ABSTRACT
Earthquakes are among the most destructive and unpredictable natural disasters. Various diseases and ailments, such as bone fractures, organ and soft-tissue injuries, cardiovascular diseases, lung diseases, and infectious diseases, can develop in the aftermath of severe earthquakes. Digital radiography, ultrasound, computed tomography, and magnetic resonance imaging are significant imaging modalities utilized for the quick and reliable assessment of earthquake-related ailments to facilitate the planning of suitable therapy. This article examines the usual radiological imaging characteristics observed in individuals from quake-damaged regions and summarizes the strengths and functionality of imaging modalities. In such circumstances, where quick decision-making processes are life-saving and essential, we hope this review will be a practical reference for readers.
Main points
• Earthquake-induced power outages may limit the use of computed tomography and digital radiography and the risk of quenching may limit the use of magnetic resonance imaging.
• Ultrasonography, especially Focused Assessment with Sonography for Trauma, stands out as the most accessible and functional imaging method in disaster situations such as earthquakes.
• Contrast medium should be used with extreme caution due to the risk of rhabdomyolysis-related nephropathy.
• Knowing the typical features and distribution of earthquake-related injuries is important for rapid diagnosis and the detection of accompanying pathologies.
Earthquakes are among the most destructive and unpredictable natural disasters.1 A magnitude 7.7 foreshock occurred in the epicenter of the Kahramanmaraş earthquake at 04:17:35 (UTC +03:00) on February 6, 2023. Then, at 13:24:49 (UTC+03:00), another earthquake of magnitude 7.6 occurred with its epicenter in Kahramanmaraş-Elbistan (Figure 1).2,3 The natural calamity devastated 10 cities, and thousands of injured individuals were taken to hospitals throughout Turkey. In the first month after the earthquake, it was reported that 46,104 people had perished and over 100,000 were injured as a result of the quakes centered in Kahramanmaraş.4
Various diseases and ailments, such as bone fractures, organ and soft-tissue injuries, cardiovascular diseases, lung diseases, and infectious diseases, can develop in the aftermath of severe earthquakes. Digital radiography (DR), ultrasound (US), computed tomography (CT), and magnetic resonance imaging (MRI) are significant imaging modalities utilized for the quick and reliable assessment of earthquake-related ailments to facilitate the planning of suitable therapy.5
Based on previously published experiences after major earthquakes, this article examines the typical radiological imaging characteristics observed in individuals from quake-damaged regions and summarizes the strengths and functionality of imaging modalities. In this way, it aims to provide a practical source of information to radiologists during fieldwork in large-scale disasters where rapid diagnosis is of great importance.
Imaging method availability and utility
Ultrasound: US is the most useful and accessible method, both at the time of the disaster and in the following six-hour period. The main reason for this is the energy requirement of imaging methods. As the sole method of cross-sectional imaging accessible while CT was unavailable, US was widely utilized (it is easy to get to, can be used on the go, and helps doctors figure out which injuries are superficial and which are internal). US proved invaluable in the initial phases following the disaster, especially in the absence of CT, and should be incorporated into local disaster or mass-casualty strategies.6 Larger devices are less useful than portable ones. Even in the absence of biochemical laboratory tests, portable ultrasonography instruments can aid in narrowing the differential diagnosis or ruling out more serious illnesses. It is portable, simple, and painless, and in many instances, it has provided rapid results.7
Focused Assessment with Sonography for Trauma (FAST) is the main sonographic method for earthquake-related ailments (Figure 2). After Hurricane Katrina, 9/11 in New York, the Lebanon War in 2006, and the Iran earthquake in 2010, FAST was found to be successful in assessing and triaging patients during periods of high patient volume. In the acute post-disaster phase, it can be utilized to check for hemothorax/pneumothorax, solid organ injury, fractures, pregnancy and vascular investigations, pediatric head scans, and intravenous access help.8 A clinician can perform FAST with the same sensitivity but less specificity compared to a radiology assistant. In addition, FAST can reduce the number of needless CT scans. In a study conducted after an earthquake in Christchurch, New Zealand, it was seen that the imaging method most frequently used and most accessible by physicians providing post-disaster health care was US (especially FAST).7,8
Computed tomography: Power cuts and damage to health centers at the time of disasters seriously restrict the use of CT. It has been shown that the first use of CT in the delivery of health care to earthquake victims may extend to the fifth hour after the earthquake.6 Pan-CT examinations, if available, can guide emergency surgeries; nevertheless, in situations with a high patient volume, it is impossible and impractical to perform pan-CT on every patient. Therefore, FAST-guided CT examinations provide better and more effective results,8 and contrast-enhanced CT examinations should be approached with extreme caution. In circumstances that impede kidney function, such as crush syndrome caused by earthquakes, the use of contrast material may induce severe complications. Again, if contrast agent extravasation occurs in cases with compartment syndrome induced by earthquake-related traumas, the situation may worsen. However, in some special cases, such as suspected major vascular injury, dissection, or pulmonary embolism in a clinical examination, intravenous contrast agents can be administered without waiting for the results of the patient’s kidney function tests.9
