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General Principles of Pathophysiology

General Principles of Pathophysiology. Energy Metabolism Perfusion Shock. Topics. Define shock in terms of cellular function Review the requirements for adequate cellular perfusion (Fick principle) Review the mechanisms for starling’s law Preload vs. afterload Muscle contraction.

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General Principles of Pathophysiology

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  1. General Principles of Pathophysiology Energy Metabolism Perfusion Shock

  2. Topics • Define shock in terms of cellular function • Review the requirements for adequate cellular perfusion (Fick principle) • Review the mechanisms for starling’s law • Preload vs. afterload • Muscle contraction

  3. Topics Continued • Discuss the mechanisms for oxygen transport • oxyhemoglobin dissociation curve • Define the stages of shock • Describe different causes of shock • Define multiple organ dysfunction syndrome

  4. Shock Defined • Inadequate tissue perfusion • Anaerobic metabolism Final Common Pathway!

  5. 6 O2 GLUCOSE Aerobic Metabolism 6 CO2 6 H2O METABOLISM 36 ATP HEAT (417 kcal)

  6. Anaerobic Metabolism 2 LACTIC ACID GLUCOSE METABOLISM 2 ATP HEAT (32 kcal)

  7. Inadequate Energy Production Anaerobic Metabolism Lactic Acid Production Metabolic Failure Cell Death! Metabolic Acidosis Anaerobic? So What? Inadequate Cellular Oxygenation

  8. Homeostasis is maintenance of balance • Requires proper functioning systems • Cardiovascular • Respiratory • Renal

  9. Physiology of Perfusion • Dependant on 3 components of circulatory system • Pump • Fluid • Container

  10. Factors Affecting The Pump • Preload • Contractile force • Frank-starling mechanism • Afterload

  11. What Is Blood Pressure? BP = Cardiac Output X Systemic Vascular Resistance CO = Stroke Volume X Heart Rate

  12. What Affects Blood Pressure? • ANS balance • Contractility • Preload • Starling’s law • Afterload

  13.  peripheral vascular resistance… •  afterload… •  blood pressure. Changes in Afterload and Preload  •  Peripheral vasoconstriction…

  14.  peripheral vascular resistance… •  afterload… •  blood pressure. Changes in Afterload and Preload •  Peripheral vasodilation…

  15.  preload… •  contractility (Starling’s Law)… •  blood pressure. •  cardiac output. Changes in Afterload and Preload •  fluid volume…

  16.  preload… •  contractility (Starling’s Law)… •  blood pressure. •  cardiac output. Changes in Afterload and Preload •  fluid volume…

  17. Hemostasis • The stoppage of bleeding. • Three methods • Vascular constriction • Platelet plug formation • Coagulation

  18. Coagulation • Formation of blood clots • Prothrombin activator • Prothrombin  thrombin • Fibrinogen  fibrin • Clot retraction

  19. Disseminated Intravascular Coagulation “A systemic thrombohemorrhagic disorder … with evidence of: • Procoagulant activation • Fibrinolytic activation • Inhibitor consumption • End-organ failure” Bick, R.L. Seminars in Thrombosis and Hemostasis 1996

  20. Pathophysiology of DIC • Uncontrolled acceleration of clotting cascade • Small vessel occlusion • Organ necrosis • Depletion of clotting factors • Activation of fibrinolysis • Ultimately severe systematic hemorrhage

  21. Container • Vasculature is continuous, closed and pressurized system • Microcirculation responds to local tissue needs • Blood flow dependent on PVR

  22. Fick Principle • Effective movement and utilization of O2 dependent on: • Adequate fio2 • Appropriate O2 diffusion into bloodstream • Adequate number of RBCs • Proper tissue perfusion • Efficient hemoglobin ‘loading’

  23. Fick Principle • Perfusion = Arterial O2 Content - Venous O2 Content • Affected by: • Hemoglobin levels • circulation of RBCs • distance between alveoli and capillaries • pH and temperature

  24. Causes of Inadequate Perfusion • Inadequate pump • Inadequate preload • Poor contractility • Excessive afterload • Inadequate heart rate • Inadequate fluid volume • Hypovolemia • Inadequate container • Excessive dilation • Inadequate systematic vascular resistance

  25. Responses to Shock • Normal compensation includes: • Progressive vasoconstriction • Increased blood flow to major organs • Increased cardiac output • Increased respiratory rate and volume • Decreased urine output

  26. O2 use Impaired cellular metabolism Anaerobic metabolism Stimulation of clotting cascade & inflammatory response Impaired glucose usage • ATP synthesis  Intracellular Na+ & water • Cellular edema  Vascular volume • Na+ Pump Function Cellular Response to Shock • Tissue perfusion

  27. Stages of Shock • Compensated • Uncompensated • Irreversible

  28. Compensated Shock • Defense mechanisms are successful in maintaining perfusion • Presentation • Tachycardia • Decreased skin perfusion • Altered mental status

  29. Uncompenstated Shock • Defense mechanisms begin to fail • Presentation • Hypotension • Prolonged Cap refill • Marked increase in heart rate • Rapid, thready pulse • Agitation, restlessness, confusion

  30. Irreversible Shock • Complete failure of compensatory mechanisms • Death even in presence of resuscitation

  31. Types of Shock • Hypovolemic • Cardiogenic • Neurogenic • Anaphylactic • Septic

  32. Hypovolemic Shock • “Fluid failure” • Decreased intravascular volume • Causes? • “Third spacing”

  33. Anaphylactic Shock • “Container failure” • Massive & systemic allergic reaction • Large release of histamine • Increases membrane permeability & vasodilation

  34. Septic Shock • “Container failure” • Systemic infection

  35. Multiple Organ Dysfunction System • Progressive dysfunction of two or more organ systems • Caused by uncontrolled inflammatory response to injury or illness • Typically sepsis

  36. References • New York Presbyterian hospital hypertension center: • Http://pc101186.Med.Cornell.edu/htchome/htbk/Htbkindex.htm • Biographics Gallery: http://www.accessexcellence.com/AB/GG/#Anchor-Building-11481 • RAS (Renin-Angiotensin-Aldosterone System): • http://www.science.mcmaster.ca/Biology/4S03/RAS.HTM • A graduate student’s hypertension page: • http://www.teaching-biomed.man.ac.uk/student_projects/2000/mnpm6ven/default.htm

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