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Communication in Sudden-Onset Major Incidents: Patterns and Challenges—Scoping Review

Published online by Cambridge University Press:  08 September 2023

Peter Martin Hansen*
Affiliation:
The Mobile Emergency Care Unit, Department of Anesthesiology and Intensive Care, Odense University Hospital Svendborg, Svendborg, Denmark Danish Air Ambulance, Aarhus N, Denmark The Prehospital Research Unit, Region of Southern Denmark, Odense University Hospital, Odense, Denmark
Søren Mikkelsen
Affiliation:
The Mobile Emergency Care Unit, Department of Anesthesiology and Intensive Care, Odense University Hospital, Odense, Denmark The Prehospital Research Unit, Region of Southern Denmark, Odense University Hospital, Odense, Denmark Department of Regional Health Research, University of Southern Denmark, Odense, Denmark
Marius Rehn
Affiliation:
Department of Regional Health Research, University of Southern Denmark, Odense, Denmark Department of Research and Development, Norwegian Air Ambulance Foundation, Oslo, Norway Air Ambulance Department, Division of Prehospital Services, Oslo University Hospital, Oslo, Norway Institute of Clinical Medicine, University of Oslo, Oslo, Norway
*
Corresponding author: Peter Martin Hansen; Email: [email protected].
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Abstract

Objective:

To identify and describe patterns and challenges in communication in sudden-onset major incidents.

Methods:

Systematic scoping review according to Joanna Briggs Institute and PRISMA-ScR guidelines. Data sources included Cochrane Library, EMBASE, PubMed/MEDLINE, Scopus, SweMed+, Web of Science, and Google Scholar. Non-indexed literature was searched as well. The included literature went through data extraction and quality appraisal as per pre-registered protocol.

Results:

The scoping review comprised 32 papers from different sources. Communication breakdown was reported in 25 (78.1%) of the included papers. Inter-authority communication challenges were reported in 18 (56.3%) of the papers. System overload and incompatibility was described in 9 papers (28.1%). Study design was clearly described in 30 papers (93.8%).

Conclusions:

The pattern in major incident communication is reflected by frequent breakdowns with potential and actual consequences for patient survival and outcome. The challenges in communication are predominantly inter-authority communication, system overload and incompatibility, and insufficient pre-incident planning and guidelines.

Type
Systematic Review
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of Society for Disaster Medicine and Public Health

Sudden-onset major incidents (MI) are defined as incidents that require the mobilization of extraordinary emergency medical services (EMS) resources. Reference Fattah, Rehn, Reierth and Wisborg1 Communication within and between authorities is essential to achieve, maintain, and execute command and control in MI management. The sheer process of creating and sharing information and facts to reach a common understanding is essential.

Disorder and confusion are common in MI, especially in the initial phase before responding staff are in place and organized. Abnormal situations challenge normal communication routines, potentially hindering professionals in obtaining essential information regarding tasks, risks, and ability to command. Communication breakdown is frequent in MI Reference Sollid, Rimstad and Rehn2,Reference Wurmb, Franke and Schorscher3 and may affect patient outcomes, safety of personnel, and the expedited return to normal conditions. Communication in MI has been sparsely quantified until recently in a case report by Hansen et al. Reference Hansen, Jepsen, Mikkelsen and Rehn4

Modes of communication may range from a verbal exchange of information to sophisticated digital platforms, depending on the geo-political and socio-economic settings of the MI. Low- to middle-income countries may be challenged by a lack of access to reliable, well-functioning communication systems or sufficient communication devices as well as limited planning, education, and training. Conversely, high-income countries with government funded EMS organizations typically utilize encrypted high fidelity and reliability radio systems such as the Terrestrial Trunked Radio 5 (TETRA) standard. Similar systems such as Very High Frequency (VHF) 6 and Ultra High Frequency (UHF) 7 radios, satellite phones, Reference Lamminen8 computer-aided dispatch, Reference Horn9 and digital platforms are in use worldwide. In addition, short wave radios and amateur (ham) radios may be used in MI management.

