Hyperfibrinolysis diagnosed by rotational thromboelastometry (ROTEM) is associated with higher mortality in patients with severe trauma

The effects of tranexamic acid and prothrombin complex concentrate on the coagulopathy of trauma: an in vitro analysis of the impact of severe acidosis

BACKGROUND

Bleeding is the most frequent cause of preventable death after severe injury. Our purposes were to study the efficacy of tranexamic acid (TXA) and prothrombin complex concentrate (PCC) on a traumatic coagulopathy with a severe native metabolic acidosis and compare the efficacy of PCC versus fresh frozen plasma (FFP) to reverse a dilutional coagulopathy.

METHODS

In vitro effects of TXA and PCC were assessed with standard laboratory analysis (prothrombin time [PT]/international normalized ratio [INR]) and rotational thromboelastometry in a porcine hemorrhage with ischemia-reperfusion (H/I) model. FFP was used in comparison with PCC. In vitro doses were calculated to be the equivalent of 1-g TXA, 100-mg tissue plasminogen activator, 45-IU/kg PCC, and 4-U FFP. Agents were tested at baseline and then with severe metabolic acidosis after 6 hours of resuscitation.

RESULTS

Thirty-one swine were studied. Baseline hematocrit was 24%, pH was 7.56, INR was 1.0, and lactate level was 1.47. Six hours after H/I, the hematocrit was 15.9%, pH was 7.1, INR was 1.7, and lactate level was 10.26. Rotational thromboelastometry revealed that maximum clot firmness at baseline was 71.71 mm and decreased to 0.29 mm with tissue plasminogen activator, representing severe fibrinolysis. Following TXA dosing, the maximum clot firmness was immediately corrected to 69.06 mm. There was no difference (p = 0.48) between TXA function at baseline pH (mean, 7.56) or acidotic pH (mean, 7.11). The mean baseline PT was 13 ± 0.49 seconds (INR, 1). After H/I and resuscitation, the mean PT was 23.03 seconds (INR, 2.1). PCC reduced the PT to 20 (INR, 1.75; p = 0.001) and FFP to 17.44 (INR, 1.47; p = 0.001).

CONCLUSION

Both TXA and PCC seem to function well in reversing a traumatic coagulopathy in vitro, and TXA seems to have no loss of function in a severe metabolic acidosis. Further investigations are warranted.

Thromboelastographic Study of Psychophysiological Stress: A Review

Thromboelastography (TEG) is drawing more attention for clinical and laboratory studies of hemostasis. It has been applied to evaluate the effects of both psychological and physiological stress on whole blood coagulation from the onset of the coagulation cascade through clot formation, to the end with fibrinolysis. We conducted a comprehensive review on the applications of TEG for assessment of different stressors, ranging from physical exercise to emotional situations. The methodology is unique in terms of instrumentation, the methods to activate blood coagulation, the type of blood (citrated vs fresh blood), and study settings (in vitro vs in vivo vs clinical trials). Thromboelastography has most often been used to study the effects of physiological stress. The author's own work and future directions are discussed as well. The review would facilitate future development of TEG for evaluating hemostasis and potential pathological pathways in response to various forms of stress.

Monitoring fibrinolysis in whole blood by viscoelastic instruments: a comparison of ROTEM and ReoRox

OBJECTIVE

Increased fibrinolysis with the risk of bleeding is a consequence of thrombolytic therapy and can also be seen in clinical situations such as acute trauma. Thrombelastography and thrombelastometry are viscoelastic coagulation instruments that can detect higher degrees of fibrinolysis; hyperfibrinolysis. A newer viscoelastic instrument is the ReoRox, which uses free oscillation rheometry to detect clot formation, strength and fibrinolysis. The ReoRox has a new test for detection of fibrinolysis, called ReoLyse. The aim of this study was to compare ReoRox with its new ReoLyse test with rotational thrombelastometry (ROTEM) in the monitoring of in vitro-induced fibrinolysis.

