Hostname: page-component-78c5997874-dh8gc Total loading time: 0 Render date: 2024-11-19T20:38:41.290Z Has data issue: false hasContentIssue false

25-year follow-up of treated and not-treated adolescents after the Spitak earthquake: course and predictors of PTSD and depression

Published online by Cambridge University Press:  14 January 2020

Armen K. Goenjian*
Affiliation:
Department of Psychiatry and Biobehavioral Sciences, UCLA/Duke University National Center for Child Traumatic Stress, University of California, Los Angeles, Los Angeles, CA, USA Collaborative Neuroscience Network, Garden Grove, CA, USA Psychiatric Outreach Program, Armenian Relief Society, Long Beach, CA, USA
Alan M. Steinberg
Affiliation:
Department of Psychiatry and Biobehavioral Sciences, UCLA/Duke University National Center for Child Traumatic Stress, University of California, Los Angeles, Los Angeles, CA, USA
David Walling
Affiliation:
Collaborative Neuroscience Network, Garden Grove, CA, USA
Sheryl Bishop
Affiliation:
School of Nursing, University of Texas Medical Branch at Galveston, Galveston, TX, USA
Ida Karayan
Affiliation:
Psychiatric Outreach Program, Armenian Relief Society, Long Beach, CA, USA
Robert Pynoos
Affiliation:
Department of Psychiatry and Biobehavioral Sciences, UCLA/Duke University National Center for Child Traumatic Stress, University of California, Los Angeles, Los Angeles, CA, USA
*
Author for correspondence: Armen K. Goenjian, E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Background

There is a paucity of long-term prospective disaster studies of the psychological sequelae among survivors.

Methods

At 1½ and 25 years after the Spitak earthquake, 142 early adolescents from two cities were assessed: Gumri (moderate–severe exposure) and Spitak (very severe exposure). The Gumri group included treated and not-treated subjects, while the Spitak group included not-treated subjects. Instruments included: DSM-III-R PTSD-Reaction Index (PTSD-RI); DSM-5 PTSD-Checklist (PCL); Depression Self-Rating Scale (DSRS); and Center for Epidemiological Studies-Depression Scale (CES-D).

Results

(1) Between 1½ and 25 years, PTSD rates and mean scores decreased significantly in the three groups (over 50%). However, at 25 years 9.1–22.4% met DSM-5 PTSD criteria. (2) At 1½ years, the Spitak group had higher PTSD-RI (p < 0.001) and DSRS scores (p < 0.001) compared to the Gumri-not-treated group. At 25 years, the Spitak group that had experienced fewer post-earthquake adversities (p < 0.03), had a greater decrease in PTSD-RI scores (p < 0.02), and lower CES-D scores (p < 0.01). (3) Before treatment, PTSD-RI and DSRS scores did not differ between the Gumri-treated and not-treated groups. At 25-years, the Gumri-treated group showed a greater decrease in PTSD-RI scores (p < 0.03), and lower mean PTSD-RI (p < 0.02), PCL (p < 0.02), and CES-D (p < 0.01) scores. (4) Predictors of PTSD symptom severity at 25-years included: home destruction, treatment, social support, post-earthquake adversities, and chronic medical illnesses.

Conclusion

Post-disaster PTSD and depressive symptoms can persist for decades. Trauma-focused treatment, alleviation of post-disaster adversities, improving the social ecology, and monitoring for chronic medical illnesses are essential components of recovery programs.

Type
Original Articles
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 in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s) 2020. Published by Cambridge University Press

Introduction

The field of Disaster Psychiatry has become well-established and is anchored in numerous studies of the psychological sequelae among survivors of various types of natural and man-made disasters. The majority of disaster studies conducted among children and adolescent do not extend past 12 months (Terasaka, Tachibana, Okuyama, & Igarashi, Reference Terasaka, Tachibana, Okuyama and Igarashi2015; Wang, Chan, & Ho, Reference Wang, Chan and Ho2013). Consequently, there is a lack of information on the natural course and predictors of the psychological sequelae past a decade due to difficulties inherent in conducting longer-term post-disaster research. Reviews of posttraumatic stress disorder (PTSD) studies among children and adolescents exposed to disasters have shown that only about 10% of studies have extended beyond 3 years (Terasaka et al., Reference Terasaka, Tachibana, Okuyama and Igarashi2015; Wang et al., Reference Wang, Chan and Ho2013). Some of these studies have been cross-sectional (Agustini, Asniar, & Matsuo, Reference Agustini, Asniar and Matsuo2011; Goenjian et al., Reference Goenjian, Walling, Steinberg, Roussos, Goenjian and Pynoos2009; Jia et al., Reference Jia, Duan, Liu, Pan, Chen and Tian2013; Karakaya, Ağaoğlu, Coskun, Sişmanlar, & Yildiz Oc, Reference Karakaya, Ağaoğlu, Coskun, Sişmanlar and Yildiz Oc2004; Morgan, Scourfield, Williams, Jasper, & Lewis, Reference Morgan, Scourfield, Williams, Jasper and Lewis2003; Thordardottir et al., Reference Thordardottir, Valdimarsdottir, Hansdottir, Hauksdóttir, Dyregrov, Shipherd and Gudmundsdottir2016), while others have been longitudinal (Goenjian et al., Reference Goenjian, Walling, Steinberg, Karayan, Najarian and Pynoos2005; Green et al., Reference Green, Grace, Vary, Kramer, Gleser and Leonard1994; Kronenberg et al., Reference Kronenberg, Hansel, Brennan, Osofsky, Osofsky and Lawrason2010; McFarlane & Van Hooff, Reference McFarlane and Van Hooff2009; Najarian, Sunday, Labruna, & Barry, Reference Najarian, Sunday, Labruna and Barry2011; Piyasil et al., Reference Piyasil, Ketuman, Plubrukarn, Ularntinon, Sitdhiraksa, Pithayaratsathien and Sanguanpanich2011; Sahin, Batigün, & Yilmaz, Reference Sahin, Batigün and Yilmaz2007; Udwin, Boyle, Yule, Bolton, & O'Ryan, Reference Udwin, Boyle, Yule, Bolton and O'Ryan2000; Ularntinon et al., Reference Ularntinon, Piyasil, Ketumarn, Sitdhiraksa, Pityaratstian, Lerthattasilp and Pimratana2008; Yule et al., Reference Yule, Bolton, Udwin, Boyle, O'Ryan and Nurrish2000). Of these studies, four were conducted past a decade post-disaster (Green et al., Reference Green, Grace, Vary, Kramer, Gleser and Leonard1994; McFarlane & Van Hooff, Reference McFarlane and Van Hooff2009; Morgan et al., Reference Morgan, Scourfield, Williams, Jasper and Lewis2003; Najarian et al., Reference Najarian, Sunday, Labruna and Barry2011). Three showed that PTSD was persistent in adulthood among a substantial proportion (7% to 29%) of child and adolescent survivors (Green et al., Reference Green, Grace, Vary, Kramer, Gleser and Leonard1994; Morgan et al., Reference Morgan, Scourfield, Williams, Jasper and Lewis2003; Najarian et al., Reference Najarian, Sunday, Labruna and Barry2011), while the fourth found a small direct effect of the disaster on adult psychiatric morbidity at follow-up (McFarlane & Van Hooff, Reference McFarlane and Van Hooff2009).

