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Risks to emergency medical responders at terrorist incidents: a narrative review of the medical literature

Abstract

As the threat of international terrorism rises, there is an increasing requirement to provide evidence-based information and training for the emergency personnel who will respond to terrorist incidents. Current major incident training advises that emergency responders prioritize their own personal safety above that of the `scene and survivors’. However, there is limited information available on the nature of these threats and how they may be accurately evaluated. This study reviews the published medical literature to identify the hazards experienced by emergency responders who have attended previous terrorist incidents. A PubMed literature search identified 10,894 articles on the subject of `terrorism’, and there was a dramatic increase in publications after the 9/11 attacks in 2001. There is heterogeneity in the focus and quality of this literature, and 307 articles addressing the subject of scene safety were assessed for information regarding the threats encountered at terrorist incidents. These articles demonstrate that emergency responders have been exposed to both direct terrorist threats and environmental scene hazards, including airborne particles, structural collapse, fire, and psychological stress. The emphasis of training and preparedness for terrorist incidents has been primarily on the direct threats, but the published literature suggests that the dominant causes of mortality and morbidity in responders after such incidents are the indirect environmental hazards. If the medical response to terrorist incidents is to be based on evidence rather than anecdote, analysis of the current literature should be incorporated into major incident training, and consistent collection of key data from future incidents is required.

Introduction

Terrorist attacks have the aim of causing disruption and widespread fear [1]. In recent years, such attacks have increasingly been designed to cause maximal casualties, and sometimes emergency responders may be targeted [2]-[4]. Early in the emergency response to a terrorist attack, the exact intent, scale, and hazards of an incident may be unclear [5],[6]. Emergency medical service (EMS) responders have occupational fatality rates that are comparable to those of other emergency services [7] and, despite major incident training that advocates prioritization of personal safety above that of the `scene and survivors’ [8], continue to die at terrorist incidents [9],[10].

Without an informed appreciation of the potential threats, an emergency responder is unable to evaluate the risks to personal safety on arrival at a terrorist incident [11]. A rapidly expanding medical literature addresses the increasing burden of international terrorist incidents [12]-[14] (Figure 1), but articles that do directly address scene hazards are mostly anecdotal or based on expert opinion [15],[16], extrapolate a generic approach to safety from single incidents [17], or focus on single threat types that may not be apparent to the responder on arrival at an incident [18]. Few attempts have been made to integrate information from the numerous incidents that occur each year [19],[20].

Figure 1
figure 1

PubMed publications on the subject of terrorism from 1995 through 2013.

This narrative review was conducted to identify hazards to EMS providers involved in the immediate management of terrorist incidents described in the medical literature. The review has the objective of using the risks or harm identified to inform emergency medical responders of likely sources of threat and allow them to mitigate risks to safety at future terrorist incidents.

Methods

Search strategy

The controlled vocabulary of Medical Subject Headings (MeSH) does not include specific terms relevant for this topic. Accordingly, we searched the electronically indexed database PubMed by using the non-indexed `All Field’ terms of `scene AND safety AND terrorism’, `prehospital AND terrorism’, and `emergency AND responder AND terrorism’. Furthermore, we applied an `All Field’ search of PubMed by using the term `terrorism’ to avoid exclusion of relevant articles (Figure 2). The search was last undertaken on 4 February 2014. Literature was limited to English language publications. The reference lists of publications found on the search criteria were scanned to identify additional relevant literature. Additionally, the reports of KAMEDO (Swedish disaster medicine study organization) were included where reporting specifically on terrorist incidents. The search was conducted independently by two authors (JT and MR).

Figure 2
figure 2

Flow diagram of literature search and retrieved results. KAMEDO, Swedish disaster medicine study organization.

Selection criteria

Scoping searches revealed that few articles primarily addressed the subject of scene safety at terrorist incidents, but relevant information was included in many other articles that described the response to terrorist incidents. Therefore, no single article type was specified as an inclusion criterion, and important information was identified in study designs ranging from multi-incident studies of scene hazards through detailed single incident reports to opinion articles (Figure 2).

Data extraction and quality appraisal

All relevant full-text articles were retrieved and assessed for the identification of risks or injury to emergency responders attending terrorist incidents. Scene hazards identified were categorized into direct terrorist threats aimed at EMS providers and, secondly, the environmental hazards of working at an unstable scene. Data on the nature of the threat and risk to emergency responders were extracted. We evaluated manuscript category of the included articles, and no further assessment of methodological quality was made.

Results

The results of the literature search are illustrated in Figure 2.

Threats directed at emergency responders

Secondary explosive devices

Secondary explosive devices are bombs that are placed to cause casualties among emergency personnel responding to incidents. A delay in detonation following a primary explosion or other event is designed to draw in and then target emergency personnel in large numbers and maximize injury and damage to the emergency infrastructure [21],[22]. Terrorist use of explosive devices has increased significantly in recent years, with an estimated fourfold increase worldwide from 1999 to 2006 and with an eightfold increase in related injuries [14]. Even in a country with a low risk of terrorist incidents, such as the US, 36,110 bombing incidents occurred between January 1983 and December 2002, resulting in 5,931 injured and 699 deaths, and the majority of injuries and deaths were caused by primary explosive devices with homicidal intent targeting residential or commercial locations [23]. This analysis of Bureau of Tobacco, Alcohol, Firearms, and Explosives data did not identify whether these victims were emergency medical responders but did note an increasing terrorist tendency to attempt to psychologically intimidate a country’s civilian population rather than target government resources.

The threat of secondary explosive devices creates great concern among emergency responders [5],[22], and emergency responders have been exposed to numerous incidents of improvised explosive device in non-terrorist situations [24]. However, despite the increasing worldwide prevalence of primary explosive devices [14], remarkably few accounts in the medical literature pertain to secondary devices designed to target civilian emergency responders at terrorist incidents [23],[25]. Secondary devices may be more frequent in asymmetrical military conflicts in which a military emergency response may be perceived by the terrorist as a legitimate military target [26]-[28]; however, incidents of this type are not routinely reported in the medical literature.

Perhaps of comfort to the civilian emergency responder is that of the 36,110 bombing incidents identified in the US between 1983 and 2002 [23], only four or five involved secondary devices; of this limited number, two were undertaken by the same individual: in 1997, Atlanta Olympic Park bomber Eric Rudolph planted several devices, including a device that detonated 1 hour after a primary device, injuring four public safety personnel with shrapnel and blast injuries [25].

