Authors:
Yeong Seon Jo Department of Psychology, The Sung-Shin Women's University, Seoul, South Korea
Department of Psychiatry, The Catholic University of Korea Uijeongbu St. Mary's Hospital, Gyeonggi, South Korea

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Soo Young Bhang Department of Child and Adolescent Psychiatry, Eulji University School of Medicine, Seoul, South Korea

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Jung-Seok Choi Department of Psychiatry, SMG-SNU Boramae Medical Center, Seoul, South Korea
Department of Psychiatry and Behavioral Science, Seoul National University College of Medicine, Seoul, South Korea

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Hae Kook Lee Department of Psychiatry, Uijeongbu St. Mary's Hospital, Catholic University College of Medicine, Gyeonggi, South Korea

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Seung Yup Lee Department of Psychiatry, Eunpyeong St. Mary's Hospital, Catholic University College of Medicine, Seoul, South Korea

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Yong-Sil Kweon Department of Psychiatry, Uijeongbu St. Mary's Hospital, Catholic University College of Medicine, Gyeonggi, South Korea

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Abstract

Background and aim

Whereas many studies on Internet gaming disorder (IGD) have used self-report questionnaires, only a few have adopted clinical interviews and samples. The current study aimed at using data from face-to-face diagnostic interviews, based on the criteria for IGD in the DSM-5, to determine the Internet, gaming, and smartphone usage patterns of children and adolescents.

Methods

A latent class analysis was conducted using data collected through diagnostic interviews for Internet, gaming, and smartphone addiction with 190 participants (M = 13.14 years, SD = 2.46; 143 boys, 47 girls) who were part of a multicenter clinical cohort study.

Results

Participants were classified into four groups: pleasure-seeking (Class 1), internal-use (Class 2), problematic-use (Class 3), and pathological-use (Class 4). The pleasure-seeking group (8.11%) showed low tendencies in general and proper control. The internal-use group (17.63%) showed significant increases in “cognitive salience” and “craving,” with strong internal desires. The problematic-use group (37.28%) had no “interference with role performance”; however, they displayed “difficulty regulating use” and “persistent use despite negative consequences,” with a slight functional impairment. The pathological-use group (36.98%) scored the highest on all these items, revealing a severe functional impairment. Compared to the other groups, the pathological-use group had the highest depression and daily stress levels and displayed the lowest levels of happiness.

Conclusions

This study provides basic data to elucidate Internet, gaming, and smartphone overuse patterns among children and adolescents, which could be used to develop differentiated intervention strategies for each group.

Abstract

Background and aim

Whereas many studies on Internet gaming disorder (IGD) have used self-report questionnaires, only a few have adopted clinical interviews and samples. The current study aimed at using data from face-to-face diagnostic interviews, based on the criteria for IGD in the DSM-5, to determine the Internet, gaming, and smartphone usage patterns of children and adolescents.

Methods

A latent class analysis was conducted using data collected through diagnostic interviews for Internet, gaming, and smartphone addiction with 190 participants (M = 13.14 years, SD = 2.46; 143 boys, 47 girls) who were part of a multicenter clinical cohort study.

Results

Participants were classified into four groups: pleasure-seeking (Class 1), internal-use (Class 2), problematic-use (Class 3), and pathological-use (Class 4). The pleasure-seeking group (8.11%) showed low tendencies in general and proper control. The internal-use group (17.63%) showed significant increases in “cognitive salience” and “craving,” with strong internal desires. The problematic-use group (37.28%) had no “interference with role performance”; however, they displayed “difficulty regulating use” and “persistent use despite negative consequences,” with a slight functional impairment. The pathological-use group (36.98%) scored the highest on all these items, revealing a severe functional impairment. Compared to the other groups, the pathological-use group had the highest depression and daily stress levels and displayed the lowest levels of happiness.

Conclusions

This study provides basic data to elucidate Internet, gaming, and smartphone overuse patterns among children and adolescents, which could be used to develop differentiated intervention strategies for each group.

