Dynamics of Platelet Counts in Major Trauma: The Impact of Haemostatic Resuscitation and Effects of Platelet Transfusion-A Sub-Study of the Randomized Controlled RETIC Trial

Comparison between point-of-care international normalised ratio, COAST, TICCS and truncated FibAT scores to rule in clinically significant hypofibrinogenaemia in the prehospital setting

BACKGROUND

Hypofibrinogenaemia on ED arrival and in the prehospital setting has been associated with both increased mortality and increased blood transfusions. The timely administration of fibrinogen-rich products on arrival to hospital is difficult to achieve and there is no clinical benefit with early, in-hospital empirical fibrinogen supplementation.

METHODS

This was a prospective study of a convenience sample of adult trauma patients who had blood drawn in the prehospital setting prior to the administration of tranexamic acid. A point-of-care international normalised ratio (PoCINR) was performed at the time of blood draw, and Coagulopathy of Severe Trauma (COAST) score, Trauma Induced Coagulopathy Clinical Score (TICCS) and truncated Fibrinogen on Admission in Trauma (FibAT) score were calculated. Hypofibrinogenaemia was defined as a FibTEM A5<10 or a fibrinogen level ≤1.5 g/L with a clinically important specificity defined as 85%.

RESULTS

A total of 152 patients were included in the primary analysis. The cohort was predominately male (82.9%) with a median age of 35 years (IQR 26-51). The median Injury Severity Score was 17 (IQR 10-25.5) with 18.4% sustaining penetrating trauma and 24.3% receiving prehospital blood transfusions. The area under the receiver operating characteristic curve for hypofibrinogenaemia was PoCINR: 0.63 (95% CI 0.53 to 0.73), FibAT: 0.57 (95% CI 0.47 to 0.67), COAST: 0.47 (95% CI 0.37 to 0.58) and TICCS: 0.50 (95% CI 0.40 to 0.61). A cut-off PoCINR value of ≥1.2, FibAT score ≥4, COAST≥4 and TICCS≥12 all yielded ≥85% specificity in detecting hypofibrinogenaemia.

CONCLUSIONS

PoCINR and a truncated FibAT are potential tools for the prehospital detection of hypofibrinogenaemia. Future work should examine the feasibility of PoC devices to test for hypofibrinogenaemia in the prehospital setting and if the use of PoC devices and/or clinical risk stratification tools would result in more rapid fibrinogen replacement.

Revolutionizing trauma care: advancing coagulation management and damage control anesthesia

Despite advances in emergency transfer systems and trauma medicine, the incidence of preventable deaths due to massive hemorrhage remains high. Recent immunological research has elucidated key mechanisms underlying trauma-induced coagulopathy in the early stages of trauma, including sympathoadrenal stimulation, shedding of the glycocalyx, and endotheliopathy. Consequently, the condition progresses to fibrinogen depletion, hyperfibrinolysis, and platelet dysfunction. Coexisting factors such as uncorrected acidosis, hypothermia, excessive crystalloid administration, and a history of anticoagulant use exacerbate coagulopathy. This study introduces damage-control anesthetic management based on recent insights into damage-control resuscitation, emphasizing the importance of rapid transport, timely bleeding control, early administration of antifibrinolytics and fibrinogen concentrates, and maintenance of calcium levels and body temperature. Additionally, this study discusses brain-protective strategies for trauma patients with brain injuries and the utilization of cartridge-based viscoelastic assays for goal-directed coagulation management in trauma settings. This comprehensive approach may provide potential insights for anesthetic management in the fast-paced field of trauma medicine.

Effect of early hemostasis strategy on secondary post-traumatic sepsis in trauma hemorrhagic patients

INTRODUCTION

Fibrinogen and platelet, as the two main components of hemostatic resuscitation, are frequently administered in traumatic massive hemorrhage patients. It is reasonable to infer that they may have an impact on post-traumatic sepsis as more and more recognition of their roles in inflammation and immunity. This study aims to determine the association between the fibrinogen/platelet transfusion ratio during the first 24 h after trauma and the risk of the post- traumatic sepsis.

METHODS

We analyzed the data from the National Trauma Data Bank (NTDB). Subjects included the critically injured adult patients admitted to Level I/II trauma center from 2013 to 2017 who received fibrinogen and platelet supplementation and more than 10 units (about 4000 ml) packed red blood cells (pRBCs) during the first 24 h after trauma. Two parts of analyses were performed: (1) multivariable stepwise regression was used to determine the variables that influence the risk of post-traumatic sepsis; (2) propensity score matching (PSM), to compare the influences of different transfusion ratio between fibrinogen and platelet on the risk of sepsis and other outcomes after trauma.

