TY - JOUR
AU - Stockinger, Zsolt
AB - Abstract Medical imaging plays a critical role in the rapid diagnosis, effective triage, and management of complex poly-trauma patients. High-quality medical imaging can be accomplished successfully in a deployed or wartime setting. Due to advances in aggressive resuscitation techniques and the speed of the latest generation computed tomography scanners (64-detector and beyond), rapid trauma scans utilizing computed tomography and ultrasound imaging can routinely be performed prior to taking the patient to the operating room potentially providing the trauma team with lifesaving information. This clinical practice guideline provides an overview of the imaging modalities available in austere settings, the equipment required, and the role that each plays in triaging and diagnosis of the acutely injured poly-trauma patients. Radiology, CT scan, imaging, poly-trauma, trauma scans, ultrasound INTRODUCTION Imaging has become a critical component of the care of any patient in the age of modern medicine. The goal of this manuscript is to provide guidelines and recommendations for the optimum integration of high-quality diagnostic imaging into the treatment and management of casualties with multiple mechanisms of traumatic injuries and how to facilitate the transfer of this information with the patient across the continuum of care. BACKGROUND Given the catastrophic injuries sustained by high-energy mechanisms, including high-velocity ballistic trauma and blast injuries often seen during the current conflict, rapid diagnosis and treatment is required to optimally treat these critically injured patients. Advances in aggressive resuscitation techniques and the speed of the latest generation computed tomography (CT) scanners (64-detector and beyond), rapid trauma scans utilizing CT and ultrasound (US) imaging routinely allows for imaging to be performed prior to taking the patient to the operating room potentially providing the trauma team with lifesaving information. Imaging Evaluation Radiographs The initial radiographic evaluation of a trauma patient begins with supine Anterior-Posterior (AP) chest and pelvis radiographs taken in the trauma bay usually with a portable X-ray machine. The initial focus being major cardiopulmonary injury and fracture dislocations of the pelvis, the latter can be an indicator of life-threatening internal hemorrhage and/or need for pelvic stabilization. Fragments Radiographs can easily demonstrate metallic fragments common in military specific trauma that can be helpful in determining potential sites of injury and injury tracts. Cervical Spine Cervical spine radiographic evaluation has been largely replaced by CT and should only be performed when a CT is unavailable. Refer to the JTS CPG, Cervical and Thoracolumbar Spine Injury Evaluation, Transport, and Surgery in the Deployed Setting, for further guidance.1,2 Extremity Injuries If extremity injury is suspected, radiographs can be obtained; however, these can be time-consuming and should not delay more diagnostic imaging with CT, if available. Additionally with CT, extremity osseous and soft tissue injuries can be easily identified with the added benefit of a lower extremity angiogram as well. See Trauma CT Scan section below.3 Retrograde Urethrogram When there is a clinical suspicion of possible urethral injury, which can occur with significant pelvic fractures or penetrating perineal injury, a retrograde urethrogram may be helpful to further characterize the injury. One field expedient method uses the portable x-ray machine with a single oblique AP scout image of the pelvis. 10 cc of contrast is injected into the tip of the urethra through a Foley catheter. While injecting additional contrast through the catheter an image of the pelvis/urethra is obtained in the same slight AP oblique position. This image is typically obtained at the end of an injection of 17–20 cc of IV contrast but prior to the completion of the injection to insure full luminal distention with contrast. Equipment A variety of portable X-ray units are utilized in theater at Roles 2 and 3 facilities. Many of the portable units, especially at the Role 2, have limited ability to penetrate (limited range of kVp and mAs) soft tissues. Obtaining lateral views generally requires penetrating a greater thickness of soft tissue, particularly in large patients, and often produces very limited quality images. AP projection