Introduction

Gaming addiction was first identified as Internet gaming disorder (IGD) in the Diagnostic and Statistical Manual of Mental Disorders, 5th Edition (DSM-5; American Psychiatric Association [APA], 2013). Given the lack of empirical research, it was classified as a condition for further study and included as part of DSM-5 Section III, Emerging Measures and Models, rather than being considered a formal diagnosis (APA, 2013). Since 2014, the World Health Organization (WHO) has indicated gaming addiction as an important public health issue (World Health Organization [WHO], 2014). In 2015, gaming addiction was named “gaming disorder” (GD), and its listing in the International Classification of Diseases (ICD) was promoted (WHO, 2016). In 2019, GD was passed as an official disease included in the ICD-11 (WHO, 2019). Preliminary data showed that addiction to the Internet, games, and smartphones is a serious social phenomenon, which requires clinical attention; however, the introduction of GD as an official disease remains debated (Aarseth et al., 2017; Kuss, Griffiths, & Pontes, 2017a, 2017b; Rumpf et al., 2018; VandenBrink, 2017). Thus, diagnostic evidence is needed regarding the clinical characteristics of GD. In addition to the existing games and Internet addiction, the high accessibility and mobility of smartphones has determined the inclusion of a smartphone addiction too (Yu & Sussman, 2020). Although the addictive behaviors, concepts, usage devices, and usage contents are not clear yet, theories about the psychological and biological foundations of the problematic use have been proposed. Further multidisciplinary research is needed to define the problematic overuse of Internet, games, and smartphones, users' characteristics, and social consensus regarding treatment techniques.

Internet, gaming, and smartphone addiction are not affected by a single factor only; thus, various aspects should be considered in the biopsychosocial framework, such as personal characteristics, parent-related variables, peer-related variables, and school-related variables. Depression contributes to functional problems, such as restricting outdoor activities because of excessive use of the Internet, gaming, and smartphones, as well as over-involvement with virtual interpersonal relationships (Jo et al., 2019; Lee et al., 2018; Liu et al., 2018; Wang, Cho, & Kim, 2018). Gaming addiction is associated with low self-esteem, high impulsiveness, and high aggressiveness (Park, Kim, & Kang, 2013; Ryu et al., 2019; Wang et al., 2018). Children and adolescents with high aggression and high harm-avoidance tend to have an increased likelihood of gaming problems as they obtain increased positive psychological rewards through gaming (Park et al., 2013). High-risk groups for Internet addiction include those with high stress and low happiness levels (Kim & Yu, 2017; Lee et al., 2018; Park & Jo, 2018 ; Ryu et al., 2019). Moreover, happiness has a mitigating influence on both smartphone (Park & Jo, 2018) and Internet addiction (Muusses, Finkenauer, Kerkhof, & Billedo, 2014).

Most research has used a variable-centered approach, exploring a single factor affecting Internet, gaming, and smartphone addiction and its relationship with other variables (Jo et al., 2019; Kim & Yu, 2017; Lee et al., 2018; Liu et al., 2018; Muusses et al., 2014; Park et al., 2013; Park & Jo, 2018; Ryu et al., 2019). This approach assumes that participants in the sample are taken from a single population and sums multiple items into one addiction level. Therefore, interpreting the heterogeneous individual differences within addiction groups or the content of various items is challenging (Meyer & Morin, 2016).

Conversely, a person-centric approach assumes that the relationships among variables differ between individuals (Meyer & Morin, 2016) and estimates the attributes shared by members in the same group by the levels of variables (Magnusson, 2003). Therefore, a person-centric approach would be beneficial to clarify the addictive usage patterns in children and adolescents and determine their personal characteristics through a latent class analysis (LCA) (Vermunt & Magidson, 2002).

The latent classes of Internet addiction and use have previously been examined (Deleuze et al., 2015; Kwon & Kwon, 2017; Park & Lee, 2018; Vermunt & Magidson, 2002; Wang et al., 2018); however, most analyses were based on aggregated sub-factor scores from the addiction scale or by the type and level of addictive behavior, rather than each item (Deleuze et al., 2015; Kwon & Kwon, 2017; Lee et al., 2018; Park & Lee, 2018; Pickard, 2016). Previous research relied on self-report questionnaires; thus, the addiction level might be measured inaccurately because of the denial defense mechanism, a characteristic of addiction (Pickard, 2016).