RESULTS

8 features were screened out by bi-directional multivariable stepwise logistic regression to predict the post-traumatic sepsis. They are age, sex, BMI, ISSabdomen, current smoker, COPD, Fib4h/24h and Fib/PLT24h. Fib/PLT24h was negatively related to sepsis (p < 0.05). A total of 1601 patients were included in the PSM cohort and grouped by Fib/PLT24h = 0.025 according to the fitting generalized additive model (GAM) model curve. The incidence of sepsis was significantly decreased in the high Fib/PLT group [3.3 % vs 9.4 %, OR = 0.33, 95 %CI (0.17-0.60)]; the length of stay in ICU and mechanical ventilation were both shortened as well [8 (IQR 2.00,17.00) vs 9 (IQR 3.00,19.25), p = 0.006 and 4 (IQR 2.00,10.00) vs 5 (IQR 2.00,14.00), p = 0.003, respectively.

CONCLUSIONS

Early and sufficient supplementation of fibrinogen was a convenient way contribute to reduce the risk of sepsis after trauma.

Elevation of White Blood Cell Subtypes in Adult Trauma Patients with Stress-Induced Hyperglycemia

BACKGROUND

Blood immune cell subset alterations following trauma can indicate a patient's immune-inflammatory status. This research explored the influence of stress-induced hyperglycemia (SIH) on platelet counts and white blood cell (WBC) subtypes, including the derived indices of the monocyte-to-lymphocyte ratio (MLR), neutrophil-to-lymphocyte ratio (NLR), and platelet-to-lymphocyte ratio (PLR), in trauma patients.

METHODS

We studied 15,480 adult trauma patients admitted from 1 January 1998 to 31 December 2022. They were categorized into four groups: nondiabetic normoglycemia (NDN, n = 11,602), diabetic normoglycemia (DN, n = 1750), SIH (n = 716), and diabetic hyperglycemia (DH, n = 1412). A propensity score-matched cohort was formed after adjusting for age, sex, and comorbidities, allowing for comparing the WBC subtypes and platelet counts.

RESULTS

Patients with SIH exhibited significantly increased counts of monocytes, neutrophils, and lymphocytes in contrast to NDN patients. However, no significant rise in platelet counts was noted in the SIH group. There were no observed increases in these cell counts in either the DN or DH groups.

CONCLUSIONS

Our results demonstrated that trauma patients with SIH showed significantly higher counts of monocytes, neutrophils, and lymphocytes when compared to NDN patients, whereas the DN and DH groups remained unaffected. This underscores the profound association between SIH and elevated levels of specific WBC subtypes.

The European guideline on management of major bleeding and coagulopathy following trauma: sixth edition

BACKGROUND

Severe trauma represents a major global public health burden and the management of post-traumatic bleeding continues to challenge healthcare systems around the world. Post-traumatic bleeding and associated traumatic coagulopathy remain leading causes of potentially preventable multiorgan failure and death if not diagnosed and managed in an appropriate and timely manner. This sixth edition of the European guideline on the management of major bleeding and coagulopathy following traumatic injury aims to advise clinicians who care for the bleeding trauma patient during the initial diagnostic and therapeutic phases of patient management.

METHODS

The pan-European, multidisciplinary Task Force for Advanced Bleeding Care in Trauma included representatives from six European professional societies and convened to assess and update the previous version of this guideline using a structured, evidence-based consensus approach. Structured literature searches covered the period since the last edition of the guideline, but considered evidence cited previously. The format of this edition has been adjusted to reflect the trend towards concise guideline documents that cite only the highest-quality studies and most relevant literature rather than attempting to provide a comprehensive literature review to accompany each recommendation.

RESULTS

This guideline comprises 39 clinical practice recommendations that follow an approximate temporal path for management of the bleeding trauma patient, with recommendations grouped behind key decision points. While approximately one-third of patients who have experienced severe trauma arrive in hospital in a coagulopathic state, a systematic diagnostic and therapeutic approach has been shown to reduce the number of preventable deaths attributable to traumatic injury.

CONCLUSION

A multidisciplinary approach and adherence to evidence-based guidelines are pillars of best practice in the management of severely injured trauma patients. Further improvement in outcomes will be achieved by optimising and standardising trauma care in line with the available evidence across Europe and beyond.

