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Transfusion Practices with Combat Wounded. Francis (Frank) M. Chiricosta, LTC, MC Transfusion Medicine Consultant, US Army. Overview. Massive Transfusion / Coagulopathy Resuscitation change in practices Traditional Guidelines / Practices Use of plasma Use of Fresh Whole Blood Factor VIIa
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Transfusion Practices with Combat Wounded Francis (Frank) M. Chiricosta, LTC, MC Transfusion Medicine Consultant, US Army www.milblood.mil
Overview • Massive Transfusion / Coagulopathy • Resuscitation change in practices • Traditional Guidelines / Practices • Use of plasma • Use of Fresh Whole Blood • Factor VIIa • Age of blood www.milblood.mil
Hemorrhagic Mortality • While bleeding is the #2 cause of mortality, hemorrhage is the #1 reversible cause for mortality • Bleeding to death is an acute problem • Almost all mortality from hemorrhage occurs within 1st 24 hours • Early control of hemorrhage can save lives Data adapted from: Acosta, et al. J Am Coll Surg 1998 & Sauaia, et al. J Trauma 1995 www.milblood.mil Slide courtesy JG Perkins
Massive transfusion • One body volume in 24 hours • “Dilutional” coagulopathy • depleted coagulation factors • thrombocytopenia • hypoperfusion • confounding conditions: DIC, sepsis www.milblood.mil
N=450 combat casualties in the Vietnam War on Admission Hematocrit % 20 40 Heart Rate (BPM) 70 90 110 130 150 Lactate mg/100 mL 20 40 60 80 100 Base Deficit mEq/L 0 2 4 6 8 10 Pathophysiology of Trauma • With decreased blood pressure • Base deficit increased • Lactate Increased • Hematocrit Modestly Decreased • Heart Rate Increased Adapted from: Collins JA, Simmons RL, James PM, Bredenberg CE, Anderson RW, Heisterkamp CA 3rd.The acid-base status of seriously wounded combat casualties. I. Before treatment. Ann Surg. 1970 Apr;171(4):595-608. Slide courtesy JG Perkins
Pathophysiology of Trauma Acidosis Coagulopathy Hypothermia
Traditional resucitation • Replace lost volume first with crystalloid • May be able to restore normal BP • Blood transfusion comes later • Potential complications of aggressive fluid resuscitation • “Pop the clot” • Hemodilution • Coagulopathy • Hypothermia • Acidosis www.milblood.mil
Damage Control Resucitation • Do not replace volume quickly • Hypovolemia / hypotension is tolerated • Stop bleeding • Correct abnormal physiology later • “... inaccessible or uncontrolled sources of blood loss should not be treated with intravenous fluids until the time of surgical control.” --Cannon WB, FaserJ, CollewEM: The preventive treatment of wound shock. JAMA, 47:618, 1918 1918! Not a totally new idea www.milblood.mil
Coagulopathy of Trauma • Hemodilution due to resucitation… and • Coagulopathy that is due to the trauma itself • Evidence that coagulopathy starts before fluid resuscitation; not a dilutional coagulopathy • Molecular mechanism: thrombomodulin, protein C (Brohi, K) www.milblood.mil
Massive Transfusion,Transfusion considerations • assessment: clinical and lab together • microvascular bleeding • PT/PTT > 1.5 nl, plt < 50 – 100 • Warm patient • one 6-pk platelets roughly same coag. factors as U FFP • Plt, CRYO, FFP short/difficult supply • Fresh whole blood www.milblood.mil
Massive Transfusion,Problematic transfusion management • Transfused plasma is foreign to recipient; has anti-A, -B; A substance, B substance • ABO incompatible plasma (e.g. type O rbc/WB/Plt to type A patient) may be associated with adverse outcome (Blumberg, N) www.milblood.mil
Massive Transfusion,complications • Citrate toxicity • Hypocalcemia, prolonged QT • With normal liver, not generally a problem • Rapid infusion centrally can be a problem • Alkalosis with metabolism • Hyperkalemia? • Usually the opposite: with metabolic derangement, K+ goes low • Theoretic problem in renal failure www.milblood.mil
Massive Transfusion,complications • Hypothermia (use of blood warmer) • PT/PTT elevation • Platelet dysfunction • Dilutional coagulopathy • Old blood is bad blood? • Transfusion reactions • More error prone • Less likely to recognize www.milblood.mil
Packed Red Blood Cellspurpose of the transfusion • To increase oxygen carrying capacity in an anemic patient when it is needed • Need is based on clinical assessment of risk of complications of low oxygen delivery (e.g.. when cardiac oxygen demand increases to increase cardiac output) www.milblood.mil
Traditional Guidelines www.milblood.mil
Existing Guidelines • Red cell transfusion • Purpose: oxygen carrying • loss of 30%+ of blood volume • normovolemic, P>100, SBP<100, ssx • Diluent: normal saline only • Assessment: clinical; H/H may not be valid • Golden Hour www.milblood.mil