images should be adequate on most portable units, but will rely upon the X-ray technician to optimize technique to maximize image quality. Radiation Safety Members of the trauma team should have lead aprons and thyroid shields available near the trauma bay. In ideal situations, trauma team members will do the lead shielding beneath other personal protective equipment prior to patient arrival. Distance is also protective from radiation exposure. If feasible based on the patient’s condition, any personnel without lead shielding should move a short distance (recommended minimal distance 6 feet) away from the X-ray unit. Cross table lateral images produce a much higher level of radiation exposure to personnel in the trauma bay and nearby areas and should only be obtained when absolutely necessary. Focused Assessment with Sonography for Trauma Examination While the Focused Assessment with Sonography for Trauma (FAST) scan has been validated only in hemodynamically unstable blunt trauma patients, it has become a standard tool in the trauma bay and Emergency Department (ED) in most trauma patients.4 It is now considered an adjunct to the primary survey in Advanced Trauma Life Support (ATLS) guidelines, ninth edition.5 It has also come into use for hemodynamically stable patients and penetrating trauma in the deployed setting where CT scans are not readily available. If positive, these scans provide quick information that can aid trauma surgeons in triaging patients, either to the Operating Room (OR) or to further imaging. FAST in combat trauma has a sensitivity of only 56% and specificity of 98%.6 Routine use of the FAST in trauma patients allows for a consistent evaluation strategy while maintaining the skills of providers. A negative FAST cannot be relied upon to rule out injury, even in penetrating trauma. Diagnostic Peritoneal Lavage In the absence of a CT scanner, diagnostic peritoneal lavage (DPL) should be considered in determining need for laparotomy in trauma patients. It has largely been supplanted by the FAST exam (and is considered an optional skill in the current edition of ATLS). DPL remains the most sensitive test for hollow viscus injury and mesenteric injury, and retains its usefulness in the unstable patient with a negative or equivocal FAST exam. DPL is 100% accurate for intra-abdominal injury in these patients.7 One must consider the additional time that this diagnostic test may require, and should not delay immediate surgical intervention in patients that have mechanisms concerning for intra-abdominal trauma and remain unstable despite resuscitative measures.8 Role of the Radiologist At the Role 3, properly trained providers including radiologists, surgeons and emergency physicians, can perform and interpret FAST scans in the ED on a hand-held portable U.S. device. The utility of radiologists performing the exams would be to free up emergency providers and surgeons to either perform other assessments or interventions, or care for additional patients in the trauma bays. While in the trauma bay, the radiologist would also be available to provide preliminary interpretations of the portable chest X-ray/pelvis exams on the digital portable machines. However, once CT scans begin to be obtained on the trauma patients, the emergency physicians and surgeons would primarily perform the FAST scans and interpret plain radiographs at the bedside. Equipment The examination is performed with a portable hand-held machine most commonly using a standard 3–7 MHz curved array U.S. probe. A phased array probe is also acceptable, and occasionally is preferred if cardiac or pulmonary imaging is necessary. Real-time imaging is performed without the necessity of saving static images. Standard Examination The standard FAST examination is focused on evaluating for the presence of free intraperitoneal fluid in: The right upper quadrant between the liver and kidney. The left upper quadrant between the spleen and kidney. The pelvis at the level of the bladder. An evaluation for cardiac activity and hemopericardium/tamponade should also be performed by placing the probe in the subxiphoid location and aiming towards the patients left shoulder.4 Additional Examination The cardiac portion of the exam can rapidly identify cardiac injury, evaluate cardiac function and give information about the success of resuscitation.9 In the case of massive exsanguination; the examination should be rechecked for free fluid after