METHODS

Whole blood from 10 healthy volunteers was mixed with tissue plasminogen activator (t-PA) to obtain seven different plasma concentrations (0, 0.25, 0.5, 0.75, 1, 3 and 5 μg/mL). Whole blood samples with the different t-PA plasma concentrations were analyzed with ROTEM EXTEM and FIBTEM tests, ReoRox standard test Fib1 (clot formation/strength) and ReoLyse (fibrinolysis) tests.

RESULTS

The fibrinolysis variables with the best dose-response effect were the ReoRox ReoLyse lysis variables and ROTEM EXTEM Time to complete lysis. However, these variables only detected high t-PA levels (> 1 μg/mL).

CONCLUSIONS

The new ReoRox ReoLyse test provides more information on fibrinolysis compared to the ReoRox Fib1 program. Neither ReoRox nor ROTEM could detect lower degrees of fibrinolysis. ReoRox is a valuable alternative to ROTEM to study high degrees of fibrinolysis and should be evaluated in clinical situations with increased fibrinolysis and during therapeutic thrombolysis.

Resuscitation and transfusion management in trauma patients: emerging concepts

PURPOSE OF REVIEW

Severe trauma is associated with hemorrhage, coagulopathy and transfusion of blood and blood products, all associated with considerable mortality and morbidity. The aim of this review is to focus on resuscitation, transfusion strategies and the management of bleeding in trauma as well as to emphasize on why coagulation has to be monitored closely and to discuss the rationale of modern and future transfusion strategies.

RECENT FINDINGS

Coagulopathy and uncontrolled bleeding remain leading causes of death in trauma, lead to blood transfusions and increased mortality as it has been recently shown that blood transfusion per se results in an adverse outcome. In the last years, damage control resuscitation, a combination of permissive hypotension, hemostatic resuscitation and damage control surgery, has been introduced to treat severely traumatized patients in hemorrhagic shock. Goals of treatment in trauma patients remain avoiding metabolic acidosis, hypothermia, treating coagulopathy and stabilizing the patient as soon as possible. The place of colloids and crystalloids in trauma resuscitation as well as the role of massive transfusion protocols with a certain FFP : RBC ratio and even platelets have to be reevaluated.

SUMMARY

Close monitoring of bleeding and coagulation in trauma patients allows goal-directed transfusions and thereby optimizes the patient's coagulation, reduces the exposure to blood products, reduces costs and may improve clinical outcome.

Antifibrinolytic agents in current anaesthetic practice

Antifibrinolytic drugs have become almost ubiquitous in their use during major surgery when bleeding is expected or commonplace. Inhibition of the fibrinolytic pathway after tissue injury has been consistently shown to reduce postoperative or traumatic bleeding. There is also some evidence for a reduction of perioperative blood transfusion. However, evidence of complications associated with exaggerated thrombosis also exists, although this appears to be influenced by the choice of the individual agent and the dose administered. There is controversy over the use of the serine protease inhibitor aprotinin, whose license was recently withdrawn but may shortly become available on the market again. In the UK, tranexamic acid, a tissue plasminogen and plasmin inhibitor, is most commonly used, with evidence for benefit in cardiac, orthopaedic, urological, gynaecological, and obstetric surgery. In the USA, ε-aminocaproic acid, which also inhibits plasmin, is commonly used. We have reviewed the current literature for this increasingly popular class of drugs to support clinical judgement in daily anaesthetic practice.

Thrombelastography (TEG®): practical considerations on its clinical use in trauma resuscitation

Background

Thrombelastography is a laboratorial test that measures viscoelastic changes of the entire clotting process. There is growing interest in its clinical use in trauma resuscitation, particularly for managing acute coagulopathy of trauma and assisting decision making concerning transfusion. This review focuses on the clinical use of thrombelastography in trauma, with practical points to consider on its use in civilian and military settings.

Methods

A search in the literature using the terms “thrombelastography AND trauma” was performed in PUBMED database. We focused the review on the main clinical aspects of this viscoelastic method in diagnosing and treating patients with acute coagulopathy of trauma during initial resuscitation.