This study included an LCA of data collected through face-to-face interviews conducted by clinical psychologists and psychiatrists. The diagnostic criteria for IGD in the DSM-5 were used to determine Internet, gaming, and smartphone usage patterns in a multicenter clinical cohort of children and adolescents. Additionally, we identified the usage patterns to determine distinct groups of individuals and examined the differences in users' psychosocial characteristics to provide a comprehensive understanding of children and adolescents' Internet, gaming, and smartphone use. We asked, first, what are the latent subgroups of Internet, gaming, and smartphone usage patterns in children and adolescents? Second, what are the differences in psychosocial variables in the identified latent subgroups?

Materials and methods

Participants and procedure

The c-CURE study is a prospective cohort study designed to track the natural history of Internet, gaming, and smartphone addiction in children and adolescents, and identify risks and protective factors. It was conducted from August 2015 to August 2019 in Seoul and Gyeonggi-do, Korea and included 194 participants (Jo et al., 2019). Children, adolescents, and their primary caregivers who wished to participate completed a screening questionnaire on Internet and smartphone addiction. Participants with scores crossing the screening threshold were eligible to participate. In this study, data from 190 of the 194 participants were analyzed (four people with incomplete diagnostic interviews for addiction [DIA] were excluded).

Participants' mean age was 13.14 (SD = 2.46), and included 51 children and 139 adolescents (143 boys; 47 girls). Clinical psychologists and psychiatrists conducted face-to-face, semi-structured interviews with the participants and their primary caregivers. Participants and caregivers also completed self-report questionnaires (Fig. 1). Follow-up interviews with participants and caregivers were conducted after three and six months. Finally, we standardized the protocols, including training, to ensure the reliability and validity of the diagnostic evaluation.

Fig. 1.
Fig. 1.

Study flow chart and sociodemographic characteristics. The cutoff values for each screening scale are presented. K-scale: Korean Scale for Internet Addiction for adolescents; SAS-SV: Smartphone Addiction Scale-short form version; S-scale: Korean smartphone addiction scale; O_C: Internet Addiction Proneness Scale for Child, checked by caregivers; O_A: Internet Addiction Proneness Scale for Adolescents, checked by caregivers; DIA: Diagnostic interview for Internet, game, SNS, etc. addiction

Citation: Journal of Behavioral Addictions 9, 2; 10.1556/2006.2020.00022

Diagnostic interview for Internet, gaming, and smartphone addiction

The DIA is a semi-structured interview diagnostic tool developed by adding “craving” to the nine diagnostic items for IGD in the DSM-5 (Jo et al., 2019; Ryu et al., 2019). Clinical psychologists and psychiatrists asked questions related to Internet's contents and devices. The DIA interviews with each participant and primary caregiver lasted approximately 15–20 min. Participants' responses were combined with clinicians' impressions and determined whether participants were addicted to the Internet, gaming, and/or smartphones. Items were rated on a four-point scale, ranging from 0 to 3 (0: no information, 1: no symptoms, 2: below threshold, and 3: above threshold), and the number of DIA items were used to assess addiction (range = 0–10; 0–2 = mild-risk, 3–4 = moderate-risk, 5–10 = addicted). The scale's internal consistency for this study was α = 0.768 at baseline and α = 0.813 at the six-month follow-up.

Internet and smartphone addiction scales

Internet addiction symptoms were measured using the Korean Scale for Internet Addiction (K-scale), Young's Internet Addiction Test (YIAT) for children and adolescents, the Internet Addiction Proneness Scale for Child (O_C), and the Internet Addiction Proneness Scale for Adolescents (O_A). Both contained observer's scales completed by the primary caregivers. Smartphone addiction symptoms were measured using the Smartphone Addiction Scale-short form version (SAS-SV) and the Smartphone Addiction Scale (S-scale). Higher scores indicated higher levels of Internet and smartphone addiction.

