Methods and Applications: Measuring the Capability of Biological Incident Rescue Teams in China: A Fuzzy Analytic Hierarchy Process Based Model — Tianjin Municipality, China, 2022–2023

We utilized the Delphi method to construct the indicator system in this research study and deployed the boundary value method for indicator selection. Once identified, we calculated the weight of each index via the analytic hierarchy process and utilized these calculations to construct a fuzzy comprehensive evaluation model. Microsoft Excel (Version 2016; Microsoft, New York, USA) and SPSS software (Version 22.0; IBM, New York, USA) were employed for all statistical analyses. Further details regarding these methodologies are furnished in the Supplementary Material .

We elicited insights from experts affiliated with the Chinese Academy of Military Medical Sciences, the Chinese Center for Disease Control and Prevention, and various academic institutions, through comprehensive semi-structured interviews prior to formal correspondence. This approach facilitated dynamic and adaptable dialogues, allowed for customized inquiries according to unique needs, and helped to foster rapport with the interviewees.

Questions were drafted in accordance with the Guidelines for Capacity Building and Grading Evaluation of National Urban Rescue Teams (draft), exploring their perceptions of bioterrorism events, the core responsibilities of rescue teams, and interdepartmental collaboration, among other relevant topics.

After assimilating the study’s background, objectives, and methods, the experts offered extensive inputs and recommendations through the provisional indicator framework. Consequently, we refined and improved the draft indicator framework by integrating these expert opinions to guide the subsequent development of the questionnaire.

Considering the suitability of the Delphi method and the field-specific requirements of the study, we selected 11 senior professionals as expert participants. These experts were pulled from various domains such as public health, emergency management, or epidemiology. They were drawn from several organizations, including the Chinese Center for Disease Control and Prevention, People’s Liberation Army, People’s Armed Police Force, hospitals, and universities, as well as aggregated from experts at the national and provincial levels, utilizing purposive sampling.

All chosen expert participants had accumulated over five years of experience in emergency management, disaster-related occupations, or on the subject of research. Each held an associate senior professional title or superior, obtained a minimum of a bachelor’s degree, and was acknowledged for conducting relevant research in their fields. All expert participants voluntarily contributed to the study with good compliance and gave the assurance of their dedication until the study consultations were concluded.

Based on the framework derived from literary analysis and expert interviews, the initial draft of the expert consultation questionnaire was developed. This draft showcased the underlying context, explanations pertinent to the index system, assessment of index importance and familiarity, and expert-specific data. Following the first round of expert consultation, the questionnaire was revised to reflect the outcome. The second version incorporated comprehensive scoring averages, coefficients of variance, full score ratios, and each index’s expert opinion from the initial consultation round for reference. Experts assigned weights to every index using a 5-point scale.

The Delphi survey was carried out between August 19 and September 20, 2022. We invited a total of 15 specialists from national, provincial, and municipal disease control and prevention centers, health administrative departments, scientific research institutions, and allied domains. After reaching out via email, 11 experts expressed their interest and confirmed their availability to participate. Subsequently, we communicated with these experts through emails soliciting their feedback on the indicator content. This process was repeated for the second round of consultation. Ultimately, all 11 invited experts successfully participated in the full Delphi survey, achieving a response rate of 100%. Information detailing the participant’s demographic characteristics can be found inTable 1.

Through a combination of literature review, semi-structured expert interviews, and consideration of China’s unique national conditions, the tasks of emergency rescue teams in bioterrorism incidents were distilled into four main responsibilities. These include: controlling exposure within the population and halting transmission to prevent further infection; rapidly curbing the situation through establishing isolation areas, conducting epidemiological investigations, and decontaminating affected regions; identifying biological pathogens and incident types to provide an essential basis for medical services; and mitigating harmful consequences while ensuring thorough on-site recovery. The expert interview questionnaire is presented in Supplementary Table S1 .

In two iterations of expert consultation, our team computed and scrutinized the expert authority coefficient as well as the consistency degree. The given experts’ judgment basis (Ca) values were 0.895 and 0.877 respectively, while the familiarity degree (Cs) values stood at 0.836 and 0.855 in respective order. The expert authority coefficient (CR), on the other hand, was consistently at 0.866, thereby satisfying the Cr≥0.7 criterion. This implies a high level of expert authority and, by extension, the reliability of the expert consultation process ( Supplementary Table S2 ).

The Kendall coordination coefficient demonstrated a shift from 0.303 (P<0.05) to 0.632 (P<0.05). This increase, falling within the 0.6 to 0.8 range, signifies a high degree of consistency and a low level of significance, thereby indicating a high level of independence among the indicators. Coefficients of variation for the two evaluations were observed to be 0.106 and 0.063 respectively, both under the threshold of 0.25. This detail suggests that expert opinions were notably aligned, yielding consistent evaluation results and validating the credibility of the index system. The results of the Kendall coordination coefficient test can be found in Supplementary Table S3 .

