Arasch Wafaisade

Epidemiology and risk factors of sepsis after multiple trauma: An analysis of 29,829 patients from the Trauma Registry of the German Society for Trauma Surgery*

Objectives:The objectives of this study were 1) to assess potential changes in the incidence and outcome of sepsis after multiple trauma in Germany between 1993 and 2008 and 2) to evaluate independent risk factors for posttraumatic sepsis. Design:Retrospective analysis of a nationwide, population-based prospective database, the Trauma Registry of the German Society for Trauma Surgery. Setting:A total of 166 voluntarily participating trauma centers (levels I–III). Patients:Patients registered in the Trauma Registry of the German Society for Trauma Surgery between 1993 and 2008 with complete data sets who presented with a relevant trauma load (Injury Severity Score of ≥9) and were admitted to an intensive care unit (n = 29,829). Interventions:None. Measurements and Main Results:Over the 16-yr study period, 10.2% (3,042 of 29,829) of multiply injured patients developed sepsis during their hospital course. Annual data were summarized into four subperiods: 1993–1996, 1997–2000, 2001–2004, and 2005–2008. The incidences of sepsis for the four subperiods were 14.8%, 12.5%, 9.4%, and 9.7% (p < .0001), respectively. In-hospital mortality for all trauma patients decreased for the respective subperiods (16.9%, 16.0%, 13.7%, and 11.9%; p < .0001). For the subgroup of patients with sepsis, the mortality rates were 16.2%, 21.5%, 22.0%, and 18.2% (p = .054), respectively. The following independent risk factors for posttraumatic sepsis were calculated from a multivariate logistic regression analysis: male gender, age, preexisting medical condition, Glasgow Coma Scale score of ≤8 at scene, Injury Severity Score, Abbreviated Injury ScaleTHORAX score of ≥3, number of injuries, number of red blood cell units transfused, number of operative procedures, and laparotomy. Conclusions:The incidence of sepsis decreased significantly over the study period; however, in this decade the incidence remained unchanged. Although overall mortality from multiple trauma has declined significantly since 1993, there has been no significant decrease of mortality in the subgroup of septic trauma patients. Thus, sepsis has remained a challenging complication after trauma during the past 2 decades. Recognition of the identified risk factors may guide early diagnostic workup and help to reduce septic complications after multiple trauma.

Venous thromboembolism after severe trauma: Incidence, risk factors and outcome

BACKGROUND Venous thromboembolic events (VTEs) are common life-threatening complications after trauma, but epidemiology and reported risk factors still vary. The purpose of this investigation was to determine the incidence of VTEs among hospitalised trauma patients, to identify potential risk factors and to assess whether their presence was associated with: (a) the magnitude and pattern of injury, (b) therapeutic interventions and (c) outcome, all by using a large population-based registry. PATIENTS AND METHODS Patient data from the Trauma Registry of the German Society for Trauma Surgery (TR-DGU) including datasets from more than 35,000 trauma patients were screened for all clinically relevant VTEs, i.e. deep vein thrombosis (DVT) and pulmonary embolism (PE). A total of 7937 patients were identified for further investigation and multivariate logistic regression analyses were performed to assess potential risk factors for VTEs and to evaluate the effect of VTEs on outcome. RESULTS One hundred forty-six of 7937 patients developed clinically relevant VTEs during post-traumatic hospitalisation corresponding to an overall incidence rate of 1.8%. Two-thirds (97/146) of all VTEs occurred during the first 3 weeks after admission. At the time point of the event 118/146 (80.8%) patients were under either mechanical or chemical prophylaxis. Multivariate analysis with VTE as dependent variable identified injury severity score, the number of operative procedures, pelvic injury (abbreviated injury scale > or = 2) and concomitant diseases (i.e. diabetes, renal failure, malignancies and congenital or acquired coagulation disorders) as independent risk factors. The presence of VTEs was associated with higher frequencies of sepsis (25% vs. 9.1%), single (63.6% vs. 41.3%) and multiple organ failure (49% vs. 25%) and prolonged in-hospital length of stay (52+/-34 days vs. 29+/-30 days; all p<0.001). The mortality in the VTE group totaled 13.7% vs. 7.4% in the non-VTE group (p=0.004). The presence of PE was associated with a mortality rate of 25.7%. The adjusted odds ratio of post-traumatic VTEs for hospital mortality was 2.08 (CI95 1.15-3.78; p=0.016). CONCLUSION The occurrence of clinically apparent VTEs during post-traumatic hospitalisation is low but associated with increased morbidity and mortality. Conclusions about the effectiveness of different thromboprophylactic measures could not be drawn, since detailed information was not recorded. However, 80.8% of VTE patients had received thromboprophylaxis at the time point of the event.

