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Article

The Arabic Version of the Impact of Event Scale-Revised: Psychometric Evaluation among Psychiatric Patients and the General Public within the Context of COVID-19 Outbreak and Quarantine as Collective Traumatic Events

1
Department of Psychiatric Nursing and Mental Health, Faculty of Nursing, Alexandria University, Smouha, Alexandria 21527, Egypt
2
Faculty of Nursing, Isra University, Amman 11953, Jordan
3
School of Nursing and Midwifery, Western Sydney University, Penrith, NSW 2751, Australia
4
Department of Psychiatry, Teikyo University School of Medicine, 2-11-1 Kaga, Itabashi-ku, Tokyo 173605, Japan
5
Department of Mental Disorder Research, National Institute of Neuroscience, National Center of Neurology and Psychiatry, 4-1-1 Ogawahigashi, Kodaira, Tokyo 187-8502, Japan
6
Faculty of Psychology and Educational Sciences, University of Bucharest, 050663 Bucharest, Romania
7
Psychiatric and Mental Health Nursing Department, Faculty of Nursing, Mansoura University, Mansoura 30016, Egypt
8
Clinical Nursing Department, School of Nursing, The University of Jordan, Amman 11942, Jordan
9
Department of Medicine, Unayzah College of Medicine and Medical Sciences, Qassim University, Unayzah 52571, Al Qassim, Saudi Arabia
10
Department of Animal and Poultry Production, Faculty of Agriculture, Damanhour University, Damanhour 22516, Egypt
*
Author to whom correspondence should be addressed.
J. Pers. Med. 2022, 12(5), 681; https://doi.org/10.3390/jpm12050681
Submission received: 21 March 2022 / Revised: 6 April 2022 / Accepted: 19 April 2022 / Published: 24 April 2022

Abstract

:
The Coronavirus Disease-19 (COVID-19) pandemic has provoked the development of negative emotions in almost all societies since it first broke out in late 2019. The Impact of Event Scale-Revised (IES-R) is widely used to capture emotions, thoughts, and behaviors evoked by traumatic events, including COVID-19 as a collective and persistent traumatic event. However, there is less agreement on the structure of the IES-R, signifying a need for further investigation. This study aimed to evaluate the psychometric properties of the Arabic version of the IES-R among individuals in Saudi quarantine settings, psychiatric patients, and the general public during the COVID-19 outbreak. Exploratory factor analysis revealed that the items of the IES-R present five factors with eigenvalues > 1. Examination of several competing models through confirmatory factor analysis resulted in a best fit for a six-factor structure, which comprises avoidance, intrusion, numbing, hyperarousal, sleep problems, and irritability/dysphoria. Multigroup analysis supported the configural, metric, and scalar invariance of this model across groups of gender, age, and marital status. The IES-R significantly correlated with the Depression Anxiety Stress Scale-8, perceived health status, and perceived vulnerability to COVID-19, denoting good criterion validity. HTMT ratios of all the subscales were below 0.85, denoting good discriminant validity. The values of coefficient alpha in the three samples ranged between 0.90 and 0.93. In path analysis, correlated intrusion and hyperarousal had direct positive effects on avoidance, numbing, sleep, and irritability. Numbing and irritability mediated the indirect effects of intrusion and hyperarousal on sleep and avoidance. This result signifies that cognitive activation is the main factor driving the dynamics underlying the behavioral, emotional, and sleep symptoms of collective COVID-19 trauma. The findings support the robust validity of the Arabic IES-R, indicating it as a sound measure that can be applied to a wide range of traumatic experiences.

1. Introduction

Coronavirus Disease-19 (COVID-19) is associated with high infectivity and fatality, creating a collective crisis in the global community [1,2]. Apart from loneliness and distress resulting from COVID-19 lockdowns [2,3], terrorizing images of the outbreak and fake information communicated by mass media heighten psychological distress, intensify traumatic emotions, and accelerate fear levels regarding the negative effects of the pandemic on health and everyday life, with increased universal occurrence of COVID-19-related post-traumatic stress disorder (PTSD) [2,3,4,5,6,7]. PTSD is associated with increased mental symptomatology (e.g., anxiety and depression) and maladaptive behaviors (e.g., illicit drug use and suicidality) [8,9]. Such adverse effects have been reported during the COVID-19 outbreak among youth and older adults, especially those with chronic physical and mental disorders [10,11,12]. Emotional resolution of traumatic experiences may be complicated by associated and/or pre-existing psychological symptoms [13,14]. Therefore, adequate measurement of PTSD symptoms may allow timely identification and management of individuals vulnerable to trauma and related psychological disability [15].
The Impact of Event Scale-Revised (IES-R) is a common measure of the severity of PTSD key features: intrusion, avoidance, and hyperarousal [8,16,17]. It has been translated into many languages, such as Italian [8], Japanese [18,19], Chinese [20], French [21], Greek [22], Norwegian [17], Spanish [23], and Arabic [24]. Nonetheless, reports on its dimensionality are inconsistent both in English [16,17,25] and translated versions [23,24,26]. A few studies replicated the three-factor structure [9,21,27], while other studies reported best fits of two-factor (avoidance and intrusion/hyperarousal) [16,19], four-factor (intrusion, avoidance, hyper-arousal, and numbing or sleep disturbance) [23,25], and five-factor structures (intrusion, avoidance, hyperarousal, numbing, and sleep disturbance) [25,26]. Models comprising more than three factors were improved through error correlations [25], suggesting that the IES-R may contain more undetected factors [25]. Studies of measurement invariance of the IES-R are scarce, and they report metric and scalar non-invariance across groups (e.g., occasions within the emergency room and gender) [20,25]. This necessitates further evaluation of the invariance of the IES-R to ensure valid comparison of PTSD symptomatology across groups.
The Arabic version of the IES-R has been previously tested via exploratory factor analysis (EFA) in 40 Middle Eastern refugees in Australia [24]. This small sample fails to meet the minimum sample size required to perform a reliable EFA, which casts doubt on the credibility of the findings. Given that the literature is inconsistent regarding the structure [16,23,24,25] and invariance of the IES-R [25], the current study aimed to investigate the factor structure of the Arabic version of the IES-R in relevance to the current COVID-19 crisis in a sample from quarantine settings in Saudi Arabia (quarantine sample), a clinical sample of community-dwelling psychiatric patients (sample 1), and a sample from the general public (sample 2). We also assessed its measurement invariance across gender, age, and marital status. Criterion validity was examined by assessing the association of the IES-R with the Depression Anxiety Stress Scale-8 (DASS-8) and its subscales as measures of psychological distress, depression, anxiety, and stress [28,29]. We hypothesized that the IES-R will positively correlate with the DASS-8 and its subscales. The IES-R was also expected to correlate with perceived vulnerability to COVID-19 and perceived physical health status. Hyperarousal and intrusion are reported to shape the mental and behavioral aspects of COVID-19 trauma [7]. Therefore, we conducted a path analysis model to examine the mechanism through which cognitive activation may affect sleep, mood, and avoidance aspects of COVID-19 trauma in our samples.

2. Materials and Methods

2.1. Study Design, Participants, and Procedure

This cross-sectional study is a secondary analysis based on three convenience samples collected from Saudi Arabia during the lockdown period (29 April until 19 May 2020). The first sample (N = 214) was collected from seven quarantine settings in Riyadh and Qassim. It comprised travelers returning back to Saudi Arabia, with suspected COVID-19, or mild cases. This sample is referred to herein as the quarantine sample. In Saudi Arabia, quarantine settings are hotels designated for quarantine purposes. The capacity of each setting varies from 40 to 200 rooms. They are equipped with doctors, nurses, social workers, and psychologists. Each individual is placed in a single room alone for a planned period of 14 days. The residents are observed for vital signs at least twice a day, and they receive necessary medication prescribed by the doctor on duty [30].
A sample of 1160 community-dwelling individuals was collected through invitations disseminated via WhatsApp and Twitter groups. Sample 1 comprised 168 respondents who testified having a pre-existing mental disorder diagnosed by a psychiatrist. Sample 2 comprised 992 individuals testifying an absence of mental diseases. From all respondents, including those in quarantine, data were collected through an anonymous online survey delivered through Google Forms. Individuals were included in the study if they were 18 years or older, could speak Arabic, and signed a digital informed consent. Further details are described elsewhere [6,29].

