Emergency (****); * (*): *-* This open-access article distributed under the terms of the Creative Commons Attribution Non Commercial 3.0 License (CC BY-NC 3.0). Copyright © 2016 Shahid Beheshti University of Medical Sciences. All rights reserved. Downloaded from: www.jemerg.com 29 Emergency (2016); 4 (1): 29-33 ORIGINAL RESEARCH Diagnostic Accuracy of Ultrasonography and Radiography in Initial Evaluation of Chest Trauma Patients Ali Vafaei1, Hamid Reza Hatamabadi2, Kamran Heidary1, Hosein Alimohammadi2, Mohammad Tarbiyat2* 1. Department of Emergency medicine, Loghman Hakim Hospital, Shahid Beheshti University of Medical Sciences, Tehran, Iran. 2. Department of Emergency medicine , Imam Hossein Hospital, Shahid Beheshti University of Medical Sciences, Tehran, Iran. *Corresponding Author: Mohammad Tarbiyat; Emergency Department, Loghman Hakim Hospital, Kamali Street, Karegar Avenue, Tehran, Iran. Tel: +989133089597 / Fax: +982155415539 / E-mail: mohammadtarbiat@yahoo.com Received: April 2015; Accepted: June 2015 Abstract Introduction: Application of chest radiography for all multiple trauma patients is associated with a significant in- crease in total costs, exposure to radiation, and overcrowding of the emergency department. Ultrasound has been introduced as an alternative diagnostic tool in this regard. The aim of the present study is to compare the diagnostic accuracy of chest ultrasonography and radiography in detection of traumatic intrathoracic injuries. Methods: In the present prospective cross-sectional study, patients with traumatic intrathoracic injuries, who were referred to the emergency department from December 2013 to December 2014, were assessed. The patients underwent bed- side ultrasound, radiographic and computed tomography (CT) scan examinations based on ATLS recommenda- tions. Screening performance characteristics of ultrasonography and radiography were compared using SPSS 21.0. Chest CT scan was considered as gold standard. Results: 152 chest trauma patients with a mean age of 31.4 ± 13.8 years (range: 4 ‒ 67), were enrolled (77.6% male). Chest CT scan showed pulmonary contusion in 48 (31.6%) pa- tients, hemothorax in 29 (19.1%), and pneumothorax in 55 (36.2%) cases. Area under the ROC curve of ultraso- nography in detection of pneumothorax, hemothorax, and pulmonary contusion were 0.91 (95% CI: 0.86‒0.96), 0.86 (95% CI: 0.78‒0.94), and 0.80 (95% CI: 0.736‒0.88), respectively. Area under the ROC curve of radiography was 0.80 (95% CI: 0.736‒0.87) for detection of pneumothorax, 0.77 (95% CI: 0.68‒0.86) for hemothorax, and 0.58 (95% CI: 0.5‒0.67) for pulmonary contusion. Comparison of areas under the ROC curve declared the significant superiority of ultrasonography in detection of pneumothorax (p = 0.02) and pulmonary contusion (p < 0.001). However, the diagnostic value of the two tests was equal in detection of hemothorax (p = 0.08). Conclusion: The results of the present study showed that ultrasonography is preferable to radiography in the initial evaluation of patients with traumatic injuries to the thoracic cavity. Key words: Thoracic cavity; wounds and injuries; diagnostic imaging; ultrasonography; radiography Cite this article as: Vafaei A, Hatamabadi HR, Heidary K, Alimohammadi H, Tarbiyat M. Diagnostic accuracy of ultraso- nography and radiography in initial evaluation of chest trauma patients. Emergency. 2016;4(1):29-33. Introduction: Trauma is the most important cause of death during the first four decades of life (1). In this context, traumatic in- trathoracic injuries comprise 25-40% of mortalities (2). Prompt diagnosis of such injuries can decrease mortality and the resultant burden. Computed tomography (CT) scan is the gold standard for this diagnosis (3-5). Alt- hough this diagnostic tool is highly accurate in detection of intrathoracic injuries, patients undergoing CT scan ex- amination receive a high radiation dose (6-8). Currently, chest radiography is used as the initial diagnostic tool in these cases. Although these techniques are inexpensive and non-invasive, their application for all multiple trauma patients is