Platelet Transfusion and Outcomes After Massive Transfusion Protocol Activation for Major Trauma: A Retrospective Cohort Study

BACKGROUND

Incorporation of massive transfusion protocols (MTPs) into acute major trauma care has reduced hemorrhagic mortality, but the threshold and timing of platelet transfusion in MTP are controversial. This study aimed to describe early (first 4 hours) platelet transfusion practice in a setting where platelet counts are available within 15 minutes and the effect of early platelet deployment on in-hospital mortality. Our hypothesis in this work was that platelet transfusion in resuscitation of severe trauma can be guided by rapid turnaround platelet counts without excess mortality.

METHODS

We examined MTP activations for all admissions from October 2016 to September 2018 to a Level 1 regional trauma center with a full trauma team activation. We characterized platelet transfusion practice by demographics, injury severity, and admission vital signs (as shock index: heart rate/systolic blood pressure) and laboratory results. A multivariable model assessed association between early platelet transfusion and mortality at 4 hours, 24 hours, and overall in-hospital, with P <.001.

RESULTS

Of the 11,474 new trauma patients admitted over the study period, 469 (4.0%) were massively transfused (defined as ≥10 units of red blood cells [RBCs] in 24 hours, ≥5 units of RBC in 6 hour, ≥3 units of RBC in 1 hour, or ≥4 units of total products in 30 minutes). 250 patients (53.0%) received platelets in the first 4 hours, and most early platelet transfusions occurred in the first hour after admission (175, 70.0%). Platelet recipients had higher injury severity scores (mean ± standard deviation [SD], 35 ± 16 vs 28 ± 14), lower admission platelet counts (189 ± 80 × 109/L vs 234 ± 80 × 109/L; P < .001), higher admission shock index (heart rate/systolic blood pressure; 1.15 ± 0.46 vs 0.98 ± 0.36; P < .001), and received more units of red cells in the first 4 hours (8.7 ± 7.7 vs 3.3 ± 1.6 units), 24 hours (9 ± 9 vs 3 ± 2 units), and in-hospital (9 ± 8 vs 3 ± 2 units) than nonrecipients (all P < .001). We saw no difference in 4-hour (8% vs 7.8%; P = .4), 24-hour (16.4% vs 10.5%; P = .06), or in-hospital mortality (30.4% vs 23.7%; P = .1) between platelet recipients and nonrecipients. After adjustment for age, injury severity, head injury, and admission physiology/laboratory results, early platelet transfusion was not associated with 4-hour, 24-hour, or in-hospital mortality.

CONCLUSIONS

In an advanced trauma care setting where platelet counts are available within 15 minutes, approximately half of massively transfused patients received early platelet transfusion. Early platelet transfusion guided by protocol-based clinical judgment and rapid-turnaround platelet counts was not associated with increased mortality.

First-Line Administration of Fibrinogen Concentrate in the Bleeding Trauma Patient: Searching for Effective Dosages and Optimal Post-Treatment Levels Limiting Massive Transfusion-Further Results of the RETIC Study

Fibrinogen supplementation is recommended for treatment of severe trauma hemorrhage. However, required dosages and aimed for post-treatment fibrinogen levels remain a matter of discussion. Within the published RETIC study, adult patients suffering trauma-induced coagulopathy were randomly assigned to receive fibrinogen concentrate (FC) as first-line (n = 50) or crossover rescue (n = 20) therapy. Depending on bodyweight, a single dose of 3, 4, 5, or 6 g FC was administered and repeated if necessary (FibA10 < 9 mm). The dose-dependent response (changes in plasma fibrinogen and FibA10) was analyzed. Receiver operating characteristics (ROC) analysis regarding the need for massive transfusion and correlation analyses regarding fibrinogen concentrations and polymerization were performed. Median FC single doses amounted to 62.5 (57 to 66.66) mg·kg⁻¹. One FC single-dose sufficiently corrected fibrinogen and FibA10 (median fibrinogen 213 mg·dL⁻¹, median FibA10 11 mm) only in patients with baseline fibrinogen above 100 mg·dL⁻¹ and FibA10 above 5 mm, repeated dosing was required in patients with lower baseline fibrinogen/FibA10. Fibrinogen increased by 83 or 107 mg·dL⁻¹ and FibA10 by 4 or 4.5 mm after single or double dose of FC, respectively. ROC curve analysis revealed post-treatment fibrinogen levels under 204.5 mg·dL⁻¹ to predict the need for massive transfusion (AUC 0.652; specificity: 0.667; sensitivity: 0.688). Baseline fibrinogen/FibA10 levels should be considered for FC dosing as only sufficiently corrected post-treatment levels limit transfusion requirements.