View clinical trials related to Coagulopathy.
Filter by:The goal of this observational study is to learn about the performance of the TEG6s in normal pediatric patients. The main questions it aims to answer are: What are the normal TEG 6S lab results in normal pediatric patients and how do they compare to existing published reference ranges. Participants and their guardians will be asked to submit a small amount of blood at the beginning of an elective operation for analysis in the TEG 6s machine.
When small children undergo heart surgery with the heart-lung machine, in the past, blood products to help the blood clot such as Fresh Frozen Plasma (FFP) was routinely used in children under 10kg. With blood clot monitoring technology, we feel that it might not be necessary to expose all children to FFP. We want to determine if those children who did not receive FFP bleed more or require more blood products as compared to those who did receive FFP while on the heart lung machine.
Hypocalcaemia is an independent risk factor of TIC in elderly trauma patients. TIC combined with hypocalcemia had worse coagulation function and more serious acidosis.
Annually over 7000 Australians are treated for severe trauma. Haemorrhage secondary to severe trauma is a major cause of potentially preventable death and poor outcomes in Australian adults. Severe trauma may trigger changes in blood clotting mechanisms and factor levels leading to inhibition of clot formation and reduced clot strength. This results in the inability of the severely injured trauma patient to form adequate clots to help stop bleeding. There is good evidence to suggest the loss of clotting factors during haemorrhage is associated with worse outcomes and it is thought the early replacement of these factors may reduce bleeding and improve patient outcomes. Fibrinogen is a key clotting factor that helps bind clots together and early fibrinogen replacement may improve outcomes. Currently fibrinogen is replaced using cryoprecipitate, a blood product made from blood donated by healthy donors which is a precious resource. It can take a significant amount of time to administer as it is frozen and stored in the blood bank. Timely administration of cryoprecipitate is difficult as it requires thawing prior to transfusion. The large doses of cryoprecipitate used in traumatic haemorrhage can put strain on local blood banks in supplying requested units in a timely manner. Additionally, the widely dispersed population of Australia introduces logistic challenges to the maintenance of adequate cryoprecipitate stocks to individual hospital blood banks, especially in remote regions. However, cryoprecipitate contains a number of other coagulation factors (not just fibrinogen) that may be instrumental in clot formation and resistance to fibrinolysis. Fibrinogen concentrate is an alternative product used to assist in blood clotting. It is a dry powder form of fibrinogen and can be reconstituted at the bedside and given quickly. The use of a fibrinogen factor concentrate with a long shelf life that is easy to use has significant implications for both large urban metropolitan areas and remote isolated communities. The timing and mode of fibrinogen replacement in traumatic haemorrhage has implications for patient outcomes, blood product availability, costs and the national blood supply. Despite the importance of fibrinogen replacement in traumatic haemorrhage, there have been no clinical trials powered for clinical outcomes directly comparing fibrinogen concentrate and cryoprecipitate. FEISTY II will evaluate the efficacy, safety and cost-effectiveness of Fibrinogen Concentrate vs Cryoprecipitate in trauma patients with major haemorrhage. FEISTY II is a phase III randomised trial which will enrol 850 patients from Australian and New Zealand major trauma centres, with a primary patient outcome of days alive out of hospital at day 90 after injury. Severely injured trauma patients who require blood transfusion and have evidence of low fibrinogen levels will be randomised to receive either fibrinogen concentrate or standard care with cryoprecipitate
The existence of AAS coagulopathy has been reported, related to blood contact with the walls of the non-endothelialized false lumens. It is likely that endothelial dysfunction generated by vascular lesions may largely contribute to the development of coagulopathy, such as described in trauma-induced coagulopathy. This endotheliopathy of the AAS has never been evaluated. The coagulopathy of AAS and more specifically the endotheliopathy are poorly described and therefore have no standardized treatment. The main objective of this study is to describe the coagulopathy
Injury is the leading cause of death for people between the ages of 1-44. This is especially true in trauma patients who have bleeding complications. Acute trauma coagulopathy (ATC) is associated with high transfusion requirements, longer ICU stays, and a greater incidence of multi-organ dysfunction. The cause of coagulopathy is multi-factorial. One major driver is acquired fibrinogen deficiency (hypofibrinogenemia). Fibrinogen is critical in clot formation and enhances platelet aggregation. Due to the body's limited reserve, it is the first clotting factor to fall to critical levels during life-threatening bleeding. This can impair coagulation and increases bleeding complications. There are two primary options available for fibrinogen supplementation: - Cryoprecipitate- North American standard - Fibrinogen Concentrate (FC)- European standard Consumption of coagulation factors, including fibrinogen, is another important component of ATC. To replenish these depleted coagulation factors and improve thrombin generation, two therapies are available: - Frozen Plasma (FP)- North American standard - Prothrombin Complex Concentrate (PCC)- European standard Strategies for hemorrhage and coagulopathy treatment have changed significantly over the last decade. Prompt hemorrhage control, along with targeted coagulation factor replacement, are emerging as key components of trauma care. Currently, the initiation of a massive hemorrhage protocol (MHP) results in red blood cells (RBCs) and FP transfusions in a 1:1 or 2:1 ratio. Clotting factors are replaced via FP administration. Fibrinogen supplementation is administration after lab verification or at the clinician's discretion. MHP continues until the rate of hemorrhage is under control. FC and PCC have several important advantages over cryoprecipitate and FP but there is a scarcity of data regarding their efficacy and safety of their use in hemorrhaging trauma patients. The FiiRST-2 study aims to understand if early use of FC and PCC in trauma patients at risk of massive hemorrhage will lead to superior patient outcomes. This trial will also provide safety data on early administration of FC and PCC as a first-line hemostatic therapy in trauma care, and its impact on hemostatic and other clinical endpoints.
