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Validity and Reliability Study of the Turkish Adaptation of the Disaster Response Self- Efficacy Scale (DRSES)

Published online by Cambridge University Press:  15 February 2023

Aynur Uysal Toraman
Affiliation:
Faculty of Nursing, Public Health Nursing Department, Ege University, Izmir, Turkey
Ebru Konal Korkmaz*
Affiliation:
Faculty of Nursing, Public Health Nursing Department, Ege University, Izmir, Turkey
*
Corresponding author: Ebru Konal Korkmaz, Emails: [email protected], [email protected].
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Abstract

Objective:

This study aimed to assess the validity and reliability of the Turkish version of the ‘Disaster Response Self-Efficacy Scale (DRSES).’

Method:

This is a methodological study to validate the DRSES. Third and fourth grade nursing students participated in the study (n = 340). Construct validity was evaluated by exploratory and confirmatory factor analysis. Reliability was assessed by internal consistency and test-retest reliability. Data were analyzed in SPSS 20.0 (IBM Corp., Armonk, NY, USA) and IBM SPSS AMOS 21.0. (IBM Corp., Armonk, NY, USA).

Results:

The content validity was 0.96, Cronbach’s alpha coefficient was 0.94, and the intraclass correlation coefficient for test-retest reliability was 0.95. The exploratory factor analysis revealed that 3 factors accounted for 59.4% of the explained variance. The factor loads ranged between 0.50 - 0.81. The construct validity was good (χ2/df = 2.54; RMSEA = 0.067; CFI = 0.93; NFI = 0.95; GFI = 0.93; TLI = 0.94; IFI = 0.92; P < 0.001).

Conclusions:

The results of this study show that the Disaster Response Self-Efficacy Scale is a valid and reliable tool that could be used to determine the nursing students’ disaster response self-efficacy.

Type
Original Research
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, Inc.

Introduction

The World Health Organization (WHO) defines disasters where human life is lost and the environment is endangered as states of emergency. 1 In terms of dealing with disasters, having all health disciplines at the ready in case of disaster is no longer an option but a critically important responsibility. It is because of this that it is vitally imperative that all health professionals are knowledgeable about disaster management, have the critical decision-making skills, as well as the understanding, and attitudes that are needed in emergencies. In considering the circumstances in the world and in Turkey, the conviction that there is a need for disaster and emergency nursing services is rapidly increasing. Reference Alfred, Chilton and Connor2Reference Veenema4

Nurses are an integral part of the healthcare workforce that assumes roles in every stage of the disaster cycle and in emergency management. In every stage of emergency management, nurses have a responsibility toward the community they live and work in. Reference Veenema4,Reference Park and Kim5 All nurses, no matter what their area of specialization, must have the basic competences necessary to prepare for emergencies, protect the community from disaster, and employ their knowledge and skills in the time during and after a disaster. Reference Veenema4 Nurses must integrate the knowledge, skills, competences, and good judgments required in disaster and emergency nursing and the abilities to fulfill their duties to produce the desired results under varied circumstances. Reference Li, Bi and Zhong6 However, a review of the studies in this context shows that nurses do not feel confident about their abilities to intervene in emergency situations, and that their perceptions of preparing for disasters and their levels of knowledge are inadequate. Reference Veenema4,Reference Park and Kim5,Reference Labrague, Hammad and Gloe7,Reference Tzeng, Feng and Cheng8 The International Council of Nurses (ICN) created a ‘Framework for Core Competencies in Disaster Nursing’ in 2009 for the purpose of training all nurses for disaster readiness and emergency intervention. These competences are part of the guidelines that specifically define the role of nurses in disaster circumstances, leading them in the task of developing a system of disaster training and instruction. 9

