucosal injury was evaluated light microscopically by blinded examiners. Results: Our results showed that the incidence of bacterial translocation was increased after burns, which was accompanied by significant decrease in number of bifidobacteria but significant increase in E. coli and fungi in gut mucosa, and elevation of levels of plasma endotoxin and IL-6 (P<0. 001).The incidence of bacterial translocation was markedly reduced after 3- and 5-day supplementation of bifidobacteria compared with control group (P<0.05). The counts of mucosal bifidobacteria were increased by 4- to 40-fold,while E. coli and fungi were decreased by 2- to 30-fold and 10- to 150-fold, respectively, after bifidobacterial supplementation in contrast to control group. The damage of mucosa tended to be less pronounced after 3-day bifidobacteria-supplemented formula compared with control group [grade 2(0-6) vs. grade 4(3-6), P<0.05]. Moreover, the expression and release of sIgA was markedly augmented after 3-day bifidobacteria-supplementation formula and it returned to normal range on day 5. Conclusion: The decrease in counts and proportion of bifidobacteria in mucous membrane flora may play an important role in the development of bacteria/endotoxin translocation following thermal injury. The supplement of exogenous bifidobacteria could per se improve gut barriers, and attenuate bacteria/endotoxin translocation secondary to major burns.     

Macrophage elimination increases bacterial translocation and gut-origin septicemia but attenuates symptoms and mortality rate in a model of systemic inflammation.

OBJECTIVE: The central question tested in this study was whether dichloromethylene-diphosphonate (CL2MDP) liposome-mediated elimination of hepatic and splenic macrophages would influence zymosan-induced bacterial translocation and the zymosan-induced generalized inflammatory response. SUMMARY BACKGROUND DATA: Both an uncontrolled activation of macrophages and the loss of intestinal barrier function have been implicated in the development of adult respiratory distress syndrome and multiple organ failure. METHODS: Macrophage elimination was accomplished by intravenous injection of 200 microL of CL2MDP-liposome suspension. Control mice received an intravenous injection of 200 microL of phosphate-buffered saline. Two days later, the animals were challenged intraperitoneally with zymosan suspended in paraffin to determine a dose-response curve (0.1, 0.5, or 1.0 mg/g body weight). Twenty-four hours after zymosan challenge, signs of systemic stress were determined, and bacterial translocation to the mesenteric lymph node, liver, spleen, and blood was measured. A separate mortality study was performed with a dose of 1.0 mg/g of zymosan suspension. RESULTS: The incidence of the systemic spread of bacteria was significantly increased in the macrophage-depleted mice. Although systemic bacterial translocation was promoted by macrophage elimination, the systemic toxic response was significantly decreased in all macrophage-depleted groups (p < or = 0.01). The 12-day mortality rate was 0% in the macrophage-depleted groups and 27% in the control group (p = 0.05). CONCLUSIONS: The lethal and toxic effects of zymosan appear to be related more to the excessive activation of macrophages than to the systemic spread of bacteria.     

Genetic susceptibility to mucosal damage leads to bacterial translocation in a murine burn model

Since genetic factors may be important in host resistance to infections after thermal injury, we screened the susceptibility of three mouse strains (CD-1, Balb/c, and C57/bl) to thermally induced bacterial translocation from the GI tract. Bacteria translocated to the MLNs of Balb/c but not the CD-1 or C57/bl mice receiving 25% body burns. The increased incidence of bacterial translocation in the burned Balb/c mice appeared to be due to a burn-induced gut mucosal injury, since the intestinal mucosa of the Balb/c but not the CD-1 or C57/bl mice was damaged 24 hr after the thermal injury. The mucosal injury appears to be mediated, at least in part, by xanthine oxidase-generated oxygen-free radicals, since inhibition of xanthine oxidase activity with allopurinol, or inactivation of xanthine oxidase activity by a molybdenum-free tungsten diet, prevented the mucosal injury and reduced the extent of bacterial translocation.     

