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Hemorrhagic shock
- 2. What is hemorrhagic shock? • Hemorrhagic shock is a type of hypovolemic shock in which severe blood loss leads to inadequate oxygen delivery at cellular level. • The causes of hemorrhage resulting in shock vary widely and include trauma, postpartum hemorrhage, gastrointestinal hemorrhage, rupture of an aneurysm, perioperative hemorrhage.
- 5. PATHOPHYSIOLOGY • At the site of hemorrhage, clotting cascade and platelets form a hemostatic plug whereas remote from the site fibrinolytic activity increases, presumably to prevent microvascular thrombosis. • However excess plasmin activity and autoheparinization can lead to pathologic hyperfibrinolysis and coagulopathy.
- 6. CELLULAR LEVEL • There is transition to anaerobic metabolism which generates lactic acid, inorganic phosphates and oxygen radicals. • Release of Damage Associated Molecular Patterns (DAMP) incites a systemic inflammatory response. • As ATP levels deplete, cellular homeostasis fails and cell death ensues
- 7. CATEGORIES • Compensated • (0-20% blood loss) • Feedback mechanisms to maintain blood pressure- • 1) Atrial and ventricular stretch receptors • 2) Baroreceptor reflexes from carotid sinus and aortic arch • 3) Chemoreceptor reflexes • 4) Renin Angiotensin Aldosterone Axis • 4)Release of vasopressin,epinephrine,angiotensin • Results in – Tachycardia, tachypnea, increased blood pressure, increased preload, increased stroke volume.
- 9. • The organs who win - • Brain • Heart • Kidney • Liver • The organs who lose – • Skin • GI tract • Muscles
- 10. UNCOMPENSATED • 20-30% loss of blood volume • The compensatory mechanisms can no longer maintain blood pressure • Body’s response- • → Tachycardia, decreased CO, Increased RR, decreased urine output.
- 11. LETHAL EXSANGUINATION >30% blood loss (class iii & iv) Severe hypotension, pulselessness, negligible urine output Inability to perfuse vital organs leading to cerebral anoxia & fatal arrhythmias Cold clammy extremities Death
- 12. MANAGEMENT • ABC of trauma • Secure - • Airway • Breathing • Circulation
- 13. PREHOSPITAL CARE • Stop further bleeding- Recent studies indicates that tourniquet application proximal to the site of hemorrhage in the extremities saves lives without risking amputation or extremity dysfunction, if the patient can be quickly transported to the hospital. • Studies have shown that delaying resuscitation until hemostasis has been achieved improves survival in patients with penetrating trauma because this approach averts dilutional coagulopathy.
- 14. HEMOSTASIS • Patients with purely abdominal or pelvic bleeding may benefit from endovascular occlusion of aorta as a temporizing measure to slow hemorrhage. • Resuscitative endovascular balloon occlusion of aorta (REBOA) lowers perfusion pressure to distal sites of severe hemorrhage, increases afterload and redistributes remaining blood preferentially to heart and brain.
- 15. VOLUME RESTORATION-CHOICE OF FLUID • Isotonic crystalloid resuscitation has been used for decades in early management of bleeding. However they only transiently expand the intravascular volume & have no intrinsic therapeutic benefit. • Overzealous resuscitation with crystalloid dilutes the oxygen carrying capacity and clotting factors. • Limiting crystalloid infusion to 3L in 1st 6 hours is recommended as a part of bundle of care for patients with acute bleeding & trauma.
- 16. BLOOD TRANSFUSION • Blood products transfusion provide a greater survival benefit as compared to colloids/crystalloids • TYPES- • Red blood cells • Plasma • Platelets • Cryoprecipitate • Prospective studies show that 1:1:1 ratio of plasma to platelets to RBC’s is safe • TXA can be given to patients with severe hemorrhage who present within 3 hours of the starting of event. • However all these contain citrate which can lead to hypocalcemia & progressive coagulopathy. • Thus emperical dosing of calcium & frequent measurement of electrolytes is recommended.
- 17. MASSIVE TRANSFUSION PROTOCOL • Traditionally, a massive transfusion was considered 10 units of PRBCs or more transfused over a 24-hour period, but many experts now advocate a revised definition of 10 units or more transfused over 6 hours. • Determining when to initiate an MTP has been the subject of considerable research. While a number of scores have been developed for this purpose, the Assessment of Blood Consumption (ABC) score has been validated and is easy to use. The ABC score relies on 4 parameters that can be determined upon arrival to the ED: • 1)Penetrating mechanism of injury • 2)Positive FAST (Focused Assessment with Sonography in Trauma) examination (i.e. evidence of hemorrhage) • 3)SBP of 90 mmHg or less • 4)Heart rate of 120 bpm or greater • Each positive parameter receives a score of one. A score of 2 or more predicts the need for massive transfusion with a sensitivity of 75 percent and a specificity of 86 percent.
- 18. OXYGEN CARRIER AS AS AN ALTERNATIVE TO RBC • An ideal substance for carrying (and delivering) oxygen would have the following characteristics: • Rapid availability • Effective oxygen-carrying capacity and provision of volume expansion • Free of pathogens, to the extent possible • Minimal side effects • Viability over a range of storage temperatures • Long shelf life • Universal compatibility and elimination of crossmatching • Cost effectiveness • Adequate supply • TYPES – • 1) Hemoglobin based oxygen carriers • 2)Perfluorocarbons
- 19. IDEAL RESUSCITATION FLUID • The answer remains unclear. • Large volume of normal saline infusion can cause non anion gap hyperchloremic metabolic acidosis where as large volume LR can cause metabolic alkalosis as lactate generates bicarbonate. • Based on current data, limiting fluid resuscitation to 1 L or less and moving directly to blood products appears to be the best strategy.
- 20. DELAYED FLUID RESUSCITATION • Research suggests that permissive hypotension which describes an approach that targets early fluid resuscitation only to a SBP of 70 may improve outcomes. • The rationale is that aggressive fluid administration causes dilution of clotting factors, produces hypothermia, disrupts thrombus formation and enhances bleeding. • This does not apply to blunt trauma patients with brain injury as hypotension reduces cerebral perfusion & increases risk of mortality.
- 21. DELAYED FLUID RESUSCITATION • While it is clear that resuscitation to supraphysiological values is not necessary, resuscitation allowing permissive hypotension in penetrating trauma patients cannot be recommended with confidence. • Factors that should be considered when determining whether this strategy is appropriate include the patient's mental status and likelihood of intracranial injury, likelihood of spinal cord injury (SCI), underlying illness such as chronic hypertension and proximity to a trauma center.
- 22. ENDPOINTS FOR PROLONGED RESUSCITATION • The following parameters may be used to guide prolonged resuscitation of traumatic shock - • Blood pressure: Maintain MAP above 65 mmHg for penetrating trauma, and above 85 mmHg for blunt trauma • Heart rate (HR): Maintain between 60 and 100 beats per minute. Keep in mind that a HR in this range may be abnormal for some patients, such as a healthy young adult with a resting HR of 50 who presents with a HR of 90 following trauma. • Oxygen saturation: Maintain above 94 percent. • Urine output: Maintain above 0.5 mL/kg per hour. • Lactate and base deficit: Monitor serum lactate and serum bicarbonate every four hours to ensure end-organ perfusion is adequate or improving with resuscitation. Reasonable goals of resuscitation include a serum lactate <2 mmol/L and normalization of any base deficit. • Mixed central venous oxygen saturation: Monitor every four hours to ensure end-organ perfusion is adequate or improving with resuscitation; goal is to maintain above 70 percent.