The K-scale is a 40-item questionnaire developed by the National Information Society Agency. It is measured on a 4-point Likert scale (Korean National Information Society Agency, 2013), and in this study the Cronbach's alpha was 0.940. The YIAT was developed by Young (Young, 1998), and validated and translated into Korean by Kim et al. (Kim, Lee, & Oh, 2003). It consists of 20 questions rated on a 5-point Likert scale with an internal consistency in this study of 0.928. Primary caregivers completed the observer's scales comprising 15 items rated on a 4-point Likert scale. The internal consistency in this study was 0.861 for O_C and 0.867 for O_A (Kim et al., 2015; Korean National Information Society Agency, 2011). The 10-item SAS-SV was rated on a 6-point Likert scale with an internal consistency of 0.903 in this study (Kwon, Kim, Cho, & Yang, 2013). Different cutoff values ​​were suggested for each sex group based on the ROC analysis. The SAS-SV has cutoff values of 31 points for boys and 33 points for girls, which indicate problematic use. The 15-item S-scale is measured on a 4-point Likert scale with an internal consistency of 0.898 in this study (Kim, Chung, Lee, Kim, & Jeon, 2016).

Psychosocial variables

Psychosocial variables associated with Internet, gaming, and smartphone addiction, such as depression, impulsivity, aggression, everyday stress, and happiness were measured, with higher scores indicating higher levels of the variables.

The Children Depression Inventory (CDI) and Beck Depression Inventory-II (BDI-II) were used to measure depression in children and adolescents, respectively. The BDI-II includes 21 items on a 4-point scale and was developed by Beck et al. (Beck, Steer, & Brown, 1996) and validated in Korean by Lee et al. (Lee, Lee, Hwang, Hong, & Kim, 2017). The Cronbach's alpha in this study was 0.944. The 27-item CDI was adapted from the BDI for use with school-aged children (Kovacs, 1983), and translated into Korean by Cho and Lee (1999). It is rated on a 3-point scale, and in this study, the Cronbach's alpha was 0.813.

The Barratt Impulsiveness Scale-II (BIS-II), which measures impulsiveness (Barratt & White, 1969), was translated by Lee into Korean (1992). The BIS-II assesses 23 items on a 4-point scale, and the internal consistency in this study was 0.821.

The Aggression Questionnaire (AQ) for measuring aggression levels was developed by Buss and Perry (1992) and translated into Korean by Seo and Kwon (2002); it consists of 27 items measured on a 5-point Likert scale. Its internal consistency in this study was 0.884.

The Daily Hassles Questionnaire (DHQ) developed by Rowlison and Felner (1988) and translated into Korean by Han and Yoo (1995) was used to measure adolescents' daily stress was. It includes 36 questions on a 4-point Likert scale with internal consistency in this study of 0.934.

The Happy Scale was developed to measure the happiness of Korean adolescents (Bang et al., 2007). It consists of four sub-factors: self-concept, family relationships, leisure activities, and friendship. This 30-item scale is measured on a 4-point Likert scale, with an internal consistency in this study of 0.922.

Statistical analyses

Data analyses comprised two stages. Latent class modeling based on the 10 DIA items was performed with Mplus 8.0, and maximum likelihood estimation was used. Differences in psychosocial variables among latent groups were analyzed with SPSS 23.0 (SPSS, Inc., Chicago, IL, USA). First, LCA was used to classify the latent classes of Internet, gaming, and smartphone usage patterns among participants based on the 10 DIA items. To perform the LCA, the number of clusters was determined. Given the lack of a widely accepted statistical indicator, several statistical information indices were used in combination (Nylund-Gibson, Asparouhov, & Muthén, 2007). Specifically, the number of latent classes was determined using Akaike's information criterion (AIC; Akaike, 1987), Bayesian information criterion (BIC; Schwarz, 1978), and sample-size-adjusted BIC (SABIC; Sclove, 1987). For these indices, lower values indicated better agreement with the model (Muthén, 2004). A class was added when the proportion of participants belonging to the latent class was at least 5% (Jung & Wickrama, 2008). If the Lo-Mendell-Rubin adjusted likelihood ratio test (LMR LRT; Lo, Mendenll, & Rubin, 2001) and bootstrap likelihood ratio test (BLRT; McLachlan & Peel, 2000), which statistically analyzed the research hypothesis assuming the number of latent classes as k and the null hypothesis assuming the number of latent classes as k-1, have a significant probability of less than 0.05, the null hypothesis is rejected and the research hypothesis is adopted. Entropy, which assesses the quality of latent class classification, increases as the probability of belonging to one latent class is close to 1 while the probability of belonging to another latent class is close to 0 (Ramaswamy, DeSarbo, Reibstein, & Robinson, 1993). Therefore, the range of entropy is between 0 and 1. If it is about 0.6, 80% or more, it is considered properly classified, and if it is 0.8 or more, 90% or more is considered properly classified (Muthén, 2004). In fact, entropy can be used to determine if too many latent classes are extracted and determine the usefulness of LCA to see whether the set of indicators are actually suitable for grouping in the samples. Separately, in accordance with the recommendations of Muthén and Muthén (2000), the interpretability of each latent class and ratio of latent class to samples were considered. The final number of latent classes was determined combining the values of each information criteria index, and the ratio and interpretability of each latent class. To clarify Internet, gaming, and smartphone usage patterns per latent class, the collective characteristics of the latent class were interpreted.