blood is given. A clot identified within a ventricle indicates prolonged asystole and may aid in the decision to terminate efforts. Pneumothorax or hemothorax may also be identified by placing the probe along the chest wall and looking for the presence of lung sliding. Loss of sliding implies the possible presence of a pneumothorax.10 Trauma CT Scan If at all possible given the patient’s clinical stability, a trauma CT can be performed before going to OR. Often indications for surgical intervention are already present; however the CT scan can provide additional information to the surgeon, identifying unsuspected and potentially clinically significant injuries. Given the relatively small footprint of most Role 3 facilities the patient can be taken to the OR immediately following the acquisition of the CT scan, with the radiologist providing the pertinent findings to surgeons while in the OR. For clinically unstable patients, this trauma CT can be obtained after continued resuscitation and surgical intervention in the OR.11 CT Protocol (Adult) Initial acquisition includes non-contrast CT through head and face (to include the entire mandible), at 1 mm axial slice thickness which allows for isotropic sagittal and coronal reformatted images. This scan is followed by a contrast enhanced CT from the level of the circle of Willis through the bottom of the pelvis. Alternatively in the setting of significant lower extremity trauma such as dismounted complex blast injury, the scan can be performed through the lower extremities (default through the feet) allowing evaluation of skeletal and vascular injury of the lower extremities. A discussion with the trauma team should be performed prior to the scan to establish the inferior extent of the scan coverage. Of course, additional information including long bone fractures and metallic fragments can be seen on the scout image, which may alter the scan coverage to include those areas. Some difficulties may arise if the patient is tall and the CT gantry movement does not allow coverage through the lower extremities, however this can be ameliorated by scanning from the head to as low as possible, then either physically sliding the patient up on the gantry or rotating them 180° on the gantry table and scanning through the remainder of the legs.11–13 See Table I below for more information. Table I. CT Protocol Trauma CT Protocol ▪Unenhanced spiral brain 1.25 mm (bone and soft tissue algorithm); 5 mm reconstructions immediately available for review ▪Circle of Willis to symphysis (bone and soft tissue algorithms) ▪150 mL biphasic contrast injection – initial 65 mL at 2 mL/s then 85 mL at 3.5 mL/s ▪Scan starts at 60 seconds ▪This gives both portal venous enhancement with good arterial contrast at the same time and the scan can be carried on down to the legs/feet is necessary. The cervical contrast has been very useful both for penetrating injury and for spinal injury/vertebral artery injury ▪The use of delayed scans limited to specific cases at the request of the radiologist 64 Detector Trauma CT Protocol ▪Unenhanced helical brain 1.25 mm (bone and soft tissue algorithm); 3 mm reconstructions immediately available for review ▪Circle of Willis to symphysis 1.25 mm (bone and soft tissue algorithms); 3 to 5 mm reconstructions immediately available for review ▪150 mL biphasic contrast injection – initial 80 cc at 1.4 cc/s then 70 cc at 3.5 cc/s ▪Scan starts 3 seconds before the completion of the contrast injection ▪This gives both portal venous enhancement with good arterial contrast at the same time and the scan can be carried on down to the legs/feet is necessary. The cervical contrast has been very useful both for penetrating injury and for spinal injury/vertebral artery injury ▪The use of delayed scans limited to specific cases at the request of the radiologist 16 Detector Trauma CT Protocol ▪Unenhanced helical brain 1.5 mm (bone and soft tissue algorithm); 3 mm reconstructions immediately available for review ▪Circle of Willis to symphysis 1.5 mm (bone and soft tissue algorithms); 5 mm reconstructions immediately available for review ▪Arterial phase imaging – 150 mL single arterial phase contrast injection at 3.5 cc/s ▪Automatically triggered with a threshold of 100 HU at the level of the aortic arch ▪The arterial phase imaging alone is preferred due to the technical limitations of the scanner ▪The use of delayed scans limited to specific cases at the request