Further reassurance may be derived from analysis of incidents where secondary devices to target rescuers have been reported. The discovery of four unexploded devices during the aftermath of the Madrid train bombings of 2004 required repeated evacuation of the incident site and rapid evacuation of casualties and has been cited as an attempt to target the emergency response [6]. However, the KAMEDO analysis of the Madrid bombings reports that the four unexploded devices had mobile phone timer triggers identical to the 10 devices that did explode but that the trigger mechanism appears to have been set exactly 12 hours out of synchronization [29]. It may be that the four unexploded devices had been accidentally allocated a different detonation time rather than an intentionally delayed detonation to target responders. Similarly, the KAMEDO report of the Bali bombing of 2002 challenges popular belief of a planned delay between the suicide vest explosion in a packed tourist bar and a minivan explosion on the street outside. It was speculated that this delay was intended to maximize casualties among fleeing revelers and arriving responders [30]. However, KAMEDO reports that the interval between the explosions may have been seconds rather than minutes as originally suspected [31]. These facts do not diminish the catastrophic loss of life in these events but may help counter fears that terrorists are routinely targeting civilian emergency responders.

Small arms fire

Rifles and handguns have been widely used as tools of terrorism across the world and may be used alone or in conjunction with explosive devices [2],[32]. In the US, around 30,000 people are killed each year by guns, and such numbers dwarf fatalities due to biological and other feared but rare modes of terrorism. Deaths due to small arms fire in the US are largely secondary to criminal rather than terrorist activity and present a significant threat to civilian emergency medical responders undertaking their duties in this country [33]. However, in regard to terrorist incidents specifically, there are few accounts of injuries to civilian responders from small arms fire in the medical literature. The majority of reports and analysis are derived from the Israel-Palestine conflict [27],[34].

The perceived threat of small arms incidents dramatically increased following the 2008 attacks in Mumbai, where terrorists used multiple strategies of attack (including automatic weapons), roamed across the city, and remained active for several days. Although the 172 killed and 304 injured are not reported to have been medical personnel, civilians and security forces were killed. This generated worldwide media attention and international fear of repeated `Mumbai-style’ attacks [35].

The horrific massacre of at least 348 people, including 171 children, at a school in Beslan, North Ossetia (Russia), in 2005 included the murder of two paramedics by small arms fire. During negotiations with the terrorists, an agreement was made that Ministry of Emergency Situations medical personnel in two ambulances could safely remove the bodies of 20 murdered hostages from the school grounds. As the paramedics approached the school, the hostage-takers opened fire, killing two rescuers [36].

Although no emergency responders were injured in the 2011 shootings on Utoya island in Norway, the emergency responders were under direct threat during the events. During the establishment of the major incident infrastructure, the initial casualty clearing station came under direct rifle fire from the terrorist. In the same incident, when the victims were being medically assessed in what remained an unsafe environment, medical personnel were not equipped in the same way as other emergency response teams at the scene with appropriate personal protective equipment (PPE) [32].

Chemical hazards

Despite the Chemical Weapons Convention, which came into force in 1997 and which forbids the possession, development, and use of chemical weapons, chemical terrorism remains a threat. Countries that possessed chemical weapons undertook to destroy them, but several states, including Iran, Iraq, Libya, and Israel and its neighboring countries, did not accede to the convention [37]. Even without state support, non-governmental groups or even individuals can successfully manufacture chemical weapons and may remain undetected by government intelligence agencies. Some chemical agents are used in a controlled environment in industry or agriculture and do not require illicit manufacture. Consequently concerns have been expressed regarding the accessibility of agents such as organophosphates and the vulnerability to attack or theft of chemical establishments [38],[39].

In conflict and peacetime, there have been numerous chemical incidents with large numbers of casualties. There have been multiple attempts by terrorists to harness the lethal effect of such agents, but despite generating widespread fear, these attempts have met with limited success to date [37]. Secondary contamination of medical personnel treating contaminated victims is seen to occur in accidental incidents, and one study identified 17 medical personnel injured in this way over a 3-year period in the US [40].

The 1994 sarin nerve agent attacks by the Aum Shinrikyo cult in Matsumoto and Tokyo, Japan, claimed the lives of 19 people and injured over 6,000 [41]-[55]. Health-care workers suffered secondary contamination in both incidents; 18 were affected in Matsumoto [46] and 245 in Tokyo [44],[46],[48],[51]. Identification of the chemical agent was delayed, and contaminated patients were treated on the scene and in the hospital by staff without appropriate PPE. Consequently, secondary contamination of medical staff occurred; in one report, 13 of 15 doctors involved in resuscitating a patient became symptomatic, 6 of whom required atropine [47]. Follow-up of victims after this sarin attack demonstrated chronic decline of psychomotor and memory function at 7 years [43] and high levels of post-traumatic stress disorder (PTSD) at 10 years [56]. The lessons learned from these incidents have informed chemical terrorism preparedness across the world [57].

Biological hazards

Biological warfare (but not research into defense or protection against biological agents) was outlawed by the Biological Weapons Convention in 1972. Biological weapons are biological toxins or infectious agents such as bacteria, viruses, fungi, or parasites intended to kill or incapacitate and have been widely used throughout history [37],[58]. With the exception of some rapidly acting toxins, biological agents usually present only hours or days after exposure with non-specific `flu-like’ symptoms before organ-specific diseases become apparent [58]. The risk presented by biological agents can be classified by their individual pathogenicity, infectivity, latency, lethality, transmissibility, and virulence. The US Centers for Disease Control and Prevention categorize agents depending on the threat that they may pose to national security because of their dissemination, person-to-person transmission, high mortality rates, potential for social disruption, and need for public health preparedness. The Category A (highest priority) organisms are rarely seen in the US and include anthrax, botulism, plague, smallpox, tularemia, and viral hemorrhagic fever [59]. Category B agents are more commonly encountered and include food-and-water safety threats such as Salmonella species, Escherichia coli 0157:H7, and Vibrio cholerae. Ricin is the Category B agent most frequently encountered in the US, can be easily prepared from castor beans, and has been used in `white powder’ letters. Although such acts have been largely criminal in nature rather than true bioterrorism and are frequently hoaxes, such incidents pose a potential threat to emergency medical responders [60]. Successful terrorist use of biological weapons is extremely rare, and one source suggests that only two confirmed terrorist biological attacks have harmed humans [61].

Between October and December 2001, widespread fear was caused across the US by a series of letters containing anthrax spores that were sent to government buildings. Five people died from anthrax, 13 contracted disease, and many thousands were exposed and took preventative antibiotics. Health-care personnel were not specifically targeted, although other emergency services required to deal with suspicious packages were exposed to risk [62].