2.2. Study Instruments

The online questionnaire consisted of several parts. The first part assessed sociodemographic and clinical characteristics of the participants. It contained questions about gender, age, education, and having a medical diagnosis of a pre-existing mental health problem. Accordingly, participants reporting a diagnosis of a psychiatric disorder were included in the clinical sample (sample 1) while participants reporting an absence of a clinical diagnosis were included in the general public sample (sample 2).
The second part consisted of the IES-R. The IES-R comprises 22 items in three subscales, which describe the major features (intrusion, avoidance, and hyperarousal) of PTSD relevant to a specific trauma—COVID-19 in the current context. An example intrusion item is “thought of it when I didn′t mean to” (item 6). An example avoidance item is “tried not to think about it” (item 11). An example hyperarousal item is “was watchful or on-guard” (item 21) [16]. The internal consistency of the IES-R is good (α = 0.93) with a test–retest reliability of 0.95 [25]. We obtained this Arabic version of the IES-R (File S1) from Davey and co-workers who translated the scale into Arabic and back-translated it into English according to standards declared by the World Health Organization. They reported good reliability of the IES-R (α = 0.93) and its subscales: intrusion (α = 0.77), avoidance (α = 0.75), and hyperarousal (α = 0.86) [24].
The third part of the questionnaire consisted of the validated Arabic version of the DASS-21. This scale consists of three subscales, which measure symptoms of depression, anxiety, and stress. Each subscale consists of 7 items. Items are rated on a 4-point scale that ranges from 0 (did not apply to me at all) to 3 (applied to me very much or most of the time). The DASS-21 demonstrates good internal consistency (α = 0.88) [31]. However, it does not discriminate mental symptoms underlying the tripartite model (depression, anxiety, and stress) [31,32,33]. Discriminant validity tests uncovered better discrimination among the subscales of the DASS-8, a shortened version of the DASS-21, than the parent scale [28]. Therefore, we included the DASS-8 in the present analysis for criterion validity testing. The DASS-8 comprises eight items in three subscales: depression (three items, e.g., had nothing to look forward), anxiety (three items, e.g., felt close to panic), and stress (two items, e.g., found it difficult to relax). The minimum score of the DASS-8 and its subscales is 0 while their maximum scores are 24, 9, 9, and 6, respectively [28,29]. The reliability of the DASS-8 and its subscales ranges from excellent to very good in sample 1 (α = 0.94, 0.85, 0.89, 0.84, respectively) and sample 2 (α = 0.91, 0.79, 0.79, 0.80, respectively) [29].
A single question was used to assess perceived health status “rate your physical health status on a scale from 1 = very bad to 5 = very good”. One question was used to assess participants′ perceived vulnerability to COVID-19 “rate your perceived vulnerability to COVID-19 on a scale from 1 = very unvenerable to 5 = very vulnerable”.

2.3. Ethical Considerations

The study plan was approved by the Institutional Review Board of Al Qassim University (No.19-08-01). Participants who accessed the questionnaire were first introduced to a consent form confirming that the purpose of data collection was purely scientific and that participation was voluntary as it would help the researchers explore the psychological impact of the COVID-19 outbreak. The form presented information on the average time required to complete the questionnaire. It also noted that the questionnaire was anonymous and emphasized that collected personal data would not be disclosed, shared, or communicated to anyone.

2.4. Statistical Analysis

The dimensionality of the Arabic version of the IES-R was tested in the quarantine sample using EPA, with maximum likelihood method of extraction, varimax rotation, Kaiser–Meyer–Olkin (KMO) measure of sampling adequacy, and Bartlett′s test of sphericity. In addition, CFA (maximum likelihood with bootstrapping based on 2000 random replications) was used to examine data fit to a number of competing models in sample 1 and sample 2. Based on previous research that assessed the latent factor structure of the IES-R, we tested the theory-based three-factor structure as well as a one-factor structure, five-factor structure, and six-factor structure in addition to three bifactor structures. Model-data fit was evaluated based on Comparative Fit Index (CFI), Tucker–Lewis Index (TLI), root mean square error of approximation (RMSEA), and standardized root mean square residual (SRMR). Acceptable fit can be achieved by CFI and TLI values above 0.90, along with RMSEA and SRMR values less than 0.08 [34]. Multigroup CFA was used to evaluate the invariance of the best fitting structure of the IES-R across groups of gender, age, and marital status (see Table 1 for categories). Four models were tested to examine whether the same number of factors are expressed in groups (configural invariance), items load equally on corresponding factors across groups (metric invariance), true mean differences do not vary as a result of constraining intercepts of the regression equations of items on the corresponding factors to equality across groups (scalar invariance), and items display uniqueness (strict invariance) [35,36]. Sample size may affect the values of chi square (χ2) index, resulting in the disqualification of fitting models, which demonstrate minor modifications. Therefore, non-invariance was evaluated based on absolute fit indices, which are less likely to be affected by sample size. Particularly, models were deemed non-invariant based on a significant χ2, along with ΔCFI and ΔRMSEA above 0.02 and 0.015, respectively. In CFA and multigroup CFA, suggestions indicated by modification indices were performed in order to improve model fit.
Coefficient alpha, item-total correlations, and alpha if item deleted were used to assess the internal consistency of the IES-R. Spearman′s r correlation between the IES-R and its subscales was conducted to determine convergent validity. Spearman′s r correlation between the IES-R and criterion variables (the DASS-8 and its subscales, perceived vulnerability to COVID-19, and perceived physical health status) was used to reflect on the criterion validity of the IES-R. Discriminant validity of the IES-R was evaluated in sample 1 and sample 2 by the heterotrait–monotrait (HTMT) ratio of implied correlations associated with CFA [28]. Known-group validity of the IES-R was evaluated by Mann–Whitney U test, which was employed to compare IES-R scores between quarantined and non-quarantined participants as well as between non-quarantined healthy individuals and psychiatric patients [29,36]. A path analysis structural equation model (SEM) was conducted to examine the relationship among factors comprising the IES-R in the three samples. Analyses were conducted in SPSS and AMOS version 24, and significance was considered at 0.05 two-tailed.

3. Results

3.1. Characteristics of the Participants

As shown in Table 1, the quarantine sample comprised more males than females. Meanwhile, the majority of the participants in sample 1 and sample 2 were females. The age of around half the participants ranged between 18 and 30 years. Most participants in all the samples had a bachelor’s degree. In the quarantine sample, 7.9% (n = 17) of the respondents reported a pre-existing psychiatric disorder. As for sample 1, depression, generalized anxiety disorder (GAD), and obsessive–compulsive disorder (OCD) prevailed in 54.9%, 50%, and 20.5% of the participants, respectively. Few patients were diagnosed with bipolar disorder (6.6%), personality disorders (7.4%), eating disorders (5.7%), sleep disorders (4.1%), and psychotic disorders (2.5%). A considerable number of patients had dual diagnosis, e.g., GAD and/or sleep disorders on top of depression or OCD. More participant characteristics are reported elsewhere [6,29].

3.2. Factor Structure of the Arabic Version of the Impact of Event Scale-Revised (IES-R)

3.2.1. Exploratory Factor Analysis

EFA using maximum likelihood with varimax rotation revealed that the items of the IES-R in the quarantine sample covered five factors with eigenvalues > 1, accounting for 62.0% of the variance. Table 2 shows that several items cross-loaded on two or more factors. The KMO test indicated that the participant-to-item ratio was proper for an EFA test. Likewise, Bartlett′s test denoted appropriateness of the sample size for EFA analysis (Table 2).

3.2.2. Confirmatory Factor Analysis

Several competing models of the structure of the IES-R were tested in this study. Supplementary Table S1 describes the factor structure and items on each factor in every tested model. Table 3 shows that the one-factor structure of the IES-R (Model 1) expressed poor fit in both samples in terms of low CFI and TLI and high RMSEA and SRMR, along with several correlated errors. Model 2 was used to evaluate the proposed three-factor structure of the IES-R (intrusion, avoidance, and hyperarousal). This model and the bifactor structure based on this model had unsatisfactory fit, particularly in the clinical sample. Guided by the results of EFA (see the footnote of Table 2), we tested a five-factor structure (Model 4) including avoidance, intrusion, hyperarousal, difficulty sleeping and concentrating, and numbing. As displayed in Table 3, this model expressed a poor fit. Modification indices revealed that several items had high cross-loadings. Therefore, we kept the five-factor structure but modified the model to allow items with cross-loadings to load only on factors to which they expressed the highest loadings (Model 5). This model has been further modified by forcing items with lower loadings on their domain-specific factors to load on more relevant factors—sleep and irritability/dysphoria appeared as distinct factors in Model 7.
The bifactor structures examined in Model 6 and Model 8 (five and six domain-specific factors along with a general factor) expressed the best fit in sample 2, with all the items of the IES-R loading significantly on the general factor and their domain-specific factors. However, in both models, the loadings of item 20 were less than 0.2 and the loadings of items 7 and 19 were less than 0.3 (Supplementary Excel S1), indicating weak association with their domain-specific factors. Although Model 6 expressed the best acceptable fit in the clinical sample, item 21 failed to load on the numbing factor, and all the items of the intrusion factor failed to load on their specific factor. Standard errors associated with the items of the intrusion factor were considerably greater than 1 (16.1 to 95.3). In addition, SRMR was not produced due to failure of this model to properly converge. Likewise, Model 8 expressed the best fit compared with other models tested in sample 1. However, item 20 did not load significantly on its corresponding intrusion factor while the loadings of items 3, 19, and 21 on their domain-specific factors were less than 0.3 (Supplementary Excel S1), denoting that these items had limited contributions to the variance explained by the corresponding factors. The second-order factor structure (Model 9) had a fit slightly lower than that of the six-factor structure in both samples. Accordingly, the six-factor structure seems to represent the best fit in both samples (Figure 1).