Red Cell Indicationsclinical studies • Hébert, et al. 1999 • randomized, controlled clinical trial, 838 critically ill patients • liberal group: Hb tx. trigger 10g/dl • restrictive group: trigger 7 g/dl • findings: • overall 30-day mortality similar (p=0.11) • lower rates for restrictive group for less acutely ill and age<55 (p=0.02, 0.03) • in-hospital mortality rate lower in restrictive group (p=0.05) www.milblood.mil
Red Cell Indicationsclinical studies • Hébert, et al. 1999 • findings: • liberal group had significantly higher rates for: • MI (p=0.02) • pulmonary edema (p<0.01) • no significant difference in other complications • trend toward lower 30-day mortality in restrictive group • decreased blood exposure in restrictive group www.milblood.mil
Red Cell Indicationsclinical studies • Carson, 1998 • almost 9000 patients 60 years and older getting hip fracture repair • at pre-transfusion Hb (“trigger”) of 8 to 10 g/dl, no difference in 30- and 90-day mortality between transfused and not transfused • Weiskopf, 1998 • experiment in isovolemic hemodilution in 23 healthy adults • Hb as low as 5g/dl tolerated at rest www.milblood.mil
Treating Bleeding Related to Coagulation AbnormalitiesPlatelets, FFP, and CRYO • General rule: If bleeding greater than expected and is of a microvascular nature and lab values meet threshold (or not available in time or dysfunction of hemostasis is known or suspected) www.milblood.mil
Microvascular Bleeding • surgical: wetness/oozing from all or most exposed tissue, no visible vessel to mechanically stop • non-surgical: • ecchymosis at sites other than surgical wound • oozing around catheters; from mucosal surfaces www.milblood.mil
PlateletsIndications, Guidelines and Practice Parameters • American Society of Anesthesiology • Prophylactic transfusion is rarely indicated if thrombocytopenia is due to increased destruction • With surgery, • usually not indicated >100,000 • usually indicated <50,000 • between 50 and 100,000: base on risk of bleeding • With microvascular bleeding, • same guidelines as for surgery • known platelet dysfunction • Procedures associated with insignificant blood loss may be done <50,000 www.milblood.mil
Fresh Frozen PlasmaIndications, Guidelines and Practice Parameters • American Society of Anesthesiology, 1996 • urgent reversal of warfarin effect • correction of known factor deficiency • for correction of microvascular bleeding in the presence of elevated (>1.5 x nl.) PT or PTT • for correction of microvascular bleeding in a patient who has received >1 blood volume www.milblood.mil
Fresh Frozen PlasmaIndications, Guidelines and Practice Parameters • College of American Pathologists, 1994 • with active bleeding or procedure and • PT* 1.5 x midpoint of normal (18s) or • PTT* 1.5 x top of normal (51s) • in massive transfusion with microvascular bleeding and coagulation abnormality *fibrinogen must be normal, >100mg/dl; patient not on heparin www.milblood.mil
Fresh Frozen PlasmaInappropriate Use • Volume expander, Source of albumin, When heparin is cause of lab abnormality, When a specific therapy is available (VIII, IX, ATIII, Vitamin K, DDAVP) • On a routine schedule with red cell transfusion (prophylactically in massive transfusion) British JH 2004 www.milblood.mil
Evidence against Routine Schedule of Plamsa in Massive Transfusion Mannucci et al. Vox Sang 42(3):113-23 (1982) “Standard schemas involving the administration of platelet concentrates and/or fresh-frozen plasma without evaluation of hemostasis … failed to decrease the requirements for … packed red cells. Therefore, indiscriminate administration in the massively transfused postoperative patient of blood components based on preestablished schemes appears to be unjustified.” www.milblood.mil
Current Practice with Plasma • More aggressive? earlier • Agrees with traditional guidelines: • Apply aggressive strategy for patients that present with coagulopathy • Is treating bleeding assoc with abnl lab • Apparent conflict with guidelines (ratio, routine schedule), but not if there is evidence of coagulopathy www.milblood.mil
Evidence Supporting use of1:1 Ratio RBC:plasma • Borgman, MA. J Trauma 2007 • Retrospective study • Stratified patients by ratio of plasma:rbc • Improved outcome with higher plasma proportion www.milblood.mil
Mortality % RBC:FFP ratio Recent Evidence, Plasma (Borgman, MA. J Trauma 2007) www.milblood.mil Slide courtesy JG Perkins
Evidence Supporting use of Apheresis Platelets • Retrospective study pts at Ibn Sina • Received 10 or more rbcs/FWB • Compare groups: • Did not get platelets or FWB • Received platelets and not FWB • Received FWB • Findings: www.milblood.mil
Study Profile - Retrospective 8,618 Trauma Patients Arrived at CSH 2,024 (23%) Received Blood Transfusions 708 (8.2%) Received ≥ 10 u Blood (RBC + FWB) in 24 hours 12 MT occurred during hospital course, not on admission 89 treated at forward surgical teams/hospitals prior to transfer to CSH 434 charts reviewed for analysis 285 Platelets – either as FWB or aPLT 149 No FWB or aPLT 23 Both FWB and aPLT 78 FWB 184 aPLT Time Period: January 2004 – December 2006 CSH = Combat Support Hospital, RBC = red blood cell, FWB = fresh whole blood, aPLT = apheresis platelets, MT = massive transfusion
