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Sepsis: stopping an insidious killer

Sepsis: stopping an insidious killer . What you must know to understand, identify, and treat this lethal condition. Learning Objectives. Describe the physiologic response to sepsis. Discuss the signs and symptoms of sepsis. State strategies for managing sepsis. A woman, age 65.

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Sepsis: stopping an insidious killer

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  1. Sepsis: stopping an insidious killer What you must know to understand, identify, and treat this lethal condition

  2. Learning Objectives • Describe the physiologic response to sepsis. • Discuss the signs and symptoms of sepsis. • State strategies for managing sepsis.

  3. A woman, age 65 • Admitted because of a hip infection after hip replacement surgery. The infection, caused by Staphylococcus aureus, has been difficult to treat, so she’s admitted for more aggressive antibiotic therapy. • On admission, a nurse records this information: • Heart rate: 113 beats/minute (tachycardia) • Respiratory rate: 28 breaths/minute (tachypnea) • Temperature: 100.9° F (38.3° C) (febrile) • White blood cell count (WBC): 21,200/μl(leukocytosis)

  4. A woman, age 65 • Within 24 H of admission to a medical unit, her urine output falls. Believing she may be dehydrated, the physician orders 1,500 ml of normal saline solution. But she doesn’t respond well to the fluid administration. • The next day, her pulse oximeter reading falls from 96% to 88%. In response, she’s given nasal oxygen at 3 L/minute, which increases her oximeter reading to 92%. Then, < 36 hours after the start of oxygen therapy, her BP drops, and she is transferred to the intensive care unit (ICU).

  5. A woman, age 65 • In the ICU, she’s intubated and given the only treatments available for sepsis: a) aggressive fluid replacement to return oxygen saturation to normal b) tight glycemic control to keep her blood glucose level below 150 mg/dl c) corticosteroid replacement d) activated protein C (Xigris). • Despite these efforts, she dies after 10 days in the ICU.

  6. Infection or Sepsis ? • The confusion between infection and sepsis is responsible for delays in identifying sepsis. And delays in treating sepsis can result in tragic outcomes. • Sepsis is lethal, and its development is insidious. Be vigilant in recognizing the condition.

  7. Epidemiology • Prior to 1987, gram-negative organisms were predominant. In the past 20 years, sepsis caused by gram-positive organisms has increased markedly, and now predominant. Additionally, over the same time period, the incidence of fungal sepsis has increased by over 200%. • Changes due to  numbers of IC patients & debilitated surgical patients, & increased use of indwelling catheters and devices. • The causative organisms implicated in sepsis have changed over time, and many cases have non-diagnostic or negative cultures. • The identified sites of primary infection are:lung(47%), unknown/other (28%), peritoneum (15%), and urinary tract (10%).

  8. Severe Sepsis Among Adults in PGH ICUs 223/1207 (18.5%) with severe sepsis Mean duration of stay 14 days (S.D.12) ICU mortality rate 58.9% (95% CI 52%, 66%) Respiratory tract most common site Gram negative infections common: Pseudomonas aeruginosa, Klebsiella, Acinetobacter Most frequent organ dysfunction: resp., CVS, neuro Source: Taguiang-Abu C. and Alejandria M., Phil. J. Internal Medicine 2008

  9. Risk Factors: Immunosuppresion OR 2.45 (C.I. 1.11, 5.42) Cardiovascular dysfunction OR 3.57 (C.I. 1.56, 8.16) Hematologic dysfunction OR 3.45 (C.I 1.43, 8.29) Inappropriate antibiotic OR 9.20 ( C.I. 4.27, 19.82) Severe Sepsis Among Adults in PGH ICUs Source: Taguiang-Abu C. and Alejandria M., Phil. J. Internal Medicine 2008

  10. Special Concerns – Sepsis in the Elderly • Increased in the elderly; WHY? • Decrease in cell-mediated & humoral immune function • Cytokine & chemokine signaling networks are altered • Induction of proinflammatory cytokines after septic stimuli not adequately controlled by anti-inflammatory mechanism • Pronounced procoagulant state

  11. Definitions of Sepsis (ACCP/SCCM Consensus Conference) • Bacteremia– presence of viable bacteria in the blood. Similarly, the presence of other pathogens in blood would be described appropriately as viremia, fungemia, or parasitemia • Infection– microbial phenomenon characterized by an inflammatory response to the presence of microorganisms or the invasion of otherwise sterile host tissues by those organisms

  12. SEPSIS • Systemic inflammatory response to an infection • Infection = presence of microorganisms (bacteria, fungi, viral, parasitic) in a normally sterile site • If associated with proven or clinically suspected infection SIRS = SEPSIS