Predicting on-going hemorrhage and transfusion requirement after severe trauma: a validation of six scoring systems and algorithms on the TraumaRegister DGU®

IntroductionThe early aggressive management of the acute coagulopathy of trauma may improve survival in the trauma population. However, the timely identification of lethal exsanguination remains challenging. This study validated six scoring systems and algorithms to stratify patients for the risk of massive transfusion (MT) at a very early stage after trauma on one single dataset of severely injured patients derived from the TR-DGU (TraumaRegister DGU® of the German Trauma Society (DGU)) database.MethodsRetrospective internal and external validation of six scoring systems and algorithms (four civilian and two military systems) to predict the risk of massive transfusion at a very early stage after trauma on one single dataset of severely injured patients derived from the TraumaRegister DGU® database (2002-2010). Scoring systems and algorithms assessed were: TASH (Trauma-Associated Severe Hemorrhage) score, PWH (Prince of Wales Hospital/Rainer) score, Vandromme score, ABC (Assessment of Blood Consumption/Nunez) score, Schreiber score and Larsen score. Data from 56,573 patients were screened to extract one complete dataset matching all variables needed to calculate all systems assessed in this study. Scores were applied and area-under-the-receiver-operating-characteristic curves (AUCs) were calculated. From the AUC curves the cut-off with the best relation of sensitivity-to-specificity was used to recalculate sensitivity, specificity, positive predictive values (PPV), and negative predictive values (NPV).ResultsA total of 5,147 patients with blunt trauma (95%) was extracted from the TR-DGU. The mean age of patients was 45.7 ± 19.3 years with a mean ISS of 24.3 ± 13.2. The overall MT rate was 5.6% (n = 289). 95% (n = 4,889) patients had sustained a blunt trauma. The TASH score had the highest overall accuracy as reflected by an AUC of 0.889 followed by the PWH-Score (0.860). At the defined cut-off values for each score the highest sensitivity was observed for the Schreiber score (85.8%) but also the lowest specificity (61.7%). The TASH score at a cut-off ≥ 8.5 showed a sensitivity of 84.4% and also a high specificity (78.4%). The PWH score had a lower sensitivity (80.6%) with comparable specificity. The Larson score showed the lowest sensitivity (70.9%) at a specificity of 80.4%.ConclusionsWeighted and more sophisticated systems such as TASH and PWH scores including higher numbers of variables perform superior over simple non-weighted models. Prospective validations are needed to improve the development process and use of scoring systems in the future.

Drivers of acute coagulopathy after severe trauma: a multivariate analysis of 1987 patients

Objective The role of acute coagulopathy after severe trauma as a major contributor to exsanguination and death has recently gained increasing appreciation, but the causes and mechanisms are not fully understood. This study was conducted to assess the risk factors associated with acute traumatic coagulopathy together with quantitative estimates of their importance. Methods Using the multicentre Trauma Registry of the German Society for Trauma Surgery, adult trauma patients with an Injury Severity Score ≥16 were retrospectively analysed for independent risk factors of acute traumatic coagulopathy on arrival at the emergency department (ED) by multivariate stepwise logistic regression analysis. Coagulopathy was defined as prothrombin time test (Quicks value) <70% and/or platelets <100 000/μl. Results A total of 1987 patients was eligible for further analysis. Independent risk factors for acute traumatic coagulopathy calculated by multivariate analysis were the Injury Severity Score, abdomen Abbreviated Injury Scale score, base excess, body temperature ≤35°C, presence of shock at the scene and/or in the ED (defined as systolic blood pressure ≤90 mm Hg), prehospital intravenous colloid:crystalloid ratio ≥1:2 and amount of prehospital intravenous fluids ≥3000 ml. Conclusions The risk factors from multivariate analysis correspond to the current understanding that coagulopathy is influenced by several clinical key factors; for example, an ongoing state of shock (at the scene and in the ED) was associated with a threefold increased risk of developing coagulopathy. When adjusted for all factors including the amount of prehospital intravenous fluids, a high colloid:crystalloid ratio was still associated with coagulopathy on admission to the ED. The recognition, prevention and management of the mechanisms and risk factors of coagulopathy aggravating haemorrhage after trauma are critical in the treatment of the severely injured patient.