The difficulty in identifying biological attacks is apparent from the Salmonella typhi outbreak in The Dalles, Oregon, in 1984 when 751 citizens were affected [63]. Only 1 year later did it emerge that the Rajneeshee cult had intentionally contaminated water and salad bars in an attempt to influence a local election result. Similarly, when the Aum Shinrikyo cult was investigated in the wake of the 1995 Tokyo sarin subway attacks, it was discovered that they had built three laboratories to culture Bacillus anthracis, botulinum toxin, and Coxiella burnetti and carried out nine undetected biological weapon attacks between 1990 and 1993 [58],[64].

Secondary biological threat has been identified as a consequence of exposure to contaminated biological material in explosive incidents. Following the London bombings of 7 July 2005, bone fragments from other victims were found embedded as biological foreign bodies within the soft tissues of five patients at one receiving hospital [65]. Similar events have occurred in suicide bombings in Israel and in conflict zones against US military personnel, and protocols have been established for post-exposure interventions to prevent infection with hepatitis B and C, HIV, or tetanus [66]-[68].

Radiation

Nuclear detonation by terrorists is perceived to be unlikely given the state-sponsored level of technology required to develop or deploy a device [37]. A `dirty bomb’ or radiological dispersal device (RDD) is a more likely scenario [69]. Radiation sources are routinely used in science, industry, and medicine and could be used by terrorists to create an RDD. Concerns have been compounded by the low level of security surrounding these sources, and there is documented evidence of multiple missing sources [70]-[72].

A very small amount of radioactive energy can cause serious biological damage. External radiation is primarily gamma radiation that has no mass, travels long distances in air, and penetrates shielding. Alpha and beta particles represent the dominant risk if a radioactive substance has entered the body. Alpha particles consist of two neutrons and two protons, and although they can travel up to 3 cm in air, they cannot penetrate skin but are extremely dangerous if ingested or inhaled. Beta particles are electrons that can penetrate approximately 5 mm in skin and 3 cm in air [73].

In recent decades, there have been multiple radiation accidents, including incidents at nuclear power stations and the accidental misuse of scientific radiation sources [37],[74]. The single non-accidental incident using radiation identified in the medical literature is an assassination that occurred in London in 2006, when Alexander Litvinyenko was poisoned with polonium-210. The single victim is alleged to have unknowingly ingested an alpha source and died 22 days later suffering from multiorgan failure as a result of radiation. Despite the limited size of this polonium-210 source, the potential scale of the radiation contamination was illustrated by the 664 individuals from 52 countries who were considered at risk of exposure following this single incident [75].

Secondary threats for emergency responders

Environmental hazards

Although chemical, biological, radiological, nuclear, and explosive (CBRNE) hazards are correctly emphasized when terrorist incidents are discussed, the more conventional scene hazards of working in an unstable environment may be associated with greater risk [76]. The list of potential sources of danger at an incident is lengthy. However, one generic approach to risk identification is that of identifying and mitigating the threat of unstable energy sources, most commonly in the form of kinetic, potential, electrical, or thermal energy [11]. This theoretical exercise can identify the key hazards of many high-risk environments but may be of limited practical assistance when confronted by a mass casualty terrorist incident.

If the medical literature is assessed to determine the main environmental threats at terrorist incidents, the majority of the relevant publications assess the aftermath of the 9/11 attacks, where extraordinary resources were required both in the initial phase of the response and in the prolonged process of rescue and recovery. Unprecedented numbers of rescuers worked at the site, and their experience has created an unparalleled resource documenting the medical sequelae of responding to such an incident. Between 14 and 21 November 2001, a medical center was established at the scene of the World Trade Center (WTC) attacks and treated 9,349 rescue and recovery personnel working on the site. The most common presentations were traumatic injuries (29%), respiratory problems (22%), and eye complaints (12%). The medical literature published following the 9/11 attacks and other international terrorist incidents has illustrated several principal immediate hazards and long-term consequences.

Airborne particles

Explosions, fire, and building collapses as a consequence of terrorist activity create dust clouds containing particulate matter that may have an immediate and a delayed health impact for emergency responders. This effect has been most extensively studied following the 9/11 attacks [77]. Although no air-sampling monitors were operating close to the WTC on the day of this attack, analysis of fallen dust samples was performed 5 and 6 days afterward. This demonstrated contamination (1% to 4% by weight) with particles small enough to be respirable in rescue workers without protective masks [78]. Early symptoms reported included eye, skin, respiratory, and nose and throat complaints [79].

Extensive longitudinal study of WTC workers has been undertaken and has demonstrated that this cohort has an increased incidence of asthma, sinusitis, chemosensory loss, sarcoidosis, and gastroesophageal reflux disease [80]-[83]. Additionally, suspected carcinogens in the dust cloud have been proposed as the cause of excess risk for prostate cancer, thyroid cancer, and myeloma in WTC rescue workers when compared with that for New York State residents [84]. Appropriate respiratory protection reduces the risk of the respiratory and systemic manifestations of airborne pollutants [85]. In emergency responders to the 9/11 attacks, longer delays in the initial use of masks or respirators were associated with an increased risk of asthma, as was earlier arrival and longer duration of exposure [86].

Structural instability

Building collapse has been proposed as the most important risk factor for fatality in building bombings [87], and residents and responders are at risk following an incident. When the twin towers of the WTC collapsed, over 400 emergency responders lost their lives [88]. Proposals for reducing fatalities in a building bombing include evacuation planning exercises for vulnerable buildings and regular evacuation training of personnel [87],[89]. Appropriate PPE, including eye protection, can reduce the risk of injury due to falling objects and flying glass [90],[91].

Fire

Fires at terrorist incidents may continue to burn for many weeks and pose an ongoing threat of both direct thermal injury and inhaled toxic agents, such as carbon monoxide and hydrogen cyanide [9],[92]-[94]. Close communication with fire services and the avoidance of exposure unless wearing appropriate PPE are central to minimizing risk [11],[92].

Mental health

Many studies have identified psychopathology among emergency responders to terrorist incidents [95]-[103]. Although the prevalence of PTSD varies greatly between studies and incidents, one of the largest cohorts studied consists of the 28,962 rescue workers who worked at the WTC site. The overall prevalence of PTSD among rescue/recovery workers was 12.4%, but the risk was increased in those who arrived earlier, who worked for longer, and who were asked to undertake roles that were not within their usual professional remit [104]. A longitudinal study of a similar cohort of WTC rescue and recovery workers demonstrated a cumulative incidence of depression of 27.5%, PTSD in 31.9%, and panic disorder in 21.2% [82].