Communication in MI relies on technological and human integration, interpretation, processing, and output of data. Radiotelephony procedure, 10 radio discipline, 11 the use of the international NATO phonetic spelling alphabet, 12 and voice calling procedures 13 are crucial structural communication adjuncts. Human factors in emergency communication are described in theoretical models such as the Shannon Weaver Reference Chandler14 model of communication and Endsley’s model of Situation Awareness Reference Endsley15 that describe the influence of factors such as stress, fatigue, interface design, and expectations on emergency communication.

Several emergency authorities are involved in the management of MI, depending on the complexity and severity of the MI in question. Communication between authorities is essential to maintain command and control, and, therefore, inter-authority communication challenges are pivotal to the review. Similarly, communication within 1 authority is defined as intra-authority communication. Therefore, the mechanisms and mitigating actions in MI communication are identical worldwide, whereas the outcome depends on a multitude of factors, such as the socio-economic arena, pre-incident MI preparedness and training, and society infrastructure.

Technology failure due to system overload, damage, or destruction may compromise MI communication. Reference De Cauwer, Barten and Willems16 Similarly, incompatibility between systems used by emergency authorities can challenge MI communication.

This study aimed to systematically identify and extract the existing literature on communication in the medical management of sudden-onset MI. Furthermore, the study aimed to provide an overview of both scientific and non-indexed literature on the topic with no limitation concerning the type of study design. To our best knowledge, this is the first review of communication in MI. There is a potential to identify similarities between countries and to call for common techniques for improved results.

The review question asked in this scoping review was: What are the patterns and challenges in communication in sudden-onset major incidents?

Methods

Protocol and Registration

The authors conducted a scoping review with a narrative synthesis and reported this according to the JBI Reference Peters, Godfrey and Khalil17 (formerly known as Joanna Briggs Institute) protocol and Preferred Reporting Items for Systematic Reviews and Meta-Analysis Extension for Scoping Reviews (PRISMA ScR) Reference Page, McKenzie and Bossuyt18 guidelines for reporting of systematic and scoping reviews. The protocol was published on Open Science Framework (OSF) on November 12, 2021, with registration no. 10.17605/OSF.IO/MBT7V (https://doi.org/10.17605/OSF.IO/MBT7V).

Search Strategy

The search strategy for scientific databases was developed by 1 author who is the subject specialist. The search strategy was peer-reviewed by a research librarian. The search included literature published from 1946 until January 10, 2022. Medical Subject Headings (MeSH) controlled vocabulary was used, including subheadings, various publication types, and the supplementary concept. For the scientific database search, 1 set of entry terms described communication, the second set described MI, and, finally, free search phrases were included. The 3 sets of entry terms were applied and combined (Figure 1). The following databases were searched:

  • Cochrane Library

  • Embase

  • Medline

  • Scopus

  • SveMed+

  • Web of Science

Figure 1. Search strategy. Two sets of entry terms and free search phrases.

The search strategy was developed in Embase and Medline, validated using known references and translated to the additional databases.

One author developed the non-indexed literature search strategy with the assistance of a research librarian. The search included non-indexed literature issued from 1946 until March 15, 2022. The systematic search was performed on March 16–22, 2022. The following databases were searched:

Eligibility Criteria

The current review included literature found by an extensive search that described communication in the medical management of an MI. Furthermore, captured literature stating that the incident described was considered an MI was included in the scoping review.

Inclusion criteria

  • Literature reporting major incident communication

  • Literature published after 1946 and until the date of the literature search

Exclusion criteria

  • Non-English literature, except for Scandinavian

  • Literature without an available abstract in English or Scandinavian

  • Literature reporting only technological aspects

The use of a specific definition was obviated to avoid the exclusion of possible relevant studies. The study population was an MI, concept was communication, and context was medical management of the MI.

