The acute inflammatory response to sepsis gives rise to significant morbidity and mortality. The mechanisms underlying this form of tissue injury are poorly understood. This review examines the evidence that tissue ischaemia due, to generalized microvascular thrombosis may play an important role.
Microvascular thrombosis is probably an adaptive response that prevents bacteria in the tissues reaching the systemic circulation via the capillaries. In time, a definitive response by leucocytes removes the bacteria and repairs the damaged tissues. There is however evidence that if microvascular thrombosis becomes generalized, then extensive tissue ischaemia may precipitate organ failure and death.
Post-mortem studies of patients with sepsis demonstrate microvascular thrombi in many organs including the kidney, liver, lung, gut, adrenals and brain, and the degree of organ injury is related to the quantity of thrombi. Furthermore studies in human and animal models of sepsis demonstrate therapies that inhibit coagulation or promote fibrinolysis reduce organ failure and mortality.
In view of the personal and economic burdens that tissue injury associated with the acute inflammatory response places on the community, further studies to establish the role of microvascular thrombosis are clearly required. Such studies may lead to new therapies to limit or prevent this form of injury.
TraceyK.J., LowryS.F., FaheyTJ3rd. Cachectin/tumor necrosis factor induces lethal shock and stress hormone responses in the dog. Surg Gynecol Obstet1987; 164: 415–422.
2.
JansenP.M., BoermeesterM.A., FischerE.Contribution of interleukin-1 to activation of coagulation and fibrinolysis, neutrophil degranulation, and the release of secretory-type phospholipase A2 in sepsis: studies in nonhuman primates after interleukin-1 alpha administration and during lethal bacteremia. Blood1995; 86: 1027–1034.
HinshawL.B., EmersonT.E.Jr., TaylorF.B.Jr.Lethal Staphylococcus aureus-induced shock in primates: prevention of death with anti-TNF antibody. J Trauma1992; 33: 568–573.
5.
FischerE., MaranoM.A., Van ZeeK.J.Interleukin-1 receptor blockade improves survival and hemodynamic performance in Escherichia coli septic shock, but fails to alter host responses to sublethal endotoxemia. J Clin Invest1992; 89: 1551–1557.
6.
FinferS., BellomoR., LipmanJ., FrenchC., DobbG., MyburghJ.Adult-population incidence of severe sepsis in Australian and New Zealand intensive care units. Intensive Care Med2004; 30: 589–596.
7.
ScheldW.M., KoedelU., NathanB., PfisterH.W.Pathophysiology of bacterial meningitis: mechanism(s) of neuronal injury. J Infect Dis2002; 186Suppl 2: S225–S233.
8.
HotchkissR.S., KarlI.E.The pathophysiology and treatment of sepsis. N Engl J Med2003; 348: 138–150.
9.
CrouserE.D., JulianM.W., BlahoD.V., PfeifferD.R.Endotoxin-induced mitochondrial damage correlates with impaired respiratory activity. Crit Care Med2002; 30: 276–284.
10.
ArgenbrightL.W., BartonR.W.Interactions of leukocyte integrins with intercellular adhesion molecule 1 in the production of inflammatory vascular injury in vivo. The Shwartzman reaction revisited. J Clin Invest1992; 89: 259–272.
11.
IvanyiB.Hypoxic damage to tubules due to blockage of perfusion in acute hematogenous E. coli pyelonephritis of rats. Acta Morphol Hung1991; 39: 239–248.
12.
ShibayamaY.Sinusoidal circulatory disturbance by micro-thrombosis as a cause of endotoxin-induced hepatic injury. J Pathol1987; 151: 315–321.
13.
De BackerD., CreteurJ., PreiserJ.C., DuboisM.J., VincentJ.L.Microvascular blood flow is altered in patients with sepsis. Am J Respir Crit Care Med2002; 166: 98–104.
14.
DondorpA.M., AngusB.J., HardemanM.R.Prognostic significance of reduced red blood cell deformability in severe falciparum malaria. Am J Trop Med Hyg1997; 57: 507–511.
15.
EsmonC.T.Inflammation and thrombosis. J Thromb Haemost2003; 1: 1343–1348.
16.
LeviM., Ten CateH.Disseminated intravascular coagulation. N Engl J Med1999; 341: 586–592.
17.