  13. Identifying Acute Organ Dysfunction as a Marker of Severe Sepsis Altered Consciousness Confusion Psychosis Tachycardia Hypotension  CVP  PAOP Tachypnea PaO2 <70 mm Hg SaO2 <90% PaO2/FiO2300 Oliguria Anuria  Creatinine Jaundice  Enzymes  Albumin  PT  Platelets  PT/APTT  Protein C  D-dimer

  14. Organ Dysfunction Associated with Severe Sepsis and Septic Shock • Skin: Skin lesions in sepsis can arise by at least 5 mechanisms: • Disseminated intravascular coagulation and coagulopathy - for example, in sepsis due to gram-negative and gram-positive bacteria. • Invasion of blood vessel walls - for example, in ecthymagangrenosum, Rocky Mountain spotted fever, meningococcemia, disseminated candidiasis, Aspergillus infection, and mucormycosis.

  15. Ecthymagangrenosum • The initial skin lesions of ecthymagangrenosum are erythematous to purpuricmacules, hemorrhagic vesicles, bullae, or nodules. They rapidly progress to a painless, indurated ulcer with a central necrotic black eschar and surrounding erythema. • The most common sites of distribution are the axillae and anogenital regions. • Early clue to severe infection caused by Pseudomonas aeruginosaand, less commonly, to other bacteria and fungi.

  16. Organ Dysfunction Associated with Severe Sepsis and Septic Shock • Immune complex formation with vasculitis―for example, endocarditis, disseminated gonococcal disease, typhoid fever, and meningococcemia (later phases). • Embolism―for example, endocarditis and, rarely, mycotic aneurysm. • Toxin formation―for example, toxic shock syndrome, scarlet fever

  17. Organ Dysfunction Associated with Severe Sepsis and Septic Shock • Endocrine- Relative adrenal insufficiency Hypo/hyperglycemia Persistent hypotension

  18. SEPTIC SHOCK • Sepsis with hypotension that requires pressor therapy despite adequate fluid resuscitation (or normotensive on vasopressors) accompanied by perfusion abnormalities described for Severe Sepsis • If no response in >1hr: Refractory Septic Shock MODS Dysfunction of > 1 organ requiring intervention to maintain homeostasis

  19. Differential Diagnosis

  20. Pathogenesis • Determinants of the Sepsis Syndrome: • Virulence of the organism. b)Inoculum of the organism. Greater# of invaders  greater inflammatory response c) Site of Infection- what organisms invade what areas d) Host Response– the balance between inflammatory & anti-inflammatory response e)Genetic Factors– susceptibility and regulation

  21. Pathogenesis • Organisms: cause sepsis syndrome either by Direct Invasion or Intoxication. A.Sources of Direct Invasion: • Gram (-)’s: some of the enterics, pseudomonas • Gram (+)’s have become the leading cause of Septic Shock • TB (less common) • Virus (becoming more common) eg. SARS • Fungal (alarming growth in infection rate over last decade in the US)

  22. Pathogenesis B.Intoxication: elaboration of proteins by a number of bacteria S. aureus can secrete toxic shock syndrome toxin-1 (TSST-1) S. pyogenes secretes streptococcal pyrogenicexotoxin A (SPEA)

  23. Sepsis & Inflammation • Microorganisms have unique cell-wall molecules called pathogen-associated molecular patterns that bind to pattern-recognition receptors (toll-like receptors [TLRs]) on the surface of immune cells. • The LPS of GNB binds to LPS-binding protein, CD14 complex. The peptidoglycan of GPB and the LPS of GNB bind to TLR-2 and TLR-4, respectively.

  24. Sepsis & Inflammation • Interaction of a PAMP with a Tlr results in a cellular cascade which leads to activation of innate immune mechanisms 􀂄Message sent to nucleus resulting in transcription of repressed genes 􀂄 Antimicrobial peptide synthesis and release 􀂄 Beginning of a specific adaptive antibody response 􀂄Release of Mediators of inflammation 􀂄 Normally protective but some type of dysregulation leads to signs of SEPSIS

  25. Cytokines & other inflammatory mediator cascades • Infection stimulates neutrophils & monocytesto produce reactive oxygen intermediates. • Interleukin-10 is an antiinflammatory cytokine that inactivates macrophages and has other antiinflammatoryeffects. • Stimulated monocytes-macrophages produce proinflammatorycytokines  TNF- IL-1, IL-6, IL-8  interferon- • Infection activates the complement & coagulation pathways.

  26. Sepsis and Inflammation • Animal models using large endotoxin or bacterial load lead to a cytokine storm and death • Failure of trial agents that block the inflammatory cascade to reduce mortality in humans leads to question of whether death in sepsis is due to uncontrolled inflammation

  27. Sepsis & Immunosuppression • Septic patients have features of immunosuppression • Sepsis may initially have increased inflammatory mediators and later an anti-inflammatory state

  28. Clinically, this procoagulant state of sepsis is manifested by decreased platelets, protein C deficiency, and positive D-dimers.