P<0.001 p=0.04 Log Rank p=0.003 48 Hour and 30 Day Survival by Platelet versus No Platelet Groups www.milblood.mil
p=0.72 p=0.87 Log Rank p=0.96 48 Hour and 30 Day Survival by Fresh Whole Blood versus Apheresis Platelet Subgroups www.milblood.mil
Factor VII Use • rFVIIa (NovoSeven) • Hemophiliac with anti-VIII (approved for) • Coumadin reversal • Stroke • Massive transfusion www.milblood.mil
Factor VII Use and Outcome in OIF1 of 2 • Jan04 – Oct05, records for 61 of 117 patients who rec’d FVIIa • Groups: • Early (FVIIa before 8 units blood) • Late (after 8 units) • Groups similar for severity of injuries - Perkins, JG. J Trauma, 2007 May;62(5):1095-9 www.milblood.mil
Factor VII Use and Outcome in OIF 2 of 2 • Early group rec’d fewer units of blood (20.6 vs. 25.7, p=0.048) and pRBC (16.7 vs. 21.7, p=0.049) • Similar outcomes • Mortality (33.3% vs. 34.2%, p=NS) • ARDS (5.9 vs. 6.8%, p=NS) • Infection (5.9% vs. 9.1%, p=NS) • Thrombotic events (0% vs. 2.3%, p=NS) www.milblood.mil
Conclusions Regarding Blood Therapy in Massive Transfusion For select patients with coagulopathy (7-8%) • Use of either FWB or aPLT is associated with improved survival at 48 hrs and 30 days • FWB and aPLT appear equivalent with regards to survival • FFP:RBC ratios 1:2 to 1:1 are associated with improved survival at 48 hours, though this survival benefit is not apparent at 30 days. • FVIIa use might reduce red cell with no appreciable excess adverse outcome www.milblood.mil
Is Old Blood Bad Blood? • “Age:” duration of storage • Storage lesion • Decreased pH • Increased K+ • Decreased 2,3-DPG • Decreased deformability • Clinical outcomes worse? (or not) www.milblood.mil
Age of Blood: the Evidence • Retrospective • Inconsistent definition of age • Different preservatives, modifications • Inconsistent findings • Uniform or near uniform findings/conclusions: • Number of units is associated with worse outcome • Findings are insufficient to recommend routine use of “young” units www.milblood.mil
Age of Blood: the Evidence Basran Anesth Analg 2006;103:15–20 • Retrospective, 321 re-do CABG pts • Measures of age: mean; oldest unit • Findings: correlates with longer LOS, mortality • Conclusions: should be studied with RCT before informing practice www.milblood.mil
Age of Blood: the Evidence Vamvakas Transfusion 1999;39:701-710 • Retrospective, 269 cardiac surgery pts • Measures of age: mean; • Findings: age correlates with pneumonia, not with wound infection • Conclusions: should be studied with RCT before guiding transfusion policy www.milblood.mil
Age of Blood: the Evidence Vamvakas Transfusion 2000;40:101-109 • Retrospective, 268 cardiac surgery pts • Measures of age: mean; oldest; 2 oldest • Findings: age does not correlate with LOS, time on ventilator • Conclusions: future studies of transfusion should consider age www.milblood.mil
Age of Blood: the Evidence Keller J Trauma 2002;53:1023–1025 • Retrospective registry 18 hospitals, 86 trauma pts who rec’d 1-4 units • Measures of age: mean; oldest; 2 oldest; number >7d; >14d; >21d; >28d • Findings: only number of units >14d correlated with total LOS, not with ICU stay or vent • Conclusions: further study needed www.milblood.mil
Age of Blood: the Evidence Leal-Noval Anesthesiology 2003;98:815-22 • Prospective cohort, 585 cardiac surgery pts • Measures of age: mean; oldest; youngest • Findings: • age does not correlate with LOS, time on ventilator, MI • Oldest unit and youngest unit correlates with pneumonia • Conclusions: age does not increase morbity except maybe pneumonia (number of units) www.milblood.mil
Age of Blood: the Evidence Van de Watering Transfusion2006;46:1712-1718 • Retrospective, 2732 cardiac surgery pts • Measures of age: mean; oldest; youngest; comparisons for patients with all units < 18d vs all units > 18d • Findings: age correlates with number; no correlation with outcome • Conclusions: there is no justification for limitation of storage time www.milblood.mil
Age of Blood: the Evidence Walsh Crit Care Med 2004; 32(2):364 –371 • Randomized ControlledTrial, 22 critical pts • Comparison: ≤5d vs ≥20d • Findings: age has no adverse effect on gastric function or measures of global oxygenation • Conclusions: no support for the use of fresh red cells in critically ill patients www.milblood.mil
Summary • Current resucitation emphasizes early control of bleeding, later correction of injury • Aggressive plasma transfusion is probably best practice for coagulopathic bleeding patient • Component therapy better than FWB • FWB as good when component therapy not available • rFVII may be helpful in reducing red cell use • We will do our patients more good (or at least less harm) by reducing number of units compared with reducing age of units www.milblood.mil