Risk factors for PTSD identified in these medium to longer-term studies have included: death toll and proximity to the event (Furr, Corner, Edmunds, & Kendall, Reference Furr, Corner, Edmunds and Kendall2010); severity of initial exposure (Piyasil et al., Reference Piyasil, Ketuman, Plubrukarn, Jotipanut, Tanprasert, Aowjinda and Thaeeromanophap2007); previous history of trauma and physical injury (Ularntinon et al., Reference Ularntinon, Piyasil, Ketumarn, Sitdhiraksa, Pityaratstian, Lerthattasilp and Pimratana2008); occurrence of subsequent traumatic events (Perkonigg et al., Reference Perkonigg, Pfister, Stein, Höfler, Lieb, Maercker and Wittchen2005); pre-disaster psychosocial and physical difficulties in childhood (Udwin et al., Reference Udwin, Boyle, Yule, Bolton and O'Ryan2000); and lack of social support in the aftermath (Thordardottir et al., Reference Thordardottir, Valdimarsdottir, Hansdottir, Hauksdóttir, Dyregrov, Shipherd and Gudmundsdottir2016).

Regarding treatment outcome studies of PTSD among children and adolescents after disasters, most follow-ups have been conducted within 6–12 months (Chemtob, Nakashima, & Hamada, Reference Chemtob, Nakashima and Hamada2002; March, Amaya-Jackson, Murray, & Schulte, Reference March, Amaya-Jackson, Murray and Schulte1998; Pityaratstian et al., Reference Pityaratstian, Piyasil, Ketumarn, Sitdhiraksa, Ularntinon and Pariwatcharakul2015). To our knowledge, only a few studies that have investigated post-disaster treatment effect have employed longer (up to 4 years) follow-up periods (Basoglu, Salcioglu, & Livanou, Reference Basoglu, Salcioglu and Livanou2007; Giannopoulou, Dikaiakou, & Yule, Reference Giannopoulou, Dikaiakou and Yule2006; Goenjian et al., Reference Goenjian, Karayan, Pynoos, Minassian, Najarian, Steinberg and Fairbanks1997, Reference Goenjian, Walling, Steinberg, Karayan, Najarian and Pynoos2005). These studies have shown a beneficial effect of a variety of trauma-focused interventions in reducing the severity of PTSD symptoms.

The Spitak earthquake

In 1988, a catastrophic earthquake struck Armenia with a death toll estimated to be over 25 000. In Spitak, located 6.6 miles from the epicenter (population 30 000), the intensity of the earthquake was rated X (‘Devastating’) on the Medvedev–Sponheuer–Karnik-64 (MSK-64) scale, with a death toll of 5000. In Gumri, located 16.8 miles from the epicenter (population 250 000), the intensity of the earthquake was rated IX (‘Destructive’), with a death toll of 17 000 (Balassanian et al., Reference Balassanian, Arakelian, Nazaretian, Avanessian, Martirossian, Igoumnov and Tovmassian1995).

Due to the pervasive mental health problems related to the disaster and lack of adequate mental health workers in the earthquake zone, the Psychiatric Outreach Program was initiated by volunteer mental health workers from the United States in collaboration with the Ministries of Education and Health of Armenia, and the Armenian Relief Society of the Western United States. The purpose was to provide mental health services to the survivors. Initially, the work was focused on schools, and later in clinics. During the two decades following the earthquake, periodic assessments were made to monitor the mental health recovery of students who were being followed. The current study is a 25-year post-earthquake follow-up of a cohort evaluated at 1½ years post-earthquake (Goenjian et al., Reference Goenjian, Pynoos, Steinberg, Najarian, Asarnow, Karayan and Fairbanks1995). The purpose was to (1) assess the course of earthquake-related PTSD and depressive symptoms among differentially exposed subjects in Spitak and Gumri; (2) assess the effect of trauma-grief focused treatment; and (3) investigate potential risk and protective factors for PTSD and depression.

Methods

Participants

In 1990, 1½ years after the Spitak earthquake, 164 early adolescents aged 12–14 years from Gumri (N = 94) and Spitak (N = 70) were evaluated for PTSD, depression, and separation anxiety disorder. Information on these subjects has been reported previously (Goenjian et al., Reference Goenjian, Pynoos, Steinberg, Najarian, Asarnow, Karayan and Fairbanks1995). Within a few weeks after the assessment, school-based trauma/grief-focused brief psychotherapy was provided in some schools in Gumri and not others due to the shortage of qualified mental health workers. The selection of schools was based on proximity to the location of the clinical staff, availability of transportation to the schools, and adequacy of working space at the schools. These schools were representative of the schools in the region. The destruction and death toll was widespread throughout the city so that the children across Gumri schools experienced similar levels of earthquake exposure. All students in the classrooms selected for the intervention participated.

Data for the current study were collected in 2014, 25-years post-earthquake. Seventy-six of the original 94 participants from Gumri were located, with only one refused to participate. Three of the original group had died, and the rest were lost to follow-up. Of these 75 participants, 33 were among the group of 36 students who were provided treatment at 1½ years shortly after the baseline assessments. The rest (N = 42) had not received mental health treatment up to the time of the follow-up. In Spitak, 67 of the original 70 subjects were located and completed the study. None of these subjects had received mental health treatment since the earthquake. Two of the original group had died, and the third was lost to follow-up. The total number of participants in 2014 was 142 (87% of the original cohort). The high rate of capturing subjects at follow-up was because many of the original participants had remained in the city they lived in at the time of the earthquake, were cooperative in helping to locate their peers from the original cohort, and were positive about participating.

After obtaining approval from the IRB Company (a fully accredited IRB by the Association for the Accreditation of Human Research Protection Programs), the study subjects were given a full description of the study, including potential risks and benefits. Written informed consent was obtained from all participants.

Treatment at 1½ years post-earthquake

The treatment provided at 1½ years post-earthquake, after the baseline data were collected, has been detailed previously (Goenjian et al., Reference Goenjian, Walling, Steinberg, Karayan, Najarian and Pynoos2005). It consisted of four 90-min group therapy sessions with all the students in the same classroom and an average of two 1-hour individual therapy sessions over 3 weeks. It targeted five major areas: traumatic experiences; trauma reminders; losses and grief; secondary adversities; and developmental issues. The treatment included psychoeducation and interpersonal and cognitive-behavior therapy techniques. No medications were prescribed.

Instruments

Demographic information collected at 25 years (Tables 1 and 2) included data on City During the Earthquake; Age; Sex; Current Employment; Education; and Marital Status. Current Employment was dichotomized: employed (reference group), and unemployed. Education was dichotomized: ⩽high school (reference group), and >high school education. Marital status was dichotomized: married (reference group), and separated, divorced, single, widowed.

Table 1. Demographic, earthquake exposure and clinical characteristics of not-treated differentially exposed subjects from Spitak and Gumri at 1½ and 25 years after the 1988 Spitak earthquake

EQ, earthquake; Dx, diagnosis; MSK-64, Medvedev–Sponheuer–Karnik-64 scale; PTSD-RI, Posttraumatic Stress Disorder-Reaction Index; PCL, PTSD Checklist; DSRS, Depression Self Rating Scale; CES-D, Center for Epidemiologic Studies Depression Scale; SAD, separation anxiety disorder.

a Spitak-not-treated group by time (1½ and 25 years) comparison of PTSD rates: 55.2%a to 28.3%a2 = 9.93, p < 0.002).

b Gumri-not-treated group by time (1½ and 25 years) comparison of PTSD rates: 35.7%b to 14.3%b2 = 5.14, p < 0.02).

Table 2. Demographic, earthquake exposure, and clinical characteristics of Gumri-treated v. Gumri-not-treated groups at 1½ and 25 years after the 1988 Spitak earthquake

EQ, earthquake; Dx, diagnosis; MSK-64, Medvedev–Sponheuer–Karnik-64 scale; PTSD-RI, Posttraumatic Stress Disorder-Reaction Index; PCL, PTSD Checklist; DSRS, Depression Self Rating Scale; CES-D, Center for Epidemiologic Studies Depression Scale; SAD, Separation anxiety disorder.

α = Fisher's exact test.

a Gumri-treated group by time (1½ and 25 years) comparison of PTSD rates: 33.3%a to 12.1%a2 = 4.22, p < 0.04).

b Gumri-not-treated group by time (1½ and 25 years) comparison of PTSD rates: 35.7%b to 14.3%b2 = 5.14, p < 0.02).

