Experimental study on pathogenesis of endotoxin-induced gut origin infection

It has been documented that endotoxin could induce gut origin infection. Consequently, experiments were performed to correlate endotoxin-induced gut origin infection with changes in intestinal mucosal structure and xanthine dehydrogenase and oxidase activity. Bacteria infection from the intestines to extraintestinal organs in 70% of the mice receiving endotoxin. Endotoxin injured primarily the ileal and cecal mucosa and increased ileal and hepatic xanthine dehydrogenase and cecal oxidase activities (P less than 0.05). These results suggest that xanthine oxidase-induced mucosal damage plays a role in endotoxin-induced gut origin infection.     

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.     

Obstructive jaundice promotes bacterial translocation from the gut

Experiments were performed to determine if obstructive jaundice promotes the translocation of bacteria from the gastrointestinal tract to visceral organs. Three groups of mice were studied: control (n = 20), sham ligated (n = 28), and bile duct ligated (n = 33). The sham-ligated group underwent laparotomy and manipulation of the portal region, whereas the ligated group had their common bile ducts ligated. Seven days later, the mice were killed, their organs cultured, and the gastrointestinal tract examined histologically. The bilirubin levels of the ligated group (18.7 mg/dL) were elevated compared with the other groups (0.5 mg/dL) (p less than 0.05). The incidence of bacterial translocation was higher in the ligated (33%) than in the control (5%) or sham-ligated (7%) groups (p less than 0.05). Since bile is important in binding endotoxin and maintaining a normal intestinal microflora, cecal bacterial populations were quantitated. The cecal levels of gram-negative, enteric bacilli were 100-fold higher in the bile duct-ligated mice in which bacterial translocation occurred (p less than 0.05), indicating that intestinal bacterial overgrowth was a major factor responsible for bacterial translocation. The mucosal appearance of the intestines from the control and sham-ligated groups was normal. In contrast, subepithelial edema involving the ileal villi was present in the ligated group. In conclusion, the absence of bile within the gastrointestinal tract allows intestinal overgrowth with enteric bacilli and the combination of bacterial overgrowth and mucosal injury appears to promote bacterial translocation.     

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.     

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.     

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).     

Splenectomy influences endotoxin-induced bacterial translocation

To determine whether splenectomy affects the antibacterial defenses of the gut, experiments were performed using bacterial translocation (BT) as a marker of intestinal barrier failure. The incidence of BT was measured 8 days after splenectomy or sham-splenectomy in mice receiving or not receiving endotoxin (0.1 mg IP). Splenectomy does not appear to promote BT from the gut, since the incidence of bacterial translocation after splenectomy or sham-splenectomy (5%) were not different. A second experiment was performed to determine whether the resistance to endotoxin-induced BT was modified after splenectomy. The incidence of endotoxin-induced BT was 73% in the unoperated control group, 59% in the sham-splenectomy group, but 23% in the splenectomy group (p less than 0.002). Thus, splenectomy but not sham-splenectomy increased the resistance of otherwise healthy mice to endotoxin-induced BT.     

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.     

Localization and changes of diamine oxidase during cardiopulmonary bypass in rabbits

BACKGROUND: We previously observed increased serum diamine oxidase activity during clinical cardiopulmonary bypass, indicating small intestinal mucosal ischemia followed by bacterial translocation. MATERIALS AND METHODS: In seven female rabbits undergoing cardiopulmonary bypass for 1 h, we analyzed the localization of diamine oxidase immunohistochemically, and measured its activity in serum and abdominal organs before and after cardiopulmonary bypass (CPB). RESULTS: Preoperatively, diamine oxidase activity and immunoreactivity were high in the small intestine, localized to villus tips. Serum activity increased significantly after CPB, whereas small intestinal diamine oxidase decreased with mucosal injury. CONCLUSIONS: In this model serum diamine oxidase activity appeared to reflect CPB induced intestinal mucosal injury.     

