Events such as the Boston Marathon bombing and the Manchester attack are reminders that terrorist attacks are of great concern to the general public. The various types of weapons of mass destruction (WMDs) can be remembered by the acronym CBRNE which stands for chemical, biological, radiological, nuclear, and explosive weapons. The focus of this paper will be improvised explosive devices (IEDs).
The United States Department of Defense defines IEDs as “devices placed or fabricated in an improvised manner incorporating destructive, lethal, noxious, pyrotechnic or incendiary chemicals, designed to destroy, disfigure, distract or harass…” Explosive-related injuries were once thought to be related solely to combat medicine. While the IED is considered one of the greatest threats to troops operating in Afghanistan during the War on Terror, they are not exclusively confined to the battlefield as civilian-targeted terrorist attacks like those mentioned above are becoming more commonplace. In fact, Kluger states that “[b]ombing and explosions directed against innocent civilians have become the primary instrument of global terror…” It is of great importance that medical personnel be aware of the threat of terrorist-related IED attacks so that the appropriate steps can be taken if such an event were to occur.
Blast injuries are the classification of injuries that can be sustained by explosives, and to fully comprehend these injuries, practitioners must first understand the physics behind an explosion. Explosions occur due to an exothermic reaction that is generated when chemical bonds are disrupted. This ultimately causes the solid or liquid explosive material to be converted to a gas, which rapidly expands, releasing a large amount of energy. The explosion created by an IED can be classified into high-energy, which creates a supersonic high-pressure blast wave or low-energy explosion which creates a subsonic explosion without a blast wave. Examples of high-energy explosives include material such as TNT, C4, Semtex, nitroglycerin, dynamite, and ammonia nitrate fuel oil, while materials like gunpowder and petroleum are examples of substances that cause low-energy explosions. Upon contact with a target, a significant amount of kinetic energy is dispersed which ultimately leads to the injury patterns described below.
Blast Injury Classification
A primary blast injury is a type of barotrauma, which results from the interaction of a blast wave with the body. Hollow viscous organs such as tympanic membranes, the lungs, and the gastrointestinal organs are at particular risk in this specific type of blast injury. Blast lung injury (BLI) will be discussed below.
Secondary blast injury results in penetrating trauma by bomb fragments and other projectiles. Some IEDs can be specifically enhanced with objects such as nails, metal ball bearings, or screws with the specific goal to cause a secondary blast injury and inflict as much trauma as possible. Energy from the explosive wave is transferred into the objects that then act as either high-energy or low-energy missiles.
A tertiary blast injury occurs when the victim becomes displaced due to the pressure wave. The victim is ultimately propelled and encounters a stationary object such as a wall, which leads to direct, blunt trauma. This can lead to injuries such as traumatic brain injury, closed skull fractures, limb amputations, and musculoskeletal injuries.
Quaternary blast injury is a broader term to describe all other explosion-related injuries, which may include burns of various degrees or other types of toxic exposure.
Approach to IED-related Injury
The clinical approach a practitioner takes to explosive-related injuries depends on the experience of the provider. Tactical Combat Casualty Care (TCCC) is a protocol-based, pre-hospital guideline for trauma care that is specific to the battlefield. However, considering most pre-hospital providers responding to IED detonation will not be familiar with TCCC, it is important for responders to implement Advanced Trauma Life Support (ATLS). The primary survey in ATLS consists of the ABCs, Airway, Breathing, and Circulation. However, in the case of an explosive detonation, exsanguination secondary to hemorrhage is an important caveat responder must consider. Therefore, instead of ABC, medical personnel should implement CABC, Catastrophic Bleeding, Airway, Breathing, and Circulation. The ‘C’ standing for ‘Catastrophic Bleeding’ reminds medical personnel that hemorrhage control should take precedence over airway security as exsanguination is associated with most potentially survivable deaths on the battlefield, and therefore, can be thought to have more deleterious outcomes as compared to airway compromise in the victim of an explosion. Moreover, hemorrhage is the second leading cause of civilian-related trauma death furthering the idea that the CABC-model is of great importance.
Upon arriving at the scene of an explosion, there are important steps that medical professionals should take to control hemorrhage as exsanguination is of great concern in such a situation. Therefore, direct pressure with sterile packing and application with of a tourniquet is the mainstay of treatment with active bleeding. In fact, there are some recommendations that first responders should apply bilateral tourniquets to a victim of an explosion, even if there is no active bleeding as there is thought that bleeding will likely occur when resuscitation with intravenous fluid is initiated. One study found that the application of the Combat Application Tourniquet (CAT) was an effective tool during civilian trauma (including terrorist events) to control extremity hemorrhage while offering few complications. While other tourniquets like the Combat Ready Clamp (CRoC) and the Junctional Emergency Treatment Tool (JETT) are the preferred tools by military medics, familiarity with them by non-combat medical providers could prove to be very useful, as both devices have proved to occlude arterial flow in less than 1 minute.