of the radiologist Trauma CT Protocol ▪Unenhanced spiral brain 1.25 mm (bone and soft tissue algorithm); 5 mm reconstructions immediately available for review ▪Circle of Willis to symphysis (bone and soft tissue algorithms) ▪150 mL biphasic contrast injection – initial 65 mL at 2 mL/s then 85 mL at 3.5 mL/s ▪Scan starts at 60 seconds ▪This gives both portal venous enhancement with good arterial contrast at the same time and the scan can be carried on down to the legs/feet is necessary. The cervical contrast has been very useful both for penetrating injury and for spinal injury/vertebral artery injury ▪The use of delayed scans limited to specific cases at the request of the radiologist 64 Detector Trauma CT Protocol ▪Unenhanced helical brain 1.25 mm (bone and soft tissue algorithm); 3 mm reconstructions immediately available for review ▪Circle of Willis to symphysis 1.25 mm (bone and soft tissue algorithms); 3 to 5 mm reconstructions immediately available for review ▪150 mL biphasic contrast injection – initial 80 cc at 1.4 cc/s then 70 cc at 3.5 cc/s ▪Scan starts 3 seconds before the completion of the contrast injection ▪This gives both portal venous enhancement with good arterial contrast at the same time and the scan can be carried on down to the legs/feet is necessary. The cervical contrast has been very useful both for penetrating injury and for spinal injury/vertebral artery injury ▪The use of delayed scans limited to specific cases at the request of the radiologist 16 Detector Trauma CT Protocol ▪Unenhanced helical brain 1.5 mm (bone and soft tissue algorithm); 3 mm reconstructions immediately available for review ▪Circle of Willis to symphysis 1.5 mm (bone and soft tissue algorithms); 5 mm reconstructions immediately available for review ▪Arterial phase imaging – 150 mL single arterial phase contrast injection at 3.5 cc/s ▪Automatically triggered with a threshold of 100 HU at the level of the aortic arch ▪The arterial phase imaging alone is preferred due to the technical limitations of the scanner ▪The use of delayed scans limited to specific cases at the request of the radiologist Open in new tab Table I. CT Protocol Trauma CT Protocol ▪Unenhanced spiral brain 1.25 mm (bone and soft tissue algorithm); 5 mm reconstructions immediately available for review ▪Circle of Willis to symphysis (bone and soft tissue algorithms) ▪150 mL biphasic contrast injection – initial 65 mL at 2 mL/s then 85 mL at 3.5 mL/s ▪Scan starts at 60 seconds ▪This gives both portal venous enhancement with good arterial contrast at the same time and the scan can be carried on down to the legs/feet is necessary. The cervical contrast has been very useful both for penetrating injury and for spinal injury/vertebral artery injury ▪The use of delayed scans limited to specific cases at the request of the radiologist 64 Detector Trauma CT Protocol ▪Unenhanced helical brain 1.25 mm (bone and soft tissue algorithm); 3 mm reconstructions immediately available for review ▪Circle of Willis to symphysis 1.25 mm (bone and soft tissue algorithms); 3 to 5 mm reconstructions immediately available for review ▪150 mL biphasic contrast injection – initial 80 cc at 1.4 cc/s then 70 cc at 3.5 cc/s ▪Scan starts 3 seconds before the completion of the contrast injection ▪This gives both portal venous enhancement with good arterial contrast at the same time and the scan can be carried on down to the legs/feet is necessary. The cervical contrast has been very useful both for penetrating injury and for spinal injury/vertebral artery injury ▪The use of delayed scans limited to specific cases at the request of the radiologist 16 Detector Trauma CT Protocol ▪Unenhanced helical brain 1.5 mm (bone and soft tissue algorithm); 3 mm reconstructions immediately available for review ▪Circle of Willis to symphysis 1.5 mm (bone and soft tissue algorithms); 5 mm reconstructions immediately available for review ▪Arterial phase imaging – 150 mL single arterial phase contrast injection at 3.5 cc/s ▪Automatically triggered with a threshold of 100 HU at the level of the aortic arch ▪The arterial phase imaging alone is preferred due to the technical limitations of the scanner ▪The use of delayed scans limited to specific cases at the request of the radiologist Trauma CT Protocol ▪Unenhanced spiral brain 1.25 mm (bone and soft tissue algorithm); 5 mm reconstructions immediately available for review ▪Circle of Willis to symphysis (bone and soft tissue algorithms) ▪150 