Spectrum and detection of musculoskeletal findings on trauma-related CT torso examinations

Early detection of severe injuries after major trauma by immediate total-body CT scouts

INTRODUCTION

Evaluation of immediate total-body CT (iTBCT) scouts during primary trauma care could be clinically relevant for early detection and treatment of specific major injuries. The aim of this study was to determine the diagnostic usefulness of TBCT scouts in detecting life-threatening chest and pelvic injuries.

METHODS

All patients who underwent an iTBCT during their primary trauma assessment in one trauma center between April 2011 and November 2014 were retrospectively included. Two experienced trauma surgeons and two emergency radiologists evaluated iTBCT scouts with structured questionnaires. Inter-observer agreement and diagnostic properties were calculated for endotracheal tube position and identification of pneumo- and/or hemothorax and pelvic fractures. Diagnostic properties of iTBCT scouts for indication for chest tube placement and pelvic binder application were calculated in comparison to decision based on iTBCT.

RESULTS

In total 220 patients with a median age of 37 years (IQR 26-59) were selected with a median Injury Severity Score of 18 (IQR 9-27). There was moderate to substantial inter-observer agreement and low false positive rates for pneumo- and/or hemothorax and for severe pelvic fractures by iTBCT scouts. For 19.8%-22.5% of the endotracheal intubated patients trauma surgeons stated that repositioning of the tube was indicated. Positive predictive value and sensitivity were respectively 100% (95%CI 52%-100%) and 50% (95%CI 22%-78%) for decisions on chest tube placement by trauma surgeon 1 and 67% (95%CI 13%-98%) and 22% (95%CI 4%-60%) for decisions by trauma surgeon 2. Only in one of 14 patients the pelvic binder was applied after iTBCT acquisition.

CONCLUSIONS

iTBCT scouts can be useful for early detection of pneumo- and/or hemothorax and severe pelvic fractures. Decision for chest tube placement based on iTBCT scouts alone is not recommended.

Emergency imaging after a mass casualty incident: role of the radiology department during training for and activation of a disaster management plan

In the setting of mass casualty incidents (MCIs), hospitals need to divert from normal routine to delivering the best possible care to the largest number of victims. This should be accomplished by activating an established hospital disaster management plan (DMP) known to all staff through prior training drills. Over the recent decades, imaging has increasingly been used to evaluate critically ill patients. It can also be used to increase the accuracy of triaging MCI victims, since overtriage (falsely higher triage category) and undertriage (falsely lower triage category) can severely impact resource availability and mortality rates, respectively. This article emphasizes the importance of including the radiology department in hospital preparations for a MCI and highlights factors expected to influence performance during hospital DMP activation including issues pertinent to effective simulation, such as establishing proper learning objectives. After-action reviews including performance evaluation and debriefing on issues are invaluable following simulation drills and DMP activation, in order to improve subsequent preparedness. Historically, most hospital DMPs have not adequately included radiology department operations, and they have not or to a little extent been integrated in the DMP activation simulation. This article aims to increase awareness of the need for radiology department engagement in order to increase radiology department preparedness for DMP activation after a MCI occurs.

Pediatric trauma care with computed tomography--criteria for CT scanning

Trauma centers, trauma management concepts, as well as integration of whole-body computed tomography (CT) reduced mortality significantly. The accuracy of a trauma care algorithm with emergency CT in children was evaluated. Data of 71 children with emergency CT were recorded retrospectively. In addition to epidemiological data admission date, kind of CT scan, mechanism of injury, missed diagnoses, injury severity score (ISS), admission to and time on intensive care unit (ICU), and time of hospitalization were observed. The algorithm for CT scanning was based on mechanism of injury, pattern of injury, and altered vital signs. Sixty-nine percent of the children reached the ER during on-call service hours. A percentage of 32.4 received a whole-body scan and 67.6 % a cranial scan. The mean ER ISS was 9.9 points (1-57). Children have different trauma mechanisms compared to adults. A percentage of 33.8 of the children had relevant trauma related findings in the CT scan. In 2 children, (2.8 %) 3 diagnoses (2.2 %) were initially missed. After reevaluation of the CT data, all diagnoses were identified. Thus, the accuracy of our algorithm in children was 100 %. In children, our algorithm detected all injuries, but only one third of the children had relevant trauma related findings in the CT scan. In order to reduce radiation exposure but preserve the advantages of CT, a new algorithm was developed with more flexibility taking the child's age and mental status more into account as well as clinical findings. The mechanism of injury itself is not anymore an indication for CT scanning.