The literature emphasizes that providing nursing students with training in disaster nursing and management has the potential to produce such positive outcomes as reducing mortality rates among individuals and communities that fall victim to disaster as well as diminishing the costs involved in dealing with emergencies. Reference Veenema4,Reference Park and Kim5,Reference Hassmiller, Stanley and Wolanski10 It is asserted that disaster nursing and management training together with identifying the effectiveness of such education is an important priority that must not be neglected. Reference Hassmiller, Stanley and Wolanski10 An examination of the studies carried out in this context shows that many focus on the indications of disaster nursing competency and on determining the methods and teaching techniques that can form a framework for disaster nursing education. Reference Han, Lu and Li11Reference Said and Chiang14 However, the number of studies exploring levels of disaster nursing competency among nursing students is quite limited. Reference Alim, Kawabata and Nakazawa3,Reference Li, Bi and Zhong6 In particular, it can be seen that most of the literature in Turkey is about education, focusing on the level of students’ knowledge, nurses’ readiness for states of emergency, and their duties, authorities, and responsibilities in this context. Reference Kalanlar and Kubilay15,Reference Ozpulat and Kabasakal16 Additionally, there is no evidence in the literature that indicates that any measuring instrument has been developed or is being used in Turkey to assess nursing students’ competencies with regard to interventions in an emergency. To ensure that nurses can provide qualified services in disaster situations, their roles and responsibilities, training, and scope of service are matters that must be addressed so that both nurses and nursing students can be evaluated in terms of their readiness and competence in a state of emergency. Valid and reliable tools must be used to make an objective and standardized assessment that will result in determining quality and competence. The aim of this study was to assess in the Turkish culture, the validity and reliability of the ‘Disaster Response Self-Efficacy Scale’ developed by Li et al. Reference Li, Bi and Zhong6

Materials and methods

Design, setting, and sample

The study design was methodological and was conducted in a nursing faculty in a city, in provinces located in the western part of Turkey, between May and June 2019. The study population comprised of 280 3rd-year nursing students and 275 4th-year nursing students (N = 555). The reason for choosing third and fourth grade students is that they have taken courses that include topics such as nursing, triage, infectious diseases and their control, psychological assessment, therapeutic approach, and professional ethical principles in disasters. This study was conducted with 340 students who attended the 2018 - 2019 academic year and volunteered to participate after the purpose of the research was announced. The participation rate was 61.26%.

Research instruments

The study data were collected using the descriptive information form and the Turkish version of the ‘Disaster Response Self-Efficacy Scale (DRSES).’

Descriptive Information Form

The form has 4 questions the participating students’ age, gender, and year at school, and whether they have received disaster nursing education other than university education.

Disaster response self-efficacy scale (DRSES)

The scale developed by Hong-Yan Li, Rui-Xue, and Qing-Ling in 2017 is composed of 19 items and 3 subscales. Reference Li, Bi and Zhong6 The items are rated on a 5 -point Likert scale ranging from 1 to 4 (1 = No confidence at all, 2 = Basically no confidence, 3 = Little confidence, 4 = Basically confident, 5 = Complete confidence). A higher rating was representative of a higher self-efficacy score in disaster response. While the Cronbach’s alpha value for the overall scale is 0.91, it is 0.89 for the on-site rescue competency subscale, 0.86 for the disaster psychological nursing competency subscale, and 0.83 for the disaster role quality and adaptation competency subscale. Reference Li, Bi and Zhong6

Data collection

The data were filled out based on self-reporting. Filling out the forms took place at the end of the students’ classes, after an appropriate time was chosen based on their class schedule and on a day that did not coincide with their clinical practice. The process took 10 minutes.

Data analysis

The Statistical Package for the Social Sciences (SPSS) 20.0 (IBM Corp., Armonk, NY, USA) and the ‘Analysis of Moment Structures (Amos) 21.0 (IBM Corp., Armonk, NY, USA) statistics package programs were used in the analysis of the data collected. Descriptive sample characteristics are presented as number and percentages.

Test of validity and reliability

The method of translation/back-translation was used in assessing the linguistic validity of the DRSES. Content validity was evaluated by 8 experts with scientific expertise in the field of disaster and disaster nursing. Content validity was assessed by content validity index (CVI) (item-level and scale-level). Item and scale CVIs were evaluated based on the Polit and Beck model. Reference Polit and Beck17 A scale CVI of 0.80 or higher was considered acceptable. The Kendall W coefficient of concordance was used to determine the degree of concordance between the scores of the multiple referees.