mL biphasic contrast injection – initial 65 mL at 2 mL/s then 85 mL at 3.5 mL/s ▪Scan starts at 60 seconds ▪This gives both portal venous enhancement with good arterial contrast at the same time and the scan can be carried on down to the legs/feet is necessary. The cervical contrast has been very useful both for penetrating injury and for spinal injury/vertebral artery injury ▪The use of delayed scans limited to specific cases at the request of the radiologist 64 Detector Trauma CT Protocol ▪Unenhanced helical brain 1.25 mm (bone and soft tissue algorithm); 3 mm reconstructions immediately available for review ▪Circle of Willis to symphysis 1.25 mm (bone and soft tissue algorithms); 3 to 5 mm reconstructions immediately available for review ▪150 mL biphasic contrast injection – initial 80 cc at 1.4 cc/s then 70 cc at 3.5 cc/s ▪Scan starts 3 seconds before the completion of the contrast injection ▪This gives both portal venous enhancement with good arterial contrast at the same time and the scan can be carried on down to the legs/feet is necessary. The cervical contrast has been very useful both for penetrating injury and for spinal injury/vertebral artery injury ▪The use of delayed scans limited to specific cases at the request of the radiologist 16 Detector Trauma CT Protocol ▪Unenhanced helical brain 1.5 mm (bone and soft tissue algorithm); 3 mm reconstructions immediately available for review ▪Circle of Willis to symphysis 1.5 mm (bone and soft tissue algorithms); 5 mm reconstructions immediately available for review ▪Arterial phase imaging – 150 mL single arterial phase contrast injection at 3.5 cc/s ▪Automatically triggered with a threshold of 100 HU at the level of the aortic arch ▪The arterial phase imaging alone is preferred due to the technical limitations of the scanner ▪The use of delayed scans limited to specific cases at the request of the radiologist Open in new tab CT Review Three-dimensional (3D) workstations are a required resource in any civilian trauma center and are a required resource for any Role 3 where major casualties are expected. These workstations allow the radiologist a rapid overview of injuries and ability to zoom into abnormalities. Additionally, these powerful workstations allow for rapid creation of detailed 3D-shaded surface and multiplanar reconstructions that facilitate a broad overview of numerous soft tissue and osseous injuries at different locations and accentuate the location of fragments. Utilizing these shaded bone or skin surface and multiplanar reconstruction images can be very helpful for injury tract analysis. The workstation also enables focused arterial vascular analysis, thus supporting early identification of more subtle vascular injuries that can have a significant clinical impact on patient morbidity and mortality.13 In mass casualty situations, a modified workflow may be necessary. The performance of preliminary readings or “wet reads” may be required, especially when there is a sole radiologist present. IV Access for CT 18 g antecubital IV is typically desired. If placed on a medical evacuation platform prior to arrival, the cannula must be thoroughly rechecked/flushed to ensure function and avoid contrast extravasation. More distal upper extremity IVs should typically not be used due to the risk of extravasation and compartment syndrome. A central line can be used for contrast power injection. A large lumen resuscitation catheter such as those utilized for the rapid infusion device (normally rated up to 9 cc/s) can most often handle the contrast injection.14 Ensure that the correct size catheter lumen is utilized for the power injection as the catheter will often have various sized lumens. The largest lumen of the catheter would be the best to handle the power injection. Of course, should the rapid infusion device be used to infuse fluid/blood products at the same time, it should be turned off during the injection to avoid dilution of the contrast with the instillate. Current intraosseous needles should not be used for contrast administration. Though a few case reports of individual patients undergoing CT examination with contrast injection through IO needles have been published, larger studies in trauma patients are needed to establish efficacy, adverse effects, and bolus timing modifications. CT Contrast Injection The goal of the injection is to provide concurrent solid organ enhancement, arterial enhancement, and pulmonary arterial. Typical doses are approximately 150 cc of Isovue 300 or 340 contrasts utilizing a dual phase injection – 80 cc at 1.4 cc/s, followed immediately by 70 cc at 3.5 cc/s for the pan scan. The scan is started 2–3 seconds before the completion of the contrast injection to maximize pulmonary arterial filling. For pediatric injection volume and rates by weight, see Table II at the end of the article. Table II. 64 Detector Pediatric (MWD) IV Contrast Injection Protocols Child Weight (kg) . Venous Phase Rate/Volume . Arterial Phase Rate/Volume . Total Contrast Delivered . 