Hemorrhagic shock-induced bacterial translocation: the role of neutrophils and hydroxyl radicals

We previously documented a relationship between xanthine oxidase activation, intestinal injury, and bacterial translocation (BT) in rats subjected to hemorrhagic shock. The current experiments were performed to determine the relative roles of hydroxyl radicals and neutrophils in the pathogenesis of shock-induced mucosal injury and BT. The incidence of BT was higher in the shocked rats (30 mm Hg for 30 min) than the sham-shock controls (87% vs 12.5%; p less than 0.01). Administration of the hydroxyl radical scavenger, dimethyl sulfoxide (DMSO), or the iron chelator, deferoxamine, reduced the incidence of BT from 87% to 20% and 40%, respectively (p less than 0.05). DMSO and deferoxamine appear to prevent shock-induced BT by blunting the magnitude of shock-induced mucosal injury. In contrast, neutrophil depletion did not prevent BT or protect the intestinal mucosa in shocked rats. Instead, the incidence of systemic spread of translocating bacteria past the mesenteric lymph nodes to the livers and spleens of the shocked rats was higher in the neutrophil-depleted rats (56%) than in any other group (p less than 0.01). Thus, shock-induced BT and intestinal injury appear to be mediated by oxidants (.OH) derived from xanthine oxidase, rather than granulocytes.     

肠道双歧杆菌与烫伤大鼠肠源性细菌/内毒素移位

目的　观察肠道双歧杆菌在肠源性细菌 /内毒素移位中的变化和作用。　方法　制作严重烫伤大鼠模型 ,同时设假伤组。检测细菌和内毒素 (LPS)移位及盲肠膜菌群变化 ,ELISA法检测血浆白细胞介素 6(IL 6)浓度。　结果　大鼠严重烫伤后脏器细菌移位明显增多 (P <0 .0 1) ;血LPS水平在致伤 1、3、5d后分别为 (0 .2 3 6± 0 148)Eu/ml、(0 .197± 0 .15 6)Eu/ml、(0 10 4± 0 .0 90 )Eu/ml,显著高于假伤组的 (0 .0 72± 0 .0 49)Eu/ml(P <0 .0 5 ) ;盲肠膜菌群中双歧杆菌数剧减 2 0～2 5 0倍、真菌数剧增至 5～ 60倍、大肠杆菌数增加 0 .5～ 3 0倍 ,双歧杆菌与大肠杆菌比值由假伤组的2 5 0 0 0∶1降为伤后的 4～ 80 0∶1;血浆IL 6水平显著增高。经分层统计 ,与未发生肠道细菌移位大鼠相比 ,盲肠膜菌群移位大鼠的双歧杆菌量减少约 12 0倍 ,真菌数增加约 5 0倍 ,大肠杆菌数增加约 3 0倍。盲肠膜菌群中双歧杆菌数量与血浆中IL 6、LPS浓度呈负相关 (r1=- 0 .4817,r2 =- 0 .4912 ,P <0 .0 1) ,血IL 6和LPS浓度间存在显著正相关 (r =0 .82 5 8,P =0 .0 0 0 1)。　结论　严重烫伤可导致大鼠盲肠膜菌群紊乱 ,细菌和LPS移位增加 ;盲肠膜菌群中双歧杆菌的比例和数量的减少 ,可能促使了严重烫伤后肠源性细菌 /内毒素移位     

大鼠门静脉高压症及梗阻性黄疸时细菌移位与黄嘌呤脱氢酶和黄嘌呤氧化酶的关系

目的探讨大鼠门静脉高压症（porta; ju[ertemsopm,PH）及梗阻性黄疸（obstructive jaundioe,OJ）时,细菌移位（bacterial translocation,BT）与黄嘌呤氧化酶（xanthine oxidase,XO）、黄嘌呤脱氢酶（xanthine dehydrogenase,XD）之间的关系。方法将雄性SD大鼠60只随机分为对照组（A组）,胆总管结扎组（B组）和门静脉缩窄组（C组）,每组20只。术后第3周取肠系膜淋巴结、脾、肝组织及门静脉、腔静脉血细菌培养,测定门静脉压力（free portal pressure,FPP）,及肠XO,XD活性水平。结果B组及C组细菌移位率明显高于对照组（P〈0．01）,对照组为12％,B组和C组分别为28％和54％;B组和C组空肠XO水平活性明显高于对照组（P〈0．01）,B组和C组门静脉压力也较对照组升高。细菌移位率与XO活性成正相关（r=0．603）。XD活性水平无显著差异。结论门静脉高压症及梗阻性黄疸时可发生细菌移位,可能与肠黏膜屏障被破坏通透性增强有关,肠壁XO水平活性增强引起肠黏膜屏障通透性增高有助于细菌移位发生。     

Early effects of catecholamine therapy on mucosal integrity, intestinal blood flow, and oxygen metabolism in porcine endotoxin shock.