To explore and test a model of DRSES, both exploratory (EFA) and confirmatory (CFA) factor analyses were performed. To support dimensionality and interpretation of the factors, EFA was used. Then, a 3-factor model was evaluated through a CFA. The Kaiser-Meyer-Olkin (KMO) measure of sampling adequacy and Bartlett test of sphericity were used to assess whether the sample was adequate, and the factor correlation matrix was suitable for factor analysis. Principal component analysis (PCA) and varimax rotation was used to count factor loadings. The CFA tested the model fit of the extracted factor model. Multiple model fit indices are recommended that χ2/ degrees of freedom (x2/sd0.90); Tucker-Lewis index (TLI > 0.90); Incremental fit index (IFI > 0.90). Reference Hooper, Coughlan and Mullen18Reference Schermelleh-Engel, Moosbrugger and Müller21

For reliability, Cronbach’s α values, test-retest reliability, intraclass correlation coefficient, and paired-sample t tests were used.

Ethical considerations

Permission for the use of the DRSES was obtained via email from Hong-Yan Li. Ethical approval was granted by the Scientific Research and Publication Ethics Committee of Ege University (Date and Number: 28.03.2019-03/23/194). Permission to conduct the study was also obtained from the nursing faculty. The purpose of the study was explained to the students, and the students who agreed to voluntarily participate in the research were included in the study. Moreover, oral and written informed consent was obtained from the students.

Results

Descriptive characteristics of the sample

The average age of the students who participated in the research is 22.55 ± 0.74, 70.3% are women and 54.6% are fourth grade students. All the students participating in the study stated that the subject of ‘disasters nursing’ was included in the course content during the nursing education process.

Validity analysis

Content validity

As a result of expert evaluation, the items of the scale (item 8, item 10, item 16, and item 19) were modified and adjusted. As evaluated by the 7 experts, the I-CVIs range was 0.87 to 1.00 and S-CVI was 0.96. According to the Kendall W test, there was an agreement between the experts (Kendall’s W= 0.367, P = 0.000).

Construct validity

According to Bartlett’s test of sphericity, the KMO was 0.928 and χ2 was 3790.68 (P < 0.001), confirming the suitability of the factor analysis. The PCA was applied to extract common factors and 3 factors whose eigenvalue was above 1.0 were extracted. The first eigenvalue was 9.11, the second was 1.14, and the third was 1.04, which together explained 59.40% of the total variance. Individually, factors 1, 2, and 3 explained 24.3%, 18.4%, and 16.7% of the total variance, respectively. As a result of the Varimax rotation technique, it was determined that the factor loading for the 19 items of the scale ranged between 0.50 - 0.81. According to the results of factor analysis, items between 6 - 15 were included in Factor 1, items 1- 5 were in Factor 2, and items 16 - 19 were in Factor 3 (Table 1).

Table 1. Factor loading of the Disaster Response Self-Efficacy Scale (DRSES)

According to the CFA results, the fit indices were: x2/ df = 2.54; RMSEA = 0.067; CFI = 0.93; NFI = 0.95; GFI = 0.93; TLI = 0.94; IFI = 0.92; P < 0.001. The 19-item 3-factor model of the Turkish version of the scale created can be seen in Figure 1.

Figure 1. Structural equation model of the Disaster Response Self-Efficacy Scale.

Reliability analysis

All item-total correlations were greater than 0.30 (0.54 – 0.72). According to the t-test analysis, the item discrimination power between the group that corresponded to the upper 27% based on total scores, and the group corresponding to the lower 27%, was statistically significant (P < 0.001) (Table 2).

Table 2. Item analysis of Disaster Response Self-Efficacy Scale

Internal consistency and test-retest reliability

The total Cronbach’s alpha of the scale was 0.94, and the Cronbach’s alphas for the 3 dimensions were 0.89, 0.86, and 0.86. The questionnaires were re-tested 2 weeks after the first round, and the test-retest reliabilities of the 3 dimensions were 0.998, 0.940, and 0.960. The total test-retest reliability of the scale was 0.950 (P < 0.001) (Table 3).