3.2.3. Invariance of the Six-Factor Structure of the Impact of Event Scale-Revised (IES-R) across Different Groups

Based on model fit indices, Model 7 was examined for measurement invariance across groups of gender, age, and marital status in both samples. Multigroup CFA showed that the six-factor structure of the IES-R holds configural, metric, and scalar invariance across different groups in both samples, i.e., this model is generally fitting similarly across men and women, young and older, as well as single and married participants. There was a tendency toward strict non-invariance across groups of age and marital status in both samples and across gender in sample 2—as noted by ΔCFI greater than 0.02. However, ΔRMSEA was within the acceptable range (Table 4 and Table 5).
Scalar invariance expressed by this model indicates the suitability of the IES-R to portray variations in true mean differences between groups. Accordingly, Mann–Whitney U test was used to compare differences in the IES-R and the underlying six latent constructs between groups. In sample 1, there were no significant differences in the scores of the IES-R and most of its subscales between men and women, single and married, or individuals aged 30 years or below and those older than 30 years. Only women and participants aged 30 years or below expressed significantly higher levels of irritability/dysphoria than men and older participants (U = 2233.0, 2744.5; z = −2.4, −2.5; p = 0.015, 0.012, respectively). As for sample 2, the scores of the IES-R and its subscales, except for sleep disturbance, were significantly higher among women than men (all p values = 0.001). The scores of the IES-R, intrusion, hyperarousal, and irritability/dysphoria were significantly higher among single and younger participants in this sample (all p values < 0.01). Single participants also expressed significantly higher levels of sleep disturbance (p = 0.002). Values of the Mann–Whitney U test and related z scores are shown in Supplementary Excel S1.

3.3. Reliability, Convergent Validity, Normality, Criterion Validity, and Known-Group Validity of the Arabic Version of the Impact of Event Scale-Revised (IES-R)

In order to identify items that may represent a source of misfit, we checked scale reliability and the range of alpha if item deleted. Reliability analysis revealed excellent internal consistency of the IES-R in the quarantine sample, sample 1, and sample 2 (α = 0.90, 0.93, and 0.92, respectively) while alpha if item deleted indicated no further increase in the reliability of the scale following any item removal (range = 0.892 to 0.902, 0.917 to 0.923, and 0.909 to 0.915 in both samples, respectively). Table 6 shows good internal consistency of the factors comprising Model 7, albeit the reliability of the numbing factor was fair in the quarantine sample and acceptable in the other samples.
All the six factors had strong positive correlations with the total scores of the IES-R in the three samples (r ranges between 0.653 and 0.867). Shapiro–Wilk W test shows that the IES-R and its underlying six factors displayed a non-normal distribution, with all p values < 0.001. As hypothesized, strong positive correlations were expressed among the scores of the IES-R and the scores of the DASS-8 and its subscales in all the samples (r ranges between 0.176 and 0.716, all p values < 0.01). Perceived health status was negatively correlated with the IES-R and its subscales. Meanwhile, the IES-R scores were positively correlated with perceived vulnerability to COVID-19 (Table 6). These results reflect sound criterion validity of the IES-R in all the samples.
As shown in Table 7, Mann–Whitney U test revealed significantly higher levels of the IES-R, avoidance, hyperarousal, sleep disturbance, and irritability/dysphoria among quarantined than community-dwelling participants (p values < 0.05). The scores of the IES-R and all its six factors were significantly higher among psychiatric patients compared with those without a psychiatric diagnosis (all p values < 0.01), which supports known-group validity of the scale.
The six subscales comprising the Arabic IES-R are distinct from each other in the samples of psychiatric patient and healthy individual, as indicated by all values of the HTMT ratios below 0.85. Only the HTMT ratio between the hyperarousal and intrusion subscales was 0.87 in the community sample, suggesting a trivial overlap—it was less than 0.90 (Supplementary Excel S2).

3.4. Path Analysis Involving the Core Factors Comprising the Arabic Version of the Impact of Event Scale-Revised (IES-R)

In the tested models, all non-significant paths were trimmed. As shown in Supplementary Table S2, all path analysis models displayed excellent fit on all indices. In the quarantine sample, the path model explained 38%, 44%, 24%, and 34% of the variances in irritability, sleep disturbance, numbing, and avoidance. Intrusion only had significant direct effects on sleep disturbance and numbing (p = 0.048, 0.043); its indirect effects on avoidance and sleep disturbance were non-significant (p values > 0.05). The direct effects expressed by hyperarousal and numbing were significant at the level of 0.001 (Figure 2a). Numbing mediated the indirect effects of hyperarousal on avoidance and sleep disturbance (β = 0.109, 0.056; 95% CI: 0.60–0.172, 0.018–0.103; p = 0.001, 0.003).
In the psychiatric patient sample, the path model explained 40%, 47%, 29%, and 49% of the variances in irritability, sleep disturbance, numbing, and avoidance. All direct effects were significant at the level of 0.001 (Figure 2b). Irritability mediated the indirect effects of intrusion and hyperarousal on sleep disturbance (β = 0.093, 0.120; 95% CI: 0.046–0.160, 0.056–0.214; p values = 0.001). Numbing mediated the indirect effects of intrusion and hyperarousal on avoidance (β = 0.084, 0.067; 95% CI: 0.30–0.173, 0.025–0.132; p = 0.004, 0.010).
In the healthy community sample, the path model explained 38%, 42%, 34%, and 45% of the variances in irritability, sleep disturbance, numbing, and avoidance. All direct effects were significant at the level of 0.001 (Figure 2c). Numbing mediated the indirect effects of intrusion and hyperarousal on avoidance (β = 0.163, 0.101; 95% CI: 0.132–0.197, 0.069–0.132; p values = 0.001) and on irritability (β = 0.065, 0.040; 95% CI: 0.041–0.094, 0.025–0.061; p values = 0.001). Irritability mediated the indirect effects of intrusion, hyperarousal, and numbing on sleep disturbance (β = 0.041, 0.064, 0.027; 95% CI: 0.024–0.064, 0.038–0.097, 0.014–0.046; p values = 0.001).