5 0.2 s/7 mL 0.4 s/3 mL 10 10 0.3 s/14 mL 0.6 s/6 mL 20 15 0.4 s/20 mL 0.8 s/10 mL 30 20 0.5 s/26 mL 1.0 s/14 mL 40 25 0.6 s/33 mL 1.3 s/17 mL 50 30 0.7 s/40 mL 1.6 s/20 mL 60 35 0.8 s/47 mL 1.8 s/23 mL 70 40 0.9 s/53 mL 2.1 s/26 mL 80 45 1.0 s/60 mL 2.2/30 mL 90 50 1.2 s/66 mL 2.4 s/34 mL 100 55 1.3 s/73 mL 2.6 s/37 mL 110 60 1.4 s/80 mL 2.8 s/40 mL 120 70 1.6 s/94 mL 3.3/46 mL 140 Color coded pediatric dose settings (mA/kV) Pink 6.0–7.5 kg 59.5–66.5 cm Red 7.5–9.5 kg 66.5–74 cm Purple 9.5–11.5 kg 74–84 cm Yellow 11.5–14.5 kg 84.5–97.5 cm White 14.5–18.5 kg 97.5–110 cm Blue 18.5–22.5 kg 110–122 cm Orange 22.5–31.5 kg 122–137 cm Green 31.5–40.5 kg 137–150 cm Black 40.5–55 kg <150 cm Child Weight (kg) . Venous Phase Rate/Volume . Arterial Phase Rate/Volume . Total Contrast Delivered . 5 0.2 s/7 mL 0.4 s/3 mL 10 10 0.3 s/14 mL 0.6 s/6 mL 20 15 0.4 s/20 mL 0.8 s/10 mL 30 20 0.5 s/26 mL 1.0 s/14 mL 40 25 0.6 s/33 mL 1.3 s/17 mL 50 30 0.7 s/40 mL 1.6 s/20 mL 60 35 0.8 s/47 mL 1.8 s/23 mL 70 40 0.9 s/53 mL 2.1 s/26 mL 80 45 1.0 s/60 mL 2.2/30 mL 90 50 1.2 s/66 mL 2.4 s/34 mL 100 55 1.3 s/73 mL 2.6 s/37 mL 110 60 1.4 s/80 mL 2.8 s/40 mL 120 70 1.6 s/94 mL 3.3/46 mL 140 Color coded pediatric dose settings (mA/kV) Pink 6.0–7.5 kg 59.5–66.5 cm Red 7.5–9.5 kg 66.5–74 cm Purple 9.5–11.5 kg 74–84 cm Yellow 11.5–14.5 kg 84.5–97.5 cm White 14.5–18.5 kg 97.5–110 cm Blue 18.5–22.5 kg 110–122 cm Orange 22.5–31.5 kg 122–137 cm Green 31.5–40.5 kg 137–150 cm Black 40.5–55 kg <150 cm Open in new tab Table II. 64 Detector Pediatric (MWD) IV Contrast Injection Protocols Child Weight (kg) . Venous Phase Rate/Volume . Arterial Phase Rate/Volume . Total Contrast Delivered . 5 0.2 s/7 mL 0.4 s/3 mL 10 10 0.3 s/14 mL 0.6 s/6 mL 20 15 0.4 s/20 mL 0.8 s/10 mL 30 20 0.5 s/26 mL 1.0 s/14 mL 40 25 0.6 s/33 mL 1.3 s/17 mL 50 30 0.7 s/40 mL 1.6 s/20 mL 60 35 0.8 s/47 mL 1.8 s/23 mL 70 40 0.9 s/53 mL 2.1 s/26 mL 80 45 1.0 s/60 mL 2.2/30 mL 90 50 1.2 s/66 mL 2.4 s/34 mL 100 55 1.3 s/73 mL 2.6 s/37 mL 110 60 1.4 s/80 mL 2.8 s/40 mL 120 70 1.6 s/94 mL 3.3/46 mL 140 Color coded pediatric dose settings (mA/kV) Pink 6.0–7.5 kg 59.5–66.5 cm Red 7.5–9.5 kg 66.5–74 cm Purple 9.5–11.5 kg 74–84 cm Yellow 11.5–14.5 kg 84.5–97.5 cm White 14.5–18.5 kg 97.5–110 cm Blue 18.5–22.5 kg 110–122 cm Orange 22.5–31.5 kg 122–137 cm Green 31.5–40.5 kg 137–150 cm Black 40.5–55 kg <150 cm Child Weight (kg) . Venous Phase Rate/Volume . Arterial Phase Rate/Volume . Total Contrast Delivered . 5 0.2 s/7 mL 0.4 s/3 mL 10 10 0.3 s/14 mL 0.6 s/6 mL 20 15 0.4 s/20 mL 0.8 s/10 mL 30 20 0.5 s/26 mL 1.0 s/14 mL 40 25 0.6 s/33 mL 1.3 s/17 mL 50 30 0.7 s/40 mL 1.6 s/20 mL 60 35 0.8 s/47 mL 1.8 s/23 mL 70 40 0.9 s/53 mL 2.1 s/26 mL 80 45 1.0 s/60 mL 2.2/30 mL 90 50 1.2 s/66 mL 2.4 s/34 mL 100 55 1.3 s/73 mL 2.6 s/37 mL 110 60 1.4 s/80 mL 2.8 s/40 mL 120 70 1.6 s/94 mL 3.3/46 mL 140 Color coded pediatric dose settings (mA/kV) Pink 6.0–7.5 kg 59.5–66.5 cm Red 7.5–9.5 kg 66.5–74 cm Purple 9.5–11.5 kg 74–84 cm Yellow 11.5–14.5 kg 84.5–97.5 cm White 14.5–18.5 kg 97.5–110 cm Blue 18.5–22.5 kg 110–122 cm Orange 22.5–31.5 kg 122–137 cm Green 31.5–40.5 kg 137–150 cm Black 40.5–55 kg <150 cm Open in new tab Rectal Contrast This can be helpful when evaluating penetrating flank injuries or possible rectal involvement below the peritoneal reflection from pelvic injuries. One may utilize 1 L of saline/water with the addition of 1 bottle (50 mL) of IV contrast. A Foley catheter is used to cannulate the rectum and the balloon is instilled with saline. In the setting of significant rectal or perineal trauma the surgeon may need to place the Foley catheter in the rectum. Delayed Images Routinely performed for further evaluation of identified solid organ injury, identify active extravasation or pseudoaneurysm formation, which can aid surgeons in grading the solid organ injury. Additionally, contrast excretion within