Exsanguinating hemorrhage is a major cause of death from trauma. Rapid fluid resuscitation accompanied by aggressive efforts at hemostasis is required to save lives. Many questions regarding fluid resuscitation remain. These include the choice of fluid, indications for blood products, and the goals for fluid resuscitation before and after hemostasis is achieved.
Modern fluid resuscitation in trauma began in the early 1960s with the work of Shires and colleagues. During hemorrhage, fluid shifts from the interstitial space to the intravascular space because of changes in compartment pressures. Likewise, fluid initially shifts from cells into the interstitial space. As cells become ischemic during severe hemorrhagic shock (HS), however, failure of membrane ion pumps leads to a shift of fluids back into cells with resultant cellular swelling. Consequently, the interstitial space further loses fluid. Shires postulated that resuscitation with crystalloids, which fill the vascular and interstitial spaces, would be beneficial. His animal studies demonstrated that survival improved with the addition of crystalloid (lactated Ringer’s [LR] solution) to re-infusion of shed blood. Crystalloid resuscitation was quickly adopted in the military for resuscitation of trauma victims during the Vietnam conflict. Although this approach decreased the renal failure that had been seen in previous conflicts, it may have contributed to a new finding, “Da Nang lung” or “shock lung,” which may have been acute respiratory distress syndrome (ARDS) or simply hydrostatic pulmonary edema from volume overload. Administration of LR solution quickly became a standard of the Advanced Trauma Life Support (ATLS) course and of care in prehospital and emergency department (ED) resuscitation of civilian trauma victims. Recent studies suggesting possible immunologic effects of LR solution have led to questions of this practice and a great interest in finding better alternatives as plasma substitutes.
Administration of blood to replace lost red blood cells has been another mainstay of resuscitation from HS. Although whole blood was initially used, blood banks have found that dividing the blood into packed red blood cells (PRBCs), fresh frozen plasma (FFP), and platelets is more efficient and economical. Recent studies have suggested that more rapid resuscitation with blood components that essentially reconstitute whole blood may be beneficial. Blood transfusions, however, have many potentially deleterious effects. Greater recognition of these effects has led to reconsideration of aggressive transfusion protocols once hemostasis has been achieved.
Endpoints for fluid resuscitation, similar to the fluids themselves, have undergone reconsideration in recent years. Although the trauma victim has ongoing hemorrhage (uncontrolled HS), normalization of blood pressure may increase bleeding and worsen outcome. Limited, or hypotensive, fluid resuscitation may be appropriate. Once hemostasis has been achieved, determining adequacy of resuscitation is critical. Standard parameters such as blood pressure, heart rate, and urine output are insufficient because many patients remain under-resuscitated, with “compensated hemorrhagic shock.” Adjuvant tests are necessary to recognize this condition and ensure restoration of homeostasis.
Pathophysiology of Hemorrhagic Shock
HS is characterized by acute blood loss leading to decreased oxygen delivery to tissues. Although blood pressure and pulse are typically the clinical parameters used to determine the severity of shock, they lack sensitivity. In general, patients need to lose at least 30% to 40% of their blood volume to be hypotensive. An individual’s response to hemorrhage may be affected by age, comorbid conditions, medications, and ingestion of drugs and alcohol. One of the most common mistakes of the novice clinician is to assume that the patient with a normal blood pressure is not in shock. Recognition and reversal of “compensated shock” is critical to achieve optimal outcomes.
Approximately 6% to 9% of trauma patients are in shock on admission. Of these, one third have exsanguinating hemorrhage, as evidenced by a lack of response to fluid resuscitation. These patients invariably require operative intervention and aggressive fluid resuscitation including blood products or they will die within minutes to hours. Another third of patients are classified as transient responders. They are initially hypotensive and improve with fluid resuscitation only to deteriorate again. They have less active bleeding than the first group, but their transient response can lull clinicians into a sense of complacency. Without ongoing resuscitation, operative intervention if necessary, and vigilance, they also have a high risk of dying or developing multiple organ dysfunction. The final third of these patients respond appropriately to fluid resuscitation and spontaneously achieve hemostasis. These patients are still at risk of hypoperfusion and organ dysfunction. In all trauma patients, early recognition of hypoperfusion, rapid restoration of homeostasis, and continued resuscitation to appropriate endpoints can reduce the risk of early cardiovascular collapse, development of organ system dysfunction, and death.