4. Discussion

The Arabic version of the IES-R has been previously evaluated only through EFA among 40 Arab refugees in Australia. The current study examined the factor structure of the Arabic IES-R (using EFA and CFA), along with its measurement invariance, convergent validity, normality, criterion validity, known-group validity, and discriminant validity. Therefore, the findings complement existing knowledge by reporting on various psychometric properties of the IES-R in three samples (psychiatric patients, healthy adults, and quarantined individuals) from an Arab country within the context of a collective traumatic event (the COVID-19 outbreak and associated lockdown).
This study could not replicate the theory-based three-factor structure of the IES-R, at least among psychiatric patients. As shown in Table 2, most items had dual or triple loadings greater than 0.3 on more than one factor indicating absence of a well-defined structure of the scale. Several competing models tested in CFA revealed an unsatisfactory fit in the clinical sample. The three-factor structure of the IES-R and a bifactor structure based on that model expressed an acceptable fit in sample 2. However, the best fit in both sample 1 and sample 2 was expressed by a six-factor structure (Model 7) comprising avoidance, intrusion, hyperarousal, numbing, sleep disturbance, and irritability/dysphoria. The six-factor structure is superior to other models tested in this study because items have moderate to strong loadings on their domain-specific factors (Figure 1), and they do not cross-load, signifying fulfillment of the assumption of local independence. Despite the superior fit of the bifactor structure of this model in both samples, some items had low loadings on their domain-specific factors, discouraging the use of the bifactor model in subsequent analysis. Our findings are consistent with many previous studies, which reported a deviation of the dimensionality of the IES-R from the theory-based three-factor structure [16,20,23,25,26].
The literature shows a considerable debate on the dimensional structure of the IES-R. Until the current moment, there has been less consensus among trauma scientists on the best structure of symptom clusters involved in the diagnosis of PTSD [16,20,25,26]. In this respect, investigations of PTSD criteria, as defined in the Diagnostic and Statistical Manual of Mental Disorders (DSM-IV; American Psychiatric Association, 1994), among 1218 women exposed to varying levels of sexual harassment at the workplace denote failure of the intrusion, avoidance, and hyperarousal structure to depict the full picture of the disorder among these women. Alternatively, the authors suggested that PTSD is suitably described within the context of four factors: re-experiencing, effortful avoidance, emotional numbing, and hyperarousal [37]. In the same way, Baschnagel and colleagues evaluated PTSD among western New York undergraduate students one and three months after the 11 September 2001 terrorist attacks. They reported poor fit of the intrusion, avoidance/numbing, and hyperarousal structure of PTSD. Instead, they reported over-time stability of a four-factor model comprising intrusion, avoidance, dysphoria, and hyperarousal. Dysphoria comprised symptoms from hyperarousal and numbing clusters [38]. Subsequent investigations failed to produce a good fit for four-factor structures of the IES-R, which comprised standalone factors of numbing [23,25] or dysphoria [25]. However, best fits were obtained from five-factor models including intrusion, avoidance, hyperarousal, and sleep problems in addition to numbing [25,26] or dysphoria [25]. On the other hand, sleep-related symptoms emerged as an independent factor in investigations involving survivors of a destructive earthquake [20], fire fighters and students [23], as well as survivors of war [26]. A previous preliminary evaluation of the Arabic version of the IES-R also included sleep as a separate construct [24]. However, the sleep construct in our samples comprised only item 2 and item 15. On the other hand, the loadings of item 20 “had dreams about it” on the sleep factor were considerably low while the loadings of this item on the intrusion factor were above 0.4 in both samples. Having a closer look at the content of this item, dreams may be considered a form of unconscious intrusion. Indeed, the literature portrays strong links between cognitive symptoms, sleep problems, and mood dysregulation [13,39].
In our study, irritability, numbness, and sleep were distinct factors, albeit associated with one another. Although irritability and sleep comprised only two items, their internal consistency, item loadings, and item-total correlations were all high (Table 6, Figure 1), supporting these experiences as vivid aspects of PTSD. Collective research suggests that the DSM-IV does not address all the psychological symptoms of PTSD [40]. Meanwhile, a huge number of models evaluating DSM-IV criteria of PTSD report numerous factors, with almost all factors comprising only two symptoms, and high inter-factor correlations are the norm [41]. The distinction between irritability and numbness can be understood within the different contexts of trauma-related emotional responses. General emotional reactions associated with traumatic events mostly comprise anger, fear, sadness, and shame. However, some individuals may be unable to identify their feelings, or they associate strong feelings with past trauma and get overwhelmed with thoughts that expressing negative feelings is dangerous or may create more severe emotions (e.g., a sense of “being out of control/losing it/or going crazy”). Others may express numbness or lack of emotions as they unconsciously deny their trauma-related feelings [40].
Noteworthily, the fit of all tested models was improved by correlating several error terms. However, the fit of the structure expressed by Model 7 (the six-factor structure) in the absence of error correlations was the closest to acceptable fit in sample 1 (χ2 (194) = 376.248, CFI = 0.891, TLI = 0.870, RMSEA = 0.075, SRMR = 0.0630) and sample 2 (χ2 (194) = 1070.016, CFI = 0.904, TLI = 0.886, RMSEA = 0.068, SRMR = 0.0631). In the meantime, correlated error terms in Model 7 were minimal, denoting a lower chance for items from different factors to flag something other than their respective latent variables. In sample 1, the fit of Model 7 was improved by correlating the error term of item 5 “avoided letting myself get upset” with those of items 4 “was irritable or angry” and 6 “thought of it when I didn′t mean to”. Item 16 “waves of strong feelings” was also correlated with the error of item 19 “reminders of it caused physical reactions e.g., sweating, dyspnea”. In sample 2, the error term of item 5 was correlated with the errors of item 1 “reminder brought back feelings”, item 3 “making me think about it”, items 4, 6, and 9 “images popped into my mind”. Multicollinearity generally suggests the presence of extra latent structures. However, the interactions taking place among these variables may be triggered by method effects, i.e., the sequential appearance of these symptoms on the questionnaire. Alternatively, the wording of these variables denotes that cognitive activation may be evoked by intrusive thoughts about COVID-19 (items 6 and 19). Such cognitive activation may stimulate uncomfortable emotional (items 4 and 16) and physical reactions (item 19). Accordingly, individuals employ avoidance to escape negative emotions and uncomfortable sensory symptoms associated with intrusive thoughts (item 5) or reminders (item 19). Path analysis investigating the relationships among the six factors comprising the Arabic version of the IES-R conforms with this logic. In consistence with an existing Italian study [7], intrusion was associated with hyperarousal in all the samples (Figure 2), and both factors directly and indirectly predicted avoidance, irritability, and sleep disturbance. Their indirect effects were mediated by irritability and numbing. The effects of intrusion on other dimensions of the IES-R were most pronounced in the healthy and clinical samples (who were community residents) than in the quarantine sample (Table 7 and Figure 2). This result draws support from previous investigations showing protective effects of being in isolation against COVID-19-related trauma and distress [6].
The literature refers to the COVID-19 pandemic as a collective trauma, with people experiencing traumatizing information (e.g., about job loss, food shortage, rising prices, etc.) and pictures/videos of health professionals in their quarantine uniform dragging COVID-19 victims on trollies (e.g., on the news and social media) on a daily basis [4]. Although some individuals may be overwhelmed by the trauma, others may get desensitized over time [5]. The six-factor structure was obtained in psychiatric patients and healthy adults. This finding is consistent with those of Gargurevich and colleagues indicating no difference in the overall structure of the IES-R between fire survivors and university students [23]. As shown in Figure 1, most item loadings were a little bit greater in the clinical sample than in the general public sample. The scores of all the six factors were also greater in the clinical sample (Table 7). These results denote that innate stress endorsed by psychiatric patients may increase the intensity of their experience of PTSD [20].
Analysis of measurement invariance revealed that the six-factor structure of the IES-R was invariant at the configural, metric, and scalar levels across groups of gender, age, and marital status. This result is similar to that reported by Wang et al. [20] who found that a four-factor structure model holds invariance across men and women. However, in their study, item intercepts based on magnitudes of factor loadings across samples were significantly non-equivalent, denoting a degree of scalar non-invariance [20]. Scalar invariance of the IES-R expressed in the present study allowed us to compare IES levels between groups. Women and young participants expressed considerably higher levels of trauma than men and older participants in all the samples (Table 7). In accordance, comparisons involving the parents of children diagnosed with epilepsy reflect a higher prevalence of PTSD among women. Men and women experiencing PTSD are reported to exhibit obvious differences in symptom clusters except for avoidance, with women being high on cognitive and somatic symptoms [42]. Irritability, mood dysregulation, and sleep disturbance are associated with continuous activation of the sympathetic nervous system and persistent dysregulation of the hypothalamic–pituitary–adrenal axis [43]. Research reports varying levels of corticotropin-releasing factor level and their association with PTSD symptoms across men and women [18]. Therefore, the differences between men and women in our samples as well as in other studies reflect higher susceptibility of females to react more excessively to traumatic events than their male counterparts.
All the items of the IES-R had strong significant positive correlations with the total scores of the IES-R and their domain-specific factors. Values of alpha if item deleted indicated no further increase in scale reliability following any item deletion. Item-total correlations as well as correlations of the factors with the total score of the scale were high, denoting adequate convergent validity of the IES-R, with no need to remove any item from the scale/subscales. External validity of the IES-R was supported by its positive correlation with the DASS-8, its subscales (depression, anxiety, and stress), as well as perceived vulnerability to COVID-19. Its negative correlation with perceived health status is consistent with the literature reporting higher COVID-19 trauma among people with poor physical health [6]. The IES-R scores were significantly higher among quarantined individuals and psychiatric patients compared with non-quarantined individuals and the general public, which lends further support to its known-group validity. The subscales of the IES-R were not overlapping with one another, as indicated by HTMT ratios below 0.85 in sample 1 and sample 2 (Supplementary Excel S2). This result supports the discriminant validity of the scale as well as usability of the six subscales to capture the distinct manifestations of trauma.
To our knowledge, this study is the first to investigate the psychometric qualities of the Arabic IES-R in three relatively large samples. Including psychiatric patients and the general public permitted us to evaluate if co-morbidity might affect the structure of the Arabic IES-R. Moreover, sophisticated tests were included such as EFA, CFA, measurement invariance, and HTMT. Thus, our study counteracts obstacle endorsed by former investigations of the Arabic IES-R, such as the use of a small sample size and limited methods of analysis [24]. The findings emphasize that the items of the IES-R cover more than three factors—sleep problems, numbing, and irritability/dysphoria seem to be important aspects of PTSD experiences. Despite these strengths, the results should be interpreted with caution because the study has a number of limitations. Using an online survey as a method to recruit respondents may entail selection bias in terms of including more young people who have some affinity to technology and certain economic background (e.g., they afford a mobile device). Older adults are more vulnerable to severe COVID-19, and their emotional reaction to the pandemic may differ from younger groups. However, we could not test sub-group differences in trauma because those above the age of 50 were less presented (6.1, 9.5, and 14.0% of the quarantine, psychiatric, and healthy samples, respectively (see Supplementary Excel 1 for all age categories)). As the survey was disseminated through social media such as Twitter and WhatsApp, individuals taking part in the psychiatric sample may express lower severity than those who decided not to take part in the survey. The cohorts included were highly heterogenous. For example, females represented a majority in all samples. As noted above, gender may considerably contribute to differences in PTSD symptoms. Data were collected during a restricted period of time at the beginning of the COVID-19 pandemic (29 April–19 May 2020). The number of all confirmed cases in Saudi Arabia did not exceed 1000 at that time. However, the number of cases and disease fatalities have increased given that the pandemic is still ongoing. Therefore, the current levels of psychological distress and trauma associated with the outbreak may be greater than those reported in the present study. In addition, the IES-R was evaluated within the COVID-19 context and extending its functionality to other traumas such as violence, burn, and route traffic accidents may be necessary. More robust methods such as item response theory may be used in future studies to explore the definite relationships among the items of the IES-R and the latent constructs (e.g., item difficulty and discrimination).