RidkerP.M., CushmanM., StampferM.J., TracyR.P., HennekensC.H.Inflammation, aspirin, and the risk of cardiovascular disease in apparently healthy men. N Engl J Med1997; 336: 973–979.
18.
RidkerP.M., CushmanM., StampferM.J., TracyR.P., HennekensC.H.Plasma concentration of C-reactive protein and risk of developing peripheral vascular disease. Circulation1998; 97: 425–428.
19.
KwaanH.C.The role of fibrinolysis in disease processes. Semin Thromb Hemost1984; 10: 71–79.
DeLa CadenaR.A., Majluf-CruzA., StadnickiA.Recom-binant tumor necrosis factor receptor p75 fusion protein (TNFR: Fc) alters endotoxin-induced activation of the kinin, fibrinolytic, and coagulation systems in normal humans. Thromb Haemost1998; 80: 114–118.
24.
JandlJ.H.Blood: Textbook of Hematology. Second Ed. Boston: Little, Brown and Company; 1996.
25.
de JongeE., DekkersP.E., CreaseyA.A.Tissue factor pathway inhibitor dose-dependently inhibits coagulation activation without influencing the fibrinolytic and cytokine response during human endotoxemia. Blood2000; 95: 1124–1129.
26.
Anti-infective Advisory Commitee.FDA briefing document for Xigris for the treatement for sepsis. United States Food and drug administration, available at www.fda.gov 2001.
27.
BernardG.R., VincentJ.L., LaterreP.F.Efficacy and safety of recombinant human activated protein C for severe sepsis. N Engl J Med2001; 344: 699–709.
28.
KielianT.L., BlechaF.CD14 and other recognition molecules for lipopolysaccharide: a review. Immunopharmacology1995; 29: 187–205.
29.
KielianT., HickeyW.F.Proinflammatory cytokine, chemokine, and cellular adhesion molecule expression during the acute phase of experimental brain abscess development. Am J Pathol2000; 157: 647–658.
30.
FrankM.M., FriesL.F.Complement. In: PaulW.E., editor. Fundamental Immunology. Second Ed. New York: Raven Press Ltd, 1989; p. 679–701.
31.
WachtfogelY.T., DeLa CadenaR.A., ColmanR.W.Structural biology, cellular interactions and pathophysiology of the contact system. Thromb Res1993; 72: 1–21.
32.
BjorkJ., HugliT.E., SmedegardG.Microvascular effects of anaphylatoxins C3a and C5a. J Immunol1985; 134: 1115–1119.
33.
PerryM.E., KirkpatrickW.N., HapperfieldL.C., GleesonM.J.Expression of adhesion molecules on the microvasculature of the pharyngeal tonsil (adenoid). Acta Otolaryngol Suppl1996; 523: 47–51.
34.
LenkH., TannebergerS., MullerU., EbertJ., ShigaT.Phase II clinical trial of high-dose recombinant human tumor necrosis factor. Cancer Chemother Pharmacol1989; 24: 391–392.
35.
CrownJ., JakubowskiA., KemenyN.A phase I trial of recombinant human interleukin-1 beta alone and in combination with myelosuppressive doses of 5-fluorouracil in patients with gastrointestinal cancer. Blood1991; 78: 1420–1427.
36.
SteeberD.A., TangM.L., GreenN.E., ZhangX.Q., SloaneJ.E., TedderT.F.Leukocyte entry into sites of inflammation requires overlapping interactions between the L-selectin and ICAM-1 pathways. J Immunol1999; 163: 2176–2186.
McGillS.N., AhmedN.A., ChristouN.V.Increased plasma von Willebrand factor in the systemic inflammatory response syndrome is derived from generalized endothelial cell activation. Crit Care Med1998; 26: 296–300.
van de StolpeA., van der SaagP.T.Intercellular adhesion molecule-1. J Mol Med1996; 74: 13–33.
41.
McCuskeyR.S., UrbaschekR., UrbaschekB.The microcirculation during endotoxemia. Cardiovasc Res1996; 32: 752–763.
42.
CollinsP.W., NobleK.E., ReittieJ.R., HoffbrandA.V., PasiK.J., YongK.L.Induction of tissue factor expression in human monocyte/endothelium cocultures. Br J Haematol1995; 91: 963–970.
43.
