Platelet and cryoprecipitate transfusions from female donors improve coagulopathy in vitro

Transfusion in trauma: empiric or guided therapy?

A state of the art lecture titled "Transfusion therapy in trauma-what to give? Empiric vs guided" was presented at the International Society on Thrombosis and Haemostasis Congress in 2024. Uncontrolled bleeding is the commonest preventable cause of death after traumatic injury. Hemostatic resuscitation is the foundation of contemporary transfusion practice for traumatic bleeding and has 2 main aims: to immediately support the circulating blood volume and to treat/prevent the associated trauma-induced coagulopathy. There are 2 broad types of hemostatic resuscitation strategy: empiric ratio-based therapy, often using red blood cells and fresh frozen plasma in a 1:1 ratio, and targeted therapy where the use of platelets, plasma, or fibrinogen is guided by laboratory or viscoelastic hemostatic tests. There are benefits, and limitations, to each strategy and neither approach has yet been shown to improve outcomes across all patient groups. Questions remain, and future directions for improving transfusion therapy are likely to require novel approaches that have greater flexibility to evaluate and treat heterogeneous trauma cohorts. Such approaches may include the integration of machine learning technologies in clinical systems, with real-time linkage of clinical and laboratory data, to aid early recognition of patients at the greatest risk of bleeding and to direct and individualize transfusion therapies. Greater mechanistic understanding of the underlying pathobiology of trauma-induced coagulopathy and the direct effects of common treatments on this process will be of equal importance to the development of new treatments. Finally, we summarize relevant new data on this topic presented at the 2024 ISTH Congress.

Amitriptyline Decreases Mouse Lung Endothelial Cell Inflammatory Responses to Packed Red Blood Cell Microparticles

INTRODUCTION

Large-volume packed red blood cell (pRBC) transfusion is associated with lung injury and worsened outcomes. Amitriptyline reduces lung injury and inflammation in a murine sepsis model. We hypothesized that red cell microparticles (MP) activate endothelial cells, leading to lung injury and that treatment with amitriptyline would blunt the inflammatory response MPs through inhibition of acid sphingomyelinase (ASM).

METHODS

Murine pRBCs were obtained from C57Bl/6 mice and stored in AS3 for 14 d. The MPs were isolated from pRBCs by serial centrifugation. Mouse lung endothelial cells (MLECs) were pretreated with amitriptyline (0, 2.5, 25, 27 μM, n = 5) for 30 min prior to MP treatment. Chemokine secretion and adhesion molecule shedding was assessed. ASM activity was measured from cell lysates.

RESULTS

MPs increased the secretion of chemokines and shedding of adhesion molecules in MLECs at both four and 24 h. Amitriptyline treatment of MLECs decreased ASM activity in the setting of MPs. Amitriptyline pretreatment decreased the secretion of chemokines and shedding of adhesion molecules in response to MPs at 4 h but did not decrease adhesion molecule shedding at 24 h CONCLUSIONS: Endothelial cell treatment with MPs induces secretion of chemokines responsible for chemotaxis (keratinocyte chemoattractant, regulated upon activation normal T cell expressed and presumably secreted, and G-granulocyte colony-stimulating factor) as well as many downstream proinflammatory effects (interleukin-6). Additionally, MPs induce adhesion molecule shedding (vascular cell adhesion molecule-1, intracellular adhesion molecule-1, P-selectin, and E-selectin), which has been shown to be associated with endothelial cell activation. Amitriptyline pretreatment decreases MLEC inflammatory response and ASM activity is decreased. These data suggest that ASM inhibition in MLECs is a potential strategy to blunt the inflammatory response to the red blood cell storage lesion.

Whole blood storage duration alters fibrinogen levels and thrombin formation

INTRODUCTION

Whole blood resuscitation for hemorrhagic shock in trauma represents an opportunity to correct coagulopathy in trauma while also supplying red blood cells. The production of microvesicles in stored whole blood and their effect on its hemostatic parameters have not been described in previous literature. We hypothesized that microvesicles in aged stored whole blood are procoagulant and increase thrombin production via phosphatidylserine.

METHODS

Whole blood was obtained from male C57BL/6 male mice and stored in anticoagulant solution for up to 10 days. At intervals, stored whole blood underwent examination with rotational thromboelastography, and platelet-poor plasma was prepared for analysis of thrombin generation. Microvesicles were prepared from 10-day-old whole blood aliquots and added to fresh whole blood or platelet-poor plasma to assess changes in coagulation and thrombin generation. Microvesicles were treated with recombinant mouse lactadherin prior to addition to plasma to inhibit phosphatidylserine's role in thrombin generation.