Based on expert feedback and scoring, the boundary value for each index was computed ( Supplementary Table S4 ). The chosen indexes were then consolidated and accordingly adjusted, following expert recommendations. This process eventually yielded five primary indicators and twenty-five secondary indicators for assessing a bioterrorism rescue team’s capability. The significance of these level indexes within the developed evaluation system was gauged in two rounds of expert consultations and group discussions ( Supplementary Table S5 ). Importance was ascertained based on the influence of certain factors on bioterrorism rescue capabilities, thereby determining the final weight of each index (Table 2).

To the best of our knowledge, this represents the first study conducted in China that employs the Delphi survey and the Analytic Hierarchy Process (AHP) to explore expert perspectives, with the aim of establishing a capability evaluation model for biological rescue teams. The derived evaluation model from our study can serve as a useful reference instrumental in the development and enhancement of rescue team capabilities. Furthermore, it provides a robust tool for evaluating the efficacy of rescue teams in the context of bioterrorism incidents.

The formation of expert panels is integral to the Delphi method. Currently, a well-defined standard for the evaluation of bioterrorism response capabilities does not exist, hence the necessity to establish one through the guidance of an expert panel (5). In the current study, we assembled the panel from a cross-section of professionals in China, including university academicians, hospital executives, and researchers from the CDC. These individuals have established careers in public health, emergency management, and disaster relief and possess a vast array of knowledge in terms of managerial and technical roles. Equipped with a deep understanding and distinctive perspectives on rescue operations, they have generated an evaluative model in this study which can therefore be effectively deployed in critically assessing the management, personal quality, and operational competence of bioterrorism response teams.

Biological incidents, such as disease epidemics or biohazard spills, pose substantial threats to public health and safety. Consequently, the effective execution of on-site mitigation activities is vital to lessen these events' impact and safeguard lives. These activities extend beyond routine crowd management and decontamination to include critical aspects such as sampling and detection. The quality of the on-site sampling process is paramount as it influences detection accuracy. Given the novelty and diversity of biological warfare agents, their identification relies on both prompt on-site detection and meticulous laboratory monitoring. Optimal outcomes necessitate rapid field detection balanced with rigorous laboratory scrutiny. The nexus between these two aspects deserves due consideration as the detection outcomes significantly influence on-site management strategies and decision-making processes.

Since the severe acute respiratory syndrome (SARS) outbreak in 2003, China has primarily directed its emergency response capability evaluation system towards public health emergencies (6). The country’s experience with events like the H1N1 influenza pandemic and the coronavirus disease 2019 (COVID-19) pandemic further accentuates the necessity of a robust and efficient emergency response capability evaluation framework.

Presently, there appears to be an absence of rescue quality assessment. This includes evaluations of comprehensive procedures, the health and equipment deterioration of team personnel, the anticipatory control of the incident, as well as on-site and ultimate controls. To enhance impartiality, third-party evaluations should be contemplated. This approach will not only expedite the incident’s resolution but will also bolster capacity building within rescue teams.

Team building encompasses the entire cycle of entry, operation, management, and departure of team members. Strategic investment in talent can produce the most enduring contribution to the quality of rescue efforts (7). As such, it is critical to augment funding towards talent development, and to implement regular, capability-focused training and upskilling that align with practical needs, thus fostering sustainable human development. Notably, in the context of China, the role of cross-sectoral collaboration in team building demands acknowledgement, and needs to be incorporated in the initial stages of team design.

This study, like any other, has limitations that must be recognized. First, due to the infrequency of bioterrorism events and a shortage of related research, we attempted to compose an expert panel for the Delphi investigation by selecting individuals with significant research relevance. Nevertheless, the number of experts chosen was limited, and none were from outside the domestic scope. Secondly, there is a lack of research evaluating the capabilities of rescue teams, which suggests a potential avenue for future research expansion.

In summary, consensus was achieved on all indicators of the model by the panel of experts, demonstrating good content validity for the overall scale. The subsequent phase involves transforming this evaluation model into a scalable format for distribution via a questionnaire. Moreover, we plan to examine the feasibility of applying this method in other medical capacity assessments, particularly within the realm of emergency medical rescue teams for emerging infectious diseases. Prior to its utilization in actual assessment work, the practicality and implementability of this model must be analyzed in the context of evaluating the capability of a biological event rescue team.

No conflicts of interest.

All the individuals who participated in this study for their support.