Earthquake-related variables

City-wide official measures of exposure included the intensity of the earthquake and the death toll attributed to the earthquake. At 25-year follow-up the UCLA Exposure Questionnaire was used (Roussos et al., Reference Roussos, Goenjian, Steinberg, Sotiropoulou, Kakaki, Kabakos and Manouras2005) to measure objective and subjective features of experiences during the earthquake. Home Destruction due to the earthquake was dichotomized: none to moderate damage (reference group), and severe damage beyond repair. Nuclear Family Deaths related to the earthquake was dichotomized as none (reference group), and ⩾1. Earthquake-related Serious Injuries (e.g. crush injuries, fracture, and injuries requiring emergency medical care) were dichotomized: none, mild (reference group), and ⩾1 serious injury. Subjective Experiences (i.e. scared during the earthquake), was rated on a 5-point scale: 0 = none, 1 = a little, 2 = moderate, 3 = a lot, and 4 = very much. These scores were dichotomized: none, a little, moderate (reference group), and a lot, very much. Exposure to Pre- and Post-Earthquake Traumatic Experiences (events that involved an actual threat of death or serious injury of self or others) were dichotomized absent = none, mild (reference group), and present = moderate to extremely stressful.

Post-earthquake Adversities were derived by comparing post-earthquake to pre-earthquake conditions (heating; electricity; food; living space; and transportation). Responses were dichotomized into no difference, better (reference group), and worse. Change of Socioeconomic Status (SES) for the 10 years post-earthquake compared to pre-earthquake was dichotomized: no difference, better (reference group), and worse. Post-earthquake Chronic Illnesses were self-reported based on the information provided to the subjects at the polyclinics where they were enrolled. The illnesses included hypertension, myocardial infarction, stroke, asthma, and other respiratory illnesses, autoimmune illnesses, chronic genitourinary and digestive tract disease, diabetes, arthritis, musculoskeletal disorders, migraine, and cancer. The total number of illnesses (range: 0–13) for each participant was used for the analysis. Perceived Current Social Support by family and friends was assessed using the Duke-UNC Functional Social Support Questionnaire (Broadhead, Gehlbach, de Gruy, & Kaplan, Reference Broadhead, Gehlbach, de Gruy and Kaplan1988). Responses were scored on a 5-point scale: 1 = ‘much less than I would like’ to 5 = ‘as much as I would like.’ The total score was used for analysis (higher scores reflecting greater perceived social support).

PTSD and depression measures

Continuous and binary measures for PTSD were used for different reasons. The continuous scale scores provided a more sensitive representation of the progression of symptoms compared to binary measures, i.e. rates meeting diagnostic criteria, while rates were deemed useful for cross-comparisons with other studies that used rates as a primary outcome.

To compare the participants' PTSD severity at two widely separated time points, the same instrument was used at 1½ years (the DSM-III-R based PTSD Reaction Index) and at 25 years. Psychometric properties of the instrument have been reported elsewhere (Steinberg, Brymer, Decker, & Pynoos, Reference Steinberg, Brymer, Decker and Pynoos2004). For the PTSD questionnaires, the index trauma was the Spitak earthquake. Frequency of symptom occurrence during the previous month was rated on a 5-point Likert scale: 0 = not at all to 4 = almost every day. Symptom scores of 2 (symptom occurring one to two times a week) to 4 (almost every day), were used to define symptom presence. In a prior report (Pynoos et al., Reference Pynoos, Goenjian, Tashjian, Karakashian, Manjikian, Manoukian and Fairbanks1993), a cut-off of ⩾40 on the PTSD-RI was used to detect a diagnosis of PTSD. For the current study, more stringent criteria were used. Diagnosis of PTSD for both periods was based on a symptom cluster method (a minimum of 1B, 3C, and 2D category symptoms), as has been done in numerous prior studies on PTSD (McDonald & Calhoun, Reference McDonald and Calhoun2010). As a result, the baseline rates reported in this study are lower than rates reported previously (Goenjian et al., Reference Goenjian, Pynoos, Steinberg, Najarian, Asarnow, Karayan and Fairbanks1995; Pynoos et al., Reference Pynoos, Goenjian, Tashjian, Karakashian, Manjikian, Manoukian and Fairbanks1993).

At the 25-year follow-up, the Armenian version of the PTSD Check List (PCL) based on DSM-5 criteria (Demirchyan, Goenjian, & Khachadourian, Reference Demirchyan, Goenjian and Khachadourian2015) was also used to estimate the current rate of PTSD. This instrument is a modified version of the validated DSM-IV PCL questionnaire (Movsisyan et al., Reference Movsisyan, Demirchyan, Khachadourian, Haroutune, Armenian, Diener-West and Goenjian2016). As with the PTSD-RI, participants were asked to answer the symptom questions related to the earthquake. Items were rated on a 5-point scale: 0 = not at all; 1 = a little bit; 2 = moderately; 3 = quite a bit; 4 = extremely. To estimate a diagnosis of PTSD on the DSM-5 based PCL questionnaire, the symptom cluster method was used. Ratings of ‘moderately’ to ‘extremely’ were used to define symptom presence. Diagnosis of PTSD was derived by the presence of at least 1B, 1C, 2D, 2E, and category G criteria (functional impairment). Functional impairment was assessed using the Sheehan Disability Scale (Leon, Olfson, Portera, Farber, & Sheehan, Reference Leon, Olfson, Portera, Farber and Sheehan1997). Items were rated on a 5-point scale: 0 = not at all; 1 = mildly; 2 = moderately; 3 = markedly; 4 = extremely. A rating of moderate or higher was indicative of impairment.

Depression at 1½ years was evaluated by using the 21-item Depression Self-Rating Scale (DSRS) designed for use in children and adolescents (Asarnow & Carlson, Reference Asarnow and Carlson1985). The ratings of symptom frequency over the previous 2 weeks were made on a 3-point scale: 0 = never; 1 = sometimes; 3 = most of the time. Mean total scores were used for analysis. At follow-up, depression was assessed using the modified validated Armenian version of the Center for Epidemiological Studies Depression Scale (CES-D) (Demirchyan, Petrosyan, & Thompson, Reference Demirchyan, Petrosyan and Thompson2011). Items were rated on a 4-point scale: 0 = none or rarely, 1 = some of the time; 2 = moderate amount of time; 3 = most or all of the time. Mean total scores were used for analyses.

Translation of the PTSD-RI and DSRS into Armenian followed previously published guidelines, including the use of independent back-translation and pretesting with bilingual subjects (Brislin, Reference Brislin and Brislin1976). The PCL-C and CES-D were translated into Armenian after several rounds of forward and backward translations until a full concordance between the translation and the original instruments were reached, followed by rigorous testing among bilinguals (Demirchyan et al., Reference Demirchyan, Petrosyan and Thompson2011, Reference Demirchyan, Goenjian and Khachadourian2015). It remains an important question as to whether, over the many years between administrations of the same instruments, subjects' understanding of some of the terms used may have differed. All of the clinical instruments were administered in person by trained mental health professionals.

Data analysis

Data were analyzed using Statistical Package for the Social Sciences (SPSS) software (Version 22). Significance was calculated at p ⩽ 0.05. All data were examined for normality and homogeneity. χ2 analyses were used to explore distributions across nominal variables and to identify appropriate groupings for collapsing categories into dichotomous variables due to small subgroup sample sizes. Tests of differences, (e.g. t tests, ANOVA/ANCOVA) were conducted with two-tailed significance (p ⩽ 0.05). Post-hoc analyses were conducted using Tukey's HSD, and Scheffe's as well as Tamhane's T2 where issues of heterogeneity were present.