Second, after the latent classes were divided, chi-square tests, analyses of variance (ANOVAs), and paired-sample t-tests were conducted to verify the differences in psychosocial variables between the latent classes. The differences between the groups that showed significant differences in the ANOVA were examined in more detail through Duncan's post-hoc test. In addition, paired t-tests were conducted to identify the changes in Internet, gaming, and smartphone addiction symptoms and average Internet use on weekdays and weekends after six months.

Ethics

This study was approved by the Institutional Review Boards for human participants of Uijeonbu St. Mary's Hospital (no. UC150NMI0072), Eulji University Eulji Hospital (no., EMCS2015-05-020-001), and SMG-SNU Boramae Medical Center (no. 16-2016-4). Written consent was obtained from all participants and their primary caregivers after the researchers explained the study and discussed confidentiality and voluntary participation. This study was conducted in accordance with the Declaration of Helsinki.

Results

Latent classes of Internet, gaming, and smartphone use

Determining the number of latent classes

The models assuming two, three, four, five, six, and seven latent classes were estimated to determine the number of latent classes by Internet, gaming, and smartphone usage patterns. Table 1 shows the concordance indices of the latent class models with different numbers of latent classes. Consequently, the AIC and SABIC values were lowest when the number of latent classes was four (Muthén, 2004). The value of BIC increased as the number of latent classes increased; however, the rate of change decreased after four latent classes. Further, the quality of classification was over 90% because entropy was 0.836 (i.e., >0.8; Muthén, 2004). Although the probabilities of LMR LRT and BLRT were not significant (p > 0.05), the relatively small number of cases (N = 190) may have influenced these results (Rost, 2006). When the number of latent classes was four, the proportion of latent classes was evenly distributed and a clinical interpretation was possible. Thus, the final number of latent classes was four.

Table 1.

Fit measures of latent classes models

Classification criteriaNumber of latent class
234567
Information criteriaAIC3,140.5773,121.7063,117.8703,120.8463,125.8813,135.313
BIC3,273.7053,323.0223,387.3733,458.5373,531.7593,609.378
SABIC3,143.8343,126.6323,124.4643,129.1083,135.8113,146.911
Classification qualityENTROPY0.8350.7630.8360.8260.8580.885
LMR LRT<0.0010.2090.4130.8210.8350.763
BLRT<0.001<0.0010.0700.1760.2780.370
Final class proportion (%)Class 163.0634.958.1120.6712.053.69
Class 236.9427.6317.6320.496.2819.56
Class 337.4237.287.9930.1935.38
Class 436.9819.838.154.62
Class 531.0222.9417.33
Class 620.3911.63
Class 77.79

Notes: AIC: Akaike's information criterion, BIC: Bayesian information criterion, SABIC: sample size-adjusted Bayesian information criterion, LMR LRT: Lo-Mendell-Rubin adjusted likelihood ratio test, BLRT: bootstrap likelihood ratio test. All values of LMR LRT and BLRT indicate the P-value.