associated with a significant increase in total costs, exposure to radiation, and overcrowding of the emergency department (9). Some recent studies have reported not very high sensitivity and specificity of chest radiography in this regard (10-13). These studies have shown the low diagnostic yield of chest x-rays (6.3‒ 12.4%) in identifying intrathoracic injuries (9, 14-16). During recent years, chest ultrasonography has been in- troduced as a portable, inexpensive, safe, and fast alter- native for radiography in detection of traumatic in- trathoracic injuries (17). However, this tool is largely de- pendent on the experience and expertise of the operator and its results are not very reliable in identifying paren- chymal injuries and where no fluid is present (18). Based on the above-mentioned points, the present study was designed to compare the diagnostic accuracy of chest ul- trasonography and radiography in identifying traumatic intrathoracic injuries. This open-access article distributed under the terms of the Creative Commons Attribution Non Commercial 3.0 License (CC BY-NC 3.0). Copyright © 2016 Shahid Beheshti University of Medical Sciences. All rights reserved. Downloaded from: www.jemerg.com Vafaei et al 30 Methods: Study design and setting In the present prospective cross-sectional study, pa- tients with traumatic intrathoracic injuries, who were referred to the emergency department of Imam Hossein Hospital, from December 2013 to December 2014, were assessed. The study was done to calculate the diagnostic accuracy of chest ultrasonography and radiography in the initial evaluation of patients with chest trauma. Tho- racic CT scan was used as the gold standard. All patients in need for chest CT scan based on standard indications of advanced trauma life support (ATLS) guidelines were included in a consecutive manner. Exclusion criteria con- sisted of pregnancy, hemodynamic instability, and lack of interest in participating in the study. Chest ultraso- nography and data collection were carried out by an emergency medicine specialist. Chest x-ray and CT scan were reported by two radiologists separately, who were blinded to the clinical findings of patients and aim of study. The protocol of the study was approved by the Ethics Committee of Shahid Beheshti University of Med- ical Sciences. The researchers adhered to the guidelines of Helsinki Declaration throughout the study proce- dures. The protocol of the study did not interfere with the patients’ therapeutic and diagnostic procedures and the patients were not exposed to any risks. The data col- lection forms were anonymous and a code was assigned to each patient. All the patients submitted an informed consent form before being included in the study. Measurements Demographic (age, gender, and mechanism of trauma) and clinical data, as well as imaging findings of each pa- tient were recorded using a checklist. Immediately after collection of data, the patients underwent chest ultraso- nography, which was carried out using a bedside ultra- sonography unit (Honda, HS 2100) and 3.5-7 MHz linear and curvilinear transducers. Examinations were carried out at 2‒6 intercostal spaces on both sides of para-ster- nal, mid-clavicular, anterior axillary and mid-axillary lines. Then, the patients underwent an anterior posterior (AP) chest x-ray examination using a portable x-ray ma- chine (Poxible, 100 BP-OP) and chest CT scan (Siemens, Emotion-16, 5-mm-thick slices) in supine position. Pneu- Table 1: Baseline characteristics of the studied participants Variable Frequency Percentage Age Under 18 24 15.8 19‒40 92 60.5 41‒60 27 17.8 Over 60 9 6.9 Gender Male 118 77.6 Female 34 22.4 Mechanism of trauma Penetrating wound 22 14.5 Blunt trauma due to accident 93 61.2 Blunt trauma due to falling 23 15.1 Blunt trauma due to direct impact 14 9.2 Subcutaneous emphysema No 133 86.2 Yes 21 13.8 Crepitation No 131 86.2 Yes 21 13.8 Trauma to thoracic spinal No 137 90.1 Yes 15 9.9 Glasgow coma scale 14‒15 96 63.1 9‒13 39 25.7 3‒8 17 11.2 Hemodynamic status Stable 125 82.2 Unstable 27 17.8 This open-access article distributed