Protective factors that may reduce the risk of developing psychiatric illness following exposure to a terrorist incident include good pre-event mental health, disaster preparedness training, and shift rotations that limit the duration of an individual’s exposure to the scene [102],[104]. Moreover, exhaustion and sleep deprivation have been demonstrated to impair threat detection and may compound the risk of exposure to other scene hazards [105]. Psychiatric services have recently been proposed to have an important role in disaster response planning [106], and critical incident stress debriefing has been reported to mitigate the impact of an event [107]. However, even if staff members are aware that such services exist, they are often reluctant to seek help [102],[103]. Once psychiatric illness has developed, cognitive behavioral and virtual reality therapies have both been demonstrated to reduce symptom scores in PTSD following terrorist incidents [108],[109].

Discussion

To the best of our knowledge, this is the first systematic review of the medical literature that aims to identify the hazards that emergency responders have been exposed to at international terrorist incidents. The threat of CBRNE hazards exists at terrorist and non-terrorist incidents, and the risks must be actively mitigated. However, direct injury to emergency responders from such hazards is extremely rare and is dwarfed by the more conventional scene hazards that professionals encounter when responding to both terrorist and non-terrorist incidents [7],[11],[33],[110].

This strategy of systematically seeking evidence-based information from the published medical literature is a conventional medical and scientific methodology [111]. Additionally, this approach creates clear boundaries in source materials when addressing such a security-sensitive issue as terrorism. However, on this subject, the approach and the available medical literature do have limitations. Despite the number of publications, the medical literature does not present a comprehensive account of international terrorist incidents or their medical sequelae. Medical publications do not reflect the daily terrorist attacks across the globe but rather cluster around high-profile events that occur in countries with a culture of medical publication [12],[13]. Organizations that are dedicated to producing high-quality analysis and recommendations from international incidents have the capacity to report only a handful of the thousands of incidents that occur each year [37]. Even accurately establishing the denominator of total terrorist incidents remains challenging in the open-source literature, with varying global estimates and methodological difficulties in verifying data even in individual developed countries [112]. One source of worldwide data on terrorist incidents identified 19,828 incidents with 86,568 injured casualties and 25,408 fatalities between 1968 and 2004 [113], and only a small fraction of these incidents generated medical publications. Medical publications that do arise from terrorist incidents are of variable format and quality. Little standardization exists in the published incident reports, and few explicitly address issues such as scene safety, which may be of critical importance to future planning and safety.

Critical information regarding scene hazards is frequently encountered in the text of reports of the medical response to terrorist incidents but is usually incidental to the principal subject of the article. Closer examination of the included studies indicated inconsistent indexing of articles on risks to EMS responders at terrorist incidents on PubMed. Increasingly consistent reporting of studies related to EMS personnel safety may reduce these limitations.

The limited publication focus on the early medical response is reflected in the fact that 40% of disaster-related publications address the subject of mental health compared with only 4% on the subject of emergency response [13]. This may indicate the difficulties in data collection from chaotic scenes as opposed to the relative ease of psychological assessment in the long recovery phase.

Despite these limitations, the medical literature represents a large and extremely valuable source of information from hundreds of incidents that together should inform future practice. Other studies have similarly used a systematic approach to local and international incidents and derived high-quality evidence and identified recurrent systematic problems that may improve the quality and safety of future response [19],[20],[23],[114]. The results of this study may be used to further inform the provision of training and PPE for emergency services personnel who may be expected to respond in the early stages of terrorist incidents.

If the medical response to terrorist incidents is to be based on evidence rather than anecdote, then further analysis of the literature and future incidents should be undertaken. However, to achieve this, there is a critical need to improve international data collection. Several groups have published standardized medical reporting templates for major incidents but, despite their quality as research tools, they are not being routinely used [115],[116]. If the focus is to be on learning from the growing international burden of terrorist incidents across the world, then a medical reporting mechanism that does not have the high barrier that conventional medical publication presents needs to be established. A template for reporting pre-hospital major incident medical management has recently been developed following a consensus process of European major incident experts [117]. This template has been incorporated into an open-access website [118], allowing reporting of critical information that may help save the lives of victims and responders in future terrorist incidents.

Conclusions

Current major incident training emphasizes the importance of personal safety but is unable to provide an evidence-based analysis of the scene hazards encountered at terrorist incidents. There is a need to refine safety guidance for emergency medical responders in light of the experience from the thousands of international incidents that occur each year. The medical literature represents an incomplete and inconsistent record of the global burden of terrorist incidents but reports a diverse range of threats at previous incidents. Interestingly, while the direct terrorist threats of CBRNE constitute the principal focus of major incident training and the predominant fears of responders, the conventional scene hazards of building collapse, airborne particles, and mental health sequelae continue to cause greater harm to emergency responders. If the medical response to terrorist incidents is to be based on evidence rather than anecdote, analysis of the current literature should be incorporated into major incident training. Of critical importance is the need to improve data collection from major incidents so that the emergency response can develop an evidence-based approach to saving the lives of victims and responders in the future.

Abbreviations

CBRNE:

Chemical, biological, radiological, nuclear and explosive

EMS:

Emergency medical service

KAMEDO:

Swedish disaster medicine study organization

PPE:

Personal protective equipment

PTSD:

Post-traumatic stress disorder

RDD:

Radiological dispersal device

WTC:

World Trade Center

References

  1. Arnold JL, Ortenwall P, Birnbaum ML, Sundnes KO, Aggrawal A, Anantharaman V, Al Musleh AW, Asai Y, Burkle FM, Chung JM, Cruz-Vega F, Debacker M, Della Corte F, Delooz H, Dickinson G, Hodgetts T, Holliman CJ, MacFarlane C, Rodoplu U, Stok E, Tsai MC: A proposed universal medical and public health definition of terrorism. Prehosp Disaster Med. 2003, 18: 47-52.

    Google Scholar 

  2. Eckstein M, Cowen AR: Scene safety in the face of automatic weapons fire: a new dilemma for EMS?. Prehosp Emerg Care. 1998, 2: 117-122.

    Google Scholar 

  3. Borum R, Gelles M: Al-Qaeda’s operational evolution: behavioral and organizational perspectives. Behav Sci Law. 2005, 23: 467-483.

    Google Scholar 

  4. Morrison AR: `Animal rights’ terrorists/extremists: a serious threat to medicine. Mo Med. 2006, 103: 467-471.

    Google Scholar 

  5. Lockey DJ, Mackenzie R, Redhead J, Wise D, Harris T, Weaver A, Hines K, Davies GE: London bombings July 2005: the immediate pre-hospital medical response. Resuscitation. 2005, 66: 9-12.

    Google Scholar 

  6. Carresi AL: The 2004 Madrid train bombings: an analysis of pre-hospital management. Disasters. 2008, 32: 41-65.

    Google Scholar 

  7. Maguire BJ, Hunting KL, Smith GS, Levick NR: Occupational fatalities in emergency medical services: a hidden crisis. Ann Emerg Med. 2002, 40: 625-632.