Forms of latent classes

Table 2 and Fig. 2 show the mean, standard error, and stress levels of the DIA items for the four latent classes, which were named using each latent class's characteristics with the following related variables. For Class 1, the levels of DIA 4 (difficulty regulating use) and DIA 6 (persistent use despite negative consequences) increased negligibly; however, the remaining items showed a low level of about 0.200 or lower overall; thus, the class was named the “pleasure-seeking” group. For Class 2, DIA 1 (cognitive salience) and DIA 10 (craving) levels increased significantly, DIA 7 (deceiving) increased negligibly, and the levels of all other items were noticeably lower than 0.100. Given that the problematic behavioral characteristics of Internet, gaming, and smartphone use were appearing inherently, Class 2 was called the “internal-use” group. For Class 3, DIA 9 (interference with role performance) was 0; however, DIA 4 (difficulty regulating use) and DIA 6 (persistent use despite negative consequences) increased considerably, with a slight functional impairment. Class 4, on the other hand, showed the highest levels on all DIA items compared to the other latent classes. In particular, the levels of DIA 4 (difficulty regulating use), DIA 6 (persistent use despite negative consequences), and DIA 9 (interference with role performance) were significantly higher than those of other potential groups, indicating severe functional impairment. Consequently, Class 3 was named the “problematic-use” group, and Class 4 was named the “pathological-use” group.

Table 2.

Means and standard errors of DIA items for the four latent groups

Class 1Class 2Class 3Class 4
MSEMSEMSEMSE
DIA 1 (cognitive salience)0.1930.1110.5900.1150.7890.0920.9160.038
DIA 2 (withdrawal)0.0660.0660.0000.0000.4980.1280.7930.072
DIA 3 (tolerance)0.1530.1140.0680.0510.3260.1440.8870.068
DIA 4 (difficulty regulating use)0.2810.1500.0130.1720.7670.0700.9380.066
DIA 5 (decrease in other activities)0.0000.0000.0690.0490.1450.0830.6040.091
DIA 6 (Persistent use despite negative consequences)0.3550.1420.0000.0000.5850.1040.7700.071
DIA 7 (deceiving)0.1840.1100.0370.0400.1040.0570.4770.089
DIA 8 (escape of negative feelings)0.2060.1050.2300.0810.1930.0570.3480.077
DIA 9 (interference with role performance)0.1950.1040.0300.0310.0000.0000.2560.085
DIA 10 (craving)0.2260.1180.6040.1000.9470.0370.9850.016
Final class proportion (%)8.1117.6337.2836.98

Notes: DIA: Diagnostic interview for Internet, game, SNS, etc. addiction; M: mean; SD: standard deviation.

Fig. 2.
Fig. 2.

Form of four latent classes by DIA item

Citation: Journal of Behavioral Addictions 9, 2; 10.1556/2006.2020.00022

Fifteen people (8.11%) were in the pleasure-seeking group (Class 1), 34 (17.63%) in the internal-use group (Class 2), 71 (37.28%) in the problematic-use group (Class 3), and 70 (36.98%) in the pathological-use group (Class 4). Each group included significantly more boys than girls; however, the gender differences between groups were statistically non-significant (Table 3). The mean ages were 12.00 (SD = 3.44) in the pleasure-seeking group, 12.59 (SD = 2.82) in the internal-use group, 13.18 (SD = 2.65) in the problematic-use group, and 13.60 (SD = 1.63) in the pathological-use group. Thus, age and IGD symptoms were associated. The number of adolescents was significantly higher than that of children in all groups, and the difference in age group by latent class was also significant (χ2 = 12.244, p < 0.01).

Table 3.

Number of cases for the four latent groups based on DIA items

Class 1Class 2Class 3Class 4Allχ2
Pleasure-seeking

n (%)
Internal-use

n (%)
Problematic-use

n (%)
Pathological-use

n (%)
SexMale10 (66.7)25 (73.5)52 (73.2)56 (80.0)143 (75.3)1.650
Female5 (33.3)9 (26.5)19 (26.8)14 (20.0)47 (24.7)
Age groupChildren7 (46.7)14 (41.2)20 (28.2)10 (14.3)51 (26.8)12.244**
Adolescents8 (53.3)20 (58.8)51 (71.8)60 (85.7)139 (73.2)
All15 (100)34 (100)71 (100)70 (100)190 (100)

* p < 0.05, ** p < 0.01, *** p < 0.001.