NapoleoneE., Di SantoA., LorenzetR.Monocytes upregulate endothelial cell expression of tissue factor: a role for cell-cell contact and cross-talk. Blood1997; 89: 541–549.
44.
NawrothP.P., SternD.M.Modulation of endothelial cell hemo-static properties by tumor necrosis factor. J Exp Med1986; 163: 740–745.
45.
SchleefR.R., BevilacquaM.P., SawdeyM., GimbroneM.A.Jr., LoskutoffD.J.Cytokine activation of vascular endothelium. Effects on tissue-type plasminogen activator and type 1 plasminogen activator inhibitor. J Biol Chem1988; 263: 5797–5803.
46.
HajM.A., RobbieL.A., AdeyG.D., BennettB.Inhibitors of plas-minogen activator in neutrophils and mononuclear cells from septic patients. Thromb Haemost1995; 74: 1528–1532.
47.
IvanyiB., ThoenesW.Microvascular injury and repair in acute human bacterial pyelonephritis. Virchows Arch A Pathol Anat Histopathol1987; 411: 257–265.
SchaferB.M., MaierK., EickhoffU., ToddR.F., KramerM.D.Plasminogen activation in healing human wounds. Am J Pathol1994; 144: 1269–1280.
50.
BoyleM.D., LottenbergR.Plasminogen activation by invasive human pathogens. Thromb Haemost1997; 77: 1–10.
51.
GebbiaJ.A., MoncoJ.C., DegenJ.L., BuggeT.H., BenachJ.L.The plasminogen activation system enhances brain and heart invasion in murine relapsing fever borreliosis. J Clin Invest1999; 103: 81–87.
52.
SodeindeO.A., SubrahmanyamY.V., StarkK., QuanT., BaoY., GoguenJ.D.A surface protease and the invasive character of plague. Science1992; 258: 1004–1007.
53.
AsakaS., ShibayamaY., NakataK.Pathogenesis of focal and random hepatocellular necrosis in endotoxemia: microscopic observation in vivo. Liver1996; 16: 183–187.
54.
BucknallT.E.The effect of local infection upon wound healing: an experimental study. Br J Surg1980; 67: 851–855.
55.
NinikoskiJ., HeughanC., HuntT.Oxygen and carbon dioxide tensions in experimental wounds. Surg, Gynecol Obstet1971; 133: 1003–1007.
56.
NiinikoskiJ., GrislisG., HuntT.K.Respiratory gas tensions and collagen in infected wounds. Ann Surg1972; 175: 588–593.
57.
SimmenH.P., BlaserJ.Analysis of pH and pO2 in abscesses, peritoneal fluid, and drainage fluid in the presence or absence of bacterial infection during and after abdominal surgery. Am J Surg1993; 166: 24–27.
58.
WongJ.K., MustardR., GrayR.R.Predicting infection in localized intraabdominal fluid collections: value of pH and pO2 measurements. J Vasc Interv Radiol1999; 10: 421–427.
59.
SawyerR.G., SpenglerM.D., AdamsR.B., PruettT.L.The peritoneal environment during infection. The effect of monomicrobial and polymicrobial bacteria on pO2 and pH. Ann Surg1991; 213: 253–260.
60.
PinzelloG., VirdoneR., LojaconoF.Is the acidity of ascitic fluid a reliable index in making the presumptive diagnosis of spontaneous bacterial peritonitis?Hepatology1986; 6: 244–247.
61.
CazinM., PaluszezakD., BianchiA., CazinJ.C., AertsC., VoisinC.Effects of anaerobiosis upon morphology and energy metabolism of alveolar macrophages cultured in gas phase. Eur Respir J1990; 3: 1015–1022.
62.
ButterickC.J., WilliamsD.A., BoxerL.A.Changes in energy metabolism, structure and function in alveolar macrophages under anaerobic conditions. Br J Haematol1981; 48: 523–532.
63.
LawsonC.A., YanS.D., YanS.F.Monocytes and tissue factor promote thrombosis in a murine model of oxygen deprivation. J Clin Invest1997; 99: 1729–1738.
64.
KnightonD.R., HuntT.K., ScheuenstuhlH., HallidayB.J., WerbZ., BandaM.J.Oxygen tension regulates the expression of angio-genesis factor by macrophages. Science1983; 221: 1283–1285.
65.