Results

Thrombelastography is not a substitute for conventional laboratorial tests such as INR and aPTT but offers additional information and may guide blood transfusion. Thrombelastography can be used as a point of care test but requires multiple daily calibrations, should be performed by trained personnel and its technique requires standardization. While useful partial results may be available in minutes, the whole test may take as long as other conventional tests. The most important data provided by thrombelastography are clot strength and fibrinolysis. Clot strength measure can establish whether the bleeding is due to coagulopathy or not, and is the key information in thrombelastography-based transfusion algorithms. Thrombelastography is among the few tests that diagnose and quantify fibrinolysis and thus guide the use of anti-fibrinolytic drugs and blood products such as cryoprecipitate and fibrinogen concentrate. It may also diagnose platelet dysfunction and hypercoagulability and potentially prevent inappropriate transfusions of hemostatic blood products to non-coagulopathic patients.

Conclusions

Thrombelastography has characteristics of an ideal coagulation test for use in early trauma resuscitation. It has limitations, but may prove useful as an additional test. Future studies should evaluate its potential to guide blood transfusion and the understanding of the mechanisms of trauma coagulopathy.

Recombinant tissue-type plasminogen activator-evoked hyperfibrinolysis is enhanced by acidosis and inhibited by hypothermia but still can be blocked by tranexamic acid

BACKGROUND

Hypothermia and acidosis have been suggested as key initiators of trauma-induced coagulopathy, and severe bleeding caused by hyperfibrinolysis (HF) predicts mortality. We tested in vitro (1) whether clinically relevant grades of hypothermia, acidosis, and their combination impact on recombinant tissue-type plasminogen activator (r-tPA)-evoked HF and assessed (2) the efficacy of tranexamic acid (TA) in inhibiting fibrinolysis under such conditions.

METHODS

To assess the effects of r-tPA-evoked HF, venous blood (3,000 μL) from healthy volunteers was incubated with r-tPA (final concentration, 100 ng/mL) or saline (control) for 30 minutes at the final measurement temperature. Before thromboelastometric measurements, samples were acidified (addition of 40 μL of 0.5 or 1N hydrochloric acid, respectively) to achieve a pH (alpha-stat) of approximately 7.1 or 6.9, respectively. To assess effects of hypothermia, tests were performed at blood/thromboelastometer temperatures of 33°C and 37°C, respectively. Coagulation was analyzed using rotational thromboelastometry (ROTEM), particularly assessing the Clot Lysis Index (CLI) after 45 minutes (CLI45) in extrinsically activated assays (EXTEM).

RESULTS

Addition of r-tPA evoked fibrinolysis (CLI45: median, 64; 25th/75th percentile, 48/80) compared with saline controls (CLI45: median, 93; 25th/75th percentile, 91/96). Moderate acidosis (pH [mean ± SD], 7.12 ± 0.03) did not affect r-tPA-induced fibrinolysis. However, severe acidosis (pH, 6.91 ± 0.02) significantly aggravated r-tPA-induced fibrinolysis (CLI45: median, 49; 25th/75th percentile, 26/71; p = 0.0039) compared with fibrinolysis with normal pH and normothermia (median, 77; 25th/75th percentile, 65.5/83). In contrast, hypothermia (33°C) at normal pH (median ± SD, 7.37 ± 0.02) markedly mitigated fibrinolysis (CLI45: median, 94; 25th/75th percentile, 88/96; p = 0.0156) compared with normothermia (CLI45: median, 64; 25th/75th percentile, 48/80). TA (final concentration, 0.33 mg/mL) abolished r-tPA-evoked fibrinolysis even during severe acidosis (CLI45: median, 92; 25th/75th percentile, 86.5/94; p = 0.0039).

CONCLUSION

Severe acidosis significantly increases r-tPA-evoked fibrinolysis, whereas hypothermia markedly mitigates HF. The latter finding may imply that rapid rewarming of trauma patients might aggravate fibrinolysis. TA reliably abolished fibrinolysis also under these conditions, supporting its role in trauma-induced coagulopathy.

Impact of fibrinogen levels on outcomes after acute injury in patients requiring a massive transfusion

BACKGROUND

For critically injured patients requiring a massive transfusion, the optimal plasma fibrinogen level is unknown. The purpose of this study was to examine the impact of the fibrinogen level on mortality. We hypothesized that decreasing fibrinogen levels are associated with worse outcomes.