Table 3. Internal consistency and test-retest reliability for the Disaster Response Self-Efficacy Scale

Discussion

The purpose of the study was to examine the validity and reliability of the Turkish form of the Disaster Response Self-Efficacy Scale. The scale, with its 3 sub-scales and 19 items, was found to be a valid and reliable tool to be used in the Turkish culture. The validity and reliability study of the measure thus provided a tool that can be used in Turkey to determine the competence of nursing students in disaster nursing.

The content validity index (CVI) for sufficient content validity is required to be over 0.80. The study showed that the instrument has a high content validity index. Also, testing with Kendall’s coefficient of concordance (W) indicated that interrater agreement was moderate. Reference Gracht22,Reference Miller23 Exploratory Factor Analysis (EFA) and Confirmatory Factor Analysis (CFA) were used in the study to examine construct validity. The Kaiser-Meyer-Olkin (KMO) Test and Bartlett’s Test of Sphericity were performed prior to the EFA, and it was determined that the sample was sufficient to test construct validity. Reference Kline, Petscher and Schatsschneider20,Reference Gungor24

The EFA results showed that the 3-factor construct explained 59.40% of total variance. The total variance explained needs to be over 50%. Reference Yaslıoglu25 Accordingly, the fact that the factor construct of the DRSES explained more than 50% of total variance meant that the items were appropriately representative. Factor loads were examined to understand which item fell under which factor.

The literature suggests that a factor load should be > 0.30. Reference Polit and Beck17,Reference Devellis26 The factor loads in the study were over 0.50, ranging between 0.50 - 0.81, which means that the items were in agreement with each other and with the factor they were included in. Reference Devellis26 There is a difference between our study and the items in the first and second subscales of the original study by Li et al. Items 1-11 corresponded to the first subscale (search and rescue self-efficacy) of the original study and items 12-15 to the second subscale (psychological self-efficacy). Reference Li, Bi and Zhong6 Since 6 items in the search and rescue self-efficacy subscale and the items in the psychological assessment self-efficacy subscale fell under the first factor, this collective structure was called the ‘Search & rescue and psychological assessment self-efficacy’ subscale. The 5 items collected under the second factor fell under the theme of disaster assessment and therefore was called the ‘Disaster assessment self-efficacy’ subscale. Since the third factor construct showed consistency with the original study, the original subscale name of ‘Adaptation self-efficacy’ was maintained. Individuals in societies express their feelings and thoughts differently and exhibit variations in behavior. Even in the same society, in fact, factors such as social structure, education, and technological advances can lead to rapid cultural changes. For example, 1 group of persons may simply be part of a less effective education system, and this would have a significant impact on test performance. Reference Jesus and Valente27 It may explain the differences in the distribution of the items in the first and second subscales stemmed from educational and cultural differences.

The verification of the 3 -factor construct obtained from the EFA was explored with a CFA, which showed that x2/ df = 2.54, signifying an excellent fit. The RMSEA value of below 0.08, the CFI, NFI; GFI, TLI, and IFI values of above 0.90 pointed to a good fit. Reference Hooper, Coughlan and Mullen18,Reference Hu and Bentler19,Reference Schermelleh-Engel, Moosbrugger and Müller21 In the original study by Li et al. Reference Li, Bi and Zhong6 it was found that x2/ df = 2.440, RMSEA = 0.068, NFI = 0.907, CFI = 0.942. These findings are consistent with the results of the present study. The analyses confirmed the 3 -factor construct, signifying that the instrument is a valid measuring tool.