Different variables were dichotomized for different reasons. Ordinal variables, including Home Destruction, Subjective Experience (scared during the earthquake), Socioeconomic Status, Lifetime Traumatic Events, and Post-earthquake Adversities, were dichotomized for use as dummy variables in the multiple regression analyses instead of creating dummy variables for each ordinal category which would have proliferated the variables in the models given and reduced the already limited sample sizes. Numerical variables, including Nuclear Family Death(s) and Serious Injuries, were also dichotomized due to the severely restricted range, as there were only a few subjects with multiple deaths and serious injuries. It was deemed more important to explore differences in qualitative dimensions (e.g. deaths v. no deaths) rather than highly skewed and limited continuous distributions.

For this exploratory study, stepwise backward multiple regression analysis was used as it is more inclusive and allows variables that are marginally significant individually but work synergistically as a set, to be explored with the targeted dependent variables. The pre-, peri-, and post-earthquake variables were explored as potential predictors of PTSD-RI, PCL, and CES-D scores at 25 years. Limited sample size precluded assessing all variables of interest in the same model. The variables used included: Sex, Education, Home Destruction, Nuclear Family Deaths, Earthquake-related Serious Injury, Post-earthquake Adversities, Treatment after Baseline, Post-earthquake Traumatic Events, PTSD-RI, DSRS, and SAD scores at 1½ years, Post-earthquake Chronic Illnesses, and Current Social Support. Since the risks-based regression coefficients in the final stepwise model err on the high side, the full model results are also reported to provide parameter estimates of all variables considered.

Regarding missing subjects at 25-year follow-up, comparisons of the 1½ year data across the two key outcome variables, PTSD-RI and DSRS scores for those who did not participate in the 25-year follow-up with the data for those who completed the 25-year study yielded no significant differences. This was the case for the Gumri groups combined and the Spitak group, the Gumri-treated and Gumri-not-treated groups, and the Gumri-not-treated and Spitak-not-treated groups. The lack of significant differences at any level supported the decision to drop the missing subjects from the analyses.

The data were checked for completeness. At the 25-year follow-up, there were no missing data. For outcome questionnaires at 1½ years, those missing <10% of the responses, mean values were added in place of the missing data. For those with ⩾10% missing values, the subject questionnaire was excluded from the analysis. For the 1½ year study, a total of six participants had ⩾10% missing data. Four of the six participants had their DSRS and SAD responses excluded. Of the other two, one's DSRS, and another's SAD were excluded.

Results

Differentially exposed Gumri-not-treated (moderate–severe exposure) and Spitak-not-treated (very severe exposure) groups

Table 1 shows the demographic characteristics, exposure-related variables, and clinical measures between the differentially exposed Gumri-not-treated and the Spitak-not-treated groups. At 1½ years, between-city comparisons showed significantly higher rates in Spitak (the higher exposure group) for the following: Home Destruction, Earthquake-related Serious Injuries, and Post-earthquake Adversities.

PTSD rates at 1½ and 25 years

Table 1 also shows, between 1½ and 25 years, within group comparisons of PTSD rates (based on PTSD-RI). The rates decreased significantly for both the Spitak-not-treated group (55.2% to 28.3%; χ2 = 9.94, p < 0.002), and the Gumri-not-treated group (35.7% to 14.3%, χ2 = 5.14, p < 0.02).

Between-group comparisons of PTSD-RI-based PTSD rates at 1½ years showed a significantly higher rate for Spitak (p < 0.05). At 25 years, the rate was higher for the Spitak group (28.3%) compared to the Gumri-not-treated group (14.3%), but the difference was not significant (p < 0.09). Likewise, at 25 years, there was no significant difference between DSM-5 PCL-based PTSD rates.

PTSD severity scores (mean PTSD-RI and delta PTSD-RI scores, and mean PCL scores

Figure 1 shows the mean PTSD-RI scores at 1½ and 25 years between the differentially exposed Spitak-not-treated and Gumri-not-treated groups, and the mean delta scores (change in scores) between 1½ and 25 years. At 1½ years, the mean PTSD-RI score for the Spitak-not-treated group (M = 53.4, s.d. = 8.4) was significantly higher than that of the Gumri-not-treated group (M = 43.0, s.d. = 8.9) (t = 6.14, df = 107, p < 0.001). However, at 25 years, the mean PTSD-RI scores did not differ significantly between the two groups: Spitak-not-treated group (M = 39.8, s.d. = 13.9) v. Gumri-not-treated group (M = 36.1, s.d. = 10.7) (t = 1.47, df = 107, p < 0.14). The mean delta PTSD-RI score for the Spitak-not-treated group (M = 13.7, s.d. = 15.9) was significantly greater than for the Gumri-not-treated group (M = 6.9, s.d. = 11.1) (t = 2.42, df = 107, p < 0.02). At 25 years, there was no significant difference between the mean DSM-5 PCL score for the Spitak-not-treated group and the Gumri-not-treated group (Table 1).

Fig. 1. Mean PTSD-RI scores at 1½ and 25 years and the delta scores for the three groups after the 1988 Spitak earthquake. *p < 0.05; ***p < 0.001. PTSD-RI, Posttraumatic Stress Disorder-Reaction Index; Tx, treatment; EQ, earthquake.

  • A 1½ year comparison between Gumri-treated (a) and Gumri-not-treated (b) groups showed no significant difference. However, at 25 years, Gumri-treated (b) was significantly less than Gumri-not-treated (d) (t = −2.03, df = 73, p < 0.05).

  • A 1½ year comparison between differentially exposed group scores showed Spitak-not-treated (e) was higher than Gumri-not-treated (c) (t = 6.14, df = 107, p < 0.001). At 25 years there was no significant difference between the two groups, even though the mean score for Spitak was higher (f > d) (t = 1.43, df = 107, p = 0.15).

  • Within group by time analysis showed a significant decrease of PTSD-RI scores for the three groups between 1½ and 25 years: Gumri-treated (a > b) (t = 6.0, df = 32, p < 0.001); (b) Gumri-not-treated (c > d) (t = 4.0, df = 41, p < 0.001); (c) Spitak-not-treated (e > f) (t = 7.05, df = 66, p < 0.001).

  • Between group comparisons of the delta in PTSD-RI scores: Gumri-treated (g) greater than Gumri-not-treated (h) (t = 2.23, df = 73, p < 0.03); Spitak-not-treated (i) greater than Gumri-not-treated (h) (t = 2.42, df = 107, p < 0.02).

Depression severity at 1½ and 25 years

Table 1 shows that at 1½ years, the mean DSRS (depression) score was significantly higher for the Spitak-not-treated group (p < 0.001). However, at 25 years, the pattern reversed, where the mean CES-D score was less for the Spitak-not-treated group compared to the Gumi-not-treated group (p < 0.01).

Gumri-not-treated and Gumri-treated groups (similarly exposed groups)

Table 2 shows the demographic characteristics, pre-earthquake and earthquake-related variables, and clinical measures for the Gumri-treated and Gumri-not-treated groups. At 1½ and 25 years there were no significant differences in the rates or mean scores for pre-earthquake, earthquake, and post-earthquake non-clinical variables between the two groups, except for mean age, with the Gumri-treated group and Gumri not-treated group (36 v. 38 years respectively). While age was statistically significant between the two Gumri groups, the difference was minimal, and during the initial analyses, age consistently failed to be a significant covariate. Thus, to preserve degrees of freedom, age was not included in subsequent analyses as a covariate.

PTSD rates at 1½ and 25 years

Table 2 also shows, between 1½ and 25 years, within-group comparisons of PTSD-RI-based PTSD rates. There was a significant decrease for both the Gumri-treated group: 33.3% to 12.1% (χ2 = 4.22, p < 0.04), and the Gumri-not-treated group: 35.7% to 14.3% (χ2 = 5.14, p < 0.02). Between-group comparison of PTSD, rates did not differ significantly at 1½ and 25-years post-earthquake.