STUDY DESIGN

All patients undergoing a massive transfusion from January 2000 through December 2011 were retrospectively identified. Those with a fibrinogen level measured on admission to the surgical ICU were analyzed according to their fibrinogen level (normal [≥180 mg/dL], abnormal [≥101 to <180 mg/dL], and critical [≤100 mg/dL]). Primary outcome was death. Multivariate analysis evaluated the impact of fibrinogen on survival.

RESULTS

There were 260 patients who met inclusion criteria. Ninety-two patients had normal admission fibrinogen levels, 114 had abnormal levels, and 54 patients had critical levels. Patients with a critical fibrinogen level had significantly higher mortality at 24 hours compared with patients with abnormal (31.5% vs 5.3%; adj. p < 0.001) and normal fibrinogen levels (31.5% vs 4.3%; adjusted p < 0.001). Patients with a critical fibrinogen level had significantly higher in-hospital mortality compared with patients with abnormal (51.9% vs 25.4%; adjusted p = 0.013) and normal fibrinogen levels (51.9% vs 18.5%; adjusted p < 0.001). A critical fibrinogen level was the most important independent predictor of mortality (p = 0.012).

CONCLUSIONS

For patients undergoing a massive transfusion after injury, as the fibrinogen level increased, a stepwise improvement in survival was noted. A fibrinogen level ≤100 mg/dL was a strong independent risk factor for death. The impact of an aggressive fibrinogen replacement strategy using readily available products warrants further prospective evaluation.

Point of care devices for assessing bleeding and coagulation in the trauma patient

Severe trauma is associated with bleeding, coagulopathy, and transfusion of blood and blood products, all contributing to higher rates of morbidity and mortality. The aim of this review is to focus on point-of-care devices to monitor coagulation in trauma. Close monitoring of bleeding and coagulation as well as platelet function in trauma patients allows goal-directed transfusion and an optimization of the patient's coagulation, reduces the exposure to blood products, reduces costs, and probably improves clinical outcome. Noninvasive hemoglobin measurements are not to be used in trauma patients due to a lack in specificity and sensitivity.

Hyperfibrinolysis at admission is an uncommon but highly lethal event associated with shock and prehospital fluid administration

BACKGROUND

Hyperfibrinolysis (HF) has been reported to occur in a range of 2% to 34% of trauma patients. Using rapid thromboelastography (r-TEG), we hypothesized that HF is (1) rarely present at admission on patients with severe injury and (2) associated with crystalloid hemodilution. To further strengthen this hypothesis, we created an in vitro hemodilution model to improve our mechanistic understanding of the early HF.

METHODS

The trauma registry was queried for patients who were our highest-level trauma activations and admitted directly from the scene (October 2009-October 2010). HF was defined as more than 7.5% amplitude reduction 30 minutes after maximal amplitude (LY30). Using r-TEG, we then created an in vitro hemodilution model (0.9% NS) with and without tissue injury (addition of tissue factor and tissue plasminogen activator) to identify crystalloid volumes and injury needed to achieve specific LY30 values.

RESULTS

Admission r-TEG values were captured on 1996 consecutive admissions. Only 41 patients (2%) had HF at admission r-TEG. The groups were similar in demographics. Compared with patients without HF, the HF group had more prehospital crystalloid (1.5 vs. 0.5 L), higher median Injury Severity Score (25 vs. 16), greater admission base deficit (20 vs. 2), and higher mortality (76% vs. 10%); all p < 0.001. Controlling for Injury Severity Score and base deficit on arrival, prehospital fluid was associated with a significant increase in likelihood of HF. In fact, each additional liter of crystalloid was associated with a 15% increased odds of HF. The in vitro model found that hemodilution to 15% of baseline and tissue factor + tissue plasminogen activator was required to achieve an LY30 of 50%.

CONCLUSION

Although uncommon immediately after injury, HF is associated with prehospital crystalloid administration and shock at admission and is highly lethal. Our in vitro model confirms that tissue injury and significant crystalloid hemodilution result in severe and immediate HF.