    Google Scholar 

  8. Major Incident Medical Management and Support: The Practical Approach at the Scene. 2011, BMJ Books, under license by John Wiley & Sons Ltd (Wiley-Blackwell), Chichester, UK

  9. Kotelchuck D: Fire and emergency safety issues: lessons learned post September 11, 2001. Am J Ind Med. 2002, 42: 555-556.

    Google Scholar 

  10. Clark P: The Occupational Safety and Health Administration’s response to the World Trade Center attack. Am J Ind Med. 2002, 42: 550-552.

    Google Scholar 

  11. Calland V: A brief overview of personal safety at incident sites. Emerg Med J. 2006, 23: 878-882.

    Google Scholar 

  12. Kelen G, Sauer LM: Trend analysis of disaster health articles in peer-reviewed publications pre- and post-9/11. Am J Disaster Med. 2008, 3: 369-376.

    Google Scholar 

  13. Smith E, Wasiak J, Sen A, Archer F, Burkle FM: Three decades of disasters: a review of disaster-specific literature from 1977-2009. Prehosp Disaster Med. 2009, 24: 306-311.

    Google Scholar 

  14. Wolf SJ, Bebarta VS, Bonnett CJ, Pons PT, Cantrill SV: Blast injuries. Lancet. 2009, 374: 405-415.

    Google Scholar 

  15. Christen HT, Denney JP, Maniscalco PM, Rubin DL: Terrorism. Part III - response procedures for terrorist/tactical violence incidents. JEMS. 1999, 24: 58-64. 66

    Google Scholar 

  16. Maniscalco PM, Christen HT, Rubin DL, Kim P: Terrorism. Part 1: calibrating your risks and response. JEMS. 1998, 23: 38-40. 42-34, 46-51

    Google Scholar 

  17. Reports from the New York/New Jersey Occupational Safety and Health Educational Research Center 23rd annual meeting: April 5, 2002. Am J Ind Med. 2002, 42: 529-565.

  18. Baker D: Civilian exposure to toxic agents: emergency medical response. Prehosp Disaster Med. 2004, 19: 174-178.

    Google Scholar 

  19. Frykberg ER, Tepas JJ: Terrorist bombings: lessons learned from Belfast to Beirut. Ann Surg. 1988, 208: 569-576.

    Google Scholar 

  20. Juffermans J, Bierens JJ: Recurrent medical response problems during five recent disasters in the Netherlands. Prehosp Disaster Med. 2010, 25: 127-136.

    Google Scholar 

  21. Turégano-Fuentes F, Pérez-Díaz D: Medical response to the 2005 terrorist bombings in London. Lancet. 2006, 368: 2188-2189.

    Google Scholar 

  22. Vernon A: Explosive devices: what every responder should know about IEDs. JEMS. 2010, 35: 42-47.

    Google Scholar 

  23. Kapur GB, Hutson HR, Davis MA, Rice PL: The United States twenty-year experience with bombing incidents: implications for terrorism preparedness and medical response. J Trauma. 2005, 59: 1436-1444.

    Google Scholar 

  24. Dickinson E: Crosshairs on EMS: responding to MCIs caused by low-tech terrorism. JEMS. 2013, 38: 46-51.

    Google Scholar 

  25. Feliciano DV, Anderson GV, Rozycki GS, Ingram WL, Ansley JP, Namias N, Salomone JP, Cantwell JD: Management of casualties from the bombing at the centennial olympics. Am J Surg. 1998, 176: 538-543.

    Google Scholar 

  26. Ramasamy A, Hill AM, Clasper JC: Improvised explosive devices: pathophysiology, injury profiles and current medical management. J R Army Med Corps. 2009, 155: 265-272.

    Google Scholar 

  27. Nordberg M: Terrorism’s bloody trail: learning tragic lessons in scene safety from the Israelis. Emerg Med Serv. 1996, 25: 70-74. 81

    Google Scholar 

  28. Hodgetts TJ: Lessons from the Musgrave Park Hospital bombing. Injury. 1993, 24: 219-221.

    Google Scholar 

  29. Bolling R, Ehrlin Y, Forsberg R, Ruter A, Soest V, Vikstrom T, Ortenwall P, Brandstrom H: KAMEDO Report 90: terrorist attacks in Madrid, Spain, 2004. Prehosp Disaster Med. 2007, 22: 252-257.

    Google Scholar 

  30. Southwick GJ, Pethick AJ, Thalayasingam P, Vijayasekaran VS, Hogg JJ: Australian doctors in Bali: the initial medical response to the Bali bombing. Med J Aust. 2002, 177: 624-626.

    Google Scholar 

  31. Brolen P, Ortenwall P, Osterhed H, Brandstrom H: KAMEDO Report 89: terrorist attack in Bali, 2002. Prehosp Disaster Med. 2007, 22: 246-250.

    Google Scholar 

  32. Sollid SJ, Rimstad R, Rehn M, Nakstad AR, Tomlinson AE, Strand T, Heimdal HJ, Nilsen JE, Sandberg M: Oslo government district bombing and Utoya island shooting July 22, 2011: the immediate prehospital emergency medical service response. Scand J Trauma Resusc Emerg Med. 2012, 20: 3-

    Google Scholar 

  33. Whitlock DR: Bioterror killed five in US; guns kill 30,000 a year. Nature. 2005, 436: 460-

    Google Scholar 

  34. Peleg K, Aharonson-Daniel L, Stein M, Michaelson M, Kluger Y, Simon D, Noji EK: Gunshot and explosion injuries: characteristics, outcomes, and implications for care of terror-related injuries in Israel. Ann Surg. 2004, 239: 311-318.

    Google Scholar 

  35. Roy N, Kapil V, Subbarao I, Ashkenazi I: Mass casualty response in the 2008 Mumbai terrorist attacks. Disaster Med Public Health Prep. 2011, 5: 273-279.

    Google Scholar 

  36. McAllister JF, Quinn-Judge P, Zarakhovich Y: Defenseless targets. Time. 2004, 36: 16-

    Google Scholar 

  37. Thirty-Five Years of Disaster-Medicine Studies - Experience from KAMEDO’s Operations 1963-1998 - KAMEDO-Report 73. Stockholm, Sweden: Swedish Disaster Medicine Study Organization (KAMEDO); 2000 [], [http://www.socialstyrelsen.se/publikationer2000/2000-0-81]

  38. Jaeger CD: Chemical facility vulnerability assessment project. J Hazard Mater. 2003, 104: 207-213.

    Google Scholar 

  39. Jaga K, Dharmani C: Sources of exposure to and public health implications of organophosphate pesticides. Rev Panam Salud Publica. 2003, 14: 171-185.

