Beta-1 blocker improves survival of septic rats through preservation of gut barrier function

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• 作者：Katsuya Mori (1)
  Hiroshi Morisaki (1)
  Satoshi Yajima (1)
  Takeshi Suzuki (1)
  Akiko Ishikawa (1)
  Norihito Nakamura (1)
  Yasushi Innami (1)
  Junzo Takeda (1)
  
• 关键词：Gut barrier function ; β1 ; Adrenergic blocker ; Inflammatory response
• 刊名：Intensive Care Medicine
• 出版年：2011
• 出版时间：November 2011
• 年：2011
• 卷：37
• 期：11
• 页码：1849-1856
• 全文大小：1704KB
• 参考文献：1. Norbury WB, Jeschke MG, Herndon DN (2007) Metabolism modulators in sepsis: propranolol. Crit Care Med 35:S616–S620 CrossRef
  2. Herndon DN, Hart DW, Wolf SE, Chinkes DL, Wolfe RR (2001) Reversal of catabolism by beta-blocker after severe burns. N Engl J Med 345:1223-229 CrossRef
  3. Ackland GL, Yao ST, Rudiger A, Dyson A, Stidwill R, Poputnikov D, Singer M, Gourine AV (2010) Cardioprotection, attenuated systemic inflammation, and survival benefit of beta1-adrenoceptor blockade in severe sepsis in rats. Crit Care Med 38:388-94 CrossRef
  4. Suzuki T, Morisaki H, Serita R, Yamamoto M, Kotake Y, Ishizaka A, Takeda J (2005) Infusion of the β-adrenergic blocker esmolol attenuates myocardial dysfunction in septic rats. Crit Care Med 33:2294-301 CrossRef
  5. Hagiwara S, Iwasaka H, Maeda H, Noguchi T (2009) Landiolol, an ultrashort-acting β1-adrenoceptor antagonist, has protective effects in an LPS-induced systemic inflammation model. Shock 31:515-20 CrossRef
  6. Novotny NM, Lahm T, Markel TA, Crisostomo PR, Wang M, Wang Y, Ray R, Tan J, Al-Azzawi D, Meldrum DR (2009) Beta-blockers in sepsis: reexamining the evidence. Shock 31:113-19 CrossRef
  7. Schmitz D, Wilsenack K, Lendemanns S, Schedlowski M, Oberbeck R (2007) Beta-adrenergic blockade during systemic inflammation: Impact on cellular immune function and survival in murine model of sepsis. Resuscitation 72:286-94 CrossRef
  8. Berg RD (1995) Bacterial translocation from the gastrointestinal tract. Trends Microbiol 3:149-54 CrossRef
  9. Mclntyre AS, Thompson DG, Burnham WR, Walker ER (1992) Modulation of human upper intestinal nutrient transit by a beta adrenoreceptor mediated pathway. Gut 33:1062-070 CrossRef
  10. Husebye E (2005) The pathogenesis of gastrointestinal bacterial overgrowth. Chemotherapy 51(Suppl 1):1-2 CrossRef
  11. Ahluwalia NK, Thompson DG, Barlow J, Heggie (1994) Beta adrenergic modulation of human upper intestinal propulsive forces. Gut 35:1356-359 CrossRef
  12. Pérez-Paramo M, Mu?oz J, Albillos A, Freile I, Portero F, Santos M, Ortiz-Berrocal J (2000) Effect of propranolol on the factors promoting bacterial translocation in cirrhotic rats with ascites. Hepatology 31:43-8 CrossRef
  13. Liu C, Wu Q, Li Q, Liu D, Su H, Shen N, Tai M, Lv Y (2009) Mesenteric lymphatic ducts ligation decreases the degree of gut-induced lung injury in a portal vein occlusion and reperfusion canine model. J Surg Res 154:45-0 CrossRef
  14. Senthil M, Brown M, Xu DZ, Lu Q, Feketeova E, Deitch EA (2006) Gut-lymph hypothesis of systemic inflammatory response syndrome/multiple-organ dysfunction syndrome: validating studies in a porcine model. J Trauma 60:958-65 CrossRef
  15. Rittirsch D, Huber-Lang MS, Flierl MA, Ward PA (2009) Immunodesign of experimental sepsis by cecal ligation and puncture. Nat Protoc 4:31-6 CrossRef
  16. Morisaki H, Sibbald W, Martin C, Doig G, Inman K (1996) Hyperdynamic sepsis depresses circulatory compensation to normovolemic anemia in conscious rats. J Appl Physiol 80:656-64
  17. Qiao Z, Li Z, Li J, Lu L, Lv Y, Li J (2009) Bacterial translocation and change in intestinal permeability in patients after abdominal surgery. J Huazhong Univ Sci Technol Med Sci 29:486-91 CrossRef
  18. de Souza Gon?alves L, Souto R, Colombo AP (2009) Detection of / Helicobacter pylori, / Enterococcus faecalis, / Pseudomonas aeruginosa in the subgingival biofilm of HIV-infected subjects undergoing HAART with chronic periodontitis. Eur J Clin Microbiol Infect Dis 28:1335-342 CrossRef
  19. Chiu CJ, McArdle AH, Brown R, Scott HT, Gurd FN (1970) Intestinal mucosal lesion in low flow states. Arch Surg 101:478-83