Endotoxin-induced bacterial translocation: a study of mechanisms

Previously, we documented that nonlethal doses of endotoxin cause the translocation (escape) of bacteria from the gut to systemic organs. The purpose of this study was to determine which portion(s) of the endotoxin molecule induces bacterial translocation and to examine the role of xanthine oxidase activity in the pathogenesis of endotoxin-induced bacterial translocation. Nonlethal doses of Salmonella endotoxin preparations (wild type, Ra, or Rb), containing the terminal portion of the core polysaccharide, induced bacterial translocation, whereas those preparations lacking the terminal-3 sugars (Rc, Rd, Re, or lipid A) did not induce bacterial translocation. Additionally, only those endotoxin preparations that induced bacterial translocation injured the gut mucosa, increased ileal xanthine dehydrogenase and oxidase activity, and disrupted the normal ecology of the gut flora, resulting in overgrowth with enteric bacilli. Inhibition of xanthine oxidase activity by allopurinol prevented endotoxin (Ra)-induced mucosal injury and reduced the incidence of bacterial translocation from 83% to 30% (p less than 0.01). These results suggest that endotoxin-induced bacterial translocation requires the presence of the terminal core lipopolysaccharide moiety and that xanthine oxidase-generated oxidants are important in the pathogenesis of endotoxin-induced mucosal injury and bacterial translocation.     

Distribution and survival of Escherichia coli translocating from the intestine after thermal injury.

The present investigation was performed to study the kinetics of tissue distribution and deposition of Escherichia coli and endotoxin translocating from the intestine after thermal injury. Escherichia coli was grown in the presence of 14C glucose and both labeled bacteria and endotoxin prepared from the labeled bacteria were used as translocation probes. Escherichia coli (10(8) to 10(10) bacteria) and E. coli endotoxin (100 micrograms per animal) were gavaged into the stomach immediately before a 30% burn injury was inflicted in mice. Animals were killed 1, 4 and 24 hours after burn injury. Translocation occurred extensively within 1 hour after burn injury. Expressed as amount of radioactivity per gram of tissue, translocation was greatest in the mesenteric lymph node (MLN) followed by spleen, lung, and liver. Translocation of endotoxin was similar to translocation of intact bacteria, with the exception that less radioactivity could be found in the peritoneal cavity and more in the liver. Both intact E. coli and endotoxin translocated directly through the intact bowel wall. Killing of bacteria was greatest in the MLN and spleen, approximating 95% to more than 99% of translocating bacteria. Killing efficiency was lowest in the lungs. It is concluded that estimation of translocation by viable bacterial counts in tissues grossly underestimates the extent of translocation of bacteria and ignores the extent of translocation of endotoxin. Translocation of endotoxin may have biologic significance that is independent of and in addition to translocation of intact bacteria.     

Gut mucosal ischemia during cardiac surgery

Transient episodes of gut mucosal ischemia occur in many patients having cardiac surgery. Ischemic mucosal injury increases mucosal permeability and promotes the translocation of bacterial toxins and bacteria and, hence, the release of mediators. Collectively these substances are the putative cause of LOS, nosocomial infections, and MSOF. Circumstantial evidence suggests that the morbidity and mortality from cardiac surgery might be greatly reduced by preventing or limiting in duration the episodes of gut mucosal ischemia. This objective is unlikely to be reliably achieved in clinical practice without monitoring the adequacy of gut mucosal oxygenation. The adequacy of gut mucosal oxygenation can be conveniently monitored in the stomach with a Tonomitor incorporated into a nasogastric tube, because changes induced in this organ by disturbances in DO2 reflect changes occurring in other parts of the gut. Preventative measures currently possible in routine clinical practice include maintaining an intramucosal pH at normal levels by optimizing DO2, preventing the release of splanchnic vasoconstrictors and the formation of cellular aggregates by the use of pulsatile perfusion during bypass, and minimizing oxygen requirements with cooling and muscle relaxation. The translocation of bacterial toxins and bacteria across injured mucosa may be minimized by gut lavage before surgery. Therapeutic measures for gut mucosal ischemia currently possible in routine clinical practice include, in addition to the preventative measures outlined above, the prevention of free radical-induced mucosal injury during resuscitation, parenteral antibiotics, the treatment of sepsis, and the resection of infarcted gut.     

