Objective To investigate the changes and roles of myocardial adenosine triphosphate enzyme(ATPase) in the mechanism of cardiac dysfunction after blunt chest trauma(BCT). Methods Thirtysix rabbits were divided into 6 groups with random number table, control group, 2 h group, 4 h group, 8 h group, 12 h group and 24 h group, 6 in each group. The models of BCT were established with BIMⅡ biological impact machine, catheterization technique was used through the right jugular artery into the left ventricle measure its pressure. The hemodynamics and the activities of ATPase in myocardial cell plasm, homogenate and mitochondria were measured at preinjury(control group), 2 h, 4 h, 8 h, 12 h and 24 h postinjury. Results Left ventricular endsystolic pressure(LVESP), the maximal ascending rate of left intraventricular pressure(+dp/dtmax), isovolemec pressure(IP) and the maximal physiological velocity(Vpm) decreased significantly at 2 h group after BCT(Plt;0.05), and recovered to preinjury level in 4 h, 8 h and 12 h group during 4-12 h after BCT; isovolumic relaxation phase left ventricular pressure descending time constant (T). Left ventricular enddiastolic pressure(LVEDP) and the maximal descending rate of left intraventricular pressure(-dp/dtmax) were significantly higher (Plt;0.05, 0.01). The activity of ATPase in homogenate, mitochondria and cell plasm decreased significantly at 2 h group and 4 h group after BCT(Plt;0.05, 001, respectively), and 8 h group and 12 h group recovered after BCT. There was negative correlations between [CM(159mm]LVEDP and -dp/dtmax and the decrease of the activity of Na+-K+-ATPase in homogenate(r=-0.674, -0.691, Plt;0.05), the Ca2+-ATPase in homogenate(r=-0.613,-0.642, Plt;0.05), the Na+-K+-ATPase in mitochondria(r=-0.622,-0.616, Plt;0.05),the Ca2+-ATPase in myocardial cell plasm(r=-0.672,-0.658, Plt;0.05), the Na+-K+-ATPase in myocardial cell plasm(r=-0.627,-0.632,Plt;0.05),and the Mg2+-ATPase in myocardial cell plasm(r=-0.677,-0.661, Plt;0.05). Conclusion The left ventricular function is impaired obviously after BCT, especially in diastolic phase. The decrease of the activity of ATPase in myocardial cells may be one of the reasons of cardiac dysfunction after BCT.
Objective To investigate the changed rules of the cardiac functions in rabbits and to provide theoretical gists for clinical diagnosis and treatment after blunt chest trauma(BCT). Methods Using the models of moderate to severe BCT with BIM-Ⅱ Bio-impactor in 20 rabbits to examinate the cardiac functions with cardiac catheterization, the single photonemission computed tomography(SPECT) and the Doppler echocardiography at preinjury and 1h, 2h, 4h, 6h, 8h, 12h and 24h after BCT. Results Central venous pressure( CVP), left ventricular enddiastolic pressure (LVEDP) and the decreasing time constant of left intraventricular pressure (T) at 24h after trauma were higher obviously than those before trauma (Plt;0.05,0.01). The -dp/dtmax at 24h after trauma was lower markedly than that before trauma (Plt;0.05 ). The ejection fraction(EF),1/3 EF, 1/3 ejection rate(1/3ER) and the ratio of 1/3 filling rate (1/3FR) to 1/3ER of the right ventricle at 24h after impacted were lower markedly than those before impacted (Plt;0.05). The peak filling rate, 1/3 filling fraction, 1/3 filling rate, the ratio of peak filling rate to peak ejection rate and the ratio of 1/3FR to 1/3ER of the left ventricular at 24h after impacted were lower obviously than those before impacted (Plt;0.05, 0.01). Conclusion The cardiac functions are changed significantly after BCT. The expressions of the right ventricular dysfunctions mainly are systolic dysfunction while the left ventricular dysfunctions are mainly diastolic dysfunction after BCT. All the cardiac catheterization, SPECT and the Doppler echocardiography are beneficial to the diagnosis of cardiac dysfunction after BCT. The SPECT is more exactitude and the Doppler echocardiography is more cheaper.