PTSD severity scores (mean PTSD-RI, PCL, and delta PTSD-RI scores)

Figure 1 shows the mean PTSD-RI scores at 1½ and 25 years for the Gumri-treated group and the Gumri-not-treated group, and the delta scores between 1½ and 25 years. At 1½ years, there was no significant difference in the mean PTSD-RI scores between the Gumri-treated group (M = 44.0, s.d. = 9.9) and the Gumri-not-treated group (M = 43.0, s.d. = 8.9) (t = .45, df = 73, p = 0.66.). However, at 25 years, the mean PTSD-RI score of the Gumri-treated group (M = 31.1, s.d. = 10.4) was significantly lower than the Gumri-not-treated group (M = 36.1, s.d. = 10.6) (t = −2.03, df = 73, p < 0.05). Within-group by time (between 1½ and 25 years) comparisons of PTSD-RI scores showed a significant decrease (p < 0.001) for both groups. The mean delta PTSD-RI score of the Gumri-treated group (M = −12.9, s.d. = 11.2) was significantly greater than the mean delta score for the Gumri-not-treated group (M = −6.9, s.d. = 11.1) (t = −2.23, df = 73, p < 0.03). Also, at 25 years, mean DSM-5 PCL score was less for the Gumri-treated group compared to the Gumri-not-treated group (25.2 v. 33.2; p < 0.02) (Table 2).

Depression severity at 1½ and 25 years

Table 2 shows at 1½ years before treatment, that the DSRS (depression) severity scores did not differ between the Gumri-treated and -not-treated groups. At 25 years, the mean CES-D score was significantly less for the Gumri-treated group (12.6 v. 20.7; p < 0.01). At 25 years, the mean DSM-5 PCL score was lower for the Gumri-treated group compared to the Gumri-not-treated group (25.2 v. 33.2; p < 0.02).

Best predictors of PTSD-RI, PCL, and CES-D symptom severity scores at 25-year follow-up

Table 3 shows both the full regression model and the stepwise selected ‘best’ set of predictors contributing to the three outcome variables: (1) for PTSD-RI scores at 25 years, treatment at baseline, and higher current social support scores were predictive of lower symptom severity of PTSD-RI scores, while experiencing home destruction, higher PTSD-RI scores at 1½ years, a greater number of chronic illnesses, and worsening adversities were predictive of higher PTSD-RI scores (R 2 = 36%); (2) for PCL scores at 25 years, higher social support scores and treatment were also predictive of lower PCL scores, while higher number of chronic illnesses and worsening adversities were predictive of higher PCL scores (R 2 = 33%); and (3) for CES-D scores at 25 years, higher social support was predictive of lower depression, while home destruction, worsening adversities, higher number of chronic illnesses, higher SAD symptom count at 1½ years were predictive of higher CES-D score (R 2 = 40%).

Table 3. The full model and the final stepwise model for PTSD-RI, PCL, and CES-D scores at 25-year follow-up among adults who were early-adolescents in 1988

PTSD-RI, Posttraumatic Stress Disorder-Reaction Index; PCL, PTSD Checklist; CES-D, Center for Epidemiologic Studies-Depression; EQ, earthquake; SAD, separation anxiety disorder.

Discussion

To our knowledge, this is the first long-term (past 5 years) prospective study examining the 25-year status of PTSD and depressive symptoms, risk and protective factors, and treatment outcome among adults who experienced a catastrophic earthquake as early adolescents. This study culminates a 30-year series of initial and follow-up studies among children, adolescents, adults, and older adults emanating from a major post-disaster mental health outreach, recovery, and research program implemented in the aftermath of the catastrophic 1988 Spitak earthquake in Armenia. The clinical findings of importance include the chronicity of PTSD and depressive symptoms 25 years after the disaster among a substantial portion of the exposed population, and the suggested long-term benefits of trauma-focused therapy for early adolescents. Of note, the school-based intervention used at 1½ years post-earthquake was a precursor of the UCLA Trauma Psychiatry Program trauma/grief intervention that has evolved into Trauma and Grief Component Therapy for Adolescents (Saltzman et al., Reference Saltzman, Layne, Pynoos, Olafson, Kaplow and Boat2017).

Exposure effect: comparison of not-treated groups of Gumri (moderate–severe exposure) and Spitak (very severe exposure)

At 1½ years, PTSD rates and mean severity scores based on PTSD-RI were higher in the Spitak-not-treated group compared to the Gumri-not-treated group, commensurate with the rates of mortality (Spitak = 37%; Gumri = 28%), morbidity (Spitak = 23.1%; Gumri = 2%), and home destruction (Spitak = 83%; Gumri = 50%). At 25-year follow-up, rates of PTSD and mean severity scores subsided significantly in both groups, with the Spitak group manifesting a greater decrease in PTSD-RI scores (p < 0.02). The regression analysis indicated that adversities were risk factors for both the PCL and PTSD-RI scores. The post-earthquake adversities were significantly less for the Spitak group (p < 0.03). This was consistent with citywide faster recovery in Spitak (e.g. more reconstruction), with lower rates of poverty (36% Spitak v. 44% Gumri), and lower unemployment (37% Spitak v. 47% Gumri) (Goenjian, Khachadourian, Armenian, Demirchyan, & Steinberg, Reference Goenjian, Khachadourian, Armenian, Demirchyan and Steinberg2018; Statistical Committee of the Republic of Armenia, 2015). The greater decline of PTSD severity scores among the Spitak participants may be attributable in part to the fewer post-earthquake adversities experienced by the Spitak group.

The differential effect of trauma on adults v. children and adolescents is an important topic that has not been investigated adequately in the literature. Comparison of the mean PCL scores, from a prior 23-year follow-up study of survivors from Gumri and Spitak who were adults at the time of the earthquake (Goenjian et al., Reference Goenjian, Khachadourian, Armenian, Demirchyan and Steinberg2018), with the PCL scores of the not-treated subjects from Spitak and Gumri of the current study at 25-years, indicates a differential effect of age at time of exposure. Those who were early-adolescents at time of exposure showed significantly higher mean PCL scores at follow-up (Spitak M = 31.5; Gumri M = 33.2) compared to those who were adults at the time of exposure (Spitak M = 25.3; Gumri M = 19.7) (p < 0.01 for both cites) suggesting that adolescents may be more vulnerable than adults to developing chronic PTSD symptoms and should be prioritized for early risk screening and treatment. The age effect of trauma on long-term sequelae needs further investigation.

Regarding depression, at 1½-years, the DSRS score for the Spitak-not-treated group was significantly higher compared to the Gumri-not-treated group. However, at 25-years these scores were reversed. For the Spitak-not-treated group, with fewer post-earthquake adversities (p < 0.03), the mean CES-D score was lower than that of Gumri-not-treated group. Similar to PTSD, fewer adversities experienced and the more favorable recovery environment, including more rebuilding, employment, and less poverty in Spitak may have contributed to the faster recovery of depression symptoms.

Treatment effect: comparison of Gumri-treated v. Gumri-not-treated groups

At 1½ years, there were no significant differences in pre-, peri-, and post-earthquake variables, including PTSD-RI severity scores and PTSD rates between the Gumri-treated and Gumri-not-treated groups. A treatment effect was evident at 25-years post-earthquake, with the mean PTSD-RI and PCL scores for the Gumri-treated group being significantly lower than the Gumri-not-treated group. PTSD-RI scores had decreased in both groups at follow-up; however, the decrease was significantly greater for the Gumri-treated group (30% v. 16%). The treatment effect was consistent with the regression analyses showing that treatment at baseline was predictive of lower PTSD symptom severity at follow-up.