Bacterial translocation in trauma patients

Sepsis and multiple system organ failure (MSOF) are major causes of morbidity and mortality in trauma patients. Bacterial translocation induced by hypotension, endotoxemia, or burns is a reproducible phenomenon in the laboratory. The incidence of bacterial translocation to mesenteric lymph nodes (MLNs) in 29 critically ill patients was evaluated to determine its relationship to subsequent sepsis and MSOF. Bacterial translocation was documented in 3 of 4 patients who underwent laparotomy for gastrointestinal (GI) disease. No trauma patient (25 patients), even at second exploration 3-5 days after injury, had a positive MLN culture. Five patients died; 4 trauma patients, one with GI disease. Forty percent of the trauma patients had major complications, predominantly pulmonary infections with gram-negative bacteria. However, infectious complications and outcome were not related to MLN culture results. The classical progression of bacteria from the gut to the bloodstream via the MLNs may require time and gut mucosal injury. The data suggest that bacterial translocation to the MLNs is not a common occurrence in acutely injured trauma patients.     

Studies of the route, magnitude, and time course of bacterial translocation in a model of systemic inflammation

Bacteria have been documented to translocate from the gut to systemic organs, yet the exact route by which they translocate remains unclear. To determine the route of bacterial translocation, different dosages of zymosan were used to activate complement and cause systemic inflammation. At a zymosan dose of 0.1 mg/g, bacteria translocated only to the mesenteric lymph node complex, whereas at a dose of 0.5 mg/g the bacteria translocated systematically. In rats receiving 0.5-mg/g doses of zymosan, the bacteria appeared to reach systemic organs via the portal blood rather than via the mesenteric lymph, as bacteria were present in 87% of portal blood samples but only 25% of lymph samples. The number of bacteria exiting the portal vein was 11,500 times greater than the number exiting via the lymph. Thus, both the route and extent of bacterial translocation varies based on the magnitude of the inflammatory insult, with the portal blood being the major route of bacterial translocation to systemic organs.     

Antibiotic prophylaxis diminishes bacterial translocation but not mortality in experimental burn wound sepsis

Pseudomonas (PSA) burn wound sepsis results in prolonged bacterial translocation (BT) of enteric organisms such as E. coli to the mesenteric lymph nodes (MLN) and organs in rats. Intestinal decontamination with oral antibiotics may improve mortality after burn injury, perhaps due to decreased BT. To determine the effect of oral antibiotic prophylaxis effective against E. coli but not PSA on BT and subsequent mortality in a model of PSA burn wound sepsis, rats were given a 30% scald burn and wound inoculation with 10(8) PSA followed by randomization to either ampicillin (50 mg/kg/d) or saline gavage. Cultures of MLN, organs, blood, and cecal contents were obtained on days 1, 4, and 7 after injury, with additional animals observed for 14-day mortality. Although oral antibiotic prophylaxis resulted in increased cecal colony counts, the incidence of BT was unchanged. The number of organisms present in both the MLN and organs, however, was significantly reduced with prophylaxis, indicating cecal overgrowth by non-translocating bacteria. Reduction of the number of translocating organisms did not result in improved mean survival time after injury, suggesting that mortality from PSA burn wound sepsis occurs independently of bacterial translocation.     