The inflammatory response to trauma may increase the risk of organ dysfunction and late death from trauma. Although laboratory studies have suggested therapies that could mitigate these deleterious cascades, none of these agents have made it to clinical use. Despite this, recent studies suggest that late deaths from multiple organ dysfunction and sepsis are actually rare.
Presentation of Available Data Based on Systematic Review
Choice of Fluid. Although the use of crystalloids for resuscitation from traumatic HS has become standard, it seems that these solutions are not as innocuous as originally believed. Laboratory studies have demonstrated that crystalloids may exacerbate cellular injury. LR solution can cause an increase in oxidative burst and expression of adhesion molecules on neutrophils in human blood and during HS in pigs. No clinical studies have yet compared different crystalloids.
Modifications of LR solution (e.g., substituting the l -isomer of lactate or substitution of pyruvate or ketone bodies [β-hydroxybutyrate] for racemic lactate) can decrease the neutrophil activation and apoptosis. In contrast, hypertonic saline (HTS) and fresh whole blood do not cause neutrophil activation. HTS can attenuate immune-mediated cellular injury after trauma.
Several small clinical trials have suggested a benefit of hypertonic solutions for resuscitation of trauma patients ( Table 77-1 ). These studies explored the use of HTS alone or with a colloid added (e.g., hypertonic saline-dextan [HSD]) to prolong the intravascular volume expansion. Multiple studies demonstrated that HTS or HSD increased blood pressure and volume expansion better than crystalloids but could not document improved survival. Mattox et al. and Wade et al. found that HSD improved survival in the subset of trauma patients who required operation, presumably more severely injured patients. Likewise, Bulger et al. found that HSD, compared with LR solution, improved ARDS-free survival only in patients who required more than 10 units of PRBCs.
| Study, Year | Number of Subjects (Intervention/No Intervention) | Study Design | Intervention | Control | Outcomes |
|---|---|---|---|---|---|
| Hypertonic Saline for Hemorrhagic Shock | |||||
| 2011 | 376 NS | DB | HTS/HSD | NS | No difference in 28-day survival. |
| 256 HTS | |||||
| 220 HSD | |||||
| 2007 | 36/26 | DB | HSD | LR | Inhibit CD11b. |
| Trend increase IL-1β, IL-10. | |||||
| 2007 | 110/99 | DB | HSD | LR | No difference ARDS-free survival. Improved ARDS-free survival if >10 U blood. |
| 2006 | 13/14 | DB | HSD | NS | Promotes a more balanced inflammatory response. |
| 2003 | 120/110 | DB | HSD | NS | Survival 83% vs. 76% overall (NS), 85% vs. 67% for patients requiring surgery ( P = .01). |
| 1993 | 85 HTS | DB | HS or HSD | LR | HS improved survival compared with TRISS. |
| 89 HS | |||||
| 84 NS | |||||
| 1992 | 35/35/35 | DB | HS or HSD | NS | No difference in survival. Better BP and volume expansion. Less fluid needed. |
| 1991 | 83/83 | DB | HSD | LR | Improved BP. No change in survival. |
| 1991 | 211/211 | DB | HSD | Crystalloid | No difference in survival, except patient who required operation. Improved BP, fewer complications. |
| 1990 | 32 HTS | DB | HSD | LR | No safety issues except mild hyperchloremic acidosis. |
| 23 HSD | HS | ||||
| 51 LR | |||||
| 1989 | 48 | HSD | PlasmaLyte A | Feasibility study. | |
| 1989 | 32 | DB | HSD | Crystalloid | No difference in survival. |
| Transfusion | |||||
| 2007 | 240/439 | Retrospective | Leukocyte-depleted PRBCs | Standard PRBCs | No difference in LOS or mortality. |
| 2006 | 286 | Randomized | Leukocyte-depleted PRBCs | Standard PRBCs | No difference in infections, organ failures, mortality. |
| 2006 | 93/117 | Prospective Operation Iraqi Freedom | Transfused | Not transfused | Higher ISS, HR, lower Hct, increased infection rate, ICU, and LOS. |
| 2005 | 102 | Prospective, observational | The amount of transfused blood is independently associated with both the development of ARDS and hospital mortality. | ||