Selection of Sources of Evidence

Results were collected and combined in the Endnote20® software Reference Tricco, Lillie and Zarin19 (Alfasoft AB, Gothenburg, Sweden), and duplicate studies were eliminated using the Covidence® (Veritas Health Innovation, Melbourne, Australia) software. Reference Gotschall20 For the identification of potentially eligible studies and papers, 1 author screened titles and abstracts carefully. For eligible studies, full-text retrieval and review were performed.

Data Charting Process and Data Items

As per protocol, the chosen studies were read for data sampling and quality appraisal. A data extraction template was modified from related studies 21,Reference Fattah, Rehn and Lockey22 and validated by 2 authors using known references. Reference Johnsen, Fattah, Sollid and Rehn23,Reference Peters, Godfrey and McInerney24 The template included 30 items of interest, divided into 4 subheadings that included MI demography, communication, incident characteristics, and incident response.

Deviations from Protocol in Literature Search

In Scopus, the entry term “tele-communication” was excluded due to many irrelevant results. The amendment was promptly registered in the Open Science Framework for protocol adherence.

Analysis of Identified Literature

A data analysis was conducted according to the registered protocol using Population, Concept, Context (PCC) as per JBI protocol Reference Peters, Godfrey and Khalil17 and PRISMA ScR Reference Page, McKenzie and Bossuyt18 guidelines for non-indexed and indexed literature search. From each of the included articles and papers, 30 data items were extracted in accordance with the pre-registered protocol.

Data Synthesis

Due to the lack of outcome variables per se, 1 author performed a textual narrative analysis of the findings from each of the included studies and structured a synthesis based on the characteristics of the studies on the types of MI and communication challenges they described.

Ethical and Legal Considerations

According to Danish and Norwegian law, ethical approval is not required for scoping reviews.

Results

Identification of Studies from the Main Database Search

In total, 10 494 articles, papers, and studies were imported from 6 databases. The removal of duplicates (2629) produced 7865 studies, whose titles and abstracts were screened. This process rendered 45 full-text articles and papers that were assessed for eligibility. Thirty-one articles were excluded, and 14 that met the inclusion criteria were included in the scoping review. The selection process and the reasons for exclusion are listed in the PRISMA ScR flow diagram (Figure 2). A detailed description of the search strategies can be found in additional material, Appendices 1-6. The PRISMA ScR checklist is provided in Appendix 8.

Figure 2. PRISMA ScR flow diagram depicting the different scoping review stages.

Identification of Studies from the Non-Indexed Literature Search

The non-indexed literature search identified 256 published articles, of which 238 were excluded after screening based on title and, when available, abstract. Eighteen articles and papers were included after a full-text review. The PRISMA ScR flow diagram (see Figure 2) shows the selection process. The scoping review comprised 32 papers. Reference Sollid, Rimstad and Rehn2,Reference Hansen, Jepsen, Mikkelsen and Rehn4,Reference Peters, Marnie and Colquhoun25Reference Sollid54

Main Results

The main finding of the scoping review was communication breakdown, which was seen in 25 papers. In 18 papers, inter-authority communication was challenged. Communication system overload and incompatibility were both found in 9 papers. Insufficient pre-incident planning and non-intuitive guidelines were important findings as well. Main results are summarized in Table 1.

Table 1. Main findings from the scoping review

Basic information on the affected area was available in 28 papers; access to the incident site and the affected population was accounted for in 27 papers. The type of communication device was described in 25 papers, whereas the specific type of breakdown was described in 23 papers. A timeline for the incident was provided in 29 papers, and details on deceased victims, injured victims, and the total number of victims were reported in 26 papers. Basic EMS information was described in 24 papers. Findings from the data extraction are presented in Table 2. Narrative details of the included sources are summarized in Tables 3 and 4 and expanded in supplementary material, Appendix 7.

Table 2. Data extraction instrument

Coms, communication; MI, major incident; Y, yes; N, no; ?, unclear.

Table 3. Study designs and description of communication from included literature

Coms, communication; MI, major incident; HEMS, helicopter emergency medical services; Medevac, medical evacuation.

