Transcript Massive Blood Transfusion
M. Saleh Massoud, MD.
Lecturer of Anesthesiology & Intensive Care Ain-Shams University
Case Scenario
A 27-year-old male was involved in a high speed RTA. Ambulance services brought him to our ER.
Primary survey revealed : • A: Clear airway, central trachea • B: Respiratory rate 20, Pulse oximetry reading 95% on high flow oxygen • • C: Heart rate 125, Arterial blood pressure 90 ⁄ 60 mmHg D: Glasgow Coma Scale (GCS) 10 ⁄ 15 (E4, V2, M4), Symmetrical reactive pupils.
• E: Exposure showed ........
20 min after arrival: • The patient became hemodynamically unstable with marked hypotension (BP 60 ⁄ 30) , tachycardia (HR 167) • Fall in hemoglobin (Hb) level from 11 g.dl
-1 to 5 g.dl
-1 .
Causes of death following multiple trauma Etiology of trauma deaths
CNS Hemorrhage MOF 10% 50% 40% Current Orthopaedics (2004) 18, 304–310
Hemorrhagic shock
• Due to inadequate blood flow for tissue oxygenation.
• Caused by: • External blood loss • • • Occult blood loss Inadequate resuscitation Aortic or great vessel injury • Diagnosed by: • Tachycardia • • • • Hypotension Cool clammy skin Decreased loc Low urine output
Classification of Hemorrhage
American College of Surgeons Committee on Trauma Advanced Trauma Life Support Program
Blood loss (ml)
CLASS I Up to 750 CLASS II 750-1,500 CLASS III
1,500-2,000
CLASS IV
2,000
40% Blood loss (% blood volume) Pulse rate
Up to 15% 15%-30%
30%-40%
<100 >100
>120
140 Blood pressure Pulse pressure (mmHg) Capillary refill test
Normal Normal or increased Normal
Respiratory rate
14-20
Urine output (ml/hr)
30
CNS — mental status
Slightly anxious Normal Decreased Positive 20-30 20-30 Mildly anxious
Decreased
Decreased Positive 30-40 5-15 Anxious, confused
Decreased
Decreased Positive >35 Negligible Confused, lethargic
Traditional Trauma Resuscitation
Aggressive fluid resuscitation [2 L Crystalloid] • Transient response • No response • Active bleeding Packed RBCs After 6-10 u PRBC FFP & Cryoprecipitate
The bloody vicious circle
The Lethal Triad in Trauma
Mechanism of Coagulopathy in trauma The old theory
Hypothermia Acidemia Shock Inflammation Tissue trauma Coagulopathy Hemodilution
Mechanism of Coagulopathy in trauma The new theory
Systemic anticoagulation Endothelium express thrombomodulin Hyperfibrinolysis Endothelium releases tPA TM complex es with Thrombin Activation of protein C pathway coagulopathy Hyper fibrinolysis Extrinsic Pathway is inhibited Systemic anticoagulation Fibrinogen depletion
Hypothermia
A temperature < 35°C is associated with an increase in mortality.
Trauma patients that are hypothermic are not perfusing their tissue The coagulation cascade is an enzymatic pathway that degrades with temperature and ceases at 33.3C
• Reduces activity of clotting factors by 50% at 34 C • Platelet activation almost eliminated at 30 C
Acidosis
Base deficit (BD) ≥ 6 identifies patients that • require early transfusion, • • increased ICU days and risk for ARDS and MOF BD of ≥ 6 is strongly associated with the need for MT and mortality. Patients have an elevated BD before their blood pressure drops to classic “hypotension” levels.
Acidosis contributes more to coagulopathy more than hypothermia (not reversible)
The best Policy of Management: Damage Control Resuscitation
Definition
‘systematic approach to major trauma combining the catastrophic bleeding, airway, breathing and circulation (
(Hodgetts et al., 2007).