OBJECTIVE: To determine the early effects of therapy of endotoxin (ET) shock with epinephrine, norepinephrine, or dopexamine on splanchnic circulation, oxygen metabolism, sigmoid mucosal pHi, bacterial translocation, and morphologic integrity of the ileal, colonic, and sigmoid mucosa. SUMMARY BACKGROUND DATA: Conflicting concepts exist concerning the catecholamine therapy of septic shock, but little is known about the effects of catecholamine treatment on splanchnic circulation and mucosal integrity. METHODS: ET shock was induced in pigs by ET infusion over 30 minutes, and animals were studied for 4 hours. All animals were resuscitated with fluid. To mimic the treatment of septic shock in humans, mean arterial pressure was maintained in two groups at >70 mm Hg with the administration of epinephrine or norepinephrine. A third group of animals received dopexamine at 7 microg/kg per minute. Systemic and splanchnic blood flow and oxygen metabolism were studied, sigmoid colon mucosal pHi was obtained tonometrically, and bacterial translocation was determined by culture of portal venous blood, mesenteric lymph nodes, liver, spleen, and lung specimens. Histologic sections of ileal, colonic, and sigmoid mucosa were morphometrically examined for therapy effects. RESULTS: All investigated catecholamines increased cardiac output and systemic oxygen delivery, whereas intestinal blood flow and oxygen delivery remained unchanged. Sigmoid mucosal pHi decreased in all study animals, but the decrease was most pronounced in the epinephrine group. Pigs receiving epinephrine also showed >40% damage of the mucosa of the ileum and colon, whereas animals receiving ET alone, norepinephrine, or dopexamine showed only moderate lesions with signs of restitution. No animal showed bacterial translocation. CONCLUSIONS: Systemic hemodynamics and oxygen metabolism data do not reflect intestinal perfusion. Norepinephrine or dopexamine administration in ET shock causes no additional impairment of intestinal integrity. Epinephrine therapy, in contrast, is associated with a significant reduction of mucosal pHi and considerable early mucosal damage. Its application in septic shock is hazardous.     

Hemorrhagic shock-induced bacterial translocation is reduced by xanthine oxidase inhibition or inactivation

Experiments were performed to determine whether bacterial translocation (BT) after hemorrhagic shock is due to a reperfusion injury mediated by xanthine oxidase-derived oxidants. Rats were subjected to 30 minutes of shock (30 mm Hg) followed by reinfusion of shed blood. Twenty-four hours after hemorrhage and reinfusion, the mesenteric lymph node, liver, and spleen were harvested from each animal for bacterial culture, and the ileum and cecum were examined histologically. Sham-shocked (control) rats were instrumented, but blood was not withdrawn. The incidence of BT was higher in the shocked rats (61%) than in the sham-shocked animals (7%) (p less than 0.01). Allopurinol (50 mg/kg, administered orally), a competitive inhibitor of xanthine oxidase, reduced the incidence of shock-induced BT to 14% (p = 0.02). Similarly, rats fed a tungsten-supplemented molybdenum-free diet, which inactivates xanthine oxidase, reduced shock-induced BT to 10% (p = 0.02). The histologic damage cause by hemorrhagic shock was prevented by blocking xanthine oxidase activity. Thus hemorrhagic shock-induced bacterial translocation from the gut appears to be mediated by oxidants generated by activation of the xanthine oxidase system.     

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.     

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.     

Elemental diet and IV-TPN-induced bacterial translocation is associated with loss of intestinal mucosal barrier function against bacteria.

OBJECTIVE: The goal of the current study was to directly assess the role of loss of mucosal barrier function in nutritionally induced bacterial translocation. BACKGROUND: Parenteral and certain elemental enteral diets have been shown to promote bacterial translocation. The mechanisms underlying this observation, especially the question of whether nutritionally induced bacterial translocation is primarily related to loss of intestinal barrier function, versus an impaired immune system, remain to be fully elucidated. METHODS: Bacterial translocation was measured in vivo, ileal mucosal membranes were harvested, and their electrophysiologic properties and barrier function were measured ex vivo in the Ussing chamber system 7 days after receiving total parenteral nutrition solution parenterally (IV-TPN) or enterally (elemental diet). Chow-fed rats served as control subjects. RESULTS: The incidence of bacterial translocation was significantly increased both to the mesenteric lymph nodes in vivo and across the in vitro Ussing chamber-mounted ileal mucosal membranes of the elemental diet-fed and IV-TPN-fed rats. The magnitude of Escherichia coli and phenol red transmucosal passage in the Ussing chamber was significantly higher in the IV-TPN-fed rats than in the elemental diet-fed or chow-fed animals. The potential differences across the ileal membrane were similar between the three groups at all time points. However, the specific resistances of the ileal membranes of the IV-TPN and elemental diet groups were significantly less than the chow-fed animals, indicating increased membrane permeability. CONCLUSIONS: Loss of intestinal barrier function plays a major role in nutritionally induced bacterial translocation, and the loss of mucosal barrier function to both E. coli and phenol red appeared greater in the IV-TPN than the elemental diet-fed rats.     