Objective To investigate the causes of death and evaluation of injury severity in patients with thoracic trauma so as to enhance the diagnosis and treatment of thoracic trauma. Methods A retrospective study was carried out in 687 patients with thoracic trauma, which were divided into different groups according to their condition of injury (chest injury group and multiple injuries group) and outcome (survival group and death group) and penetrating into pleural cavity (penetrating injury group and blunt trauma group), then trauma scores(revised trauma score,abbreviated injury scale,injury severity score,probability of survival)were compared respectively. In addition, the highrisk causes of trauma death were analyzed. Results Among 687 cases, there are 488 cases with blunt trauma and 199 cases with penetrating injury. The causes of trauma death in blunt trauma group were brain injury (10 cases) and acute respiratory failure (6 cases) and multiple organ dysfunction syndrome (4 cases) and hypovolemic shock (1 case). The causes of trauma death in penetrating trauma group were hypovolemic shock (9 cases). There were statistically difference of trauma score in the death group and the survival group(GCS:t=4.648,P=0.000; RTS:t=4.382,P=0.000;thoracic AIS:t=2.296,P=0.027;ISS:t=4.871,P=0.000; Ps:t=4.254,P=0.000). There was no statistically difference of thoracic AIS in the chest injury group and the multiple injuries group (t=0.723, P=34.567), and there were statistical significances in RTS(t=2.553,P=0.032), ISS(t=10.776,P=0.000), Ps(t=3.868,P=0.007). There were statistically difference of RTS(t=3.161,P=0.007)and ISS (t=4.118,P=0.005) in the blunt trauma survival group and penetrating injury survival group, and there was no statistical significance in Ps(t=0.857,P=97.453). The blunt trauma death group had statistical difference compared with penetrating injury death group in trauma score(GCS:t=4.016,P=0.001,RTS:t=3.168,P=0.006;thoracic AIS:t=2.303, P=0.043;ISS:t=4.218,P=0.002;Ps:t=4.624,P=0.001). The mortality of trauma was gradually increased with the trauma scores. The mortality was 10.7% when whole ISS was 20.25. The mortality in penetrating injury group was higher than that in blunt trauma group with the same ISS between two groups. Conclusion Applying trauma score is conducive to the judgement of trauma severity and optimizing clinical treatment. The death causes in blunt trauma group were more complex than in penetrating injury group. Severe trauma and multiple injuries are the main death causes of thoracic trauma.
Objective To explore the early diagnostic value of single photon emission computed tomography(SPECT), thoracic computed tomography(CT),and chest X-ray for closed chest trauma. Methods To establish the animal model of unilateral chest impact trauma,to adopt SPECT, thoracic CT, and chest X-ray for early diagnosis of closed chest trauma,and to compare these findings with postmortem examination. Results Thirty minutes after blunt chest trauma, the region of interesting (ROI) between traumatized lung and the heart (ROI2/ROI1) immediately increased to the peak six hours after trauma; on the contralateral lung, the ratio (ROI3/ROI1) increased slowly and reached the peak after six hours, these ratio was still smaller than that of the traumatized lung. These differences were significant (Plt;0.01). Conclusions Chest X-ray is still the most fundamental diagnostic method of chest trauma,but it was thought that the patients of severe chest trauma and multiple injuries should be examined early by thoracic CT. Radionuclide imaging have more diagnostic value than chest X-ray on pulmonary contusion. The diagnostic sensibility to pulmonary contusion of thoracic CT is superior to conventional radiograph,but thoracic CT is inferior to SPECT on exploring exudation and edema of pulmonary contusion. Thoracic CT is superior to conventional radiograph on diagnosis of chest trauma,therefore patients of severe chest trauma and multiple injuries should be adopted to thoracic CT examination at emergency room in order to be diagnosed as soon as possible.
The earliest record of chest trauma surgery was B.C 3000 years. Before 15th century, chest trauma surgery only focused on simple wound treatment of the chest wall. At the beginning of 20th century, treatment of organ injury in the thoracic cavity appeared. In the 50's-80's of the 20th century, complete structure and knowledge of modern chest trauma surgery came into being. Since the 90's of the 20th century, development of new techniques such as minimally invasive surgery, new concepts such as fast-track surgery and damage control surgery, new materials, multidisciplinary cooperation, Internet technology, and translational medicine all have contributed to outcome improvement of patients with chest trauma, and will contribute to the development of chest trauma surgery in the future.
Thoracic trauma has the characteristics of complexity, specificity, urgency and severity. Therefore, the treatment is particularly important. Thoracic Traumatology Group, Trauma Medicine Branch of Zhejiang Medical Association organized the writing of the thoracic trauma and further optimization consensus of Zhejiang thoracic surgery industry Treatment and diagnosis of rib and sternum trauma: A consensus statement by Zhejiang Association for Thoracic Surgery (version 2021), compiled the popular science book Emergency Treatment and Risk Avoidance Strategy of Thoracic Trauma and Illustration of Real Scene Treatment of Trauma, actively prepared to build the trauma database of Zhejiang Province, and participated in the construction of trauma group in the Yangtze River Delta. Although Zhejiang Province has carried out many related works in the diagnosis and treatment of chest trauma, it is still inconsistent with the development requirements of the times. Standardization of chest trauma treatment, popularization of relevant knowledge, management of trauma big data, grass-roots radiation promotion tour and further optimization of industry consensus are the requirements and objectives of this era.