    Google Scholar 

  40. Horton DK, Orr M, Tsongas T, Leiker R, Kapil V: Secondary contamination of medical personnel, equipment, and facilities resulting from hazardous materials events, 2003-2006. Disaster Med Public Health Prep. 2008, 2: 104-113.

    Google Scholar 

  41. Asai Y, Arnold JL: Terrorism in Japan. Prehosp Disaster Med. 2003, 18: 106-114.

    Google Scholar 

  42. Krivoy A, Layish I, Rotman E, Goldberg A, Yehezkelli Y: OP or not OP: the medical challenge at the chemical terrorism scene. Prehosp Disaster Med. 2005, 20: 155-158.

    Google Scholar 

  43. Miyaki K, Nishiwaki Y, Maekawa K, Ogawa Y, Asukai N, Yoshimura K, Etoh N, Matsumoto Y, Kikuchi Y, Kumagai N, Omae K: Effects of sarin on the nervous system of subway workers seven years after the Tokyo subway sarin attack. J Occup Health. 2005, 47: 299-304.

    Google Scholar 

  44. Morita H, Yanagisawa N, Nakajima T, Shimizu M, Hirabayashi H, Okudera H, Nohara M, Midorikawa Y, Mimura S: Sarin poisoning in Matsumoto, Japan. Lancet. 1995, 346: 290-293.

    Google Scholar 

  45. Nakajima T, Ohta S, Morita H, Midorikawa Y, Mimura S, Yanagisawa N: Epidemiological study of sarin poisoning in Matsumoto City, Japan. J Epidemiol. 1998, 8: 33-41.

    Google Scholar 

  46. Nakajima T, Sato S, Morita H, Yanagisawa N: Sarin poisoning of a rescue team in the Matsumoto sarin incident in Japan. Occup Environ Med. 1997, 54: 697-701.

    Google Scholar 

  47. Nozaki H, Hori S, Shinozawa Y, Fujishima S, Takuma K, Sagoh M, Kimura H, Ohki T, Suzuki M, Aikawa N: Secondary exposure of medical staff to sarin vapor in the emergency room. Intensive Care Med. 1995, 21: 1032-1035.

    Google Scholar 

  48. Okudera H, Morita H, Iwashita T, Shibata T, Otagiri T, Kobayashi S, Yanagisawa N: Unexpected nerve gas exposure in the city of Matsumoto: report of rescue activity in the first sarin gas terrorism. Am J Emerg Med. 1997, 15: 527-528.

    Google Scholar 

  49. Okumura T, Suzuki K, Fukuda A, Kohama A, Takasu N, Ishimatsu S, Hinohara S: The Tokyo subway sarin attack: disaster management, Part 3: national and international responses. Acad Emerg Med. 1998, 5: 625-628.

    Google Scholar 

  50. Okumura T, Suzuki K, Fukuda A, Kohama A, Takasu N, Ishimatsu S, Hinohara S: The Tokyo subway sarin attack: disaster management, Part 2: hospital response. Acad Emerg Med. 1998, 5: 618-624.

    Google Scholar 

  51. Okumura T, Suzuki K, Fukuda A, Kohama A, Takasu N, Ishimatsu S, Hinohara S: The Tokyo subway sarin attack: disaster management, Part 1: community emergency response. Acad Emerg Med. 1998, 5: 613-617.

    Google Scholar 

  52. Suzuki J, Kohno T, Tsukagosi M, Furuhata T, Yamazaki K: Eighteen cases exposed to sarin in Matsumoto, Japan. Intern Med. 1997, 36: 466-470.

    Google Scholar 

  53. Tokuda Y, Kikuchi M, Takahashi O, Stein GH: Prehospital management of sarin nerve gas terrorism in urban settings: 10 years of progress after the Tokyo subway sarin attack. Resuscitation. 2006, 68: 193-202.

    Google Scholar 

  54. Vale A: What lessons can we learn from the Japanese sarin attacks?. Przegl Lek. 2005, 62: 528-532.

    Google Scholar 

  55. Yanagisawa N, Morita H, Nakajima T: Sarin experiences in Japan: acute toxicity and long-term effects. J Neurol Sci. 2006, 249: 76-85.

    Google Scholar 

  56. Hoffman A, Eisenkraft A, Finkelstein A, Schein O, Rotman E, Dushnitsky T: A decade after the Tokyo sarin attack: a review of neurological follow-up of the victims. Mil Med. 2007, 172: 607-610.

    Google Scholar 

  57. Okumura T, Hisaoka T, Yamada A, Naito T, Isonuma H, Okumura S, Miura K, Sakurada M, Maekawa H, Ishimatsu S, Takasu N, Suzuki K: The Tokyo subway sarin attack - lessons learned. Toxicol Appl Pharmacol. 2005, 207: 471-476.

    Google Scholar 

  58. White SM: Chemical and biological weapons: implications for anaesthesia and intensive care. Br J Anaesth. 2002, 89: 306-324.

    Google Scholar 

  59. Darling RG, Catlett CL, Huebner KD, Jarrett DG: Threats in bioterrorism. I: CDC category A agents. Emerg Med Clin North Am. 2002, 20: 273-309.

    Google Scholar 

  60. Hodge DR, Prentice KW, Ramage JG, Prezioso S, Gauthier C, Swanson T, Hastings R, Basavanna U, Datta S, Sharma SK, Garber EA, Staab A, Pettit D, Drumgoole R, Swaney E, Estacio PL, Elder IA, Kovacs G, Morse BS, Kellogg RB, Stanker L, Morse SA, Pillai SP: Comprehensive laboratory evaluation of a highly specific lateral flow assay for the presumptive identification of ricin in suspicious white powders and environmental samples. Biosecur Bioterror. 2013, 11: 237-250.

    Google Scholar 

  61. Deadly Cultures: Biological Weapons Since 1945. 2006, Harvard University Press, Cambridge, MA

  62. McCarthy M: Anthrax in USA - attacks `deadly but treatable’. Lancet. 2001, 358: 1520-

    Google Scholar 

  63. Byers M, Russell M, Lockey DJ: Clinical care in the `Hot Zone’. Emerg Med J. 2008, 25: 108-112.

    Google Scholar 

  64. Kaplan DE, Marshall A: The Cult at the End of the World: The Terrifying Story of the Aum Doomsday Cult, from the Subways of Tokyo to the Nuclear Arsenals of Russia. 1996, Crown, New York

    Google Scholar 

  65. Wong JM, Marsh D, Abu-Sitta G, Lau S, Mann HA, Nawabi DH, Patel H: Biological foreign body implantation in victims of the London July 7th suicide bombings. J Trauma. 2006, 60: 402-404.