Table 4. Major incident characteristics from included literature

MI, major incident; N/A, not applicable; 9/11, September 11; GER, Germany, SWE, Sweden; RI, Indonesia; ESP, Spain; USA, United States of America; NOR, Norway; DEN, Denmark; UK, United Kingdom; CN, China; FIN, Finland; EST, Estonia; NIR, Northern Ireland; CHI, Chile; MEX, Mexico; JPN, Japan.

Limitations

The items for data extraction and quality appraisal were selected according to their assumed relevance and their ability to inform the review question. These items may not be complete or represent a reference standard, since no such standard exists. Similarly, it may represent a potential weakness that only articles in English and Scandinavian languages were included since MIs occur worldwide and predominantly in low- to middle-income countries because of natural disasters. Reference Yamamura, Kaneda and Mizobata55,56 This represents a language limitation. Scientific articles without abstracts were not included, which may have failed to identify relevant studies; the single-reviewer format of this scoping review may have also contributed to that.

The single-reviewer format is definitely a limitation and introduces selection and publication bias, since only 1 author performed the initial review of literature for inclusion. One author performed data extraction using templates developed as per protocol ahead of the search and validated using known references. A second author checked the results, but this allows for subjective interpretations of the findings. This represents an important deviation from the PRISMA-ScR guideline, that may limit the screening process, as any disagreement or inconsistency in the review process cannot be resolved. However, this was seen in previous disaster medicine literature. 57

Similarly, the unintended inclusion of multiple reports on the same spectacular incidents is indicative of potential skewness, selection, and publication bias. However, the use of a priori protocol registered ahead of any searches contributed to an unbiased search for all literature relevant to answer the review question and 1 single protocol deviation constitutes the strengths of the study.

Discussion

Summary of Findings

The pattern of communication in major incidents is frequent breakdowns for mainly unspecified reasons. The challenges are predominantly inter-authority communication, system overload and incompatibility, and insufficient introduction and training in the use of communication devices. The majority of papers were case reports (78.1%), ranking low in the hierarchy of research. However, the ability to answer the review question was generally good and provides a foundation to identify knowledge and research gaps for future research efforts. The lack of high-quality observational studies hinders conclusions that can be used by policy-makers to develop guidelines for MI management.

Major Incident Characteristics from Included Literature

In general, the included papers described MI and disasters with a high degree of detail. Most papers addressed relevant incident data, access to the incident site, and the characteristics of injured patients and deceased patients. The heterogeneous nature of MI and disasters is mirrored in the descriptions that range from compensated MI with ample resources to sheer chaos, endangering the survival and outcome of the victims. Therefore, the included literature ranges from relatively simple MI related to road traffic incidents to uncompensated natural disasters and complex terrorist attacks killing thousands of people. The included incidents are reported from all over the world, excluding Africa, which is incidental.

The EM-DAT database Reference Yamamura, Kaneda and Mizobata55,56 provides full insight into the demographic and geographical distribution of MIs and disasters. The database provides information that natural disasters kill approximately 45 000 people each year. Reference Yamamura, Kaneda and Mizobata55 This number has decreased significantly in the last decade 56 as the result of better standards of living, infrastructure, and enhanced response systems in World Bank defined Reference Fattah, Rehn, Reierth and Wisborg58 low-income countries.

Communication Breakdown

The scoping review found that communication failure was predominant in the included literature, with breakdown reported in 25 of 29 papers disclosing operational data. Failure may rank from intermittent to permanent, and the consequences depend on the mitigating efforts to rectify or compensate for the breakdown. The definitions by majorincidentreporting.net 21 and Major Incident Medical Management and Support Courses (MIMMS) 59 focus on the availability of extraordinary resources. Therefore, the geo-political and socio-economic setting is paramount, that is, an EMS response to a road traffic incident in Finland may be standard due to ample resources, whereas the similar injury mechanism may represent an MI in Sudan. Accordingly, consequences of communication breakdown will depend on the setting of the MI.