In addition to the use of the tourniquet, hemostatic agents are another means by which responders can attempt to manage bleeding. The 2 products discussed below are part of the recommendations and guidelines of the Tactical Combat Casualty Care (TCCC). While TCCC protocol is less likely to be known to civilian physicians and medical personnel, non-combat out of hospital providers should still be aware of the applicability of these products. One animal study compared the commonly used QuickClot Combat Gauze to the FDA-approved XSTAT product and found that XSTAT subjects achieved hemostasis in less time, maintained hemostasis longer, and lost less blood as compared to the QuickClot group. Additionally, TXA, which is a recommended guideline by the TCCC, was found to reduce overall mortality among related to hemorrhage.
Special Considerations-Blast Lung
One special consideration of which providers treating victims of explosions should be aware of is Blast Lung Injury (BLI). BLI results from barotrauma secondary to an explosive wave traveling through air and is, therefore, an example of primary blast injury. BLI is thought to be secondary to pressure differentials generated upon tissues of different densities ultimately leading to pulmonary hemorrhage, contusion or edema. BLI is a clinical diagnosis based on respiratory difficulty and hypoxia in the appropriate setting and patients with blast lung may present with dyspnea, cough or chest pain. Concerning complications of BLI secondary to an explosion include pneumothorax, hemothorax, fat embolism, and air emboli, which can enter the central nervous system, ocular or coronary arterial systems. As described above, the initial pre-hospital approach should focus on CABC. After the catastrophic bleeding has been addressed with direct pressure and tourniquet placement, the focus should be moved to the airway. Patients with suspected or confirmed BLI should have high flow supplemental oxygen to prevent hypoxemia and should receive endotracheal intubation for respiratory compromise. However, providers must be aware of mechanical ventilation and the risk to precipitate or worsen conditions like alveolar rupture, pneumothorax or air embolism. Additionally, victims of explosions with suspected blast lung should be given fluids judiciously as overaggressive intravenous (IV) hydration can create volume overload and precipitate possible flash pulmonary edema.
|||Singh AK,Ditkofsky NG,York JD,Abujudeh HH,Avery LA,Brunner JF,Sodickson AD,Lev MH, Blast Injuries: From Improvised Explosive Device Blasts to the Boston Marathon Bombing. Radiographics : a review publication of the Radiological Society of North America, Inc. 2016 Jan-Feb; [PubMed PMID: 26761543]|
|||Brunner J,Singh AK,Rocha T,Havens J,Goralnick E,Sodickson A, Terrorist bombings: foreign bodies from the Boston Marathon bombing. Seminars in ultrasound, CT, and MR. 2015 Feb; [PubMed PMID: 25639179]|
|||Pumera M, Analysis of explosives via microchip electrophoresis and conventional capillary electrophoresis: a review. Electrophoresis. 2006 Jan; [PubMed PMID: 16307431]|
|||Nerlander MP,Haweizy RM,Wahab MA,Älgå A,von Schreeb J, Epidemiology of Trauma Patients from the Mosul Offensive, 2016-2017: Results from a Dedicated Trauma Center in Erbil, Iraqi Kurdistan. World journal of surgery. 2019 Feb; [PubMed PMID: 30357467]|
|||Jeyaraj P,Chakranarayan A, Treatment Strategies in the Management of Maxillofacial Ballistic Injuries in Low-Intensity Conflict Scenarios. Journal of maxillofacial and oral surgery. 2018 Dec; [PubMed PMID: 30344389]|
|||Baker WA,Chowdhury M,Untaroiu CD, A finite element model of an anthropomorphic test device lower limb to assess risk of injuries during vertical accelerative loading. Journal of biomechanics. 2018 Nov 16; [PubMed PMID: 30316546]|
|||Gordon W,Talbot M,Fleming M,Shero J,Potter B,Stockinger ZT, High Bilateral Amputations and Dismounted Complex Blast Injury (DCBI). Military medicine. 2018 Sep 1; [PubMed PMID: 30189056]|
|||Chukwu-Lobelu R,Appukuttan A,Edwards DS,Patel HDL, Burn injuries from the london suicide bombings: a new classification of blast-related thermal injuries. Annals of burns and fire disasters. 2017 Dec 31; [PubMed PMID: 29983676]|
|||Hättenschwiler N,Sterchi Y,Mendes M,Schwaninger A, Automation in airport security X-ray screening of cabin baggage: Examining benefits and possible implementations of automated explosives detection. Applied ergonomics. 2018 Oct; [PubMed PMID: 29885728]|