Digital radiography: The use of DR is also limited, for the same reasons as CT; however, DR can be commissioned more quickly because its energy requirement is less than CT. The fact that mobile DR devices allow bedside examinations provides great convenience, especially in cases with limited mobility. Versatile DR applications performed at the bedside are an important alternative in cases where CT cannot be reached. However, the fact that the batteries of these devices are sufficient for a finite time limits their use if there is a charging problem.6
Magnetic resonance imaging: Due to the possibility of quenching (quenching is the quick release of the liquid cryogen that keeps the MRI magnet in a superconducting state. If gas leaks into a room instead of leaving the building after an earthquake or other disaster, there is a chance of suffocation and freezing) MRI should not be utilized immediately following an earthquake.6,8
Reporting alternatives
Serious difficulties have been experienced in accessing radiological images during disasters. For this reason, the ideal reporting method is verbal reporting if there is an opportunity to work closely with the clinician. In cases where there is no opportunity to work in close contact, written reports that provide short and concise information and that can be created quickly come to the forefront.6 After the recent earthquake disaster, it is satisfying that a system that allows remote, fast, and effective reporting was established very quickly (Figure 3).
Non-traumatic injuries
Cerebrovascular diseases: The increase in blood pressure and heart rate caused by the activation of the sympathetic nervous system in those impacted by a natural disaster is known as “disaster hypertension”.28 Hypertension is connected with an increased risk of stroke (Figure 17) and heart attack and is one of the primary causes of cardiovascular disease. In addition, various challenges connected with evacuee life (such as poor diet and water, difficulty obtaining regular medicine, and mental stress) may have a negative impact on disaster hypertension, resulting in cerebrovascular strokes and cardiovascular disorders. It was known that several of the patients in the evacuation facilities had suffered cerebrovascular attacks.29 One month after an earthquake, spinal subdural and epidural hematomas that were not caused by trauma were also observed. It has been claimed that irregular use of antiplatelet medications and/or an uncomfortable posture resulting from spending nights in certain vehicles are potential risk factors for these types of hematomas.5
Cardiovascular diseases: Heart failure (HF), lower-extremity deep vein thrombosis (DVT), and pulmonary thromboembolism (PTE) are among the leading non-traumatic diseases associated with earthquakes (Figures 18, 19).30,31 While HF increases occur over long periods, such as into the seventh week after the earthquake, PTE and DVT cases increase closer to the occurrence of the earthquake. In addition, DVT and PTE more commonly affect women; it is thought that the primary reason for this is the combination of oral contraceptives with prolonged sitting or inadequate living conditions.30,31
Infections: Problems in clean water supply and sewage systems and poor housing conditions in evacuation centers are the main causes of post-disaster infections. Respiratory and gastrointestinal infections constitute the most common group, and increased cases of meningoencephalitis have also been reported after disasters (Figure 20).32,33It has been shown that common orthopedic injuries are accompanied by wound infections in approximately 20% of cases.33
Interventional radiologic procedures: In disaster situations such as earthquakes, where access to CT and fluoroscopy devices is limited, interventional radiological procedures cannot be widely performed. However, it is seen that the procedures performed under US guidance are practical and life-saving. Tube thoracotomies, pleural hemorrhage drainage, and central venous catheter procedures are the main life-saving interventional radiology applications in disaster areas.34
Injuries with high mortality risk and forensic medicine–radiology cooperation
Immediate deaths are those that result from catastrophic injuries sustained during the earthquake. Severe trauma to the brain or spinal cord is a common cause of such injuries, and in most cases, these patients cannot be saved. Other earthquake victims die rapidly within the first few hours following the catastrophe, and historical experience indicates that mortality could be drastically decreased if treatment is administered promptly. These people suffer subdural hematomas, lacerations to the liver or spleen, and pelvic fractures. The third peak of mortality, which comes days to weeks following the earthquake, is caused by sepsis, multisystem organ failure, and disseminated intravascular coagulation. These individuals have the highest possibility of being saved since they succumb to injury complications more slowly.35
Unfortunately, one of the post-disaster medical efforts is to determine the identities of those who lost their lives. At this point, forensic medicine physicians can also apply imaging methods. Considering the possibilities that the disaster environment can offer, it has been determined that the most frequently used method is dental radiographs. It is known that MRI and CT are highly functional in determining and clarifying the cause of death, but, unfortunately, the use of both methods is limited. The main reasons for this are the great need for life-saving interventions for these imaging methods and the large number of bodies that need to be examined in an environment where there is mass loss of life. In addition, it has been observed that many radiologists do not have enough experience in forensic imaging.36,37
In conclusion, in earthquakes and similar disaster situations, the need for imaging methods increases, and imaging plays an important role in saving lives. Due to the constraints in energy supply and easy accessibility, US examinations–especially FAST–have become the most useful method. Knowing the most common injuries, typical imaging findings of these injuries and their accompanying pathologies will help save more lives. Reporting procedures in close contact with the clinician, verbally or in the form of short notes, seems to be the most useful method. It should not be forgotten that the establishment of remote reporting systems is a practical and effective solution in cases where there is excessive demand.