DIA: Diagnostic interview for Internet, game, SNS, etc. addiction. Age is ordinary age (Korean age).

Clinical characteristics of Internet gaming disorder (IGD) diagnosis groups

Differences in Internet-usage characteristics and addiction-related variables

Tables 4, 5, and 6 show the differences in the Internet-usage characteristics and addiction-related variables across the latent classes. The differences in the Internet-usage patterns and Internet-enabled devices were not significant. Specifically, most latent classes used the Internet for games and videos (Table 4). While the pleasure-seeking (Class 1) and the internal-use groups (Class 2) tended to use a single smartphone device, the problematic-use (Class 3) and the pathological-use (Class 4) groups tended to use two or more devices.

Table 4.

Internet-usage characteristics of the four latent groups based on DIA items

Class 1

(n = 15)

n (%)
Class 2

(n = 34)

n (%)
Class 3

(n = 71)

n (%)
Class 4

(n = 70)

n (%)
χ2
Internet content (percentage in all groups)9.005
1. Games5 (2.6)4 (2.1)18 (9.5)16 (8.4)
2. Social networking services1 (0.5)3 (1.6)6 (3.2)1 (0.5)
3. Other (e.g., YouTube, AfricaTV)2 (1.1)2 (1.1)5 (2.6)5 (2.6)
4. Combination1.7 (3.7)6/125 (13.2)17/642 (22.1)27/648 (25.3)32/8
2.1/02/66/87/3
3.0/66/139/289/37
Internet device (percentage in all group)14.588
Personal computer3 (1.6)1 (0.5)7 (3.7)12 (6.3)
Smart phone8 (4.2)20 (10.5)26 (13.7)23 (12.1)
Other (e.g., tablet)01 (0.5)1 (0.5)0
Combination4 (2.1)12 (6.3)37 (19.5)35 (18.4)

DIA: Diagnostic interview for Internet, game, SNS, etc. addiction.

4. Combination: This means that content 1–3 is used as two duals. The left side of / is the primary Internet content and the right side of / is the secondary Internet content in the Internet content-combination.

Table 5.

Internet-using behaviors of the four latent groups based on DIA items (N = 190)

Class 1

(n = 15)
Class 2

(n = 34)
Class 3

(n = 71)
Class 4

(n = 70)
FDuncan
M (SD) [95% CI]
Age when first began using: Internet6.53 (2.326)

[5.25–7.82]
7.65 (1.704)

[7.05–8.24]
7.41 (1.952)

[6.95–7.88]
7.63 (2.342)

[7.07–8.19]
1.229
Age when first began using: Internet gaming7.00 (2.360)

[5.69–8.31]
8.03 (2.263)

[7.24–8.82]
8.20 (2.500)

[7.60–8.80]
8.30 (2.176)

[7.78–8.82]
1.338
Age when first began using: smartphone8.40 (2.558)

[6.98–9.82]
8.53 (2.377)

[7.70–9.36]
8.73 (1.841)

[8.29–9.17]
8.64 (2.000)

[8.17–9.12]
0.143
Usage time: weekdays (min/day)198.00 (157.444)

[110.81–285.19]
237.94 (164.865)

[180.42–295.47]
260.70 (115.367)

[233.40–288.01]
256.17 (145.644)

[221.44–290.90])
0.959
Usage time: weekends (min/day)264.00 (156.379)

[177.40–350.60]
348.53 (165.971)

[290.62–406.44]
402.68 (171.414)

[362.10–443.25]
392.31 (197.311)

[345.27–439.36]
2.917*1 < 3 = 4

* p < 0.05, ** p < 0.01, *** p < 0.001.

DIA: Diagnostic interview for Internet, game, SNS, etc. addiction. Age is ordinary age (Korean age).

Table 6.