under the terms of the Creative Commons Attribution Non Commercial 3.0 License (CC BY-NC 3.0). Copyright © 2016 Shahid Beheshti University of Medical Sciences. All rights reserved. Downloaded from: www.jemerg.com 31 Emergency (2016); 4 (1): 29-33 mothorax, hemothorax, rib fracture, and pulmonary con- tusion were considered as traumatic intrathoracic inju- ries. Statistical analysis The sample size was calculated to be 139 cases by con- sidering a minimum sensitivity of 98% for the ultraso- nography in detection of traumatic intrathoracic injuries and a 30% prevalence rate of pneumothorax in patients with chest trauma (19), at 95% confidence interval (α = 0.05), a power of 90% (β = 0.1) and maximum error of 1% (d = 0.12). Data were analyzed with SPSS 21.0. In or- der to evaluate the adequacy of radiography and ultraso- nography, receiver operating characteristic (ROC) curves were drawn and sensitivity, specificity, positive and negative likelihood ratio and positive and negative predictive values of radiography and ultrasonography were calculated. Significance level was set at p < 0.05. Results: 152 chest trauma patients with a mean age of 31.4 ± 13.8 years (range: 4 ‒ 67), were enrolled (77.6% male). Table 1 presents baseline characteristics of patients. Chest CT scan showed pulmonary contusion in 48 (31.6%) pa- tients, hemothorax in 29 (19.1%), and pneumothorax in 55 (36.2%) cases. Table 2 summarizes the screening per- formance characteristics of chest ultrasonography and radiography in detection of traumatic intrathoracic inju- ries (pneumothorax, hemothorax, contusion). Area un- der the ROC curve of ultrasonography in detection of pneumothorax, hemothorax, and pulmonary contusion were 0.91 (95% CI: 0.86‒0.96), 0.86 (95% CI: 0.78‒ 0.94), and 0.80 (95% CI: 0.736‒0.88), respectively. Area under the ROC curve of radiography was 0.80 (95% CI: 0.736‒0.87) for detection of pneumothorax, 0.77 (95% CI: 0.68‒0.86) for hemothorax, and 0.58 (95% CI: 0.5‒ 0.67) for pulmonary contusion. Comparison of areas un- der the ROC curve declared the significant superiority of ultrasonography in detection of pneumothorax (p = 0.02) and pulmonary contusion (p < 0.001). However, the diagnostic value of the two tests was equal in detec- tion of hemothorax (p = 0.08). Discussion: The results of the present study showed that chest ultra- sonography had higher diagnostic value in detection of pneumothorax and pulmonary contusion compared to radiography. This value in detection of hemothorax for two studied tools was equal. Various studies have evalu- ated the diagnostic accuracy of ultrasonography in trauma patients (20, 21). In this context, Hyacinthe et al. showed that the diagnostic accuracy of ultrasonography was higher than that of chest x-ray. The study showed that the sensitivity and specificity of ultrasonography, compared to CT scan as the gold standard, in diagnosis of thoracic cavity lesions were in the 37‒61% and 61‒ 96% ranges, respectively (22). In the present study, the emergency medicine specialist who carried out ultraso- nography examinations was aware of clinical findings Table 2: Screening performance characteristics of chest ultrasonography and radiography in detection of trau- matic intrathoracic injuries in comparison to CT scan Index Ultrasonography Chest x-ray Pneumothorax Sensitivity 83.6 (70.7‒91.8) 67.3 (53.2‒78.95) Specificity 97.9 (92.0‒99.6) 92.7 (85.1‒96.8) Positive predictive value 95.8 (84.6‒99.3) 84.1 (69.3‒92.8) Negative predictive value 91.3 (83.8‒95.7) 83.2 (74.5‒89.5) Positive likelihood ratio 45.6 (10.2‒160.7) 9.2 (4.4‒19.3) Negative likelihood ratio 0.17 (0.09‒0.3) 0.35 (0.24‒0.52) Hemothorax Sensitivity 75.9 (56.1‒90.0) 58.6 (39.1‒75.9) Specificity 95.9 (90.3‒98.5) 95.1 (89.2‒98.0) Positive predictive value 81.5 (88.4‒97.5) 73.9 (51.3‒88.9) Negative predictive value 94.4 (88.4‒97.5) 90.7 (84.0‒94.9) Positive likelihood ratio 18.7 (7.7‒45.1) 12.0 (5.2‒27.8) Negative likelihood ratio 0.25 (0.13‒0.48) 0.1 (0.06‒0.18) Pulmonary contusion Sensitivity 68.8 (53.6‒80.9) 43.8 (29.8‒58.7) Specificity 92.3 (84.9‒96.4) 73.1 (63.3‒81.1) Positive