5. Conclusions

The Arabic IES-R is best described by a six-factor structure comprising avoidance, intrusion, numbing, hyperarousal, sleep problems, and irritability/dysphoria. The scales are quite discrete, and their scores are higher among psychiatric patients, supporting the known-group validity of the IES-R. The scale expresses excellent internal consistency and strong convergent and criterion validity both in psychiatric patients and in the general public. It operates evenly across groups of gender, age, and marital status, which indicates its appropriateness as a measure of psychological trauma among different groups.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/jpm12050681/s1, Table S1: Factors and corresponding items on every model; Table S2: Goodness-of-fit indices for structural equation models examining interactions among factors comprising the Arabic version of the Impact of Event Scale-Revised (IES-R); Supplementary Excel S1: extra results of of CFA, known-group validity, etc., which are referred to but not reported in the manuscript; Supplementary Excel S2: HTMT ratios of the factors comprising the IES-R in sample 1 and sample 2; File S1: The Arabic version of the Impact of Event Scale-Revised (IES-R)—reproduced with permission from Davey et al. [24].

Author Contributions

Conceptualization, A.M.A., A.O.H. and H.K.; methodology, A.M.A. and A.A.A.; investigation, A.A.A.; software, A.M.A., R.A.-A. and S.M.T.; validation, A.M.A., A.O.H. and R.A.-A.; formal analysis, A.M.A., E.S. and A.O.H.; resources, R.A.-A. and M.Y.S.; data curation, A.M.A. and A.O.H.; writing—original draft preparation, A.O.H., S.M.T. and M.Y.S.; writing—review and editing, A.M.A., E.S. and H.K.; project administration, A.M.A. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

The study protocol has been approved by the Institutional Review Board of Al Qassim University (No. 19-08-01).

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Data Availability Statement

The dataset used to produce the current study can be found in Mendeley repository at: https://data.mendeley.com/datasets/8k3vmfxpd3/draft?a=67415321-61f7-4920-bd2a-749b365ff6fb (accessed on 18 March 2022).

Acknowledgments

The researchers would like to thank the Deanship of Scientific Research, Qassim University, for funding the publication of this project. They would also thank Chris Lennings, LSC Psychology, for allowing us to include the Arabic version of the IES-R in this article.

Conflicts of Interest

The authors declare no conflict of interest.

Abbreviations

CFAConfirmatory factor analysis
CFIComparative Fit Index
DASS-21Depression Anxiety Stress Scale-21
DSM-IVDiagnostic and Statistical Manual of Mental Disorders
EFAExploratory factor analysis
GADGeneralized anxiety disorder
IES-RImpact of Event Scale-Revised
IQRInterquartile range
KMOThe Kaiser–Meyer–Olkin
MDMedian
OCDObsessive–compulsive disorder
PTSDPost-traumatic stress disorder
RMSEARoot mean square error of approximation
SRMRStandardized root mean square residual
TLITucker–Lewis Index
USUnited States