PinskyD.J., LiaoH., LawsonC.A.Coordinated induction of plasminogen activator inhibitor-1 (PAI-1) and inhibition of plasminogen activator gene expression by hypoxia promotes pulmonary vascular fibrin deposition. J Clin Invest1998; 102: 919–928.
66.
ErtelW., MorrisonM.H., AyalaA., ChaudryI.H.Hypoxemia in the absence of blood loss or significant hypotension causes inflammatory cytokine release. Am J Physiol1995; 269: R160–166.
67.
AlbinaJ.E., HenryW.L.Jr., MastrofrancescoB., MartinB.A., ReichnerJ.S.Macrophage activation by culture in an anoxic environment. J Immunol1995; 155: 4391–4396.
68.
BodamyaliT., StevensC.R., BillinghamM.E., OhtaS., BlakeD.R.Influence of hypoxia in inflammatory synovitis. Ann Rheum Dis1998; 57: 703–710.
MargarettenW.Local tissue damage in disseminated intravascular clotting. Am J Cardiol1967; 20: 185–190.
71.
KojimaM., ShimamuraK., MoriN., OkaK., NakazawaM.A histological study on microthrombi in autopsy cases of DIC. Bibl Haematol1983; 95–106.
72.
McHenryM.C., BaggenstossA.H., MartinW.J.Bacteremia due to gram-negative bacilli. Clinical and autopsy findings in 33 cases. Am J Clin Pathol1968; 50: 160–174.
73.
LoscalzoJ.The macrophage and fibrinolysis. Semin Thromb Hemost1996; 22: 503–506.
74.
VossB.L., De BaultL.E., BlickK.E.Sequential renal alterations in septic shock in the primate. Circ Shock1991; 33: 142–155.
75.
YamamotoK., LoskutoffD.J.Fibrin deposition in tissues from endotoxin-treated mice correlates with decreases in the ex-pression of urokinase-type but not tissue-type plasminogen activator. J Clin Invest1996; 97: 2440–2451.
76.
BlaisdellF.W.Pathophysiology of the respiratory distress syndrome. Arch Surg1974; 108: 44–49.
77.
KaufmanH.H., HuiK.S., MattsonJ.C.Clinicopathological correlations of disseminated intravascular coagulation in patients with head injury. Neurosurgery1984; 15: 34–42.
78.
TomashefskiJ.F.Jr., DaviesP., BoggisC., GreeneR., ZapolW.M., ReidL.M.The pulmonary vascular lesions of the adult respiratory distress syndrome. Am J Pathol1983; 112: 112–126.
79.
BoneR.C., FrancisP.B., PierceA.K.Intravascular coagulation associated with the adult respiratory distress syndrome. Am J Med1976; 61: 585–589.
80.
HillJ.D., RatliffJ.L., ParrottJ.C.Pulmonary pathology in acute respiratory insufficiency: lung biopsy as a diagnostic tool. J Thorac Cardiovasc Surg1976; 71: 64–71.
81.
GreeneR., ZapolW.M., SniderM.T.Early bedside detection of pulmonary vascular occlusion during acute respiratory failure. Am Rev Respir Dis1981; 124: 593–601.
82.
JantschH.Incidence and prognostic significance of pulmonary artery thromboses in patients with acute respiratory failure. Wien Klin Wochenschr Suppl1989; 179: 3–15.
83.
MestersR.M., MannucciP.M., CoppolaR., KellerT., OstermannH., KienastJ.Factor VIIa and antithrombin III activity during severe sepsis and septic shock in neutropenic patients. Blood1996; 88: 881–886.
84.
LorenteJ.A., Garcia-FradeL.J., LandinL.Time course of hemostatic abnormalities in sepsis and its relation to outcome. Chest1993; 103: 1536–1542.
85.
GandoS., KameueT., NanzakiS., NakanishiY.Disseminated intravascular coagulation is a frequent complication of systemic inflammatory response syndrome. Thromb Haemost1996; 75: 224–228.
86.
MestersR.M., FlorkeN., OstermannH., KienastJ.Increase of plasminogen activator inhibitor levels predicts outcome of leukocytopenic patients with sepsis. Thromb Haemost1996; 75: 902–907.
87.
PralongG., CalandraT., GlauserM.P.Plasminogen activator inhibitor 1: a new prognostic marker in septic shock. Thromb Haemost1989; 61: 459–462.
88.
