Remark
1) Why was this study conducted? |
When the patient is admitted into the ICU, the physician should identify all the physiological alterations to establish resuscitation management goals. These strategies allow an early correction of trauma-induced coagulopathy and hypoperfusion increasing the likelihood of survival. The objective of this article is to describe the physiological alterations in a severely injured trauma patient who undergo damage control surgery and to establish an adequate management approach. |
2) What were the most relevant results of the study? |
The severely injured trauma patient who undergoes damage control surgery and is admitted to the Intensive Care Unit should always have a comprehensive evaluation that allows the physician to identify all the physiological alterations and establish the resuscitation management goals. These strategies allow an early correction of trauma-induced coagulopathy and hypoperfusion increasing the likelihood of survival. |
3) What do these results contribute? |
The physician should always be aware and correct the hypothermia, acidosis, coagulopathy and hypocalcemia presented in the severely injured trauma patients. |
Introduction
Damage control surgery has transformed the management of severely injured trauma patients. It was initially described as a three-step process that included an abbreviated initial surgery for bleeding and contamination control, aggressive resuscitation in the intensive care unit (ICU) and then deferred definitive repair 1. These principles have been subsequently used in surgical approaches for vascular, orthopedic, and thoracic injuries 2-4. The objective of the damage control strategy is to rapidly control life-threatening injuries and reverse physiological alterations such as acidosis, hypothermia, and coagulopathy (the triad of death). Then a deferred definitive repair should be performed.
One of the main causes of trauma-related mortality is uncontrolled bleeding. Hemorrhagic shock leads to tissue hypoperfusion and physiological alterations that ultimately cause organ dysfunction and death. Consequently, damage control surgery must be directed to massive bleeding control 5.
When a patient is admitted into the ICU, shock and physiological alterations must be identified and corrected. The biggest challenge is to identify if the bleeding is secondary to the injury itself or to the trauma-induced coagulopathy. The early implementation of the strategies to evaluate and correct the trauma-associated disorders improves the prognosis of the severely injured patient 6. Once resuscitation has been completed, the patient should be taken back to surgery for definitive repair. The objective of this article is to describe the experience obtained by our group in the ICU management of severely injured trauma patients who undergo damage control surgery.
This article is a consensus that synthesizes the experience earned during the past 30 years in trauma critical care management of the severely injured patient from the Trauma and Emergency Surgery Group (CTE) of Cali, Colombia which is made up of experts from the University Hospital Fundación Valle del Lili, the University Hospital del Valle "Evaristo García", the Universidad del Valle and Universidad Icesi, the Asociación Colombiana de Cirugia, the Pan-American Trauma Society and the collaboration of international specialists of the United States of America, Europe, Japan, South Africa, and Latin America.
Resuscitation in ICU
Initial Evaluation
Once the patient is transferred to the ICU after damage control surgery it is of utmost importance to evaluate the severity of shock. Therefore, extensive laboratory testing and close monitoring of the hematologic, hemodynamic, and respiratory systems should be performed. We propose the following management (Table 1).
Management | Intervention |
---|---|
Assessment of Acid-Base status | Serial monitoring of blood gases |
Correction of Hypothermia | Warmed Fluids |
Active rewarming strategies | |
Reversal of Coagulopathy | Massive Transfusion Protocol |
Transfusion therapy guided by viscoelastic tests (TEG / ROTEM) | |
Correction of electrolytes disturbances | Monitoring and correction of hypocalcemia (Calcium Ion 1.1-1.3 mmol/L) |
Monitoring and correction of hypercalcemia | |
Assessment of Tissular Perfusion | Hemodynamic status |
Tissular perfusion markers (Lactate and Base Excess) | |
Vasopressor and inotropic support |
Acid-base status
Severe trauma patients are usually admitted to the ICU with severe metabolic acidosis and hypothermia. Metabolic acidosis alters platelet function, coagulation factors, and thrombin generation. These conditions increased the mortality rate with a greater need for blood products transfusion 7,8. Some studies have shown that a pH of 7.1 or less is the limit for a severe coagulation pathway compromise 9. Also, a base excess (BE) of -12.5 or less has been considered as a sensitive measure of inadequate perfusion (10). When tissue perfusion is restored, these parameters will be corrected.
Temperature
A temperature below 34ºC increases the mortality rate of severely injured trauma patients, the mortality is almost 100% when a temperature of 32º C or lower is reached. A decrease in body temperature causes alterations in platelet function, coagulation proteases, and fibrinolytic activity 11. Therefore, hypothermia induces trauma-induced coagulopathy, which is like a coagulation factor deficiency state 12. The main cause of hypothermia in severely injured trauma patients is the administration of large amounts of cold intravenous fluids. Fluid resuscitation should be limited to maintain a mean arterial pressure ≥ 65mmHg and a systolic blood pressure > 90 mmHg. Hypothermia has also been associated with some complications such as bradycardia, first-degree atrioventricular block, prolonged QT, surgical site infection, and/or pneumonia 13-15. Therefore, the physician should ensure its early identification and management.