Renaissance of base deficit for the initial assessment of trauma patients: a base deficit-based classification for hypovolemic shock developed on data from 16,305 patients derived from the TraumaRegister DGU®

IntroductionThe recognition and management of hypovolemic shock still remain an important task during initial trauma assessment. Recently, we have questioned the validity of the Advanced Trauma Life Support (ATLS) classification of hypovolemic shock by demonstrating that the suggested combination of heart rate, systolic blood pressure and Glasgow Coma Scale displays substantial deficits in reflecting clinical reality. The aim of this study was to introduce and validate a new classification of hypovolemic shock based upon base deficit (BD) at emergency department (ED) arrival.MethodsBetween 2002 and 2010, 16,305 patients were retrieved from the TraumaRegister DGU® database, classified into four strata of worsening BD [class I (BD ≤ 2 mmol/l), class II (BD > 2.0 to 6.0 mmol/l), class III (BD > 6.0 to 10 mmol/l) and class IV (BD > 10 mmol/l)] and assessed for demographics, injury characteristics, transfusion requirements and fluid resuscitation. This new BD-based classification was validated to the current ATLS classification of hypovolemic shock.ResultsWith worsening of BD, injury severity score (ISS) increased in a step-wise pattern from 19.1 (± 11.9) in class I to 36.7 (± 17.6) in class IV, while mortality increased in parallel from 7.4% to 51.5%. Decreasing hemoglobin and prothrombin ratios as well as the amount of transfusions and fluid resuscitation paralleled the increasing frequency of hypovolemic shock within the four classes. The number of blood units transfused increased from 1.5 (± 5.9) in class I patients to 20.3 (± 27.3) in class IV patients. Massive transfusion rates increased from 5% in class I to 52% in class IV. The new introduced BD-based classification of hypovolemic shock discriminated transfusion requirements, massive transfusion and mortality rates significantly better compared to the conventional ATLS classification of hypovolemic shock (p < 0.001).ConclusionsBD may be superior to the current ATLS classification of hypovolemic shock in identifying the presence of hypovolemic shock and in risk stratifying patients in need of early blood product transfusion.

Balanced massive transfusion ratios in multiple injury patients with traumatic brain injury

IntroductionRetrospective studies have demonstrated a potential survival benefit from transfusion strategies using an early and more balanced ratio between fresh frozen plasma (FFP) concentration and packed red blood cell (pRBC) transfusions in patients with acute traumatic coagulopathy requiring massive transfusions. These results have mostly been derived from non-head-injured patients. The aim of the present study was to analyze whether a regime using a high FFP:pRBC transfusion ratio (FFP:pRBC ratio >1:2) would be associated with a similar survival benefit in severely injured patients with traumatic brain injury (TBI) (Abbreviated Injury Scale (AIS) score, head ≥3) as demonstrated for patients without TBI requiring massive transfusion (≥10 U of pRBCs).MethodsA retrospective analysis of severely injured patients from the Trauma Registry of the Deutsche Gesellschaft für Unfallchirurgie (TR-DGU) was conducted. Inclusion criteria were primary admission, age ≥16 years, severe injury (Injury Severity Score (ISS) ≥16) and massive transfusion (≥10 U of pRBCs) from emergency room to intensive care unit (ICU). Patients were subdivided into patients with TBI (AIS score, head ≥3) and patients without TBI (AIS score, head <3), as well as according to the transfusion ratio they had received: high FFP:pRBC ratio (FFP:pRBC ratio >1:2) and low FFP:pRBC ratio (FFP:pRBC ratio ≤1:2). In addition, morbidity and mortality between the two groups were compared.ResultsA total of 1,250 data sets of severely injured patients from the TR-DGU between 2002 and 2008 were analyzed. The mean patient age was 42 years, the majority of patients were male (72.3%), the mean ISS was 41.7 points (±15.4 SD) and the principal mechanism of injury was blunt force trauma (90%). Mortality was statistically lower in the high FFP:pRBC ratio groups versus the low FFP:pRBC ratio groups, regardless of the presence or absence of TBI and across all time points studied (P < 0.001). The frequency of sepsis and multiple organ failure did not differ among groups, except for sepsis in patients with TBI who received a high FFP:pRBC ratio transfusion. Other secondary end points such as ventilator-free days, length of stay in the ICU and overall in-hospital length of stay differed significantly between the two study groups, but not when only data for survivors were analyzed.ConclusionsThese results add more detailed knowledge to the concept of a high FFP:pRBC ratio during early aggressive resuscitation, including massive transfusion, to decrease mortality in severely injured patients both with and without accompanying TBI. Future research should be conducted with a larger number of patients to prove these results in a prospective study.