When communication is compromised, command and control may be lost. Measures to mitigate episodes of lost command and control are simple in everyday operations; however, in an MI, the complexity of the situation and the breakdown of essential systems may hamper such attempts. From the definition, Reference Sammut, Cato and Homer60,Reference Vassiliou, Alberts and Agre61 it follows that the “organizational and technical attributes and processes that employs human, physical, and information resources to solve problems and accomplish missions” are complex entities that involve a solid framework, substantial basic and ongoing training, and the support from leadership and management.

The consequences of a breakdown in command and control may be immense, with unnecessary fatalities Reference Kapucu45,46 and prolonged interventions Reference Sollid54 before a society’s return to a normal state. Therefore, mitigating actions to re-establish command and control should be part of any MI preparedness framework, Reference Pigeau and McCann6264 describing alternative communication pathways and redundancy.

Inter-Authority Communication Challenges

Communication is one of the key foundations of inter-authority cooperation. 65 However, several obstacles may compromise communication between authorities, including different terminology and perception of nomenclature; the widespread use of abbreviations; different nomenclature between authorities; and, finally, different priorities in respective sectors.

Especially the use of abbreviations may be a challenge in inter-authority communication and lead to mistakes, described by Holper. Reference Mondal, Van Belle and Maioni66 In the study, the authors found that more than 30% of all abbreviations used in a general medical unit were ambiguous. Coghlan et al. Reference Holper, Barmanray and Colman67 found the same pattern in the use of abbreviations in hospital discharge summaries, leading to potentially compromised patient care.

MI managers from different sectors have the same objective, but different approaches and priorities may hinder common tactical progression in the management. However, in complex arenas such as MIs, organizations tend to develop both formal and informal relationships for joint efforts, described by Kapucu. Reference Coghlan, Turner and Coverdale68 Grounded in network and complexity theories, a concept of interdependency between authorities in extreme situations is described. Interdependency may positively influence organizations in their adaptation to complicated or dynamic arenas such as MIs, enabling a better outcome.

Communication Systems Overload and Incompatibility

System overload and/or incompatibility are represented in 18 of the included papers, echoing the fact that communication systems are vulnerable, complex, and subjected to financial priorities, for example. Communication systems that operate close to maximum capacity Reference Kapucu69 under normal day-to-day conditions will invariably overload and may consequently suffer breakdown during surge situations such as an MI. Similarly, the compatibility of communication systems between different authorities and sectors Reference Barrett, Ford and Zhu70,Reference Manoj and Alexandra71 may present a barrier to MI communication, for example, between military and civilian authorities related to secrecy and encryption.

Insufficient Pre-Incident Major Incident Plans and Guidelines

In 12 papers, insufficient pre-incident MI plans and non-intuitive MI guidelines are reported. EMS personnel may be challenged by MI guidelines Reference Pigeau and McCann6264 that are significantly different from daily operations, although they clearly describe MI communication. Guidelines should serve to establish, maintain, and execute command and control. Reference Sammut, Cato and Homer60,Reference Vassiliou, Alberts and Agre61

Consequences of Lacking Initial Training in the Use of Communication Devices

Holm Reference Rogers and Lea72 has described the effects of lacking initial training in the use of communication devices among Danish prehospital physicians, reported in 2 papers. This study found that 38% had not received any initial training at all, whereas 29% rated their skills as advanced or expert level. Thirty-one percent of the responders did not feel capable of being able to handle communication sufficiently in an MI.

Simulation training in the use of radio communication has not been utilized extensively, Reference Holm73 whereas simulations in prehospital trauma care Reference Abelsson, Rystedt, Suserud and Lindwall74 and ultrasound, Reference Bredmose, Habig and Davies75,Reference Krogh, Steinmetz and Rudolph76 for example, are widely implemented with significantly improved performance after completing training. In the study by Holm, Reference Rogers and Lea72 implementation of a simulation is recommended for improvement of communication skills.