Several aspects of the intervention lend themselves as possible candidates for the long-term benefits of treatment. First, the focus in treatment on identifying and managing trauma reminders may have led to the reduction of reminder-related reactivity. Second, treatment promoted strategies for coping with hyperarousal and avoidant behavior. Finally, the promotion of skills for managing emotions and recruiting social support may have been associated with less risk-taking behavior, and anger outbursts.

CES-D scores at 25-years also showed a treatment effect, with significantly lower CES-D scores for the Gumri-treated group. Treatment included dealing with losses, enhancing problem-solving of adversities, reducing interpersonal conflicts, and promoting adaptive rather than maladaptive grief reactions. These components may have contributed to the reduction in depressive symptoms.

Risk and protective factors for PTSD and depression

There were two risk factors (post-earthquake adversities and chronic illnesses), and two protective factors (treatment and current social support) contributing to the variance in PTSD-RI, PCL, and CES-D scores at 25 years. The present findings extend shorter-term findings after disasters, indicating that adversities constitute a risk factor in adults for PTSD (Brewin, Andrews, & Valentine, Reference Brewin, Andrews and Valentine2000; Galea, Nandi, & Vlahov, Reference Galea, Nandi and Vlahov2005). Adverse conditions in the earthquake zone included lack of heat, electricity, housing, transportation, and destruction of physical and community infrastructure. Even though the Gumri-not-treated group had experienced less destruction and lower PTSD-RI scores at 1½ years compared to Spitak, post-earthquake adversities experienced were reported to be greater by the Gumri subjects, and the decrease in PTSD-RI scores among the Gumri-not-treated subjects was significantly less compared to the Spitak-not-treated group. The fewer adversities reported by the Spitak subjects was congruous with the city-wide faster rebuilding, lower unemployment, and poverty. This finding suggests that recovery programs include attention to alleviation of post-disaster adversities. In so doing, governmental and non-governmental agencies may play an important role in the mental health recovery of survivors. Improvements in these areas can foster social interaction (e.g. visits to relatives, participation in community activities), and enhance the social ecology.

The number of post-earthquake chronic illnesses was predictive of PTSD and depressive scores at 25 years. This is the first study documenting the association of chronic illness with PTSD and depression among survivors over a decade after a disaster. These results extend the findings of a 4-year follow-up study among adult survivors of the Spitak earthquake that found an increase in heart disease, newly reported hypertension, diabetes, and arthritis (Armenian, Melkonian, & Hovanesian, Reference Armenian, Melkonian and Hovanesian1998). The finding of long-term health conditions among adolescents exposed to a disaster expands current discussions of the relationship between adverse childhood experiences and health outcomes (Felitti & Anda, Reference Felitti, Anda, Lanius, Vermetten and Pain2010).

Higher levels of current social support were inversely related to PTSD-RI and CES-D scores at 25 years. The association of PTSD symptoms and social support extends prior findings among adults in this population (Goenjian et al., Reference Goenjian, Khachadourian, Armenian, Demirchyan and Steinberg2018) and children after other disasters (McDermott, Berry, & Cobham, Reference McDermott, Berry and Cobham2012; Thordardottir et al., Reference Thordardottir, Valdimarsdottir, Hansdottir, Hauksdóttir, Dyregrov, Shipherd and Gudmundsdottir2016; Udwin et al., Reference Udwin, Boyle, Yule, Bolton and O'Ryan2000). Given that current levels of social support may have been indicative of earlier levels of social support over the post-earthquake interval, we would suggest, as has been previously reported (Kaniasty & Norris, Reference Kaniasty and Norris2008; Platt, Lowe, Galea, Norris, & Koenen, Reference Platt, Lowe, Galea, Norris and Koenen2016), that there may be a bi-directional relation, in that ongoing social support may have contributed to the resolution of PTSD symptoms, while ongoing severity of PTSD symptoms may have negatively affected the acquisition and maintenance of social support. The bi-directionality may also apply to the association of social support and depression.

SAD symptoms at baseline also predicted depression at 25 years. Many of the early adolescents in the aftermath of the earthquake were fearful of something bad happening again or to their caretakers and avoided separation from them by refusing to go to school (Goenjian et al., Reference Goenjian, Pynoos, Steinberg, Najarian, Asarnow, Karayan and Fairbanks1995). Genetic vulnerabilities may also play a partial explanatory role. A multigenerational family study from Gumri after the earthquake found a significant genetic correlation between anxiety symptoms and depression (r g = 0.54) indicating pleiotropy (shared genetic vulnerability) (Goenjian et al., Reference Goenjian, Noble, Walling, Goenjian, Karayan, Ritchie and Bailey2008). This shared genetic vulnerability may have contributed to the predictive value of SAD in predicting depression.

Strengths

Strengths of the study included the extensive long-term follow-up of exposed preadolescents with 87% of the original cohort retrieved at follow-up, exposure of all of the subjects to the trauma contemporaneously, and the inclusion of treated and not-treated subjects. Additionally, we used the same instrument, the DSM-III-R based PTSD-RI scale, to measure symptom severity at 1½ and 25-year follow-up to reduce discrepancies introduced by using different measures at different time points. Finally, we used the PCL to estimate current rates of PTSD based on DSM-5 criteria.

Limitations

The response to some of the questions dating back 25 years, such as the distress experienced during the earthquake and post-earthquake adversities may have been subject to recall bias. Given that children were not randomly assigned to treatment, confidence in the outcome findings must be qualified in that there may have been unknown differences in the comparison groups.

Implications for post-disaster public mental health recovery programs

Despite the decline, a sub-group of the population in both cities continued to experience substantial levels of PTSD and depressive symptoms. This represents a public mental health problem for the region. In addressing chronic cases, mental health programs should include ongoing surveillance for PTSD and depression, as well as the post-earthquake onset of traumatic experiences. Public health programs should also strive to mitigate ongoing post-disaster adversities.

The association of persistent PTSD and depression with chronic medical illnesses point to the need for targeted outreach services across physical and behavioral health systems. Finally, the enduring impact of treatment provided at 1½ years post-earthquake reinforces the benefit of implementing school-based trauma-grief focused interventions that may benefit a generation of adolescents as they transition to adulthood.