    Google Scholar 

  66. Chapman LE, Sullivent EE, Grohskopf LA, Beltrami EM, Perz JF, Kretsinger K, Panlilio AL, Thompson ND, Ehrenberg RL, Gensheimer KF, Duchin JS, Kilmarx PH, Hunt RC: Postexposure interventions to prevent infection with HBV, HCV, or HIV, and tetanus in people wounded during bombings and other mass casualty events - United States, 2008: recommendations of the Centers for Disease Control and Prevention and Disaster Medicine and Public Health Preparedness. Disaster Med Public Health Prep. 2008, 2: 150-165.

    Google Scholar 

  67. Clint BD: Force protection and infectious risk mitigation from suicide bombers. Mil Med. 2009, 174: 709-714.

    Google Scholar 

  68. Eshkol Z, Katz K: Injuries from biologic material of suicide bombers. Injury. 2005, 36: 271-274.

    Google Scholar 

  69. Ring JP: Radiation risks and dirty bombs. Health Phys. 2004, 86: S42-S47.

    Google Scholar 

  70. Govaerts P: Loss and uncontrolled use of radioactive sources. Verh K Acad Geneeskd Belg. 2005, 67: 317-328.

    Google Scholar 

  71. Mintz RD: Safety and security of radiation sources in the aftermath of 11 September 2001. Health Phys. 2003, 84: 380-author reply 381

    Google Scholar 

  72. Leidholdt EM, William GE, McGuire LE: A reassessment of radioactive material security in health care and biomedical research. Health Phys. 2003, 85: S15-S19.

    Google Scholar 

  73. Burnham JW, Franco J: Radiation. Crit Care Clin. 2005, 21: 785-813. vii-viii

    Google Scholar 

  74. Steinhausler F: Chernobyl and Goiania lessons for responding to radiological terrorism. Health Phys. 2005, 89: 566-574.

    Google Scholar 

  75. Shaw K, Anders K, Olowokure B, Fraser G, Maguire H, Bailey M, Smith J, Frossell S, Yap K, Evans B: The international follow-up of individuals potentially exposed to polonium-210 in London 2006. Public Health. 2010, 124: 319-325.

    Google Scholar 

  76. Perritt KR, Boal WL: Injuries and illnesses treated at the World Trade Center, 14 September-20 November 2001. Prehosp Disaster Med. 2005, 20: 177-183.

    Google Scholar 

  77. Use of respiratory protection among responders at the World Trade Center site - New York City, September 2001. MMWR Morb Mortal Wkly Rep. 2002, 51 Spec No: 6-8.

  78. Gavett SH: World Trade Center fine particulate matter - chemistry and toxic respiratory effects: an overview. Environ Health Perspect. 2003, 111: 971-

    Google Scholar 

  79. Feldman DM, Baron SL, Bernard BP, Lushniak BD, Banauch G, Arcentales N, Kelly KJ, Prezant DJ: Symptoms, respirator use, and pulmonary function changes among New York City firefighters responding to the World Trade Center disaster. Chest. 2004, 125: 1256-1264.

    Google Scholar 

  80. Dalton PH, Opiekun RE, Gould M, McDermott R, Wilson T, Maute C, Ozdener MH, Zhao K, Emmett E, Lees PS, Herbert R, Moline J: Chemosensory loss: functional consequences of the world trade center disaster. Environ Health Perspect. 2010, 118: 1251-1256.

    Google Scholar 

  81. Kim H, Herbert R, Landrigan P, Markowitz SB, Moline JM, Savitz DA, Todd AC, Udasin IG, Wisnivesky JP: Increased rates of asthma among World Trade Center disaster responders. Am J Ind Med. 2012, 55: 44-53.

    Google Scholar 

  82. Wisnivesky JP, Teitelbaum SL, Todd AC, Boffetta P, Crane M, Crowley L, De la Hoz RE, Dellenbaugh C, Harrison D, Herbert R, Kim H, Jeon Y, Kaplan J, Katz C, Levin S, Luft B, Markowitz S, Moline JM, Ozbay F, Pietrzak RH, Shapiro M, Sharma V, Skloot G, Southwick S, Stevenson LA, Udasin I, Wallenstein S, Landrigan PJ: Persistence of multiple illnesses in World Trade Center rescue and recovery workers: a cohort study. Lancet. 2011, 378: 888-897.

    Google Scholar 

  83. Izbicki G, Chavko R, Banauch GI, Weiden MD, Berger KI, Aldrich TK, Hall C, Kelly KJ, Prezant DJ: World Trade Center `sarcoid-like’ granulomatous pulmonary disease in New York City Fire Department rescue workers. Chest. 2007, 131: 1414-1423.

    Google Scholar 

  84. Li J, Cone JE, Kahn AR, Brackbill RM, Farfel MR, Greene CM, Hadler JL, Stayner LT, Stellman SD: Association between World Trade Center exposure and excess cancer risk. JAMA. 2012, 308: 2479-2488.

    Google Scholar 

  85. Byers M, Greaves I: Respiratory protection for Health Care Workers. J R Army Med Corps. 2006, 152: 225-230.

    Google Scholar 

  86. Wheeler K, McKelvey W, Thorpe L, Perrin M, Cone J, Kass D, Farfel M, Thomas P, Brackbill R: Asthma diagnosed after 11 September 2001 among rescue and recovery workers: findings from the World Trade Center Health Registry. Environ Health Perspect. 2007, 115: 1584-1590.

    Google Scholar 

  87. Glenshaw MT, Vernick JS, Li G, Sorock GS, Brown S, Mallonee S: Preventing fatalities in building bombings: what can we learn from the Oklahoma City bombing?. Disaster Med Public Health Prep. 2007, 1: 27-31. discussion 31-23

    Google Scholar 

  88. Reissman DB, Howard J: Responder safety and health: preparing for future disasters. Mt Sinai J Med. 2008, 75: 135-141.

    Google Scholar 

  89. Gershon RR, Qureshi KA, Rubin MS, Raveis VH: Factors associated with high-rise evacuation: qualitative results from the World Trade Center Evacuation Study. Prehosp Disaster Med. 2007, 22: 165-173.

    Google Scholar 

  90. Mines M, Thach A, Mallonee S, Hildebrand L, Shariat S: Ocular injuries sustained by survivors of the Oklahoma City bombing. Ophthalmology. 2000, 107: 837-843.

    Google Scholar 

  91. Thompson D, Brown S, Mallonee S, Sunshine D: Fatal and non-fatal injuries among U.S. Air Force personnel resulting from the terrorist bombing of the Khobar Towers. J Trauma. 2004, 57: 208-215.

