BACKGROUND: The coagulopathy noted in hypothermic trauma patients has been variously theorized to be caused by either enzyme inhibition, platelet alteration, or fibrinolytic processes, but no study has examined the possibility that all three processes may simultaneously contribute to coagulopathy, but are perhaps triggered at different levels of hypothermia. The purpose of this study was to determine whether, at clinically common levels of hypothermia (33.0-36.9 degrees C), there are specific temperature levels at which coagulopathic alterations are seen in each of these processes. METHODS: Of 232 consecutive adult trauma patients presenting to a Level I trauma center, 112 patients met the inclusion criteria of an Injury Severity Score of 9 or greater and time since injury of less than 2 hours. Of the included patients, 40 were normothermic and 72 were hypothermic (> or =37 degrees C, n = 40; 36.9-36 degrees C, n = 29; 35.9-35 degrees C, n = 20; 34.9-34 degrees C, n = 16; 33.9-33 degrees C, n = 7). Included patients were prospectively studied with thrombelastography adjusted to core body temperature. Additionally, PT, aPTT, platelets, CO2, hemoglobin, hematocrit, and Injury Severity Score were measured. RESULTS: Analysis by multivariate analysis of variance of the relationship between coagulation and temperature demonstrated that in hypothermic trauma patients, 34 degrees C was the critical point at which enzyme activity slowed significantly (p < 0.0001), and at which significant alteration in platelet activity was seen (p < 0.001). Fibrinolysis was not significantly affected at any of the measured temperatures (p > 0.25). CONCLUSIONS: Patients whose temperature was > or =34.0 degrees C actually demonstrated a significant hypercoagulability. Enzyme activity slowing and decreased platelet function individually contributed to hypothermic coagulopathy in patients with core temperatures below 34.0 degrees C. All the coagulation measures affected are part of the polymerization process of platelets and fibrin, and this process may be the mechanism by which the alteration in coagulation occurs.
BACKGROUND: The coagulopathy noted in hypothermic traumapatients has been variously theorized to be caused by either enzyme inhibition, platelet alteration, or fibrinolytic processes, but no study has examined the possibility that all three processes may simultaneously contribute to coagulopathy, but are perhaps triggered at different levels of hypothermia. The purpose of this study was to determine whether, at clinically common levels of hypothermia (33.0-36.9 degrees C), there are specific temperature levels at which coagulopathic alterations are seen in each of these processes. METHODS: Of 232 consecutive adult traumapatients presenting to a Level I trauma center, 112 patients met the inclusion criteria of an Injury Severity Score of 9 or greater and time since injury of less than 2 hours. Of the included patients, 40 were normothermic and 72 were hypothermic (> or =37 degrees C, n = 40; 36.9-36 degrees C, n = 29; 35.9-35 degrees C, n = 20; 34.9-34 degrees C, n = 16; 33.9-33 degrees C, n = 7). Included patients were prospectively studied with thrombelastography adjusted to core body temperature. Additionally, PT, aPTT, platelets, CO2, hemoglobin, hematocrit, and Injury Severity Score were measured. RESULTS: Analysis by multivariate analysis of variance of the relationship between coagulation and temperature demonstrated that in hypothermic traumapatients, 34 degrees C was the critical point at which enzyme activity slowed significantly (p < 0.0001), and at which significant alteration in platelet activity was seen (p < 0.001). Fibrinolysis was not significantly affected at any of the measured temperatures (p > 0.25). CONCLUSIONS:Patients whose temperature was > or =34.0 degrees C actually demonstrated a significant hypercoagulability. Enzyme activity slowing and decreased platelet function individually contributed to hypothermic coagulopathy in patients with core temperatures below 34.0 degrees C. All the coagulation measures affected are part of the polymerization process of platelets and fibrin, and this process may be the mechanism by which the alteration in coagulation occurs.
Authors: Myung S Park; Barbara A L Owen; Beth A Ballinger; Michael G Sarr; Henry J Schiller; Scott P Zietlow; Donald H Jenkins; Mark H Ereth; Whyte G Owen; John A Heit Journal: Surgery Date: 2012-02-07 Impact factor: 3.982
Authors: Peter V Giannoudis; Martijn van Griensven; Frank Hildebrand; Christian Krettek; Hans-Christoph Pape Journal: Clin Orthop Relat Res Date: 2008-01-10 Impact factor: 4.176
Authors: Ales Krouzecky; Jiri Chvojka; Roman Sykora; Jaroslav Radej; Thomas Karvunidis; Ivan Novak; Jiri Ruzicka; Zuzana Petrankova; Jiri Benes; Lukas Bolek; Martin Matejovic Journal: Intensive Care Med Date: 2008-09-18 Impact factor: 17.440
Authors: Enno D Wildschut; Annewil van Saet; Pavla Pokorna; Maurice J Ahsman; John N Van den Anker; Dick Tibboel Journal: Pediatr Clin North Am Date: 2012-08-29 Impact factor: 3.278