| 2004 | 954/8585 | Prospective | Transfused | Not transfused | Older, higher ISS, lower GCS, more SIRS, higher mortality. |
| 2004 | 100/103 trauma patients | Prospective | Hb 7-9 g/dL | Hb 10-12 g/dL | No differences. |
| 2003 | 15,534 | Prospective | Transfusion | Not transfused | Increase mortality (OR, 2.8), ICU, and LOS. |
| 2002 | 61 | Prospective | Transfused | Older blood increased risk of infections. | |
| Clotting Factor Replacement | |||||
| 2011 | DCR | Prospective and retrospective | Permissive hypotension, less crystalloid | Standard care, historical controls | DCR resulted in less crystalloid, more FFP, improved survival (OR, 0.4; CI, 0.18-0.9). |
| 2011 | 108/82 | Prospective and retrospective | Permissive hypotension, less crystalloid | Standard care, historical controls | DCR was associated with increased survival (OR, 2.5; CI, 1.1-5.6). |
| 2010 | 214 patients receiving massive transfusion | Prospective and retrospective | Massive transfusion protocol | Standard care, historical controls | Factors that influenced survival were FFP/PRBC, platelets/PRBC, ISS, age, and total PRBCs. |
| 2009 | 442 patients receiving massive transfusion | Prospective and retrospective | Preemptive FFP and platelets | Standard care, historic controls | Mortality decreased from 31% to 20% long term. Thromboelastography was used to titrate. |
| 2009 | 37/40 | Prospective and retrospective | 1:1.5 FFP/PRBC, more rapid product availability | Standard care, historical controls | No difference in ratios, but more rapid administration was associated with improved mortality. |
| Limited Fluid Resuscitation for Uncontrolled Hemorrhage | |||||
| 2011 | 44/46 | Prospective, randomized, intraoperative | MAP >50 mm Hg | MAP >65 mm Hg | Lower MAP group required fewer blood products, had less coagulopathy, and decreased early death. |
| 2002 | 55/55 | Randomized | SBP >70 mm Hg | SBP >100 mm Hg | Survival 93% with no difference between groups. |
| 1996 | 527 | Retrospective | Rapid infusion system used | Historical controls | Increased risk of dying 4.8×. |
| 1994 | 309/289 | Randomized day of month | Delayed resuscitation | Immediate resuscitation | Improved survival: 70% vs. 62%. Decreased LOS. |
| 1990 | 6855 | Retrospective | Prehospital fluid | No prehospital fluid | No difference in mortality. |
| Endpoints of Resuscitation from Trauma | |||||
| 2002 | 18/18 | Prospective, nonrandomized | DO 2 500 | DO 2 600 | Less fluid and blood needed; similar outcome. |
| 2000 | 40/35 | Prospective, randomized | Supranormal DO 2 | Normal DO 2 | Patients who achieve supranormal values increased survival, but no difference between groups in mortality, organ failure, or LOS. |
| 1995 | 50/75 | Randomized | Supranormal DO 2 | Normal DO 2 | Improved survival (18% vs. 37%) and organ system failures. |
| 1992 | 33/34 | Randomized | Supranormal DO 2 | Normal DO 2 | Decreased mortality, organ failure, LOS, ventilator days. |
| 2006 | 5995 | Retrospective | Lactate did not correlate with mortality. | ||
| 2003 | 98 | Prospective | Standard care | Admission lactate level correlates with ISS and 12-h lactate with survival. | |
| 1998 | 100 | Prospective | High BD | Low BD | Increase MOF and mortality, low oxygen use. |
| 1998 | 674 | Observational | BD worse in nonsurvivors. No difference in pH. | ||
| 1992 | 3791 | Retrospective | BD, age, injury mechanism, and head injury were associated with mortality using logistic regression. | ||
| 1988 | 209 | Observational | Higher BD associated with lower BP and greater fluid resuscitation. | ||
Related posts:
What Lessons Have Intensivists Learned During the Evidence-Based Medicine Era?
What Is the Role of Invasive Hemodynamic Monitoring in Critical Care?
Should Fever Be Treated?
Are Computerized Algorithms Useful in Managing the Critically Ill Patient?
Inhaled Vasodilators in ARDS: Do They Make a Difference?
How Can We Monitor the Microcirculation in Sepsis? Does It Improve Outcome?
Stay updated, free articles. Join our Telegram channel
Full access? Get Clinical Tree