  20. Cain B, Meldrum DR, Dinarello CA, Meng X, Joo KS, Banerjee A, Harken A (1999) Tumor necrosis factor-alpha and interleukin-1 beta synergistically depress human myocardial function. Crit Care Med 27:1309-318 CrossRef
  21. van Zoelen MA, Yang H, Florquin S, Meijers JC, Akira S, Arnold B, Nawroth PP, Bierhaus A, Tracey KJ, van der Poll T (2009) Role of toll-like receptors 2 and 4, and the receptor for advanced glycation end products (RAGE) in HMGB1 induced inflammation in vivo. Shock 31:280-84 CrossRef
  22. Szelenyi J, Selmeczy Z, Brozik A, Medgyesi D, Magocsi M (2006) Dual beta-adrenergic modulation in the immune system: Stimulus-dependent effect of isoproterenol on MAPK activation and inflammatory mediator production in macrophages. Neurochem Int 49:94-03 CrossRef
  23. Casley-Smith R, Gannon BJ (1984) Intestinal microcirculation: spatial organization and fine structure. In: Shepherd AP, Granger DN (eds) Physiology of the intestinal circulation. Raven, New York, pp 9-1
  24. Vincent JL, De Backer D (2005) Microvascular dysfunction as a cause of organ dysfunction in severe sepsis. Crit Care 9(Suppl 4):S9–S12 CrossRef
  25. Brienza N, Ayuse T, Revelly JP, O’Donnell CP, Robotham JL (1995) Effects of endotoxin on isolated porcine liver: pressure-flow analysis. J Appl Physiol 78:784-92
  26. Yao GX, Shen ZY, Xue XB, Yang Z (2006) Intestinal permeability in rats with CCI₄-induced portal hypertension. World J Gastroenterol 12:479-81
  27. Garcia-Tsao G, Albillos A, Barden GE, West AB (1993) Bacterial translocation in acute and chronic portal hypertension. Hepatology 17:1081-085 CrossRef
  28. Zhou M, Das P, Simms HH, Wang P (2005) Gut-derived norepinephrine plays an important role in up-regulating IL-1beta and IL-10. Biochim Biophys Acta 1740:446-52
  29. Kosugi S, Morisaki H, Satoh T, Ai K, Yamamoto M, Serita R, Soejima J, Kotake Y, Ishizaka A, Takeda J (2005) Epidural analgesia prevents endotoxin-induced gut mucosal injury in rabbits. Anesth Analg 101:265-72 CrossRef
  30. Grisanti LA, Evanson J, Marchus E, Jorissen H, Woster AP, DeKrey W, Sauter ER, Combs CK, Porter JE (2010) Pro-inflammatory responses in human monocytes are β₁-adrenergic receptor subtype dependent. Mol Immunol 47:1244-254 CrossRef
  31. POISE Study Group (2008) Effects of extended-release metoprolol succinate in patients undergoing non-cardiac surgery (POISE trial): a randomised controlled trial. Lancet 371:1839-847 CrossRef
  32. Wallace AW, Au S, Cason BA (2010) Association of the pattern of use of perioperative β-blocker and postoperative mortality. Anesthesiology 113:794-05 CrossRef
  33. Nishina K, Akamatsu H, Mikawa K, Shiga M, Obara H, Niwa Y (2001) A comparison of atenolol, labetalol, esmolol, and landiolol for human neutrophil functions. Anesth Analg 93:641-44 CrossRef
  34. Tennenberg SD, Solomkin JS (1988) Neutrophil activation in sepsis: the relationship between fmet-leu-phe receptor mobilization and oxidative activity. Arch Surg 123:171-75
  35. Remick DG, Newcomb DE, Bolgos GL, Call DR (2000) Comparison of the mortality and inflammatory response of two models of sepsis: lipopolysaccharide VS cecal ligation and puncture. Shock 13:110-16 CrossRef
  36. Ebong S, Call D, Nemzek J, Bolgos G, Newcomb D, Remick D (1999) Immunopathologic alterations in murine models of sepsis of increasing severity. Infect Immun 67:6603-610
  37. Eskandari MK, Bolgos G, Miller C, Nguyen DT, DeForge LE, Remick DG (1992) Anti-tumor necrosis factor antibody therapy fails to prevent lethality after cecal ligation and puncture or endotoxemia. J Immunol 148:2724-730
  38. Giebelen IAJ, Le Moine A, van den Pangaart PS, Sedis C, Goldman M, Florquin S, van den Poll T (2008) Deficiency of α7 cholinergic receptors facilitates bacterial clearance in / Escherichia coli peritonitis. J Infect Dis 198:750-57 CrossRef
  39. Sewnath ME, Olszyna DP, Birjmohun R, ten Kate FJ, Gouma DJ, van Der Poll T (2001) IL-10 deficient mice demonstrate multiple organ failure and increased mortality during / Escherichia coli peritonitis despite an accelerated bacterial clearance. J Immunol 166:6323-331
  