Inclusion criteria for DCR
Rapid pattern recognition • Severe Traumatic Injury • • Abnormal mental status Weak or absent radial pulse Acidosis- Base Deficit > - 6 Coagulopathy – INR > 1.5
Hypotension – Systolic B/P < 90 Hemoglobin - < 11 Temperature - < 35 ° C
Armamentarium of Damage control resuscitation
Permissive hypotension Hemostatic Resuscitation
Armamentarium of Damage control resuscitation
Permissive hypotension Hemostatic Resuscitation
Permissive hypotension
Permissive hypotension
The concept behind permissive hypotension involves keeping the blood pressure low enough to avoid exsanguination while maintaining perfusion of end organs.
However, the concept of permissive hypotension represents a double-edged sword, since a prolonged duration of shock may further aggravate the extent of post-injury coagulopathy.
Armamentarium of Damage control resuscitation
Permissive hypotension Hemostatic Resuscitation
Hemostatic Resuscitation
Haemostatic resuscitation aims to restore tissue perfusion and arrest coagulopathy using a combination of blood products and adjuncts early in the resuscitation process (Hodgetts et al., 2007).
Aspects of hemostatic resuscitation
Minimizing use of crystalloids Early transfusion of RBC (fresh): plasma: PLTs in an optimum ratio Use of thawed plasma and Fresh Whole Blood (when available) Early prevention of hypothermia, acidosis Appropriate use of rFVIIa and fibrinogen containing products such as cryoprecipitate Use POC coagulation assays such as rapid thromboelastography (rTEG) to guide administration of blood products and hemostatic adjuncts Rapid definitive control of bleeding
Thawed Plasma
Thawed plasma should be used as a primary resuscitative fluid. This product should be present upon arrival of the casualty in the ED This approach not only addresses the metabolic abnormality of shock, but initiates reversal of the coagulopathy present.
What is the optimal ratio of blood products ?
Figure 1. Plasma:RBC product transfusion ratios effect on patient survival. (A) Survival versus ratio. () 24-hour survival; () 30-day survival. (B) Patient characteristics in each ratio group. (C) Patient outcome and characteristics in high (one or more plasma per two RBC products) versus low (less than one plasma per two RBC products) transfusion group. Ave = average.
Figure 2. PLT-to-RBC product transfusion ratios effects on patient survival. (A) Survival versus ratio. () 24-hour survival; () 30-day survival. (B) Patient characteristics in each ratio group. (C) Patient outcome and characteristics in high (one or more apheresis PLTs per 20 RBC products) versus low (less than one apheresis PLTs per 20 RBC products) transfusion group. Ave = average.
Figure 3. Cryoprecipitate-to-RBC product transfusion ratios effects on patient survival. (A) Survival versus ratio. () 24-hour survival; () 30-day survival. (B) Patient characteristics in each ratio group. (C) Patient outcome and characteristics in high (one or more unit of cryoprecipitate per two RBC products) versus low (less than 1 unit of cryoprecipitate per two RBC products) transfusion group. Ave = average.
Figure 4. Survival curves for the eight groups: 1) high plasma, high PLT, high cryoprecipitate (n = 50); 2) high plasma, high PLT, low cryoprecipitate (n = 28); 3) high plasma, low PLT, low cryoprecipitate (n = 12); 4) high plasma, low PLT, high cryoprecipitate (n = 10); 5) low plasma, high PLT, high cryoprecipitate (n = 21); 6) low plasma, high PLT, low cryoprecipitate (n = 27); 7) low plasma, low PLT, high cryoprecipitate (n = 6); and 8) low plasma, low PLT, low cryoprecipitate(n = 60). High versus low ratio groups determined as a ratio of 0.5 or more versus less than 0.5. CR = cryoprecipitate; PL = plasma; PT = PLT.
Component Therapy Vs Fresh Whole Blood in trauma patients
Component Therapy Vs Fresh Whole Blood in trauma patients
PRBC Hct 55%
335 mL
Plt 10
Dilution is inevitable with component therapy
So Component Therapy Gives You 1U PRBC + 1U PLT + 1U FFP 660 COLD mL
•Hct 29% •Plt 87K •Coag activity 65% •750 mg fibrinogen
500 mL Warm Hct: 38-50% Plt: 150-400K Coags: 100% 1500 mg Fibrinogen
•Armand & Hess, Transfusion Med. Rev., 2003
Fresh Whole Blood
Fresh whole blood (FWB) must be called for early after ED arrival FWB is the optimal resuscitation fluid for severely injured casualties. FWB is the best fluid for hypotensive resuscitation for hemorrhagic shock.