RESULTS

Aged murine whole blood had decreased fibrin clot formation compared with fresh samples with decreased plasma fibrinogen levels. Thrombin generation in plasma from aged blood increased over time of storage. The addition of microvesicles to fresh plasma resulted in increased thrombin generation compared with controls. When phosphatidylserine on microvesicles was blocked with lactadherin, there was no difference in the endogenous thrombin potential, but the generation of thrombin was blunted with lower peak thrombin levels.

CONCLUSION

Cold storage of murine whole blood results in decreased fibrinogen levels and fibrin clot formation. Aged whole blood demonstrates increased thrombin generation, and this is due in part to microvesicle production in stored whole blood. One mechanism by which microvesicles are procoagulant is by phosphatidylserine expression on their membranes.

Patient sex and outcomes in children with life-threatening hemorrhage

BACKGROUND

Recent data suggest female sex imparts a survival benefit after trauma in adults. The independent associations between patient sex and age with outcomes have not been examined in children with life-threatening hemorrhage (LTH) from all etiologies.

STUDY DESIGN AND METHODS

In a secondary analysis of a multicenter prospective observational study of children with LTH, Massive Transfusion in Children (MATIC), we analyzed if patient sex and age were associated with differences in severity of illness, therapies, and outcomes. Primary outcomes were 24 hour mortality and weight-adjusted transfusion volume during LTH. Kruskal-Wallis, chi-square testing, and multivariable linear regression were used for adjusted analyses.

RESULTS

Of 449 children, 45% were females and 55% were males. Females were more commonly younger, white, and with less trauma as the etiology of LTH compared to males. Markers of clinical severity were similar between groups, except injury severity score (ISS) was higher in females in the trauma subgroup. In terms of resuscitative practices, females received greater weight-adjusted total transfusion volumes compared to males (76 (40-150) mL/kg vs. 53 (24-100) mL/kg), as well as increased red blood cells (RBCs), plasma, and platelets compared to males. After adjustment for confounders, female sex and age 0-11 years were independently associated with increased transfusion volume during LTH. There were no differences in mortality or adverse outcomes according to patient sex.

CONCLUSION

Patient sex and age may impact factors associated with LTH and therapies received. Studies in developmental hemostasis are needed to determine the optimal transfusion strategy for LTH according to patient sex and age.

Sex dimorphisms in coagulation: Implications in trauma-induced coagulopathy and trauma resuscitation

Trauma-induced coagulopathy (TIC) is one of the leading causes of preventable death in injured patients. Consequently, it is imperative to understand the mechanisms underlying TIC and how to mitigate this mortality. An opportunity for advancement stems from the awareness that coagulation demonstrates a strong sex-dependent effect. Females exhibit a relative hypercoagulability compared to males, which persists after injury and confers improved outcomes. The mechanisms underlying sex dimorphisms in coagulation and its protective effect after injury have yet to be elucidated. This review explores sex dimorphisms in enzymatic hemostasis, fibrinogen, platelets, and fibrinolysis, with implications for resuscitation of patients with TIC.

Trans-Omics analysis of post injury thrombo-inflammation identifies endotypes and trajectories in trauma patients

Understanding and managing the complexity of trauma-induced thrombo-inflammation necessitates an innovative, data-driven approach. This study leveraged a trans-omics analysis of longitudinal samples from trauma patients to illuminate molecular endotypes and trajectories that underpin patient outcomes, transcending traditional demographic and physiological characterizations. We hypothesize that trans-omics profiling reveals underlying clinical differences in severely injured patients that may present with similar clinical characteristics but ultimately have very different responses to treatment and clinical outcomes. Here we used proteomics and metabolomics to profile 759 of longitudinal plasma samples from 118 patients at 11 time points and 97 control subjects. Results were used to define distinct patient states through data reduction techniques. The patient groups were stratified based on their shock severity and injury severity score, revealing a spectrum of responses to trauma and treatment that are fundamentally tied to their unique underlying biology. Ensemble models were then employed, demonstrating the predictive power of these molecular signatures with area under the receiver operating curves of 80 to 94% for key outcomes such as INR, ICU-free days, ventilator-free days, acute lung injury, massive transfusion, and death. The molecularly defined endotypes and trajectories provide an unprecedented lens to understand and potentially guide trauma patient management, opening a path towards precision medicine. This strategy presents a transformative framework that aligns with our understanding that trauma patients, despite similar clinical presentations, might harbor vastly different biological responses and outcomes.