• 作者单位：Katsuya Mori (1)
  Hiroshi Morisaki (1)
  Satoshi Yajima (1)
  Takeshi Suzuki (1)
  Akiko Ishikawa (1)
  Norihito Nakamura (1)
  Yasushi Innami (1)
  Junzo Takeda (1)
  
  1. Department of Anesthesiology, Keio University School of Medicine, 35 Shinanomachi, Shinjuku-ku, Tokyo, 160-8582, Japan
  

文摘

Objective Since recent study demonstrated beneficial effects of β-adrenergic blocker in sepsis, we tested the hypothesis that infusion of selective β1-blocker, esmolol, improves outcome in sepsis by modulating inflammatory responses and gut barrier function. Design Prospective randomized animal study. Setting University research laboratory. Subjects Male Wistar rats. Interventions To assess the effects of esmolol infusion on survival time, 19 animals that underwent cecal ligation and perforation were randomized into control (n?=?9) or esmolol (n?=?10) groups, the latter of which received esmolol infusion (15?mg/kg/h) throughout the study period. In an additional 20 animals, levels of tumor necrosis factor-α (TNF-α) in both plasma and intraperitoneal fluid were measured, and mesenteric lymph nodes (MLNs) and ileum were excised for evaluation of bacterial translocation and mucosal injury at the 18-h study period. Measurements and results Mean survival time in the esmolol group was significantly longer compared with the control group (69.5?±?26.8 versus 28.6?±?11.0?h). Plasma TNF-α was not detectable in either group, while intraperitoneal fluid TNF-α level was elevated in the control group but significantly depressed in the esmolol group (16.8?±?10.7 versus 5.4?±?7.1?pg/ml, P?<?0.05). Simultaneously, the Escherichia coli positive rate of MLNs was higher (100% versus 44%, P?<?0.05) and the gut mucosal injury score was elevated (4.1?±?0.6 versus 2.8?±?0.6, P?<?0.01) in the control compared with the esmolol group. Conclusions Beta-1 blocker therapy improves outcome in sepsis possibly through modulation of gut mucosal integrity and local inflammatory response.