An item analysis was performed to assess the reliability of the measure, and it was found that total correlations were over 0.40 and discrimination power was statistically significant. These results indicate that the instrument’s ability to measure the qualities it is intended to measure is at an elevated level and that its power to discriminate the measured characteristics of individuals is good. Reference Buyukozturk28Reference Tavsancıl30

Cronbach’s alpha reliability analysis showed that the internal consistency coefficients for the overall scale and its subscales were high, pointing to a prominent level of reliability. Reference Ozdamar31 The internal consistency analysis performed by Li et al. Reference Li, Bi and Zhong6 had revealed a Cronbach’s alpha value of 0.91 for the overall scale and values within the range of 0.83 - 0.89 for the subscales. The data found in the original study are like our findings. According to the test-retest analysis, the total score correlations obtained from the first and second measure were statistically significant, indicating a strong correlation. Reference Ozdamar31 At the end of their repeated measures, obtained at 2 -week intervals, Li et al. Reference Li, Bi and Zhong6 found test-retest reliability to be 0.95 for the overall scale, and between 0.91- 0.95 for the subscales, all statistically significant. These results reveal that scale measures are similar when measures are repeated at determined intervals and that there is consistency between measures. The analyses demonstrated that the scale is a reliable measuring tool.

Conclusion

The findings of our study show that the Turkish form of the Disaster Response Self-Efficacy Scale is a valid and reliable measuring instrument. The use of this scale, whose validity and reliability have thus been determined, will make it possible to plan programs designed to identify the disaster nursing competencies of undergraduate nursing students in Turkey. The results obtained from such efforts will be rendered comparable to the data collected in other countries with this instrument and it will also be possible to offer recommendations regarding the training of nurses for disaster readiness.