Recombinant factor VIIa as a rescue therapy
Mechanism of action of rFVIIa
rFVIIa works locally at the site of vascular injury, where tissue factor (TF) is exposed and activated platelets are found 1 Binding of factor VIIa or rFVIIa to TF initiates the coagulation generating small amounts of thrombin 2 At pharmacological doses rFVIIa directly activates factor X on the surface of activated platelets resulting in a “thrombin burst” 3,4 The thrombin burst leads to the formation of a stable haemostatic plug which controls the bleeding 3
FIGURE 2.
Recombinant Factor VIIa as Adjunctive Therapy for Bleeding Control in Severely Injured Trauma Patients: Two Parallel Randomized, Placebo-Controlled, Double Blind Clinical Trials
Boffard, Kenneth; Riou, Bruno; Warren, Brian; Choong, Philip Iau Tsau; Rizoli, Sandro; Rossaint, Rolf; Axelsen, Mads; Kluger, Yoram Journal of Trauma-Injury Infection & Critical Care. 59(1): 8-18, July 2005 DOI: 10.1097/01.TA.0000171453.37949.B7 Fig. 4. Massive transfusion. Percentage of patients alive at 48 hours receiving more than 12 units of RBCs within 48 hours of the first dose, which equals greater than 20 units of RBCs inclusive of the 8 predose units
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© 2005 Lippincott Williams & Wilkins, Inc. Published by Lippincott Williams & Wilkins, Inc.
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FIGURE 2.
Recombinant Factor VIIa as Adjunctive Therapy for Bleeding Control in Severely Injured Trauma Patients: Two Parallel Randomized, Placebo-Controlled, Double Blind Clinical Trials
Boffard, Kenneth; Riou, Bruno; Warren, Brian; Choong, Philip Iau Tsau; Rizoli, Sandro; Rossaint, Rolf; Axelsen, Mads; Kluger, Yoram Journal of Trauma-Injury Infection & Critical Care. 59(1): 8-18, July 2005 DOI: 10.1097/01.TA.0000171453.37949.B7 Fig. 4. Survival curves for blunt and penetrating trauma populations. The difference between treatment groups was not significant (log-rank test, not significant)
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© 2005 Lippincott Williams & Wilkins, Inc. Published by Lippincott Williams & Wilkins, Inc.
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Guideline for Recombinant factor VIIa in Trauma Patients
J. Thromb Haemost 2005; 3: 640-8 Massive bleeding: • Loss of entire blood volume in 24h (10 U PRBC in 70kg) • • • Loss of 50% blood in 3h Blood loss rate 150mL/min Blood loss rate 1.5mL/kg for over 20 min Failure to arrest hemorrhage despite: • FFP: 10-15mL/kg (4-6U for 70kg) • • • • Cryo: 1-2U/10kg (10-15U for 70kg) Platelets: 1-2U/10kg (10-15U for 70kg) Correction of acidosis: pH= 7.2
Warming of hypothermic patients (recommended, not mandatory for rFVIIa)
Guideline for Recombinant factor VIIa in Trauma Patients
J. Thromb Haemost 2005; 3: 640-8 Preconditions • Fibrinogen 50 mg/dL (100 mg/dL preferred) • • Platelet 50000*10 9 /L (100000 *10 9 /L preferred) pH 7.2
Treatment • Initial 100~140 (120) ug/kg IV bolus, • • • 15 to 20 min repeat 100 ug/kg IV Total dose > 200 ug/kg, check and correct preconditions.
• If correction not feasible, • FFP 10-15mL/kg or 4-6 U/70kg • • • Cryo 1-2 U/10kg or 10-15 U/70kg Platelet 1-2 U/10kg or 10-15 U/70kg Correct pH and calcium Third dose 100 ug/kg IV
“Our own blood is still the best thing to have in our veins” – Frenzel et al., 2008