References

  1. Chew, Q.H.; Wei, K.C.; Vasoo, S.; Chua, H.C.; Sim, K. Narrative synthesis of psychological and coping responses towards emerging infectious disease outbreaks in the general population: Practical considerations for the COVID-19 pandemic. Singap. Med. J. 2020, 61, 350–356. [Google Scholar] [CrossRef] [PubMed]
  2. Li, Z.; Ge, J.; Yang, M.; Feng, J.; Qiao, M.; Jiang, R.; Bi, J.; Zhan, G.; Xu, X.; Wang, L.; et al. Vicarious traumatization in the general public, members, and non-members of medical teams aiding in COVID-19 control. Brain Behav. Immun. 2020, 88, 916–919. [Google Scholar] [CrossRef] [PubMed]
  3. Qiu, J.; Shen, B.; Zhao, M.; Wang, Z.; Xie, B.; Xu, Y. A nationwide survey of psychological distress among Chinese people in the COVID-19 epidemic: Implications and policy recommendations. Gen. Psychiatry 2020, 33, e100213. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  4. Trnka, R.; Lorencova, R. Fear, anger, and media-induced trauma during the outbreak of COVID-19 in the Czech Republic. Psychol. Trauma Theory Res. Pract. Policy 2020, 12, 546–549. [Google Scholar] [CrossRef]
  5. Wang, C.; Pan, R.; Wan, X.; Tan, Y.; Xu, L.; McIntyre, R.S.; Choo, F.N.; Tran, B.; Ho, R.; Sharma, V.K.; et al. A longitudinal study on the mental health of general population during the COVID-19 epidemic in China. Brain Behav. Immun. 2020, 87, 40–48. [Google Scholar] [CrossRef]
  6. Ali, A.M.; Alkhamees, A.A.; Elhay, E.S.A.; Taha, S.M.; Hendawy, A.O. COVID-19-related psychological trauma and psychological distress among community-dwelling psychiatric patients: People struck by depression and sleep disorders endure the greatest burden. Front. Public Health 2022, 9, 799812. [Google Scholar] [CrossRef]
  7. Sanchez-Gomez, M.; Giorgi, G.; Finstad, G.L.; Urbini, F.; Foti, G.; Mucci, N.; Zaffina, S.; León-Perez, J.M. COVID-19 Pandemic as a Traumatic Event and Its Associations with Fear and Mental Health: A Cognitive-Activation Approach. Int. J. Environ. Res. Public Health 2021, 18, 7422. [Google Scholar] [CrossRef]
  8. Craparo, G.; Faraci, P.; Rotondo, G.; Gori, A. The Impact of Event Scale-Revised: Psychometric properties of the Italian version in a sample of flood victims. Neuropsychiatr Dis. Treat. 2013, 9, 1427–1432. [Google Scholar] [CrossRef] [Green Version]
  9. Malinauskienė, V.; Bernotaitė, L. The Impact of Event Scale-Revised: Psychometric properties of the Lithuanian version in a sample of employees exposed to workplace bullying. Acta Med. Litu. 2016, 23, 185–192. [Google Scholar] [CrossRef] [Green Version]
  10. Ge, F.; Zhang, D.; Wu, L.; Mu, H. Predicting Psychological State Among Chinese Undergraduate Students in the COVID-19 Epidemic: A Longitudinal Study Using a Machine Learning. Neuropsychiatr Dis. Treat. 2020, 16, 2111–2118. [Google Scholar] [CrossRef]
  11. Debowska, A.; Horeczy, B.; Boduszek, D.; Dolinski, D. A repeated cross-sectional survey assessing university students’ stress, depression, anxiety, and suicidality in the early stages of the COVID-19 pandemic in Poland. Psychol. Med. 2020, 1–4. [Google Scholar] [CrossRef] [PubMed]
  12. Kim, M.-J.; Paek, S.-H.; Kwon, J.-H.; Park, S.-H.; Chung, H.-J.; Byun, Y.-H. Changes in Suicide Rate and Characteristics According to Age of Suicide Attempters before and after COVID-19. Children 2022, 9, 151. [Google Scholar] [CrossRef] [PubMed]
  13. Isik, A.T.; Soysal, P.; Solmi, M.; Veronese, N. Bidirectional relationship between caregiver burden and neuropsychiatric symptoms in patients with Alzheimer’s disease: A narrative review. Int. J. Geriatr. Psychiatry 2019, 34, 1326–1334. [Google Scholar] [CrossRef]
  14. Dalgleish, T.; Power, M.J. Emotion-specific and emotion-non-specific components of posttraumatic stress disorder (PTSD): Implications for a taxonomy of related psychopathology. Behav. Res. Ther. 2004, 42, 1069–1088. [Google Scholar] [CrossRef] [PubMed]
  15. Horesh, D.; Brown, A.D. Traumatic stress in the age of COVID-19: A call to close critical gaps and adapt to new realities. Psychol. Trauma Theory Res. Pract. Policy 2020, 12, 331–335. [Google Scholar] [CrossRef] [PubMed]
  16. Creamer, M.; Bell, R.; Failla, S. Psychometric properties of the Impact of Event Scale-Revised. Behav. Res. Ther. 2003, 41, 1489–1496. [Google Scholar] [CrossRef]
  17. Eid, J.; Larsson, G.; Johnsen, B.H.; Laberg, J.C.; Bartone, P.T.; Carlstedt, B. Psychometric properties of the Norwegian Impact of Event Scale-revised in a non-clinical sample. Nord. J. Psychiatry 2009, 63, 426–432. [Google Scholar] [CrossRef]
  18. Noda, Y.; Asano, K.; Shimizu, E.; Hirano, Y. Assessing Subgroup Differences in Posttraumatic Stress Disorder Among Rescue Workers in Japan With the Impact of Event Scale-Revised. Disaster Med. Public Health Prep. 2019, 13, 309–318. [Google Scholar] [CrossRef]
  19. Asukai, N.; Kato, H.; Kawamura, N.; Kim, Y.; Yamamoto, K.; Kishimoto, J.; Miyake, Y.; Nishizono-Maher, A. Reliability and validity of the Japanese-language version of the impact of event scale-revised (IES-R-J): Four studies of different traumatic events. J. Nerv. Ment. Dis. 2002, 190, 175–182. [Google Scholar] [CrossRef]
  20. Wang, L.; Zhang, J.; Shi, Z.; Zhou, M.; Huang, D.; Liu, P. Confirmatory factor analysis of posttraumatic stress symptoms assessed by the Impact of Event Scale-Revised in Chinese earthquake victims: Examining factor structure and its stability across sex. J. Anxiety Disord. 2011, 25, 369–375. [Google Scholar] [CrossRef]
  21. Brunet, A.; St-Hilaire, A.; Jehel, L.; King, S. Validation of a French version of the impact of event scale-revised. Can. J. Psychiatry 2003, 48, 56–61. [Google Scholar] [CrossRef] [PubMed]
  22. Mystakidou, K.; Tsilika, E.; Parpa, E.; Galanos, A.; Vlahos, L. Psychometric Properties of the Impact of Event Scale in Greek Cancer Patients. J. Pain Symptom Manag. 2007, 33, 454–461. [Google Scholar] [CrossRef] [PubMed]
  23. Gargurevich, R.; Luyten, P.; Fils, J.F.; Corveleyn, J. Factor structure of the Impact of Event Scale-Revised in two different Peruvian samples. Depress. Anxiety 2009, 26, E91–E98. [Google Scholar] [CrossRef]
  24. Davey, C.; Heard, R.; Lennings, C. Development of the Arabic versions of the Impact of Events Scale-Revised and the Posttraumatic Growth Inventory to assess trauma and growth in Middle Eastern refugees in Australia. Clin. Psychol. 2015, 19, 131–139. [Google Scholar] [CrossRef]
  25. King, D.W.; Orazem, R.J.; Lauterbach, D.; King, L.A.; Hebenstreit, C.L.; Shalev, A.Y. Factor structure of posttraumatic stress disorder as measured by the Impact of Event Scale–Revised: Stability across cultures and time. Psychol. Trauma Theory Res. Pract. Policy 2009, 1, 173–187. [Google Scholar] [CrossRef]
  26. Morina, N.; Böhme, H.F.; Ajdukovic, D.; Bogic, M.; Franciskovic, T.; Galeazzi, G.M.; Kucukalic, A.; Lecic-Tosevski, D.; Popovski, M.; Schützwohl, M.; et al. The structure of post-traumatic stress symptoms in survivors of war: Confirmatory factor analyses of the Impact of Event Scale--revised. J. Anxiety Disord. 2010, 24, 606–611. [Google Scholar] [CrossRef]
  27. Beck, J.G.; Grant, D.M.; Read, J.P.; Clapp, J.D.; Coffey, S.F.; Miller, L.M.; Palyo, S.A. The impact of event scale-revised: Psychometric properties in a sample of motor vehicle accident survivors. J. Anxiety Disord. 2008, 22, 187–198. [Google Scholar] [CrossRef] [Green Version]
  28. Ali, A.M.; Hori, H.; Kim, Y.; Kunugi, H. The Depression Anxiety Stress Scale 8-items expresses robust psychometric properties as an ideal shorter version of the Depression Anxiety Stress Scale 21 among healthy respondents from three continents. Front. Psychol. 2022, 13, 799769. [Google Scholar] [CrossRef]
  29. Ali, A.M.; Alkhamees, A.A.; Hori, H.; Kim, Y.; Kunugi, H. The Depression Anxiety Stress Scale 21: Development and Validation of the Depression Anxiety Stress Scale 8-item in Psychiatric Patients and the General Public for Easier Mental Health Measurement in a Post-COVID-19 World. Int. J. Environ. Res. Public Health 2021, 18, 10142. [Google Scholar] [CrossRef]
  30. Alkhamees, A.A.; Aljohani, M.S.; Alghesen, M.A.; Alhabib, A.T. Psychological Distress in Quarantine Designated Facility During COVID-19 Pandemic in Saudi Arabia. Risk Manag. Healthc. Policy 2020, 13, 3103–3120. [Google Scholar] [CrossRef]
  31. Ali, A.M.; Green, J. Factor structure of the depression anxiety stress Scale-21 (DASS-21): Unidimensionality of the Arabic version among Egyptian drug users. Subst. Abus. Treat. Prev. Policy 2019, 14, 40. [Google Scholar] [CrossRef] [PubMed]
  32. Ali, A.M.; Ahmed, A.; Sharaf, A.; Kawakami, N.; Abdeldayem, S.M.; Green, J. The Arabic Version of The Depression Anxiety Stress Scale-21: Cumulative scaling and discriminant-validation testing. Asian J. Psychiatry 2017, 30, 56–58. [Google Scholar] [CrossRef] [PubMed]
  33. Osman, A.; Wong, J.L.; Bagge, C.L.; Freedenthal, S.; Gutierrez, P.M.; Lozano, G. The Depression Anxiety Stress Scales-21 (DASS-21): Further examination of dimensions, scale reliability, and correlates. J. Clin. Psychol. 2012, 68, 1322–1338. [Google Scholar] [CrossRef] [PubMed]
  34. Ali, A.M.; Hendawy, A.O.; Ahmad, O.; Sabbah, H.A.; Smail, L.; Kunugi, H. The Arabic version of the Cohen perceived stress scale: Factorial validity and measurement invariance. Brain Sci. 2021, 11, 419. [Google Scholar] [CrossRef] [PubMed]