The role of bifidobacteria in gut barrier function after thermal injury in rats

BACKGROUND: Early multiple organ dysfunction syndrome appears to be facilitated with bacterial translocation in severe burn injury, yet the mechanisms of bacterial translocation remain in dispute. The aim of this study was to characterize the potential role of intestinal bifidobacteria in the pathogenesis of gut-derived bacterial translocation after burns and to analyze the effects of bifidobacterial supplement on gut barrier function. METHODS: Wistar rats were randomly divided into burn group (Burn, n = 60), sham burn group (SB, n = 10) in experiment 1, and burn + saline group (BS, n = 30), burn + bifidobacteria group (BB, n = 30), and sham-burn + saline group (SS, n = 30) in experiment 2. Animals in BB group were fed bifidobacterial preparation (5 x 10(9) CFU/mL) after burns, 1.5 mL, twice daily. Animals in BS and SS were fed saline. Samples were taken on postburn days 1, 3, and 5. The incidence of bacterial translocation and counts of Bifidobacterium, fungi and Escherichia coli in gut mucosa, as well as the sIgA levels in mucus of the small intestine were determined. The positive sIgA expression in lamina propria and ileum mucosal injury were evaluated light microscopically by blinded examiners. RESULTS: The incidence of bacterial translocation was increased after burns, which was accompanied by significant decrease in number of bifidobacteria but significant increase in E. coli and fungi in gut mucosa, and elevation of levels of plasma endotoxin and IL-6 (p < 0.001). The incidence of bacterial translocation was markedly reduced after 3- and 5-day supplementation of bifidobacteria compared with control group (p < 0.05). The counts of mucosal bifidobacteria were increased by 4- to 40-fold, whereas E. coli and fungi were decreased by 2- to 30-fold and 10- to 150-fold, respectively, after bifidobacterial supplementation. The damage of mucosa tended to be less pronounced after 3-day bifidobacteria-supplemented formula compared with control group (grade 2 [0-6] versus grade 4 [3-6], p < 0.05). Moreover, the expression and release of sIgA was markedly augmented after 3-days of bifidobacteria-supplementation formula and it returned to normal range on postburn day 5. CONCLUSIONS: The decrease in counts and proportion of bifidobacteria to other flora in gut may play an important role in the development of bacterial translocation after thermal injury. Supplementation of exogenous bifidobacteria could improve gut barrier function, and attenuate bacterial/endotoxin translocation secondary to major burns.     

Endotoxin promotes the translocation of bacteria from the gut

Experiments were performed in mice to determine whether endotoxin could cause bacteria normally colonizing the gut to spread systemically, a process termed bacterial translocation. Endotoxin given intraperitoneally promoted bacterial translocation in a dose-dependent fashion from the gut to the mesenteric lymph node (MLN). The incidence of bacterial translocation to the MLN was similar whether the endotoxin was administered intramuscularly or intraperitoneally, although the number of bacteria colonizing the MLN was greater with intraperitoneal endotoxin. The incidence and magnitude of endotoxin-induced bacterial translocation were similar between CD-1 and C3H/HeJ (endotoxin-resistant) mice, indicating that bacterial translocation is not prevented by genetic resistance to endotoxin. Thus, it appears that the gut may serve as a reservoir for bacteria causing systemic infections during endotoxemia.     

Hemorrhagic shock induces bacterial translocation from the gut

Sepsis and multiple organ failure are common after hemorrhagic shock. The goal of the current experiments was to determine whether hemorrhagic shock would promote the translocation of bacteria from the gut to visceral organs. Twenty-four hours after being subjected to sham shock, or 30, 60, or 90 minutes of shock (30 mm Hg), rats were sacrificed and their organs quantitatively cultured for translocating bacteria. There was a direct relationship between the duration of hemorrhagic shock and the 24-hour mortality rate (p = 0.02). Bacteria did not translocate from the gut in the sham-shock rats, but did translocate to the mesenteric lymph nodes, livers, and spleens of the rats subjected to hemorrhagic shock (p less than 0.01). Rats subjected to 90 minutes of shock shock exhibited a greater degree of bacterial translocation than rats receiving 30 or 60 minutes of shock (p less than 0.05). The most common translocating bacteria were Escherichia coli and Enterococcus. Hemorrhagic shock injured the gut mucosa and caused subepithelial edema and focal areas of necrosis. Thus hemorrhagic shock followed by reinfusion of shed blood disrupts the gut barrier and allows indigenous bacteria normally contained within the gut to cause systemic infections.     