Association of Preexisting Medical Conditions with In-Hospital Mortality in Multiple-Trauma Patients

BACKGROUND Mortality after trauma has been shown to be influenced by host factors, such as age and preexisting medical conditions (PMCs). The independent predictive value of specific PMCs for in-hospital mortality after adjustment for injury severity, injury pattern, age, and presence of other PMCs has not been fully elucidated. STUDY DESIGN Records of 11,142 trauma patients (18 years of age or older, Injury Severity Score > or = 16, years 2002 to 2007) documented in the Trauma Registry of the German Society for Trauma Surgery were analyzed to assess the association of PMCs with in-hospital mortality. Multiple logistic regression models were used for this analysis. RESULTS PMCs were affirmed for 3,836 of the 11,142 patients studied (34.4%). An independent statistical association with increased in-hospital mortality was found for 6 of 14 analyzed PMCs after adjustment for age and the Revised Injury Severity Classification score, respectively, ie, heart disease, obesity, hepatitis/liver cirrhosis, malignancies, coagulation disorder, and peripheral arterial occlusive disease stage IV. The association with mortality varied with different injury patterns. CONCLUSION Specific PMCs were associated with increased mortality after trauma independent from injury severity and age. Knowledge of the identified relevant PMCs could help the medical team to be able to assess the mortality risk profile of trauma patients in a more detailed and quantifiable way.

Epidemiology and risk factors of multiple-organ failure after multiple trauma: an analysis of 31,154 patients from the TraumaRegister DGU.

BACKGROUND In the severely injured who survive the early posttraumatic phase, multiple-organ failure (MOF) is the main cause of morbidity and mortality. An enhanced prediction of MOF might influence individual monitoring and therapy of severely injured patients. METHODS We performed a retrospective analysis of a nationwide prospective database, the TraumaRegister DGU of the German Trauma Society. Patients with complete data sets (2002–2011) and a relevant trauma load (Injury Severity Score [ISS] ≥ 16), who were admitted to an intensive care unit, were included. RESULTS Of a total of 31,154 patients enclosed in this study, 10,201 (32.7%) developed an MOF according to the Sequential Organ Failure Assessment score. During the study period, mortality of all patients decreased from 18.1% in 2002 to 15.3% in 2011 (p < 0.001). Meanwhile, MOF occurred significantly more often (24.6% in 2002 vs. 31.5% in 2011, p < 0.001), but mortality of MOF patients decreased (42.6% vs. 33.3%, p < 0.001). MOF patients who died survived 2 days less (11 days in 2002 vs. 8.9 days in 2011, p < 0.001). Independent risk factors for the development of MOF following severe trauma were age, ISS, head Abbreviated Injury Scale (AIS) score of 3 or higher, thoracic AIS score of 3 or higher, male sex, Glasgow Coma Scale (GCS) score of 8 or less, mass transfusion, base excess of less than −3, systolic blood pressure less than 90 mm Hg at admission, and coagulopathy. CONCLUSION Over one decade, we observed an ongoing decrease of mortality after multiple trauma, accompanied by decreasing mortality in the subgroup with MOF. However, incidence of MOF in the severely injured increased significantly. Thus, MOF after multiple trauma remains a challenge in intensive care. The risk factors from multivariate analysis could be instrumental in anticipating the early development of MOF. Furthermore, a reliable prediction model might be supportive for patient enrolment in trauma studies, in which MOF marks the primary end point. LEVEL OF EVIDENCE Epidemiologic study, level III.

Administration of fibrinogen concentrate in exsanguinating trauma patients is associated with improved survival at 6 hours but not at discharge.