SARS-CoV-2 infection seems to induce in most critical cases an excessive and aberrant hyper-inflammatory host immune response that is associated with a so-called "cytokine storm", moreover pro-thrombotic derangements of haemostatic system is another common finding in most severe forms of COVID19 infections, which may be explained by the activation of coagulative cascade primed by inflammatory stimuli, in line with what is observed in many other forms of sepsis. Targeting inflammatory responses exploiting steroids' anti-inflammatory activity along with thrombosis prevention may be a promising therapeutic option to improve patients' outcome. Despite the biological plausibility, no good evidence is available on the efficacy and safety of heparin on sepsis patients, and many issues have to be addressed, regarding the proper timing, dosages and administration schedules of anticoagulant drugs. The primary objective is to assess the hypothesis that an adjunctive therapy with steroids and unfractionated heparin (UFH) or with steroids and low molecular weight heparin (LMWH) are more effective in reducing any-cause mortality in critically-ill patients with pneumonia from COVID- 19 infection compared to low molecular weight heparin (LMWH) alone. Mortality will be measured at 28 days. The study is designed as a multicenter, national, interventional, randomized, investigator sponsored, three arms study. Patients, who satisfy all inclusion criteria and no exclusion criteria, will be randomly assigned in a ratio 1:1:1 to one of the three treatment groups: LMWH group, LMWH+steroids or UFH+steroid group. A possible result showing the efficacy of the composite treatment in reducing the mortality rate among critically ill patients with pneumonia from COVID-19 infection will lead to a revision of the current clinical approach to this disease.
The prognosis of traumatized hemorrhages is correlated with the nature of transfusion therapy: a 50% reduction in mortality for an early and massive supply of plasma, and 20% for an early and massive supply of platelets. However, this strategy encounters logistical difficulties, particularly in a context of collective emergency (attacks). The use of whole blood, widely documented by the Armed Forces, improves the availability of plasma and platelets, and simplifies handling by the various actors in the chain. T-STORHM is a randomized, controlled, parallel clinical trial.This study tests non-inferiority of whole blood transfusion therapy in the management of coagulopathy in patients with acute traumatic hemorrhage.
The purpose of the study is to find out the incidence of trauma induced coagulopathy in patients with severe trauma who received fibrinogen prior admission to emergency department during prehospital care.
1. Haemorrhage in severe trauma is a significant cause of mortality and is potentially the most preventable cause of death in paediatric trauma patients 2. Trauma Induced Coagulopathy (TIC) is a complex coagulopathy associated with severe trauma 3. Hypo/dysfibrinogenaemia plays an important role in TIC 4. Early replacement of fibrinogen may improve outcomes 5. Fibrinogen replacement is potentially inadequate in standard fixed ratio Major Haemorrhage Protocols (MHP) utilising Plasma and/or Cryoprecipitate 6. The majority of centres utilise cryoprecipitate for additional fibrinogen supplementation as part of a MHP 7. Cryoprecipitate administration is often delayed (between 60 - 120 minutes) in a fixed ratio MHP 8. It is clear early intervention in severe traumatic haemorrhage is associated with improved outcomes - CRASH 2 and PROPPR studies 9. Increasing interest in the use of Fibrinogen Concentrate (FC) in severe bleeding but not supported by high level evidence 10. Benefits of FC - viral inactivation, known dose, easily reconstituted, can be administered quickly in high dose and stored at room temperature in the trauma resuscitation bay 12. No previous studies comparing FC and Cryoprecipitate in bleeding paediatric trauma patients 13. Fibrinogen supplementation will be guided by an accepted ROTEM targeted treatment algorithm 14. Pilot, multi-centre randomised controlled trial comparing FC to Cryoprecipitate (current standard practise in fibrinogen supplementation) 15. Hypothesis: Fibrinogen replacement in severe traumatic haemorrhage can be achieved quicker with a more predictable dose response using Fibrinogen Concentrate compared to Cryoprecipitate 16. It is imperative that robust and clinically relevant trials are performed to investigate fibrinogen supplementation in paediatric trauma patients before widespread adoption makes performing such studies unfeasible