    Google Scholar 

  92. Bradt DA: Site management of health issues in the 2001 World Trade Center disaster. Acad Emerg Med. 2003, 10: 650-660.

    Google Scholar 

  93. Land A, Irby D: Disaster planning & fire safety. Occup Health Saf. 2001, 70: 28-30.

    Google Scholar 

  94. Spadafora R: Firefighter safety and health issues at the World Trade Center site. Am J Ind Med. 2002, 42: 532-538.

    Google Scholar 

  95. Benedek DM, Fullerton C, Ursano RJ: First responders: mental health consequences of natural and human-made disasters for public health and public safety workers. Annu Rev Public Health. 2007, 28: 55-68.

    Google Scholar 

  96. Berninger A, Webber MP, Cohen HW, Gustave J, Lee R, Niles JK, Chiu S, Zeig-Owens R, Soo J, Kelly K, Prezant DJ: Trends of elevated PTSD risk in firefighters exposed to the World Trade Center disaster: 2001-2005. Public Health Rep. 2010, 125: 556-566.

    Google Scholar 

  97. Bills CB, Levy NA, Sharma V, Charney DS, Herbert R, Moline J, Katz CL: Mental health of workers and volunteers responding to events of 9/11: review of the literature. Mt Sinai J Med. 2008, 75: 115-127.

    Google Scholar 

  98. Bowler RM, Harris M, Li J, Gocheva V, Stellman SD, Wilson K, Alper H, Schwarzer R, Cone JE: Longitudinal mental health impact among police responders to the 9/11 terrorist attack. Am J Ind Med. 2012, 55: 297-312.

    Google Scholar 

  99. Salguero JM, Fernández-Berrocal P, Iruarrizaga I, Cano-Vindel A, Galea S: Major depressive disorder following terrorist attacks: a systematic review of prevalence, course and correlates. BMC Psychiatry. 2011, 11: 96-

    Google Scholar 

  100. Simeon D, Greenberg J, Nelson D, Schmeidler J, Hollander E: Dissociation and posttraumatic stress 1 year after the World Trade Center disaster: follow-up of a longitudinal survey. J Clin Psychiatry. 2005, 66: 231-237.

    Google Scholar 

  101. Guscott WM, Guscott AJ, Malingambi G, Parker R: The Bali bombings and the evolving mental health response to disaster in Australia: lessons from Darwin. J Psychiatr Ment Health Nurs. 2007, 14: 239-242.

    Google Scholar 

  102. Luce A, Firth-Cozens J, Midgley S, Burges C: After the Omagh bomb: posttraumatic stress disorder in health service staff. J Trauma Stress. 2002, 15: 27-30.

    Google Scholar 

  103. Misra M, Greenberg N, Hutchinson C, Brain A, Glozier N: Psychological impact upon London Ambulance Service of the 2005 bombings. Occup Med (Lond). 2009, 59: 428-433.

    Google Scholar 

  104. Perrin MA, DiGrande L, Wheeler K, Thorpe L, Farfel M, Brackbill R: Differences in PTSD prevalence and associated risk factors among World Trade Center disaster rescue and recovery workers. Am J Psychiatry. 2007, 164: 1385-1394.

    Google Scholar 

  105. Basner M, Rubinstein J, Fomberstein KM, Coble MC, Ecker A, Avinash D, Dinges DF: Effects of night work, sleep loss and time on task on simulated threat detection performance. Sleep. 2008, 31: 1251-1259.

    Google Scholar 

  106. McCabe OL, Everly GS, Siegel ER, Heitt MC, Kaminsky MJ: Psychiatry and terrorism: the profession’s role in disaster response planning. Int J Emerg Ment Health. 2004, 6: 197-204.

    Google Scholar 

  107. Hammond J, Brooks J: The World Trade Center attack: helping the helpers: the role of critical incident stress management. Crit Care. 2001, 5: 315-317.

    Google Scholar 

  108. Difede J, Malta LS, Best S, Henn-Haase C, Metzler T, Bryant R, Marmar C: A randomized controlled clinical treatment trial for World Trade Center attack-related PTSD in disaster workers. J Nerv Ment Dis. 2007, 195: 861-865.

    Google Scholar 

  109. Difede J, Cukor J, Patt I, Giosan C, Hoffman H: The application of virtual reality to the treatment of PTSD following the WTC attack. Ann N Y Acad Sci. 2006, 1071: 500-501.

    Google Scholar 

  110. Wilson N, Thomson G: Deaths from international terrorism compared with road crash deaths in OECD countries. Inj Prev. 2005, 11: 332-333.

    Google Scholar 

  111. Moher D, Liberati A, Tetzlaff J, Altman DG: Preferred reporting items for systematic reviews and meta-analyses: the PRISMA statement. Ann Intern Med. 2009, 151: 264-269. W264

    Google Scholar 

  112. Noji EK, Lee CY, Davis T, Peleg K: Investigation of Federal Bureau of Investigation bomb-related death and injury data in the United States between 1988 and 1997. Mil Med. 2005, 170: 595-598.

    Google Scholar 

  113. Bogen KT, Jones ED: Risks of mortality and morbidity from worldwide terrorism: 1968-2004. Risk Anal. 2006, 26: 45-59.

    Google Scholar 

  114. Weinhold B: Emergency responder health: what have we learned from past disasters?. Environ Health Perspect. 2010, 118: a346-a350.

    Google Scholar 

  115. Debacker M, Hubloue I, Dhondt E, Rockenschaub G, Rüter A, Codreanu T, Koenig KL, Schultz C, Peleg K, Halpern P, Stratton S, Della Corte F, Delooz H, Ingrassia PL, Colombo D, Castrèn M: Utstein-style template for uniform data reporting of acute medical response in disasters. PLoS Curr. 2012, 4: e4f6cf3e8df15a-

    Google Scholar 

  116. Fattah S, Rehn M, Reierth E, Wisborg T: Templates for reporting pre-hospital major incident medical management: systematic literature review. BMJ Open. 2012, 2: pii: e001082-

    Google Scholar 

  117. Fattah S, Rehn M, Lockey D, Thompson J, Lossius HM, Wisborg T: A consensus based template for reporting of pre-hospital major incident medical management. Scand J Trauma Resusc Emerg Med. 2014, 22: 5-

    Google Scholar 

  118. Majorincidentreporting.org homepage. [], [http://www.majorincidentreporting.org]

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Thompson, J., Rehn, M., Lossius, H.M. et al. Risks to emergency medical responders at terrorist incidents: a narrative review of the medical literature. Crit Care 18, 521 (2014). https://doi.org/10.1186/s13054-014-0521-1

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