Critical care considerations in the management of the trauma patient following initial resuscitation

Background

Care of the polytrauma patient does not end in the operating room or resuscitation bay. The patient presenting to the intensive care unit following initial resuscitation and damage control surgery may be far from stable with ongoing hemorrhage, resuscitation needs, and injuries still requiring definitive repair. The intensive care physician must understand the respiratory, cardiovascular, metabolic, and immunologic consequences of trauma resuscitation and massive transfusion in order to evaluate and adjust the ongoing resuscitative needs of the patient and address potential complications. In this review, we address ongoing resuscitation in the intensive care unit along with potential complications in the trauma patient after initial resuscitation. Complications such as abdominal compartment syndrome, transfusion related patterns of acute lung injury and metabolic consequences subsequent to post-trauma resuscitation are presented.

Methods

A non-systematic literature search was conducted using PubMed and the Cochrane Database of Systematic Reviews up to May 2012.

Results and conclusion

Polytrauma patients with severe shock from hemorrhage and massive tissue injury present major challenges for management and resuscitation in the intensive care setting. Many of the current recommendations for “damage control resuscitation” including the use of fixed ratios in the treatment of trauma induced coagulopathy remain controversial. A lack of large, randomized, controlled trials leaves most recommendations at the level of consensus, expert opinion. Ongoing trials and improvements in monitoring and resuscitation technologies will further influence how we manage these complex and challenging patients.

Criteria for empiric treatment of hyperfibrinolysis after trauma

BACKGROUND

Recent studies identify a survival benefit from the administration of antifibrinolytic agents in patients with severe injury and trauma. However, identification of hyperfibrinolysis requires thromboelastography, which is not widely available. We hypothesized that analysis of patients with thromboelastography-diagnosed hyperfibrinolysis would identify clinical criteria for empiric antifibrinolytic treatment in the absence of thromboelastography.

METHODS

From November 2010 to March 2012, serial blood samples were collected from 115 patients with critical injury on arrival to the emergency department of an urban Level I trauma center. Rotational thromboelastography was performed to assess viscoelastic properties of clot formation in the presence and absence of aprotinin to identify treatable hyperfibrinolysis. For 20 patients identified with treatable hyperfibrinolysis, clinical predictors were investigated using receiver operating characteristic analysis.

RESULTS

Of the 115 patients evaluated, 20% had hyperfibrinolysis, defined as an admission maximal clot lysis of 10% or higher, reversible by aprotinin treatment. Patients with hyperfibrinolysis had significantly lower temperature, pH, and platelet counts and higher international normalized ratio, activated partial thromboplastin time, and D-dimer. Hyperfibrinolysis was associated with multiorgan failure (63.2% vs. 24.6%, p = 0.004) and mortality (52.2% vs. 12.9%, p < 0.001). We then evaluated all non-rotational thromboelastography clinical and laboratory parameters predictive of hyperfibrinolysis using receiver operating characteristic analysis to evaluate potential empiric treatment guidelines. The presence of hypothermia (temperature ≤36.0°C), acidosis (pH ≤7.2), relative coagulopathy (international normalized ratio ≥1.3 or activated partial thromboplastin time ≥30), or relative thrombocytopenia (platelet count ≤200) identified hyperfibrinolysis with 100% sensitivity and 55.4% specificity (area under the curve, 0.777).

CONCLUSION

Consideration of empiric antifibrinolytic therapy is warranted for patients with critical injury and trauma who present with acidosis, hypothermia, coagulopathy, or relative thrombocytopenia. These clinical predictors identified hyperfibrinolysis with 100% sensitivity while simultaneously eliminating 46.6% of inappropriate therapy compared with the empiric treatment of all injured patients. These criteria will facilitate empiric treatment of hyperfibrinolysis for clinicians without access to thromboelastography.

LEVEL OF EVIDENCE

Prognostic study, level III.

Accounting for differences in transfusion volume: Are all massive transfusions created equal?

BACKGROUND

Among patients subjected to massive transfusion (MT), some will require considerably more blood than others, depending on the rate and quantity of hemorrhage. In analyses concerning plasma to red blood cell (RBC) ratios and platelet to RBC ratios, this has yet to be examined. We sought to evaluate the effect of the number of RBC units transfused on both plasma:RBC and platelet:RBC and their association with mortality in MT patients.