References

World Health Organization (WHO). Health systems in urban disasters. http://www.who.int/kobe_centre/publications/Health-systems-inurbandisasters_2013/en/. Published 2013. Accessed May 22, 2021Google Scholar
Alfred, D, Chilton, J, Connor, D, et al. Preparing for disasters: education and management strategies explored. Nurse Educ Pract. 2015;15(1):82-89. doi: 10.1016/j.nepr.2014.08.001 CrossRefGoogle ScholarPubMed
Alim, S, Kawabata, M, Nakazawa, M. Evaluation of disaster preparedness training and disaster drill for nursing students. Nurse Educ Today. 2015;35(1):25-31. doi: 10.1016/j.nedt.2014.04.016 CrossRefGoogle ScholarPubMed
Veenema, TG. Disaster nursing and emergency preparedness. 4th eds. Springer Publishing Company; 2018.CrossRefGoogle Scholar
Park, HY, Kim, JS. Factors influencing disaster nursing core competencies of emergency nurses. Applied Nurs Res. 2017;37:1-5. doi: 10.1016/j.apnr.2017.06.004 CrossRefGoogle ScholarPubMed
Li, HY, Bi, RX, Zhong, QL. The development and psychometric testing of a Disaster Response Self-Efficacy Scale among undergraduate nursing students. Nurse Educ Today. 2017;59:16-20. doi: 10.1016/j.nedt.2017.07.009 CrossRefGoogle ScholarPubMed
Labrague, LJ, Hammad, K, Gloe, DS, et al. Disaster preparedness among nurses: a systematic review of literature. Int Nurs Rev. 2018;65(1):41-53. doi: 10.1111/inr.12369 CrossRefGoogle ScholarPubMed
Tzeng, WC, Feng, HP, Cheng, WT, et al. Readiness of hospital nurses for disaster responses in Taiwan: a cross-sectional study. Nurs Educ Today. 2016;47:37-42.CrossRefGoogle ScholarPubMed
World Health Organization and International Council of Nurses. ICN framework of disaster nursing competencies. International Council of Nurses, Geneva, Switzerland. Published 2009. Accessed May 22, 2021.Google Scholar
Hassmiller, SB. Foreword. In: Stanley, S, Wolanski, T, eds. Designing and integrating a disaster preparedness curriculum: readying nurses for the worst. Indianapolis. Sigma Theta Tau International; 2015.Google Scholar
Han, RJ, Lu, H, Li, J, et al. The construction of nurses’ core competency system for disastrous events in plateau regions. Chin J Nurs. 2012;47(7):585-587.Google Scholar
Jorgensen, AM, Mendoza, GJ, Henderson, JL. Emergency preparedness and disaster response core competency set for perinatal and neonatal nurses. J Obstet Gynecol Neonatal Nurs. 2010;6(39):450-467. doi: 10.1111/j.1552-6909.2010.01157.x CrossRefGoogle Scholar
Loke, AY, Fung, OWM. Nurses’ competencies in disaster nursing: implications for curriculum development and public health. Int J Environ Res Public health. 2014;11(3):3289-3303. doi: 10.3390/ijerph110303289 CrossRefGoogle ScholarPubMed
Said, NB, Chiang, VC. The knowledge, skill competencies, and psychological preparedness of nurses for disasters: a systematic review. Int Emerg Nurs. 2020;48:100806. doi: 10.1016/j.ienj.2019.100806 CrossRefGoogle ScholarPubMed
Kalanlar, B, Kubilay, G. Disaster nursing education and duties of disaster nurse before disaster. DEUHFED. 2015;8(2):77-85.Google Scholar
Ozpulat, F, Kabasakal, E. Knowledge levels of nursing students on disaster nursing and their state of disaster preparedness. IJMRHS. 2018;7(8):165-174.Google Scholar
Polit, D, Beck, C. Nursing research: generating and assessing evidence for nursing practice. 10th eds. Philadelphia, PA: Wolters Kluwer; 2017.Google Scholar
Hooper, D, Coughlan, J, Mullen, M. Structural equation modelling: guidelines for determining model fit. EJBRM. 2008;6(1):53-60.Google Scholar
Hu, LT, Bentler, PM. Cut off criteria for fit indexes in covariance structure analysis: conventional criteria versus new alternatives. Struct Equ Model Multidiscip J. 1999;6(1):1-55.CrossRefGoogle Scholar
Kline, RB. Exploratory and confirmatory factor analysis. In: Petscher, Y, Schatsschneider, C, eds. Applied Quantitative Analysis in the Social Sciences. Routledge; 2013.Google Scholar
Schermelleh-Engel, K, Moosbrugger, H, Müller, H. Evaluating the fit of structural equation models: tests of significance and descriptive goodness-of-fit measures. MPR. 2003;8(2):23-74.Google Scholar
Gracht, HA. The future of logistics: scenarios for 2025. Gabler Verlag; 2008.CrossRefGoogle Scholar
Miller, MK. Nonparametric statistics for social and behavioral sciences. CRC Press; 2009.Google Scholar
Gungor, D. Guide to the development and adaptation of measurement tools in psychology. Turk Psikiyatri Derg. 2016;19(38):104-112.Google Scholar
Yaslıoglu, MM. Factor analysis and validity in social sciences: application of exploratory and confirmatory factor analyses. Univ. J. Bus. 2017;46:74-85.Google Scholar
Devellis, R. Scale development theory and applications. Sage Publications; 2012.Google Scholar
Jesus, LMT, Valente, AR. Cross-cultural adaptation of health assessment instruments. http://sweet.ua.pt/lmtj/lmtj/JesusValente2016.pdf. Published 2016. Accessed May 22, 2021.Google Scholar
Buyukozturk, S. Manual of data analysis for social sciences. Pegem Academy; 2011.Google Scholar
Mukaka, MM. A guide to appropriate use of correlation coefficient in medical research. Malawi Med J. 2012;24(3):69-71.Google ScholarPubMed
Tavsancıl, E. 2014. Measurement of attitudes and data analysis with SPSS. Nobel Publishing; 2014.Google Scholar
Ozdamar, K. Statistical data analysis with package programs. Seckin Publishing; 2018.Google Scholar
Figure 0

Table 1. Factor loading of the Disaster Response Self-Efficacy Scale (DRSES)

Figure 1

Figure 1. Structural equation model of the Disaster Response Self-Efficacy Scale.

Figure 2

Table 2. Item analysis of Disaster Response Self-Efficacy Scale

Figure 3

Table 3. Internal consistency and test-retest reliability for the Disaster Response Self-Efficacy Scale