  35. Ali, A.M.; Hendawy, A.O.; Elhay, E.S.A.; Ali, E.M.; Alkhamees, A.A.; Kunugi, H.; Hassan, N.I. The Bergen Facebook Addiction Scale: Its psychometric properties and invariance among women with eating disorders. BMC Women’s Health 2022, 22, 99. [Google Scholar] [CrossRef]
  36. Ali, A.M.; Hendawy, A.O.; Almarwani, A.M.; Alzahrani, N.; Ibrahim, N.; Alkhamees, A.A.; Kunugi, H. The Six-item Version of the Internet Addiction Test: Its development, psychometric properties, and measurement invariance among women with eating disorders and healthy school and university students. Int. J. Environ. Res. Public Health 2021, 18, 12341. [Google Scholar] [CrossRef]
  37. Palmieri, P.A.; Fitzgerald, L.F. Confirmatory factor analysis of posttraumatic stress symptoms in sexually harassed women. J. Trauma. Stress 2005, 18, 657–666. [Google Scholar] [CrossRef]
  38. Baschnagel, J.S.; O’Connor, R.M.; Colder, C.R.; Hawk, L.W., Jr. Factor structure of posttraumatic stress among Western New York undergraduates following the September 11th terrorist attack on the World Trade Center. J. Trauma. Stress 2005, 18, 677–684. [Google Scholar] [CrossRef]
  39. Salehinejad, M.A.; Azarkolah, A.; Ghanavati, E.; Nitsche, M.A. Circadian disturbances, sleep difficulties and the COVID-19 pandemic. Sleep Med. 2021, 91, 246–252. [Google Scholar] [CrossRef]
  40. (US), C.f.S.A.T. Chapter 3, Understanding the Impact of Trauma. In Trauma-Informed Care in Behavioral Health Services; Treatment Improvement Protocol (TIP) Series; Substance Abuse and Mental Health Services Administration (US): Rockville, MD, USA, 2014.
  41. Rasmussen, A.; Verkuilen, J.; Jayawickreme, N.; Wu, Z.; McCluskey, S.T. When did posttraumatic stress disorder get so many factors? Confirmatory factor models since DSM–5. Clin. Psychol. Sci. 2019, 7, 234–248. [Google Scholar] [CrossRef]
  42. Carmassi, C.; Corsi, M.; Bertelloni, C.A.; Pedrinelli, V.; Massimetti, G.; Peroni, D.; Bonuccelli, A.; Orsini, A.; Dell’Osso, L. Post-traumatic stress spectrum symptoms in parents of children affected by epilepsy: Gender differences. Seizure 2020, 80, 169–174. [Google Scholar] [CrossRef] [PubMed]
  43. Ali, A.M.; Ahmed, A.H.; Smail, L. Psychological Climacteric Symptoms and Attitudes toward Menopause among Emirati Women. Int. J. Environ. Res. Public Health 2020, 17, 5028. [Google Scholar] [CrossRef] [PubMed]
Figure 1. Six-factor structure of the Arabic version of the Impact of Event Scale-Revised (IES-R) among psychiatric patients (a) and the general public (b). All items had moderate to strong loadings (>0.3) on the corresponding factors as indicated by values on the arrows connecting the factors to the items of the IES-R. The values on the arrows associating the factors of the IES-R reflect considerable inter-factor correlations. The fit of this model was improved by correlating the error term of item 5 with other items in both samples as well as the error terms of items 16 and 19 in the psychiatric patient sample.
Figure 1. Six-factor structure of the Arabic version of the Impact of Event Scale-Revised (IES-R) among psychiatric patients (a) and the general public (b). All items had moderate to strong loadings (>0.3) on the corresponding factors as indicated by values on the arrows connecting the factors to the items of the IES-R. The values on the arrows associating the factors of the IES-R reflect considerable inter-factor correlations. The fit of this model was improved by correlating the error term of item 5 with other items in both samples as well as the error terms of items 16 and 19 in the psychiatric patient sample.
Jpm 12 00681 g001aJpm 12 00681 g001b
Figure 2. Path analysis model predicting the relationships among factors comprising the Arabic version of the Impact of Event Scale-Revised (IES-R) in the quarantine sample (a), psychiatric patients (b), and healthy individuals (c). The intrusion and hyperarousal subscales of the IES-R were used as predictors and other subscales were dependent variables. Direct effects of the predictors are noted by values on the arrows while indirect relationships are reported in the text. Most variables predicted avoidance both directly and indirectly.
Figure 2. Path analysis model predicting the relationships among factors comprising the Arabic version of the Impact of Event Scale-Revised (IES-R) in the quarantine sample (a), psychiatric patients (b), and healthy individuals (c). The intrusion and hyperarousal subscales of the IES-R were used as predictors and other subscales were dependent variables. Direct effects of the predictors are noted by values on the arrows while indirect relationships are reported in the text. Most variables predicted avoidance both directly and indirectly.
Jpm 12 00681 g002aJpm 12 00681 g002b
Table 1. Sociodemographic characteristics of included participants.
Table 1. Sociodemographic characteristics of included participants.
Quarantine Sample (N = 214)
No (%)
Sample 1 (N = 168)
No (%)
Sample 2 (N = 992)
No (%)
Gender
Females86 (40.2)119 (70.8)622 (62.7)
Males128 (59.8)49 (29.2)370 (37.3)
Age (years)
18–30120 (56.1)87 (51.8)448 (45.2)
>3194 (43.9)81 (48.2)544 (54.8)
Marital status
Married106 (49.5)77 (45.8)553 (55.7)
Single/widowed/divorced108 (50.5)91 (54.2)439 (44.3)
Education
School degree65 (30.4)51 (30.4)263 (26.5)
University degree88 (41.1)105 (62.5)605 (61.0)
Post-graduate degree61 (28.5)12 (7.1)124 (12.5)
DASS-8 MD (IQR)2.0 (0.0–7.0)9 (2.0–17.0)2 (0.0–7.0)
Depression MD (IQR)1.0 (0.0–3.0)4.0 (1.0–7.0)1.0 (0.0–3.0)
Anxiety MD (IQR)0 (0.0–2.0)3.0 (0.0–6.0)0 (0.0–2.0)
Stress MD (IQR)0 (0.0–2.0)2.0 (0.0–4.0)0 (0.0–2.0)
MD: median; IQR: interquartile range; DASS-8: Depression Anxiety Stress Scale-8.
Table 2. Exploratory factor analysis of the Arabic version of the Impact of Event Scale-Revised (IES-R) in the quarantine sample.
Table 2. Exploratory factor analysis of the Arabic version of the Impact of Event Scale-Revised (IES-R) in the quarantine sample.
Items Extracted Factors
Factor 1Factor 2Factor 3Factor 4Factor 5
1Any reminder brought back feelings about it0.667−0.0090.360−0.0440.187
2I had trouble staying asleep0.3030.1110.6400.1320.134
3Other things kept making me think about it0.7170.1540.290−0.0300.125
4I felt irritable and angry0.3100.7760.2220.175−0.030
5I avoided letting myself get upset when I thought about it or was reminded of it0.2590.2980.1760.3410.319
6I thought about it when I did not mean0.5050.1930.0460.2980.039
7I felt as if it hadn′t happened or wasn′t real0.0290.0820.0820.3810.044
8I stayed away from reminders of it0.055−0.0160.1020.0860.899
9Pictures about it popped into my mind0.5820.2060.1110.2030.151
10I was jumpy and easily startled0.2590.9380.2020.0790.062
11I tried not to think about it0.0310.0250.0770.4380.540
12I was aware that I still had a lot of feelings0.1560.0590.1280.5660.206
13My feelings about it were kind of numb0.0730.0570.1280.3950.050
14I found myself acting or feeling like I was back at that time0.3960.2380.1840.3010.115
15I had trouble falling asleep0.2490.1630.7870.2690.081
16I had waves of strong feelings about it0.7300.2600.2750.2840.086
17I tried to remove it from my memory0.2970.062−0.1070.5620.344
18I had trouble concentrating0.3480.2580.6310.1360.063
19Reminders of it caused me to have physical reactions0.5690.1580.3190.1400.109
20I had dreams about it0.3740.2540.0500.175-0.020
21I felt watchful and on-guard0.2270.3370.0450.3160.259
22I tried not to talk about it0.2680.0830.1060.2660.537
Kaiser–Meyer–Olkin test0.870
Bartlett′s Test of Sphericity2219.657
Df231
P<0.001
Values in boldface represent significant loadings (>0.3). Based on the highest loadings of items with cross-loadings, items were located for the following factors: factor 1, intrusion: items 1, 3, 6, 9, 14, 16, 19, 20; factor 2, hyperarousal/dysphoria: items 4, 10, 21; factor 3, difficulty sleeping/concentrating: items 2, 15, 18; factor 4, numbing: items 7, 12, 13, 17; factor 5, avoidance: items 5, 8, 11, 22.
Table 3. Goodness-of-fit indices for models of the Arabic version of the Impact of Event Scale-Revised (IES-R) tested by confirmatory factor analysis in psychiatric patients and healthy adults.
Table 3. Goodness-of-fit indices for models of the Arabic version of the Impact of Event Scale-Revised (IES-R) tested by confirmatory factor analysis in psychiatric patients and healthy adults.
ModelsSampleχ2dfCFITLIRMSEARMSEA 90% CISRMR
Model 1
1F
Sample 1464.7862050.8440.8240.0870.077 to 0.0980.0714
Sample 21540.8252050.8530.8350.0810.077 to 0.0850.0654
Model 2
3F
Sample 1409.3882030.8760.8590.0780.067 to 0.0890.0679
Sample 21005.3042020.9120.8990.0630.059 to 0.0670.0596
Model 3
3F bifactor
Sample 1404.4262020.8790.8610.0770.066 to 0.0880.0679
Sample 21069.0212020.9050.8910.0660.062 to 0.0700.0610
Model 4
5F EFA
Sample 1393.7511970.8820.8620.0770.066 to 0.0880.0744
Sample 21241.5871970.8850.8660.0730.069 to 0.0770.0751
Model 5
5F modified
Sample 1382.8911980.8890.8710.0750.063 to 0.0860.0613
Sample 2977.9841980.9140.9000.0630.059 to 0.0670.0497
Model 6
5F bifactor
Sample 1300.2391760.9250.9020.0650.052 to 0.077--
Sample 2921.4331970.9210.9070.0610.057 to 0.0650.0528
Model 7
6F
Sample 1341.2481910.9100.8910.0690.057 to 0.0800.0616
Sample 2930.6281890.9190.9010.0630.059 to 0.0670.0573