Traumatic injuries
Annually, earthquakes are the most lethal of all natural disasters. Between 2007 and 2017, 350,000 people died and over one million were injured. Earthquakes appear to have a death-to-injury ratio of approximately 1:3–4,10 though this is variable depending on the severity of the injury.
In studies conducted both in our country and globally, it has been shown that the most common injuries after earthquakes are traumatic injuries, and the most needed interventions are orthopedic procedures. Debridement was the most common operation, followed by open reduction internal fixation and then closed reduction-casting.11,12,13
Earthquake-related traumatic injuries are most common in the extremities, particularly the lower extremities. In order of frequency, extremities are followed by the thorax (Figures 4, 5), spinal injuries (Figures 6, 7), pelvic fractures, cranial and maxillofacial injuries, and abdominal traumatic findings (Figure 8).14 The femur is the most often injured bone in the extremities, followed by the tibial shaft and the ankle (Figures 9, 10). The humerus is the most often injured bone in the upper limb (Figure 11).15 It has been shown that earthquake-related lower extremity fractures, unlike other traumas, have a high rate of being multiple and comminuted (Figure 12).16,17 The characteristics of earthquake-related fractures seen in children are similar to adults; fractures are most commonly seen in the lower extremities, and external fixation is usually required.18
Pelvic fractures are generally seen as multiple and bilateral (Figure 13). In a study conducted in China, the most common pelvic fracture subtype was reported as type C, followed by type B3 and type B2.19 In a study conducted in Turkey, type C2 fractures were found most frequently, similar to the Chinese data (Table 1).20,21
When the distribution of maxillofacial traumas is examined, it is seen that mandibular fractures are the most common, followed by the zygomatic complex and maxilla. Similar to lower extremity fractures, multiple and comminuted fractures are common. Cranial injuries and lower extremity fractures are the most common types of injuries to accompany maxillofacial fractures (Figure 14).22,23 Some studies report that nasal bone, ethmoid bone, and orbital fractures are also common. Maxillofacial fractures are injuries that require a multidisciplinary approach due to the complex anatomy of the region and the frequent occurrence of accompanying cranial traumas.23
Additionally, one of the disorders associated with earthquakes is aggressive rhabdomyolysis, which appears heterogeneously hypodense on CT. On post-contrast images, there may be rim enhancement. Rhabdomyolysis exhibits more diverse findings on MRI. It is also possible to detect the status of myonecrosis with MRI findings; in mild to moderate cases, damaged muscles exhibit edema, with signal intensity matching the severity of the injury. If severe myonecrosis occurs, two different patterns can be seen: (a) homogeneously iso/hyperintense on T1 weighted images (WI), homogeneously hyperintense on T2WI/short tau inversion recovery homogeneously enhancing on postcontrast T1WI, and (b) homogeneously/heterogeneously hyperintense on T1WI, heterogeneously hyperintense on T2WI, rim-like enhancement on postcontrast T1WI (Figure 15).24 Based on data from an experimental animal study, contrast-enhanced ultrasonography (CEUS) is effective in the prehospital or bedside diagnosis of rhabdomyolysis. The study revealed that, compared with uninjured muscles, injured muscles showed early and high enhancement in CEUS images.25
Acute compartment syndrome is a surgical emergency that poses limb- and life-threatening risks. It is a painful condition brought on by increased intracompartmental pressure, which compromises perfusion and causes muscle and nerve damage inside the affected compartment. The diagnosis of acute compartment syndrome is based on clinical symptoms and measurements of compartmental pressures. Utilization of imaging techniques is often restricted, and in some instances, imaging can delay diagnosis and surgical therapy. In addition to the aforementioned signs of rhabdomyolysis, MRI reveals herniation of muscle through a tear in the surrounding fascia. In addition, CT angiography and color Doppler US can be utilized to detect vascular luminal constriction due to elevated intracompartmental pressure (Figure 16).26,27