HermansP.W., HibberdM.L., BooyR.4G/5G promoter polymorphism in the plasminogen-activator-inhibitor-1 gene and outcome of meningococcal disease. Meningococcal Research Group. Lancet1999; 354: 556–560.
89.
FourrierF., ChopinC., GoudemandJ.Septic shock, multiple organ failure, and disseminated intravascular coagulation. Compared patterns of antithrombin III, protein C, and protein S deficiencies. Chest1992; 101: 816–823.
90.
HoffmannH., SiebeckM., SpannaglM.Effect of recombinant hirudin, a specific inhibitor of thrombin, on endotoxin-induced intravascular coagulation and acute lung injury in pigs. Am Rev Respir Dis1990; 142: 782–788.
91.
TaylorF.B.Jr., ChangA., RufW.Lethal E. coli septic shock is prevented by blocking tissue factor with monoclonal antibody. Circ Shock1991; 33: 127–134.
92.
TaylorF.B., ChangA.C., PeerG., LiA., EzbanM., HednerU.Active site inhibited factor VIIa (DEGR VIIa) attenuates the coagulant and interleukin-6 and -8, but not tumor necrosis factor, responses of the baboon to LD100 Escherichia coli. Blood1998; 91: 1609–1615.
93.
TaylorF.B.Jr., EmersonT.E.Jr., JordanR., ChangA.K., BlickK.E.Antithrombin-III prevents the lethal effects of Escherichia coli infusion in baboons. Circ Shock1988; 26: 227–235.
94.
CarrC., BildG.S., ChangA.C.Recombinant E. coli-derived tissue factor pathway inhibitor reduces coagulopathic and lethal effects in the baboon gram-negative model of septic shock. Circ Shock1994; 44: 126–137.
95.
TaylorF.B.Jr., ChangA., EsmonC.T., D'AngeloA., Vigano-D'angeloA.S., BlickK.E.Protein C prevents the coagulopathic and lethal effects of Escherichia coli infusion in the baboon. J Clin Invest1987; 79: 918–925.
96.
Welty-WolfK.E., CarrawayM.S., MillerD.L.Coagulation blockade prevents sepsis-induced respiratory and renal failure in baboons. Am J Respir Crit Care Med2001; 164: 1988–1996.
97.
CarrawayM.S., Welty-WolfK.E., MillerD.L.Blockade of tissue factor: treatment for organ injury in established sepsis. Am J Respir Crit Care Med2003; 167: 1200–1209.
98.
WarrenB.L., EidA., SingerP.Caring for the critically ill patient. High-dose antithrombin III in severe sepsis: a randomized controlled trial. JAMA2001; 286: 1869–7188.
99.
AbrahamE., ReinhartK., OpalS.Efficacy and safety of tifacogin (recombinant tissue factor pathway inhibitor) in severe sepsis: a randomized controlled trial. JAMA2003; 290: 238–247.
DavidsonB.L., GeertsW.H., LensingA.W.Low-dose heparin for severe sepsis. N Engl J Med2002; 347: 1036–1037.
102.
HardawayR.M., WilliamsC.H., SunY.A new approach to the treatment of experimental septic shock. J Surg Res1996; 61: 311–6.
103.
BergsteinJ.M.Tissue plasminogen activator therapy of glomerular thrombi in the Shwartzman reaction. Kidney Int1989; 35: 14–8.
104.
SmithEF3rd, KinterL.B., JugusM., ZeidR.Effect of the thrombolytic agent, streptokinase, on the responses to endo-toxemia in conscious rats. Circ Shock1988; 25: 85–94.
105.
HarkeH R.S.Fibrinolytic enzymes in shock treatment. In: RMH., editor. Shock: The reversible stage of dying.Littleton, Massachusetts: PSG Publishing Company; 1983. p. 516–529.
106.
HardawayR.M., HarkeH., WilliamsC.Fibrinolytic agents: a new approach to the treatment of adult respiratory distress syndrome. Ad Ther1994; 11: 43–51.
107.
HardawayR.M.Traumatic and septic shock alias post-trauma critical illness. Br J Surg1998; 85: 1473–9.
108.
GreeneR., LindS., JantschH.Pulmonary vascular obstruction in severe ARDS: angiographic alterations after i.v. fibrinolytic therapy. Am J Roentgenol1987; 148: 501–8.