Role of gut-derived endotoxaemia and bacterial translocation in rats after thermal injury: effects of selective decontamination of the digestive tract

This study was performed to investigate: (1) the role of gut-derived endotoxin/bacterial translocation in the pathogenesis of sepsis, and (2) the possible effects of selective decontamination of the digestive tract (SDD) on mortality in rats following 40 per cent full-thickness scald injury. In the SDD-treated group, Enterobacteriaceae and yeasts were eradicated from the caecal mucosa, while the mucosal flora consisting of mainly anaerobes was well preserved, within 3 days. The incidence of bacterial translocation to the mesenteric lymph nodes (MLN) and viscerae was significantly lowered on postburn days 1, 3 and 5 (P < 0.05−0.01). Meanwhile, pretreatment with SDD resulted in reductions of the faecal endotoxin levels in different segments of intestinal tract to less than 0.5 per cent (0.04 – 0.45 per cent) of the untreated control; there was also a significant attenuation of the elevation of endotoxin concentrations in both portal and systemic blood. Intestinal diamine oxidase (DAO) activity returned to baseline on day 5 in rats receiving SDD but not in controls. The 5-day survival rate in the SDD-treated group was elevated by 26.7 per cent as compared with controls (P < 0.05). These data suggested that endotoxin/bacterial translocation took place early and commonly, which in turn contributed to postburn sepsis and mortality. SDD was effective in preventing gut origin endotoxaemia and bacterial translocation, and improving the survival rate in rats following severe thermal injuries.     

急性坏死性胰腺炎并发感染的机理研究

目的观察急性坏死性胰腺炎时肠屏障损伤与细菌移位情况,探讨急性胰腺炎继发感染的机理。方法１５只犬于肠道内定植ＰＵＣ１８质粒菌ＪＭ１０９后,分对照组（ｎ＝７）和急性坏死性胰腺炎组（ＡＮＰ,ｎ＝８）。ＡＮＰ组经主胰管注入牛磺胆酸钠和胰蛋白酶制作ＡＮＰ模型。结果ＡＮＰ组较对照组血胰淀粉酶显著升高（Ｐ＜０．０１）;尿中乳果糖／甘露醇比值高出对照组２～１２倍;空、回、盲肠粘膜及肠内容物中大肠杆菌明显增加（Ｐ＜０．０１）,双歧杆菌、乳酸杆菌明显减少（Ｐ＜０．０１、Ｐ＜０．０５）。对照组犬血培养阴性,除２只犬肠系膜淋巴结培养出细菌外,其余脏器培养均阴性。ＡＮＰ组犬血和脏器细菌培养阳性率均为１００％,且每只犬都能检出术前定植于肠道的质粒菌ＪＭ１０９;胰腺腺泡出血、坏死;肠粘膜绒毛破坏;血浆、回肠组织二胺氧化酶活性下降。结论ＡＮＰ时肠粘膜屏障功能严重受损,发生肠道细菌移位,成为继发性胰腺感染的潜在根源。     

Protective effects of exogenous fructose-1,6-biphosphate during small bowel transplantation in rats

BACKGROUND: We assessed the effect of adding exogenous fructose-1,6-biphosphate (F16BP) to the preservation solution (University of Wisconsin storage solution) used during an experimental procedure of small bowel transplantation in rats. METHODS: We studied levels of the nucleotides hypoxanthine/xanthine and adenosine in tissue after cold ischemia, as well as histologic changes and associated deleterious processes such as bacterial translocation produced by the reperfusion associated with the transplantation. RESULTS: The groups of rats treated with F16BP showed the lowest levels of hypoxanthine/xanthine and uric acid, the highest levels of adenosine, and the lowest levels of histologic damage and lactate dehydrogenase release to the bloodstream. Consumption of intestinal hypoxanthine during reperfusion was lowest in the groups treated with F16BP, as was the incidence of bacterial translocation. CONCLUSIONS: This study shows a protective effect of exogenous F16BP added to University of Wisconsin solution during experimental intestinal transplantation in rats. This protective effect, reflected by decreased intestinal damage and bacterial translocation, was related to a decrease in adenosine triphosphate depletion during cold ischemia before intestinal transplantation, and to the reduced availability of xanthine oxidase substrates for free radical generation during reperfusion.