predictive value 80.5 (64.6‒90.6) 42.8 (29.1‒57.7) Negative predictive value 86.5 (78.4‒92.0) 73.7 (64.0‒81.7) Positive likelihood ratio 8.9 (4.5‒17.7) 1.6 (1.0‒2.55) Negative likelihood ratio 0.34 (0.2‒0.52) 0.77(0.6‒0.99) This open-access article distributed under the terms of the Creative Commons Attribution Non Commercial 3.0 License (CC BY-NC 3.0). Copyright © 2016 Shahid Beheshti University of Medical Sciences. All rights reserved. Downloaded from: www.jemerg.com Vafaei et al 32 and could, concentrate on areas with higher odds of in- juries to some extent. However, in the Hyacinthe et al. study a blinded specialist carried out ultrasonography, which might be the reason for the higher sensitivity rate in the present study. Wilkerson and Stone meta-analysis reported a sensitivity of 85‒100% for ultrasonography in diagnosis of thoracic cavity injuries (10). Other stud- ies, have also reported similar findings (23, 24). The dif- ferences might be attributed to inclusion and exclusion criteria of the studies. Those studies have excluded pa- tients with subcutaneous emphysema and intubated pa- tients. Subcutaneous emphysema interferes with exami- nation of the parietal pleura using ultrasonography, making it difficult to identify hemothorax or pneumotho- rax in these areas. On the other hand, in the present study there was about 1‒2-hour time interval between ultrasonography and CT scan examinations. During this time, the lesions might have extended to reach a size that could make diagnose them easier. An attempt was made in this study to evaluate the diagnostic accuracy of ultra- sonography as an alternative to x-ray. Comparison of the results of these two techniques with those of CT scan showed that ultrasonography is superior to chest x-ray in initial evaluations. However, ultrasonography alone has a lower diagnostic value. Therefore, it is advisable to find ways to increase the efficacy and accuracy of the ul- trasonography technique. One of these ways is to com- bine ultrasonography with other indexes used for the di- agnosis of traumatic lesions (25). This needs to be stud- ied further. Conclusion: The results of the present study showed that ultrasonog- raphy is preferable to radiography in the initial evalua- tion of patients with traumatic injuries to the thoracic cavity. However, the low sensitivity of the ultrasonogra- phy technique in comparison to CT scan, its reliance on operator skill, and some other limitations have made it only an initial test, necessitating confirmation using other techniques. Acknowledgments: We are pleased to acknowledge from all staff of Imam Hossein Hospital for their contribution in the present study. Conflict of interest: We declare that the authors of this article have no com- peting interests. Funding support: None. Authors’ contributions: All authors met four criteria for authorship contribution based on recommendations of the International Commit- tee of Medical Journal Editors. References: 1. Søreide K. Epidemiology of major trauma. Br J Surg. 2009;96(7):697-8. 2. Heron M. Deaths: leading causes for 2008. Natl Vital Stat Rep. 2012;60(6):1-94. A B C Figure 1: Comparison of areas under the receiver op- erative characteristics curve in radiography and ultra- sonography for pneumothorax (A), hemothorax (B), and contusion (C). P value = 0.02 0 .0 0 0 .2 5 0 .5 0 0 .7 5 1 .0 0 S e n si ti v it y 0.00 0.25 0.50 0.75 1.00 1-Specificity CXR ROC area: 0.8003 CXR binormal fit Sonography ROC area: 0.9079 Sonography binormal fit Reference P value = 0.08 0 .0 0 0 .2 5 0 .5 0 0 .7 5 1 .0 0 S e n si ti v it y 0.00 0.25 0.50 0.75 1.00 1-Specificity Sonograohy ROC area: 0.859 Sonography binormal fit CXR ROC area: 0.7687 CXR binormal fit Reference P < 0.001 0 .0 0 0 .2 5 0 .5 0 0 .7 5 1 .0 0 S e n si ti v it y 0.00 0.25 0.50 0.75 1.00 1-Specificity CXR ROC area: 0.5841 CXR binormal fit Sonography ROC area: 0.8053 Sonography binormal fit Reference This open-access article distributed under the terms of the Creative Commons Attribution Non Commercial 3.0 License (CC BY-NC 3.0). 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