Model 8
6F bifactor
Sample 1336.4931900.9120.8930.0680.056 to 0.0800.0765
Sample 2895.7951900.9230.9060.0610.057 to 0.0650.0601
Model 9
6F second order
Sample 1336.3942000.8990.8830.0710.060 to 0.0820.0656
Sample 21063.7761980.9050.8890.0660.63 to 0.0700.0641
χ2: chi-square; df: degrees of freedom; CFI: Comparative Fit Index; TLI: Tucker–Lewis index; RMSEA: root mean square error of approximation; CI: confidence interval; SRMR: standardized root mean residual; F: factor; --: SRMR was not produced indicating inadequate convergence of that model.
Table 4. Invariance of the six-factor structure (Model 7) of the Arabic version of the Impact of Event Scale-Revised (IES-R) across groups of gender, age, and marital status among psychiatric patients.
Table 4. Invariance of the six-factor structure (Model 7) of the Arabic version of the Impact of Event Scale-Revised (IES-R) across groups of gender, age, and marital status among psychiatric patients.
GroupsInvariance Levelsχ2dfpΔχ2Δdfp(Δχ2)CFIΔCFITLIΔTLIRMSEAΔRMSEASRMR
GenderConfigural699.6623820.001 0.831 0.795 0.071 0.0664
Metric712.6083980.00112.947160.0670.832−0.0010.806−0.0110.0690.0020.09701
Scalar754.6234190.00142.014210.0040.8210.0110.8030.0030.0690.0000.0762
Strict809.3324440.00154.709250.0010.8050.0160.7980.0050.070−0.0010.0786
AgeConfigural668.2113820.001 0.850 0.819 0.067 0.0867
Metric 679.8113980.00111.600160.7710.853−0.0030.829−0.0100.0650.0010.0900
Scalar720.0064190.00140.195210.0070.8430.0100.8260.0030.066−0.0010.1018
Strict837.3844440.001117.378250.0010.7940.0490.7860.0400.073−0.0070.1134
Marital statusConfigural660.5843820.001 0.850 0.819 0.066 0.0847
Metric 669.5333980.0018.949160.9150.854−0.0040.831−0.0120.0640.0020.0836
Scalar723.4374190.00153.903210.0010.8370.0170.8200.0110.066−0.0020.0878
Strict798.4904440.00175.054250.0010.8100.0270.8020.0180.069−0.0030.0905
χ 2: chi-square; df: degrees of freedom; CFI: Comparative Fit Index; TLI: Tucker–Lewis index; RMSEA: root mean square error of approximation; CI: confidence interval; SRMR: standardized root mean residual; F: factor. Values in boldface indicate tendency toward non-variance.
Table 5. Invariance of the six-factor structure (Model 7) of the Arabic version of the the Impact of Event Scale-Revised (IES-R) across groups of gender, age, and marital status among healthy participants.
Table 5. Invariance of the six-factor structure (Model 7) of the Arabic version of the the Impact of Event Scale-Revised (IES-R) across groups of gender, age, and marital status among healthy participants.
GroupsInvariance Levelsχ2dfpΔχ2Δdfp(Δχ2)CFIΔCFITLIΔTLIRMSEAΔRMSEASRMR
GenderConfigural1326.6943780.001 0.898 0.875 0.050 0.0585
Metric 1346.3843940.00119.690160.2350.8970.0010.880−0.0050.0490.0010.0604
Scalar1399.2864150.00152.902210.0010.8940.0030.882−0.0020.0490.0000.0613
Strict1649.7334420.001250.447270.0010.8700.0240.8640.0180.053−0.0040.0613
AgeConfigural1217.4333780.001 0.909 0.889 0.047 0.0561
Metric 1250.2123940.00132.779160.0080.9070.0020.891−0.0020.0470.0000.0570
Scalar1324.1604150.00173.948210.0010.9020.0050.8910.0000.0470.0000.0649
Strict1637.9254420.001313.764270.0010.8710.0310.8650.0260.052−0.0050.0593
Marital statusConfigural1242.9763780.001 0.906 0.885 0.048 0.0616
Metric 1287.7033940.00144.727160.0010.9030.0030.886−0.0010.0480.0000.0602
Scalar1354.7794150.00167.076210.0010.8980.0050.887−0.0010.0480.0000.0678
Strict1687.5974420.001332.818270.0010.8650.0330.859−0.0280.053−0.0050.0606
χ 2: chi-square; df: degrees of freedom; CFI: Comparative Fit Index; TLI: Tucker–Lewis index; RMSEA: root mean square error of approximation; CI: confidence interval; SRMR: standardized root mean residual; F: factor. Values in boldface indicate tendency toward non-variance.
Table 6. Internal consistency, normality, and criterion validity of the Arabic version of the Impact of Event Scale-Revised (IES-R) and the factors it comprises.
Table 6. Internal consistency, normality, and criterion validity of the Arabic version of the Impact of Event Scale-Revised (IES-R) and the factors it comprises.
ModelsSamplesIES-RAvoidanceIntrusionNumbingHyperarousalSleep ProblemsIrritability
Coefficient alphaQuarantine0.9010.7780.7710.5930.7290.7830.927
Sample 10.9320.8170.8080.6650.7680.7730.892
Sample 20.9150.8150.7370.6810.7370.7670.872
Alpha if item deletedQuarantine0.892–0.9020.718–0.7620.681–0.7760.484–0.5650.577–0.779----
Sample 10.917–0.9230.764–0.7930.737–08230.577–0.6330.661–0.784----
Sample 20.909–0.9150.738–0.8290.645–0.7500.569–0.6950.633–0723----
Item-total correlationsQuarantine0.251–0.7530.496–0.6060.495–0.6680.315–0.4210.353–0.6910.6410.865
Sample 10.359–0.7220.568–0.6670.389–0.7000.391–0.4770.439–0.6700.6360.805
Sample 20.316–0.6550.432–0.6500.306–06070.323–0.5310.471–06120.6300.773
Correlation with the IES-RQuarantine--0.755 **0.770 **0.738 **0.854 **0.729 **0.668 **
Sample 1--0.841 **0.844 **0.679 **0.867 **0.707 **0.727 **
Sample 2--0.843 **0.842 **0.802 **0.806 **0.653 **0.677 **
Shapiro–Wilk W testQuarantine0.9710.9680.9060.9260.8920.8520.753
Sample 10.9720.9640.9330.9320.9270.8940.892
Sample 20.950.9360.8990.9070.8560.7520.793
Correlation with DASS-8Quarantine0.605 **0.264 **0.506 **0.342 **0.652 **0.641 **0.559 **
Sample 10.716 **0.457 **0.569 **0.388 **0.704 **0.638 **0.698 **
Sample 20.623 **0.408 **0.523 **0.417 **0.614 **0.508 **0.647 **
DepressionQuarantine0.496 **0.176 **0.419 **0.240 **0.559 **0.566 **0.515 **
Sample 10.637 **0.433 **0.494 **0.341 **0.634 **0.563 **0.584 **
Sample 20.555 **0.359 **0.469 **0.380 **0.547 **0.452 **0.565 **
AnxietyQuarantine0.551 **0.290 **0.515 **0.267 **0.569 **0.450 **0.564 **
Sample 10.700 **0.413 **0.551 **0.421 **0.690 **0.617 **0.695 **
Sample 20.581 **0.385 **0.489 **0.392 **0.569 **0.454 **0.618 **
StressQuarantine0.574 **0.253 **0.438 **0.396 **0.603 **0.598 **0.497 **
Sample 10.649 **0.410 **0.553 **0.299 **0.622 **0.585 **0.686 **
Sample 20.560 **0.361 **0.456 **0.372 **0.551 **0.484 **0.590 **
Correlation with health statusQuarantine−0.305 **−0.038−0.293 **−0.227 **−0.336 **−0.324 **−0.389 **
Sample 1−0.348 **−0.204 **−0.375 **−0.159 *−0.303 **−0.365 **−0.319 **
Sample 2−0.211 **−0.106 **−0.199 **−0.173 **−0.183 **−0.189 **−0.201 **
Correlation with vulnerabilityQuarantine0.136−0.0350.238 **−0.0110.165 *0.234 **0.233 **
Sample 10.236 **0.1040.280 **0.178*0.223 **0.208 **0.142
Sample 20.144 **0.0380.182 **0.062 *0.186 **0.179 **0.172 **
IES-R: Impact of Event Scale-Revised, DASS-8: Depression Anxiety Stress Scale-8 items, MD: median, IQR: interquartile range, * and ** p values are significant at 0.05 and 0.01 levels, respectively.
Table 7. Descriptive statistics and known-group validity of the Arabic version of the Impact of Event Scale-Revised (IES-R) and the factors it comprises among quarantined, psychiatric, and healthy samples.
Table 7. Descriptive statistics and known-group validity of the Arabic version of the Impact of Event Scale-Revised (IES-R) and the factors it comprises among quarantined, psychiatric, and healthy samples.
IES-R and Its SubscalesQuarantine
(N = 214)
Sample 1
(N = 168)
Sample 2
(N = 992)
Quarantined or NotHaving a Psychiatric Disorder or Not
MD (IQR)MD (IQR)MD (IQR)Mann–Whitney TestzMann–Whitney Testz
IES-R22.0 (12.0–33.0)30.0 (14.0–43.0)18.0 (7.0–29.0)111309.0−2.4 *73429.5−7.3 **
Avoidance8.0 (4.0–11.0)8.0 (4.0–12.0)6.0 (1.0–10.0)101788.5−4.2 **86858.5−4.6 **
Intrusion3.0 (1.0–6.0)5.0 (2.0–9.0)3.0 (1.0–6.0)123375.5−0.182829.5−5.5 **
Numbing4.0 (1.0–6.0)4.0 (2.0–7.0)3.0 (0–6.0)120033.0−0.890113.5−4.0 **
Hyperarousal3.0 (1.0–6.0)4.0 (2.0–8.0)2.0 (0–4.0)112402.5−2.2 *74611.0−7.1 **
Sleep disturbance1.0 (0–4.0)2.0 (0–5.0)0 (0–2.0)102192.5−4.4 **71959.0−8.0 **
Irritability0.0 (0–3.0)3.0 (0–4.0)1.0 (0–3.0)114191.5−2.0 *78877.0−6.6 **
IES-R: Impact of Event Scale-Revised, MD: median, IQR: interquartile range, * and ** p values are significant at 0.05 and 0.01 levels, respectively.
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Ali, A.M.; Al-Amer, R.; Kunugi, H.; Stănculescu, E.; Taha, S.M.; Saleh, M.Y.; Alkhamees, A.A.; Hendawy, A.O. The Arabic Version of the Impact of Event Scale-Revised: Psychometric Evaluation among Psychiatric Patients and the General Public within the Context of COVID-19 Outbreak and Quarantine as Collective Traumatic Events. J. Pers. Med. 2022, 12, 681. https://doi.org/10.3390/jpm12050681

AMA Style

Ali AM, Al-Amer R, Kunugi H, Stănculescu E, Taha SM, Saleh MY, Alkhamees AA, Hendawy AO. The Arabic Version of the Impact of Event Scale-Revised: Psychometric Evaluation among Psychiatric Patients and the General Public within the Context of COVID-19 Outbreak and Quarantine as Collective Traumatic Events. Journal of Personalized Medicine. 2022; 12(5):681. https://doi.org/10.3390/jpm12050681

Chicago/Turabian Style

Ali, Amira Mohammed, Rasmieh Al-Amer, Hiroshi Kunugi, Elena Stănculescu, Samah M. Taha, Mohammad Yousef Saleh, Abdulmajeed A. Alkhamees, and Amin Omar Hendawy. 2022. "The Arabic Version of the Impact of Event Scale-Revised: Psychometric Evaluation among Psychiatric Patients and the General Public within the Context of COVID-19 Outbreak and Quarantine as Collective Traumatic Events" Journal of Personalized Medicine 12, no. 5: 681. https://doi.org/10.3390/jpm12050681

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