METHODS

Prospective data were collected on trauma patients taken directly to surgery from the resuscitation room who received ≥ 10 RBC units by completion of operation. MT protocol was in place for all patients. To account for survival bias, intra-operative deaths were excluded. Patients were stratified by plasma:RBC and platelet:RBC (HIGH > 0.5, MID 0.33-0.5, LOW < 0.33). Crude and adjusted risk ratios (RRs) for hospital mortality were determined, using the HIGH ratio as the reference group.

RESULTS

One hundred thirty-five patients met inclusion criteria. There were no significant differences with respect to demographics, injury characteristics, or shock severity. However, the mean number of intra-operative RBC units transfused was significantly different between plasma:RBC groups (HIGH: 16.2, MID: 19.7, LOW: 25.1; p < 0.001). The crude risk for mortality was significantly higher for the LOW group relative to the HIGH group (RR 1.99, 95% confidence interval [CI] 1.02-3.89). However, after adjustment for the number of RBCs transfused, the risk was not significantly different (RR 1.54, 95% CI 0.75-3.15). The adjusted mortality risk for the LOW versus HIGH platelet:RBC groups was also not statistically different (RR 1.92, 95% CI 0.99-3.71).

CONCLUSIONS

Among patients subjected to MT, those who receive relatively higher quantities of RBCs are both more likely to receive a lower plasma:RBC and are more likely to die. Any analysis concerning transfusion ratios should take the potential confounding of this heterogeneity among MT patients into account.

LEVEL OF EVIDENCE

Prognostic study, level III.

Hyperfibrinolysis is common in out-of-hospital cardiac arrest: results from a prospective observational thromboelastometry study

BACKGROUND

Cardiocirculatory arrest (CCA) activates procoagulant pathways. It has also been reported to inhibit fibrinolysis, resulting in fibrin deposition and further impairment of blood flow. Until now, no studies have used whole-blood viscoelastic tests to characterize coagulation and the impact of fibrinolysis in out-of-hospital cardiac arrest (OHCA).

METHODS

Patient with established OHCA who underwent cardiopulmonary resuscitation (CPR) were enrolled. Blood samples were obtained immediately after placement of an intravenous line at the scene, for full blood cell count, standard coagulation tests and rotational thromboelastometric (ROTEM(®)) analyses. Patients with return of spontaneous circulation (ROSC) were compared to non-ROSC patients.

RESULTS

Fifty-three patients (median age 67 years, interquartile range: 56-73 years) were included in the study. ROSC was established in 25 patients. Prothrombin time index (PTI) was significantly lower and activated partial thromboplastin time (aPTT) was significantly prolonged in non-ROSC patients compared to ROSC patients. Clotting time (CT) in the extrinsically activated ROTEM test (EXTEM) was significantly longer in non-ROSC versus ROSC patients. For the remaining EXTEM parameters, there were no significant differences between ROSC and non-ROSC patients. Hyperfibrinolysis (maximum lysis>15% according to ROTEM test results) was observed in 19 patients (35.8%). There was no difference between ROSC and non-ROSC patients in the incidence of hyperfibrinolysis.

CONCLUSIONS

PTI, aPTT and EXTEM CT revealed significant differences between ROSC and non-ROSC patients. Hyperfibrinolysis according to ROTEM test results was much more common than previously assumed. Routine use of fibrinolytic therapy in all patients with prolonged CPR cannot therefore be recommended.

Does rotational thromboelastometry (ROTEM) improve prediction of bleeding after cardiac surgery?

BACKGROUND

Coagulopathy and massive bleeding are severe complications of cardiac surgery, particularly in procedures requiring prolonged cardiopulmonary bypass (CPB). There is huge variability in transfusion practices across hospitals and providers in cross-sectional studies. This variability may indicate unguided decision-making, perhaps attributable to lack of reliable, predictive laboratory testing of coagulopathy to guide transfusion practice. Rotational thromboelastometry (ROTEM) measures multiple coagulation parameters and may provide value from its ease of use, rapid results, and measurement of several steps in the coagulation pathway. Yet, the predictive value and utility of ROTEM remains unclear. In this study, we investigated ROTEM's predictive value for chest tube drainage after cardiac surgery.