Pancreatitis and nutrition. Significance of the gastrointestinal tract and nutrition for septic complications

Septic complications are an important factor for the morbidity and mortality of acute pancreatitis. The gut has been identified as a source of infection early in the course of the disease allowing intestinal bacteria to translocate into pancreatic necrosis and other organs. Bacterial translocation is promoted by an impaired intestinal mucosal barrier which can be attributed to the reduced oxygen and substrate supply of the intestine during the early systemic response to the pancreatic injury. A rat model of severe acute pancreatitis has been used to confirm the hypothesis that an impaired mucosal barrier can be stabilized by supplying certain nutritients, vitamins and trace elements. Following a discussion of the many aspects of bacterial translocation and gut derived sepsis, the role of the gut and nutrition for the development of septic complications in acute pancreatitis is summarized as follows: Early in the course of acute pancreatitis the gut is a target organ of the primary systemic inflammatory response (SIRS) to pancreatic injury. SIRS-induced gut barrier dysfunction promoting bacterial translocation makes the gut the motor for secondary (septic) complications. As a septic focus the gut becomes a target for therapeutic measures aimed at stabilizing the impaired gut barrier. Nutritive factors demonstrated to improve impaired gut barrier function include early enteral feeding and specific factors like glutamine which are essential for enterocytes and colonocytes in stress. Experimental data are presented to underline the significance of these nutritive factors and subsequent randomized multicenter trials performed to verify the positive experimental results are introduced. The effect of other nutritive factors (e.g. omega-3-fatty acids) has not yet been systemically investigated. Thus, experimental and clinical studies need to be performed for evaluating their effect on bacterial translocation and the disease course in acute pancreatitis.     

Effect of T cell modulation on the translocation of bacteria from the gut and mesenteric lymph node.

Although the ability of the gut-associated lymphoid tissue (GALT) to respond to orally ingested foreign antigens has been studied extensively, its function in preventing or limiting escape of resident gut bacteria has not been assessed. The following studies were performed to examine what role cell-mediated immunity (CMI) plays in this process. The ability of suppression of CMI to induce escape of gut bacteria (translocation) to the mesenteric lymph node (MLN) in immunocompetent mice whose gut flora was unaltered was examined. Administration of cyclosporine or anti-L3T4 antibody failed to induce translocation of indigenous gut bacteria after 7 or 14 days of treatment. Antithymocyte globulin (ATG) also failed to induce translocation after 7 days of treatment, despite depletion of all Thy 1, Lyt 1, L3T4, and Lyt 2 positive cells from the spleen, MLN, and intestine as demonstrated by immunofluorescent microscopy. Finally, cultures of the MLN, spleen, liver, and peritoneum of T cell-deficient BALB/c nude mice and their heterozygous T cell-replete littermates were also sterile, demonstrating that congenital suppression of T CMI also does not lead to translocation of indigenous gut bacteria. The role of CMI in limiting systemic spread of bacteria that were already translocating to the MLN was also examined. Translocation of Escherichia coli C25 to the MLN was induced by gastrointestinal (GI) monoassociation, which leads to translocation of E. coli C25 to the MLN in 80-100% of mice. Treatment with ATG during monoassociation failed to induce spread of E. coli C25 to the spleen, liver, or peritoneum, despite the same degree of T cell depletion achieved with ATG in the previous experiment. Monoassociation of conventional T cell-deficient BALB/c nude and heterozygous mice and germ-free T cell-deficient BALB/c nude and heterozygous mice also did not lead to spread of E. coli C25 beyond the MLN. However, in ATG-treated, conventional nude, and germ-free nude mice, the average number of translocating E. coli C25 per MLN was consistently higher. In separate experiments the ability of stimulation of T cell function to inhibit translocation of E. coli C25 was examined. Recombinant interleukin-2, 25,000 units, was administered intraperitoneally every 8 hours during exposure to E. coli C25. This reduced the incidence of translocation of E. coli C25 from 85% to 51% (p = 0.02). Suppression of CMI, either systemically or within the GALT, has a minimal influence on the mechanisms by which the normal gut flora are translocated to the MLN.(ABSTRACT TRUNCATED AT 400 WORDS)