  29. aProtein C modulates both the inflammatory and the coagulation cascades – Endothelial dysfunction caused by proinflammatory cytokines decreases thrombomodulin, a protein that binds with thrombin. The complex formed is required to convert protein C to aProtein C, an important anti-inflammatory, antithrombotic, and profibrinolytic molecule. Patients with sepsis are deficient in protein C and at increased risk for thrombosis and continued inflammation.

  30. Activated Protein C - Proposed Mechanisms • Anti-inflammatory effects - Inhibits cytokine production & release - Inhibits neutrophil activation & endothelial damage • Anticoagulant effects - Endogenous APC levels are depleted in sepsis - APC cleaves and inactivate factors Va & Vllla - Ultimately limits generation of thrombin • Fibrinolysis effects - Inactivates PAI-1 to promote homeostatic thrombolysisby tPA - Inhibits TAFI activation to maintain fibrinolysis Crit Care Mod 2001 ;29(Supp/):S69-S74 RSS 2001

  31. How infection leads to septic shock ? • Release of the inflammatory mediators described above leads to: Endothelial damage resulting in fluid leakage  Loss of vascular resistance  Reduced cardiac inotropy  Extensive coagulation & DIC B. End result is end-organ damage that eventually will lead to organ failure & death.

  32. Coagulation  Inflammation Homeostasis Is Lost In Sepsis • Proinflammatory mediators • Endothelial injury • Tissue factor expression • Thrombin production Fibrinolysis • Increased PAl-1 • Increased TAFIa • Reduced Protein C (Activated Protein C inhibits PAI-1) Homeostasis PAI-1= plasminogen activator inhibitor-1;TAFIa= thrombin activatablefibrinolysis inhibitor. Carvalho and Freeman. J Crit Illness. 1994;9:51; Kidokoro et al. Shock. 1996;5:223; Vervloet et al. SeminThrombHemost. 1998;24:33.

  33. What Determines Clinical Outcome of Sepsis? • Balance between proinflammatory & counter-regulatory anti-inflammatory events in response to infection determines clinical outcome. • Excessive proinflammatoryresponse causes systemic toxicity clinically manifested by as sepsis. • Excessive anti-inflammatory response causes immunoparalysis associated with increased propensity for overwhelming infection & late mortality.

  34. Bacterial, fungal, viral infection Endotoxin, Cell walls Superantigens (Exotoxins) Macrophages, monocytes T Cells Cytokine release – TNF-a, IL-1, IL-6, IL-8, IL-10 Platelet and coagulation activation Complement activation Endothelial injury, coagulation, DIC, shock, end organ damage Irrerverisble shock – Multiorgan failure - Death

  35. Clinical Manifestations • Fever  First & most common manifestation The greater the height of temperature, the more likely is bacteremia. Hypothermia & normal body temperature can be seen in patients who are bacteremic.  Hypothermia is a poor prognostic indicator in bacteremic patients.

  36. Clinical Manifestations • Hemodynamic Changes  Tachycardia in association with fever is to be expected. Bradycardia is unusual, being found in typhoid fever & brucellosis. Hypotension is the most important determinant of outcome.

  37. Clinical Manifestations Preshock the stage at which hypotension is reversible.  Characterized by warm skin, diminished mentation(often worse in the elderly), & oliguria.  Failure to reverse hypotension in its early stages results in serious end organ damage.

  38. Clinical Manifestations Persistent hypotensionoften not reversed by antibiotics & other measures.  Characterized by cool skin, ARF, &, later, hepatic injury.

  39. Figure B, page 948, reproduced with permission from Dellinger RP. Cardiovascular management of septic shock. Crit Care Med 2003;31:946-955.

  40. Physiologic Characteristics of the Various Forms of Shock Note:CVP, central venous pressure; PCWP, pulmonary capillary wedge pressure.

  41. Mechanisms of Vasodilatory or Distributive shock

  42. Clinical Manifestations C.Acid-Base Disturbances  Reduced tissue perfusion results in shift from aerobic to anaerobic metabolism causing lactic acid accumulation. Respiratory alkalosis usually seen first as a consequence of tachypnea. The first pronounced change, signaling impending shock.  Seen at the time when hemodynamic changes are reversible with fluid resuscitation.

  43. Clinical Manifestations Critical to recognize this early reversible stage of septic shock. Metabolic acidosisdevelops just prior to or accompanies hypotension.  Signals the beginning of a fatal downward spiral.  Reflects severe organ hypoperfusion& failure.

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