METHODS

Three hundred twenty-one patients undergoing cardiac surgery involving CPB were enrolled. Patient data were obtained from medical records, including chest tube output (CTO) from post-CPB through the first 8 postoperative hours. Perioperative and postoperative blood samples were collected for ROTEM analysis. Three measures of CTO were used as the primary end points for assessing coagulopathy: (i) continuous CTO; (ii) CTO dichotomized at 600 mL (75th percentile); and (iii) CTO dichotomized at 910 mL (90th percentile). Clinical and hematological variables, excluding ROTEM data, that were significantly correlated (P < 0.05) with continuous CTO were included in a stepwise regression model (model 1). An additional model that contained ROTEM variables in addition to the variables from model 1 was created (model 2). Significance in subsequent analyses was declared at P < 0.0167 to account for the 3 CTO end points. Net reclassification index was used to assess overall value of ROTEM data.

RESULTS

For continuous CTO, ROTEM variables improved the model's predictive ability (P < 0.0001). For CTO dichotomized at 600 mL (75th percentile), ROTEM did not improve the area under the receiver operating characteristic curve (AUC) (P = 0.03). Similarly, for CTO dichotomized at 910 mL (90th percentile), ROTEM did not improve the AUC (P = 0.23). Net reclassification index similarly indicated that ROTEM results did not improve overall classification of patients (P = 0.12 for CTO ≥600 mL; P = 0.08 for CTO ≥910 mL).

CONCLUSIONS

These results suggest that ROTEM data do not substantially improve a model's ability to predict chest tube drainage, beyond frequently used clinical and laboratory parameters. Although several ROTEM parameters were individually associated with CTO, they did not significantly improve goodness of fit when added to statistical models comprising only clinical and routine laboratory parameters. ROTEM does not seem to improve prediction of chest tube drainage after cardiac surgery involving CPB, although its use in guiding transfusion during cardiac surgery remains to be determined.

Trauma and Thrombelastography

Bleeding disorders associated with trauma are of paramount importance when dealing with the acutely injured individual. Statistically, up to 40% of trauma related deaths are assumed to be related to hemorrhage.1,2 Historically, there have been many varying positions on the way to handle this entity.3–5 Ironically, it is not always the injury but the physiologic sequelae of that injury that lead to trauma associated deaths.6,7 Over time, newer theories have been developed to help the clinician begin to understand the etiology and treatment of this process.6,8,9 The purpose of this paper is to review current literature and explain how these new concepts helped change practice in an urban, academic, Level One Trauma Center.

Early and individualized goal-directed therapy for trauma-induced coagulopathy

Severe trauma-related bleeding is associated with high mortality. Standard coagulation tests provide limited information on the underlying coagulation disorder. Whole-blood viscoelastic tests such as rotational thromboelastometry or thrombelastography offer a more comprehensive insight into the coagulation process in trauma. The results are available within minutes and they provide information about the initiation of coagulation, the speed of clot formation, and the quality and stability of the clot. Viscoelastic tests have the potential to guide coagulation therapy according to the actual needs of each patient, reducing the risks of over- or under-transfusion. The concept of early, individualized and goal-directed therapy is explored in this review and the AUVA Trauma Hospital algorithm for managing trauma-induced coagulopathy is presented.

Whole blood thromboelastometry: another Knight at the Roundtable?

Thromboelastography and thromboelastometry represent viscoelastic diagnostic methodologies with promising application to diseases of altered coagulation. Their use in trauma-induced coagulopathy as a means of assessing the real-time status of the patient's functional coagulation profile in addition to its impact on effective and appropriate use of blood product support has been gaining acceptance among trauma surgeons, anesthesiologists, and transfusion medicine specialists. However, the ability of viscoelastic testing to augment or supplant conventional coagulation testing for the diagnosis and management of trauma-induced coagulopathy remains controversial. Many of these issues pertain to the differences in methodology, instrumentation, logic, accessibility, ease of use, operator variability, and the method's relationship to patient care, blood product use, cost, and conventional testing algorithms.