BACKGROUND Despite poor evidence and high costs, fibrinogen concentrate (FC) represents one of the most frequently used hemostatic agents in exsanguinating trauma. The aim was to assess whether the administration of FC in severely injured patients was associated with improved outcomes. METHODS Patients documented in the Trauma Registry of the German Society for Trauma Surgery (primary admissions, Injury Severity Score [ISS] ≥16) who had received FC during initial care between emergency department (ED) arrival and intensive care unit admission (FC+) were matched with patients who had not received FC (FC−). RESULTS The matched-pairs analysis yielded two comparable cohorts (n = 294 in each group) with a mean ISS of 37.6 ± 13.7 (FC+) and 37.1 ± 13.3 (FC−) (p = 0.73); the mean age was 40 ± 17 versus 40 ± 16 (p = 0.72), respectively. Patients were predominantly male (71.1% in both groups, p = 1.0). On emergency department arrival, hypotension (systolic blood pressure, ⩽90 mm Hg) occurred in 51.4% (FC+) and 48.0% (FC−) (p = 0.41), and base excess was −7.4 ± 5.3 mmol/L for FC+ and was −7.5 ± 6.2 mmol/L for FC− (p = 0.96). Patients were administered 12.8 ± 14.3 (FC+) versus 11.3 ± 10.0 (FC−) packed red blood cell units (p = 0.20). Thromboembolism occurred in 6.8% (FC+) versus 3.4% (FC−) (p = 0.06), and multiple organ failure occurred in 61.2% versus 49.0% (p = 0.003), respectively. Whereas 6-hour mortality was 10.5% for FC+ versus 16.7% for FC− (p = 0.03), the mean time to death was 7.5 ± 14.6 days versus 4.7 ± 8.6 days (p = 0.006). The overall hospital mortality rate was 28.6% versus 25.5% (p = 0.40), respectively. CONCLUSION This is the first study to investigate the effect of FC administration in bleeding trauma. In our large population of severely injured patients, the early use of FC was associated with a significantly lower 6-hour mortality and an increased time to death, but also an increased rate of multiple organ failure. A reduction of overall hospital mortality was not observed in patients receiving FC. LEVEL OF EVIDENCE Therapeutic study, level IV.

Cardiopulmonary resuscitation traumatic cardiac arrest--there are survivors. An analysis of two national emergency registries.

IntroductionCardiac arrest following trauma occurs infrequently compared with cardiac aetiology. Within the German Resuscitation Registry a traumatic cause is documented in about 3% of cardiac arrest patients. Regarding the national Trauma Registry, only a few of these trauma patients with cardiac arrest survive. The aim of the present study was to analyze the outcome of cardiopulmonary resuscitation (CPR) after traumatic cardiac arrest by combining data from two different large national registries in Germany.MethodsThis study includes 368 trauma patients (2.8%) out of 13,329 cardiac arrest patients registered within the Resuscitation Registry, whereby 3,673 patients with a cardiac cause and successful CPR served as a cardiac control group. We further analyzed a second group of 1,535 trauma patients with cardiac arrest and early CPR registered within the Trauma Registry, whereby a total of 25,366 trauma patients without any CPR attempts served as a trauma control group. The relative frequencies from each database were used to calculate relative percentages for patients with traumatic cardiac arrest in whom resuscitation was attempted.ResultsWithin the Resuscitation Registry, cardiac arrest was present in 331 patients (89.9%) when the EMS personal arrived at the scene and in 37 patients (10.1%) when cardiac arrest occurred after arrival. Spontaneous circulation could be achieved in 107 patients (29.1%). A total of 101 (27.4%) were transferred to hospital, 95 of whom (25.8%) had return of spontaneous circulation (ROSC) on admission. According to the Trauma Registry, the overall hospital mortality rate for cardiac arrest patients following trauma was 73% (n = 593 of 814). About half of the patients who were admitted alive to hospital died within 24 hours, resulting in 13% survivors within 24 hours. 7% of the patients survived until hospital discharge, and only 2% of the patients had good neurological outcome.ConclusionsOur present study encourages CPR attempts in cardiac arrest patients following severe trauma. When a manageable number of patients is present, the decision on whether to start CPR or not should be done liberally, using comparable criteria as in patients with cardiac etiology. In this respect, trauma management programs that restrict CPR attempts should not be encouraged.