Major Incident Case Reports

Most of the included literature in the scoping review are case reports, which are limited by their retrospective, non-blinded, and nonrandomized trial design. As such, this constitutes a source of bias that may affect the study outcome. Reference Bøtker, Jacobsen, Rudolph and Knudsen77 Any findings provided by case reports might not be generalizable and therefore may not be useful in establishing a cause-effect relationship, with a consequentially high risk of over-interpretation.

A study by Krusenvik Reference Sampayo-Cordero, Miguel-Huguet and Malfettone78 found that case reports may provide in-depth relevant data since they originate from reality and may promote an understanding of complex, real-life situations. Findings are context-sensitive and may enhance new theories and add strength to previous research findings. The disadvantages are their limited generalizability and rigor.

Crowe et al. Reference Krusenvik79 found that case studies are suitable for the detailed, real-life context description of critical events and interventions, for example. Therefore, case studies should be considered when no available experimental design is appropriate to answer the research question or it is impossible regarding setting, legislation, ethics, and so on.

Future Research Perspectives

An agreement on a uniformly accepted nomenclature and a common definition of MI and disasters is essential. The use of common entities in the description of an MI will enhance the evaluation and dissemination of lessons learned in MI management locally and internationally.

This scoping review found that the predominant research design consisted of case reports, suggesting that until hypotheses have been generated for future research, systematic reporting should be endorsed or mandated by EMS management. Reporting resources such as the website, majorincidentreporting.net, 21 and similar portals should enjoy the support and endorsement from management and authorities, perhaps using public outreach in forums such as EUPHOREA. Reference Crowe, Bower and Cash80

The future might call for an international multicenter, prospective observational study on MI communication with a focus on command and control and intra- and inter-disciplinary communication. Similarly, feasibility or simulation studies of new communication methods and implementation of guidelines could provide knowledge on future MI communication progression. This scoping review has demonstrated research and knowledge gaps that would benefit from a deeper understanding of experience, for example, from studies performed during large-scale exercises or tabletop scenarios.

Systematic scientific research in the field is called for, since most of the included papers describe communication breakdowns, with both potential and actual consequences for patient survival and outcome and for society’s expedited return to a normal state.

Implications of the Findings

The included material discloses that communication challenges and breakdowns are predominant in MIs and represent potential and actual threats to (1) command and control, and (2) patient survival and outcome. There is a need for high fidelity and reliable communication devices and easy-to-follow guidelines for communication with a clearly defined grid. Pre-incident training in the use of communication devices should be highly prioritized at the same level as medical skills, and efforts to enhance resilience are paramount. The implications may be applied worldwide, as MI mechanisms and mitigating actions are uniform, however, context-sensitive, which should be taken into account in MI preparedness planning.

Conclusions

Frequent breakdowns in communication are a pattern in MIs, mainly for unspecified reasons. The challenges in communication are predominantly inter-authority communication, insufficient pre-incident planning and guidelines, lost command and control, and system overload and incompatibility.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/dmp.2023.132

Acknowledgments

The authors thank Herdis Foverskov and Mette Brandt Eriksen (University of Southern Denmark Library, Odense, Denmark), who assisted invaluably in the literature search.

Author contribution

PMH and MR conceived and designed the work; acquired, analyzed, and interpreted the data; and completed the first draft of the manuscript. SM substantively revised the manuscript. MR contributed to the design and progress of the work and substantively revised the manuscript. All authors read and approved the final manuscript.

Competing interests

The authors declare that they have no conflicts of interest.

Ethical standard

According to Danish and Norwegian law, ethics approvals are not required for scoping reviews.

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Figure 0

Figure 1. Search strategy. Two sets of entry terms and free search phrases.

Figure 1

Figure 2. PRISMA ScR flow diagram depicting the different scoping review stages.

Figure 2

Table 1. Main findings from the scoping review

Figure 3

Table 2. Data extraction instrument

Figure 4

Table 3. Study designs and description of communication from included literature

Figure 5

Table 4. Major incident characteristics from included literature

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