References

Agustini, E. N., Asniar, I., & Matsuo, H. (2011). The prevalence of long-term post-traumatic stress symptoms among adolescents after the tsunami in Aceh. Journal of Psychiatric Mental Health Nursing, 18, 543549.CrossRefGoogle ScholarPubMed
Armenian, H. K., Melkonian, A. K., & Hovanesian, A. P. (1998). Long term mortality and morbidity related to degree of damage following the 1988 earthquake in Armenia. American Journal of Epidemiology, 148, 10771084.CrossRefGoogle ScholarPubMed
Asarnow, J. R., & Carlson, G. A., & Depression Self-Rating Scale (1985). Utility with child psychiatric inpatients. Journal of Consulting and Clinical Psychology, 53, 491499.CrossRefGoogle ScholarPubMed
Balassanian, S. Y., Arakelian, A. R., Nazaretian, S. N., Avanessian, A. S., Martirossian, A. H., Igoumnov, V. A., … Tovmassian, A. K. (1995). Retrospective analysis of the Spitak earthquake. Annals of Geophysics, 38, 345372.CrossRefGoogle Scholar
Basoglu, M., Salcioglu, E., & Livanou, M. (2007). A randomized controlled study of single-session behavioural treatment of earthquake-related post-traumatic stress disorder using an earthquake simulator. Psychological Medicine, 37, 203213.CrossRefGoogle ScholarPubMed
Brewin, C. R., Andrews, B., & Valentine, J. D. (2000). Meta-analysis of risk factors for posttraumatic stress disorder in trauma-exposed adults. Journal of Consulting and Clinical Psychology, 68, 748766.CrossRefGoogle ScholarPubMed
Brislin, R. W. (1976). Translation research and its applications: An introduction. In Brislin, R. (Ed.), Translations: Applications and research. New York: Wiley/Halsted.Google Scholar
Broadhead, W. E., Gehlbach, S. H., de Gruy, F. V., & Kaplan, B. H. (1988). The Duke-UNC Functional Social Support Questionnaire: Measurement of social support in family medicine patients. Medical Care, 26, 709723.CrossRefGoogle ScholarPubMed
Chemtob, C., Nakashima, J. P., & Hamada, R. S. (2002). Psychosocial intervention for post-disaster trauma symptoms in elementary school children: A controlled community field study. Archives of Pediatric and Adolescent Medicine, 156, 211216.CrossRefGoogle Scholar
Demirchyan, A., Goenjian, A. K., & Khachadourian, V. (2015). Factor structure and psychometric properties of the Posttraumatic Stress Disorder (PTSD) Checklist and DSM-5 PTSD symptom set in a long-term post-earthquake cohort in Armenia. Assessment, 22, 594606.CrossRefGoogle Scholar
Demirchyan, A., Petrosyan, V., & Thompson, M. F. (2011). Psychometric value of the Center for Epidemiologic Studies Depression (CES-D) scale for screening of depressive symptoms in Armenian population. Journal of Affective Disorders, 133, 489498.CrossRefGoogle Scholar
Felitti, V. J., & Anda, R. F. (2010). The relationship of Adverse Childhood Experiences in adult health, well-being, social function, and health care. Chapter 8. In Lanius, R., Vermetten, E. & Pain, C. (Eds), The effects of early life trauma on health and disease: The hidden epidemic (pp. 7787). Cambridge, UK: Cambridge University Press.CrossRefGoogle Scholar
Furr, J. M., Corner, J. S., Edmunds, J. M., & Kendall, P. C. (2010). Disasters and youth: A meta-analytic examination of posttraumatic stress. Journal of Consulting and Clinical Psychology, 78, 765780.CrossRefGoogle ScholarPubMed
Galea, S., Nandi, A., & Vlahov, D. (2005). The epidemiology of post-traumatic stress disorder after disasters. Epidemiologic Reviews, 27, 7891.CrossRefGoogle ScholarPubMed
Giannopoulou, I., Dikaiakou, A., & Yule, W. (2006). Cognitive-behavioural group intervention for PTSD symptoms in children following the Athens 1999 earthquake: A pilot study. Clinical Child Psychology and Psychiatry, 11, 543553.CrossRefGoogle ScholarPubMed
Goenjian, A., Khachadourian, V., Armenian, H., Demirchyan, A., & Steinberg, A. M. (2018). Posttraumatic stress disorder 23 years after the 1988 Spitak earthquake in Armenia. Journal of Traumatic Stress, 31, 4756.CrossRefGoogle ScholarPubMed
Goenjian, A. K., Karayan, I., Pynoos, R., Minassian, D., Najarian, L. M., Steinberg, A. M., & Fairbanks, L. A. (1997). Outcome of psychotherapy among early adolescents after trauma. American Journal of Psychiatry, 154, 536542.Google ScholarPubMed
Goenjian, A. K., Noble, E. P., Walling, D. P., Goenjian, H. A., Karayan, I., Ritchie, T., & Bailey, J. N. (2008). Heritabilities of symptoms of posttraumatic stress disorder, anxiety, and depression in earthquake exposed Armenian families. Psychiatric Genetics, 18, 261266.CrossRefGoogle ScholarPubMed
Goenjian, A. K., Pynoos, R. S., Steinberg, A. M., Najarian, L. M., Asarnow, J. R., Karayan, I., … Fairbanks, L. A. (1995). Psychiatric co-morbidity in children after the 1988 earthquake in Armenia. Journal of American Academy of Child and Adolescent Psychiatry, 34, 11741184.CrossRefGoogle ScholarPubMed
Goenjian, A. K., Walling, D., Steinberg, A. M., Karayan, I., Najarian, L. M., & Pynoos, R. (2005). A prospective study of posttraumatic stress and depressive reactions among treated and untreated adolescents 5 years after a catastrophic disaster. American Journal of Psychiatry, 162, 23022308.CrossRefGoogle ScholarPubMed
Goenjian, A. K., Walling, D., Steinberg, A. M., Roussos, A., Goenjian, H. A., & Pynoos, R. S. (2009). Depression and PTSD symptoms among bereaved adolescents 6 (1/2) years after the 1988 Spitak earthquake. Journal of Affective Disorders, 112, 8184.CrossRefGoogle ScholarPubMed
Green, B. L., Grace, M. C., Vary, M. G., Kramer, T. L., Gleser, G. C., & Leonard, A. C. (1994). Children of disaster in the second decade: A 17-year follow-up of Buffalo Creek survivors. Journal of American Academy of Child and Adolescent Psychiatry, 33, 7179.CrossRefGoogle ScholarPubMed
Jia, Z., Duan, G., Liu, W., Pan, X., Chen, Y., & Tian, W. (2013). Traumatic experiences and mental health consequences among child survivors of the 2008 Sichuan earthquake: A community-based follow-up study. BMC Public Health, 13, 104.CrossRefGoogle ScholarPubMed
Kaniasty, K., & Norris, F. H. (2008). Longitudinal linkages between perceived social support and posttraumatic stress symptoms: Sequential roles of social causation and social selection. Journal of Traumatic Stress, 21, 274281.CrossRefGoogle ScholarPubMed
Karakaya, I., Ağaoğlu, B., Coskun, A., Sişmanlar, S. G., & Yildiz Oc, O. (2004). The symptoms of PTSD, depression and anxiety in adolescent students three and a half years after the Marmara earthquake. Turkish Journal of Psychiatry (Turk Psikiyatri Dergisi), 15, 257263.Google Scholar
Kronenberg, M. F., Hansel, T. C., Brennan, A. M., Osofsky, H. J., Osofsky, J. D., & Lawrason, B. (2010). Children of Katrina: Lessons learned about post-disaster symptoms and recovery patterns. Child Development, 81, 12411259.CrossRefGoogle Scholar
Leon, A. C., Olfson, M., Portera, L., Farber, L., & Sheehan, D. V. (1997). Assessing psychiatric impairment in primary care with the Sheehan Disability Scale. International Journal of Psychiatry in Medicine, 27(2), 93105.CrossRefGoogle ScholarPubMed
March, J. S., Amaya-Jackson, L., Murray, M. C., & Schulte, A. (1998). Cognitive-behavioral psychotherapy for children and adolescents with posttraumatic stress disorder after a single-incident stressor. Journal of American Academy of Child and Adolescent Psychiatry, 37(6), 585593.CrossRefGoogle ScholarPubMed
McDermott, B., Berry, H., & Cobham, V. (2012). Social connectedness: A potential aetiological factor in the development of child post-traumatic stress disorder. Australian and New Zealand Journal of Psychiatry, 46, 109117.CrossRefGoogle ScholarPubMed
McDonald, S. D., & Calhoun, P. S. (2010). The diagnostic accuracy of PTSD checklist: A critical review. Clinical Psychology Review, 30, 976987.CrossRefGoogle ScholarPubMed
McFarlane, A. C., & Van Hooff, M. (2009). Impact of childhood exposure to a natural disaster on adult mental health: 20-year longitudinal follow-up study. British Journal of Psychiatry, 195, 142148.CrossRefGoogle ScholarPubMed
Morgan, L., Scourfield, J., Williams, D., Jasper, A., & Lewis, G. (2003). The Aberfan disaster: 33-year follow-up of survivors. British Journal of Psychiatry, 182, 532536.CrossRefGoogle ScholarPubMed
Movsisyan, A., Demirchyan, A., Khachadourian, V., Haroutune, K., Armenian, H. K., Diener-West, M., & Goenjian, A. (2016). Diagnostic accuracy and operating characteristics of the Posttraumatic Stress Disorder (PTSD) Checklist in the post-earthquake population in Armenia. Journal of Traumatic Stress Disorders and Treatment, 5(1), 19.CrossRefGoogle Scholar
Najarian, L. M., Sunday, S., Labruna, V., & Barry, I. (2011). Twenty-year follow-up of adults traumatized during childhood in Armenia. Journal of Affective Disorder, 135, 5155.CrossRefGoogle ScholarPubMed
Perkonigg, A., Pfister, H., Stein, M. B., Höfler, M., Lieb, R., Maercker, A., & Wittchen, H. U. (2005). Longitudinal course of posttraumatic stress disorder and posttraumatic stress disorder symptoms in a community sample of adolescents and young adults. American Journal of Psychiatry, 162, 13201327.CrossRefGoogle Scholar
Pityaratstian, N., Piyasil, V., Ketumarn, P., Sitdhiraksa, N., Ularntinon, S., & Pariwatcharakul, P. (2015). Randomized controlled trial of group cognitive behavioral therapy for post-traumatic stress disorder in children and adolescents exposed to tsunami in Thailand. Behavioral Cognitive Psychotherapy, 43, 549561.CrossRefGoogle ScholarPubMed
Piyasil, V., Ketuman, P., Plubrukarn, R., Jotipanut, V., Tanprasert, S., Aowjinda, S., & Thaeeromanophap, S. (2007). Posttraumatic stress disorder in children after tsunami disaster in Thailand: 2 years follow-up. Journal of Medical Association of Thailand, 34, 11741184.Google Scholar
Piyasil, V., Ketuman, P., Plubrukarn, R., Ularntinon, S., Sitdhiraksa, N., Pithayaratsathien, N., … Sanguanpanich, N. (2011). Post-traumatic stress disorder in children after tsunami disaster in Thailand: A 5-year follow-up. Journal of Medical Association of Thailand, 94, 138144.Google ScholarPubMed
Platt, J. M., Lowe, S. R., Galea, S., Norris, F. H., & Koenen, K. C. (2016). A longitudinal study of the bidirectional relationship between social support and posttraumatic stress following a natural disaster. Journal of Traumatic Stress, 29, 205213.CrossRefGoogle ScholarPubMed
Pynoos, R. S., Goenjian, A., Tashjian, M., Karakashian, M., Manjikian, R., Manoukian, G., … Fairbanks, L. A. (1993). Posttraumatic stress reactions in children after the 1988 Armenian earthquake. British Journal of Psychiatry, 163, 239247.CrossRefGoogle Scholar
Roussos, A., Goenjian, A. K., Steinberg, A. M., Sotiropoulou, C., Kakaki, M., Kabakos, C., … Manouras, V. (2005). Posttraumatic stress and depressive reactions among children and adolescents after the 1999 Ano Liosia earthquake in Greece. American Journal of Psychiatry, 162, 530537.CrossRefGoogle Scholar
Sahin, N. H., Batigün, A. D., & Yilmaz, B. (2007). Psychological symptoms of Turkish children and adolescents after the 1999 earthquakes: Exposure, gender, location, and time duration. Journal of Traumatic Stress, 20, 335345.CrossRefGoogle ScholarPubMed
Saltzman, W. R., Layne, C. M., Pynoos, R. S., Olafson, E., Kaplow, J. B., & Boat, B. (2017). Trauma and grief component therapy for adolescents: A modular approach to treating traumatized and bereaved youth. New York: Cambridge University Press.CrossRefGoogle Scholar
Statistical Committee of the Republic of Armenia. (2015). Part 1 – Armenia: Poverty profile in 2008–2015. Retrieved from http://www.armstat.am/file/article/poverty_2016_eng_2.pdf.Google Scholar
Steinberg, A. M., Brymer, M. J., Decker, K. B., & Pynoos, R. S. (2004). The University of California at Los Angeles Posttraumatic Stress Disorder Reaction Index. Current Psychiatry Reports, 6, 96100.CrossRefGoogle Scholar
Terasaka, A., Tachibana, Y., Okuyama, M., & Igarashi, T. (2015). Post-traumatic stress disorder in children following natural disasters: A systematic review of the long-term follow-up studies. International Journal of Child, Youth and Family Studies, 6, 111133.CrossRefGoogle Scholar
Thordardottir, E. B., Valdimarsdottir, U. A., Hansdottir, I., Hauksdóttir, A., Dyregrov, A., Shipherd, J. C., … Gudmundsdottir, B. (2016). Sixteen-year follow-up of childhood avalanche survivors. European Journal of Psychotraumatology, 7, 19.CrossRefGoogle ScholarPubMed
Udwin, O., Boyle, S., Yule, W., Bolton, D., & O'Ryan, D. (2000). Risk factors for long-term psychological effects of a disaster experienced in adolescence: Predictors of post-traumatic stress disorder. Journal of Child Psychology and Psychiatry, 41, 969979.CrossRefGoogle ScholarPubMed
Ularntinon, S., Piyasil, V., Ketumarn, P., Sitdhiraksa, N., Pityaratstian, N., Lerthattasilp, T., … Pimratana, W. (2008). Assessment of psychopathological consequences in children at 3 years after tsunami disaster. Journal of Medical Association of Thailand, 91, 6975.Google ScholarPubMed
Wang, C. W., Chan, C. L., & Ho, R. T. (2013). Prevalence and trajectory of psychopathology among child and adolescent survivors of disasters: A systematic review of epidemiological studies across 1987–2011. Social Psychiatry and Psychiatric Epidemiology, 48, 16971720.CrossRefGoogle ScholarPubMed
Yule, W., Bolton, D., Udwin, O., Boyle, S., O'Ryan, D., & Nurrish, J. (2000). Long-term psychological effects of a disaster experienced in adolescence: 1: The incidence and course of PTSD. Journal of Child Psychology and Psychiatry, 41, 503511.CrossRefGoogle Scholar
Figure 0