Anemia
Platelets play an important role in coagulation reactions, which are important to the injured endothelium. Where tissue factor is exposed, the platelets adhere and aggregate themselves 16. Under normal conditions, platelets are ejected to the marginal layer closer to the blood vessel wall due to the interaction with erythrocytes in their number and size 17. Platelet activation and adhesion depend on the adenosine diphosphate (ADP) of red blood cells and are inhibit with decreased hematocrit levels 18. In severely injured trauma patients, the hemorrhage and the large volumes of fluids have a significant effect on hematocrit and hemostasis. Some studies demonstrate that the coagulation pathways are disturbed before tissue hypoxia 19. Therefore, the resuscitation with normal platelet and hematocrit levels is the initial objective to restore hemostasis 20.
Calcium
A calcium level below 0.9 mmol/L has been related to increased mortality rates (Normal Ionized calcium levels are between 1.1 to 1.3 mmol/L). Hypocalcemia causes life-threatening rhythm disorders of the heart and coagulation pathway dysfunction due to its function in clotting factors recruitment, fibrinogen to fibrin conversion, platelet and C-reactive protein activation, among others 21,22. The main causes of hypocalcemia are hemodilution and citrate-containing blood products. This condition is aggravated by shock and ischemia-reperfusion 23-25.
Hemodynamic status and tissue perfusion
The severity of shock should be determined to establish resuscitation goals in the severely injured trauma patient undergoing damage control surgery. Bleeding control is the priority, it reverses the hypoperfusion state and organic failure of the patient 26. At the same time, minimum perfusion levels and permissive hypotension should be established to avoid hemorrhage exacerbation (systolic blood pressure between 60-90 mmHg) 27. Once bleeding has been controlled, the hemodynamic status of the patient should be assessed. Blood pressure and heart rate have been traditionally used to estimate the degree of hypovolemia according to the Advanced Trauma Life Support (ATLS) classification. However, these parameters have a low sensitivity in young patients and should not be used as an isolated reference 28. Up to 85% of the severely injured trauma patients with normal hemodynamic parameters could have occult hypoperfusion with persistently increased BE or lactate levels 29-35. Therefore, the implementation of the tissue perfusion (BE and lactate levels) with the hemodynamic parameters contribute to a better physiological status assessment of the patient and adequate resuscitation guidance.
Coagulation
The causes of coagulopathy in patients with severe trauma are multifactorial. Two categories are recognized: trauma-induced coagulopathy and resuscitation-related coagulopathy 36. Around 25 to 35% of the trauma patients had acute trauma-induced coagulopathy on admission due to tissue damage and shock. This disorder is a hypercoagulable state produced by endogenous anticoagulant activity (endogenous heparinization, C-reactive protein activation, hyperfibrinolysis, and platelet dysfunction) that at the microvascular level counteracts the procoagulant condition 37,38.
The resuscitation-related coagulopathy is caused by the dilution of coagulation factors due to fluid resuscitation and/or coagulation dysfunction secondary to hypocalcemia, acidosis or hypothermia 39. A rapid and reliable diagnosis of coagulopathy is crucial. There are two types of tests, the standard coagulation tests (prothrombin time, partial thromboplastin time, International normalized ratio , fibrinogen level, and platelet count), and the viscoelastic tests (Thromboelastography, Thromboelastometry). The standard coagulation tests have limited ability to reveal the coagulation status in vivo, therefore are poor predictors and do not provide a realistic target for resuscitation 40,41. Whereas some evidence shows that viscoelastic testing is superior for coagulation disturbances detection in trauma patients 42. It is important to notice that neither of these tests reflects the effect of hypothermia on coagulation since both are performed at 37º C 9.
Resuscitation strategy
Once the physiological alterations have been identified, the resuscitation should be directed. The recommendation for the management of hypothermia is the implementation of active rewarming strategies with a surface, intravascular, air and/or fluid warming devices.
Hypocalcemia management has been recognized as a critical factor for resuscitation in the “Lethal Diamond” proposal 43. Although a defined consensus is not yet available, it is recommended an early administration of calcium to ensure levels between 1 and 1.2 mmol/L, starting with 1 gram of calcium chloride or its equivalent in calcium gluconate after the transfusion of the first 4 units of blood components. Then, the correction of the calcium level should be based on serial monitoring of the ionized calcium levels 44.
The main cause of acidosis in trauma patients is hypoperfusion. The volume should be optimized via the administration of intravenous fluids, blood components, vasopressors, and inotropic support. These are the main pillars of resuscitation management. Additionally, hemodynamic optimization is associated with the coagulopathy correction following the hemostatic resuscitation strategy. Initially, the institutional massive transfusion protocol should be activated, which is usually started with packed red blood cells and fresh frozen plasma in a 1:1 ratio and then platelets and cryoprecipitate 46.
Holcomb et al. compared transfusion ratios of 1:1:1 and 2:1:1 of packed red blood cells: fresh frozen plasma: platelets without statistical difference in the mortality rate 47. Another approach is goal-directed coagulation therapy, which proposes individualized transfusion management based on the results of viscoelastic tests 42. When the coagulopathy disorders have been controlled, some patients may remain hypovolemic requiring additional fluids administration. They may also have myocardial dysfunction requiring inotropic support or a vasodilatation state needing vasopressor support 48. The vasopressors improve the microvascular perfusion but also can compromise it if the hypovolemia persists. Therefore, the physician should always ensure blood volume 49.
Conclusion
The severely injured trauma patient who undergoes damage control surgery and is admitted to the Intensive Care Unit should always have a comprehensive evaluation that allows the physician to identify all the physiological alterations and establish the resuscitation management goals. These strategies allow an early correction of trauma-induced coagulopathy and hypoperfusion increasing the likelihood of survival.