the ureters and subsequently into the bladder can also aid in diagnosis of injuries to these structures. CT Cystogram 50 cc of IV contrast diluted into 500 cc of saline is infused through the indwelling urinary catheter. A minimum of 300 cc and up to 500 cc of this dilute contrast material should be infused to provide adequate evaluation of the integrity of the bladder wall. The catheter is then clamped for the CT examination. This type of exam is performed following the routine trauma CT with 1 mm thick images acquired through the pelvis with the bladder filled. If necessary, additional axial imaging of the bladder can be performed following the drainage of the contrast to detect more subtle extraperitoneal bladder injuries which may be obscured by the distended bladder.15 CT Language Settings Become familiar with the languages available/preloaded on the scanner for breathing instructions, which often include: English, French, Spanish, Japanese, and Chinese. Using interpreters available in your facility, record the same instructions in commonly encountered languages of coalition partners and host-nation patients (e.g., Arabic, Pashtun, Dari, Farsi, Georgian, Italian, Danish, Estonian, etc). Ensure to select the correct language at the time of scan setup for each patient. Using these instructions will improve image quality for conscious patients. Military Working Dogs Given the nature of military operations in the current conflict military working dogs (MWDs) have sustained similar injuries to dismounted soldiers and will need CT trauma scans as well. These examinations will typically be performed in consultation with veterinarians who will sedate the dog as necessary for the scan. However in an emergency situation, it may be necessary for the radiologist to perform the scan while the veterinarian is Enroute. Given this eventuality, prior coordination between the radiologist and veterinarian is essential. Utilize a scanning protocol based on the pediatric settings to include the doses of and rates of contrast administration. Refer to the JTS CPG Clinical Management of Military Working Dog16 and Table II for further details. Image Transfer All patients evacuated through casualty evacuation should have images sent electronically ahead of time as well as have a CD created to send with the patient as a backup. Although at times trauma patient’s true name may not be known during the initial evaluation, it should be stressed that usually it becomes known sometime soon thereafter. Ensuring the patient’s information is updated with the real name rather than a local hospital’s trauma name will ensure those studies are available for review through the health care evacuation system. CONCLUSION Trauma patients in a deployed setting often sustain complex injuries with high-energy mechanisms of injury. This clinical practice guideline provides radiologists and emergency providers with guidance on the effective use and integration of multimodality imaging into the assessment and triage of acute trauma patients in a deployed setting. Imaging is a critical component of comprehensive trauma care in the era of modern medicine and can successfully be performed in the deployed environment. Refer to the JTS CPG Use of MRI in Management of mTBI in the Deployed Setting.17 REFERENCES 1 Como JJ , Diaz JJ, Dunham CM, et al. : Practice management guidelines for identification of cervical spine injuries following trauma: Update from the Eastern Association for the Surgery of Trauma Practice Management Guidelines Committee . J Trauma 2009 ; 67 : 651 – 9 . Google Scholar Crossref Search ADS PubMed WorldCat 2 Joint Trauma System , Cervical and Thoracolumbar Spine Injury Evaluation, Transport, and Surgery in the Deployed Setting CPG. Available at http://www.jts.amedd.army.mil/assets/docs/cpgs/JTS_Clinical_Practice_Guidelines_(CPGs)/Cervical_Thoracolumbar_Spine_Injury_Evaluation_Transport_Surgery_Depoloyed_Setting_05_Aug_2016_ID15.pdf; accessed March 2018. 3 Watchorn J , Miles R, Moore N: The role of CT angiography in military trauma . Clin Radiol 2013 ; 68 : 39 – 46 . 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TI - Radiology: Imaging Trauma Patients in a Deployed Setting
JF - Military Medicine
DO - 10.1093/milmed/usy063
DA - 2018-09-01
UR - https://www.deepdyve.com/lp/oxford-university-press/radiology-imaging-trauma-patients-in-a-deployed-setting-xExK004bx0
SP - 60
EP - 64
VL - 183
IS - suppl_2
DP - DeepDyve
ER -