Table 1. Demographic, earthquake exposure and clinical characteristics of not-treated differentially exposed subjects from Spitak and Gumri at 1½ and 25 years after the 1988 Spitak earthquake

Figure 1

Table 2. Demographic, earthquake exposure, and clinical characteristics of Gumri-treated v. Gumri-not-treated groups at 1½ and 25 years after the 1988 Spitak earthquake

Figure 2

Fig. 1. Mean PTSD-RI scores at 1½ and 25 years and the delta scores for the three groups after the 1988 Spitak earthquake. *p < 0.05; ***p < 0.001. PTSD-RI, Posttraumatic Stress Disorder-Reaction Index; Tx, treatment; EQ, earthquake.A 1½ year comparison between Gumri-treated (a) and Gumri-not-treated (b) groups showed no significant difference. However, at 25 years, Gumri-treated (b) was significantly less than Gumri-not-treated (d) (t = −2.03, df = 73, p < 0.05).A 1½ year comparison between differentially exposed group scores showed Spitak-not-treated (e) was higher than Gumri-not-treated (c) (t = 6.14, df = 107, p < 0.001). At 25 years there was no significant difference between the two groups, even though the mean score for Spitak was higher (f > d) (t = 1.43, df = 107, p = 0.15).Within group by time analysis showed a significant decrease of PTSD-RI scores for the three groups between 1½ and 25 years: Gumri-treated (a > b) (t = 6.0, df = 32, p < 0.001); (b) Gumri-not-treated (c > d) (t = 4.0, df = 41, p < 0.001); (c) Spitak-not-treated (e > f) (t = 7.05, df = 66, p < 0.001).Between group comparisons of the delta in PTSD-RI scores: Gumri-treated (g) greater than Gumri-not-treated (h) (t = 2.23, df = 73, p < 0.03); Spitak-not-treated (i) greater than Gumri-not-treated (h) (t = 2.42, df = 107, p < 0.02).

Figure 3

Table 3. The full model and the final stepwise model for PTSD-RI, PCL, and CES-D scores at 25-year follow-up among adults who were early-adolescents in 1988