Internet and smartphone addiction scale of the four groups based on DIA items (N = 190)

Class 1

(n = 15)
Class 2

(n = 34)
Class 3

(n = 71)
Class 4

(n = 70)
FDuncan
M (SD) [95% CI]
DIA

3-point score
2.00 (1.927)

[0.93–3.07]
1.62 (0.985)

[1.27–1.96]
4.30 (1.061)

[4.04–4.55]
6.91 (1.349)

[6.59–7.24]
168.879***2 = 1 < 3 < 4
K-scale64.13 (12.182)

[57.39–70.88]
67.21 (17.367)

[61.15–73.27]
75.72 (17.496)

[71.58–79.86]
79.91 (20.801)

[74.92–79.86]
5.424**1 < 4
SAS-SV23.07 (7.741)

[18.78–27.35]
27.71 (12.112)

[23.48–31.93]
30.01 (11.262)

[27.35–32.68]
29.22 (13.250)

[26.03–32.40]
1.513
S-scale29.13 (7.130)

[25.18–33.08]
31.65 (8.301)

[28.75–34.54]
34.75 (7.942)

[32.87–36.63]
33.54 (10.043)

[31.12–35.95]
2.187
Y-IAT-K38.23 (10.772)

[31.72–44.74]
41.44 (15.613)

[35.99–46.89]
49.34 (16.344)

[45.26–53.43]
50.59 (16.603)

[46.41–54.77]
4.159**1 < 4
O_C (n = 51)44.29 (3.773)

[40.80–47.78]
41.00 (3.721)

[38.85–43.15]
47.20 (5.961)

[44.41–49.99]
49.90 (4.866)

[46.40–53.40]
7.381***2 < 4
O_A (n = 139)39.75 (6.902)

[33.98–45.52]
36.70 (1.738)

[33.06–40.34]
41.60 (7.031)

[39.60–43.60]
43.95 (6.390)

[42.30–45.60]
5.895**2 < 3 = 4

* p < 0.05, ** p < 0.01, *** p < 0.001.

DIA: Diagnostic interview for Internet, game, SNS, etc. addiction; K-scale: Korean Scale for Internet Addiction for adolescents; SAS-SV: Smartphone Addiction Scale-short form version; S-scale: Korean Smartphone Addiction scale; O_C: Internet Addiction Proneness Scale for Child, checked by caregivers; O_A: Internet Addiction Proneness Scale for Adolescents, checked by caregivers.

The age when the participants first started using the Internet, online games, and smartphones was not statistically different per latent class (Table 5). Further, the average weekday use time was not significantly different between groups (F (3,186) = 0.959, p = 0.413); however, the average weekend use time was significantly different (F (3,186) = 2.917, p < 0.05). On weekdays and weekends, the average Internet use time was the highest for the problematic-use group, followed by the pathological-use, internal-use, and pleasure-seeking groups. Duncan's post-hoc analyses showed that the average Internet use time for the pleasure-seeking group was 260.44 min, which was lower than the 402.68 min of the problem-use and the 392.31 min of the pathological-use groups.

Concerning addiction levels among the four latent classes, significant differences were found for all scales except for the SAS-SV, S-scale (Table 6). Post-hoc analyses revealed that the number of 3-point DIA threshold scores was highest in the problematic-use group (M = 4.30, SD = 1.061), followed by the pathological-use group (M = 6.91, SD = 1.349). Scores were lower for the internal-use and pleasure-seeking groups than for the problematic-use group; however, the differences between the two groups were non-significant. The K-scale and the Y-IAT-K scale, which were used to examine participants' Internet addiction levels, were the highest for the pathological-use group and lowest for the pleasure-seeking group. Parental observers' scales for children's and adolescents' Internet and smartphone addiction were the lowest in the internal-use group and highest in the pathological-use group.

Differences in psychosocial variables

As shown in Table 7, there were significant differences in adolescents' daily stress (F (3,181) = 3.397, p < 0.05) and total happiness scores (F (3,180) = 5.751, p < 0.01), self-concept (F (3,180) = 5.769, p < 0.01), family relationships (F (3,180) = 3.991, p < 0.01), leisure activities (F (3,180) = 4.027, p < 0.01), and depression in adolescents (F (3,132) = 3.951, p < 0.05), being comparatively higher in the problematic-use and pathological-use groups than in the pleasure-seeking group. Adolescents' daily stress levels (DHQ) were significantly higher and happiness levels (Happy) were significantly lower in the pathological-use group than in the pleasure-seeking group. Self-concept was higher in the pleasure-seeking and internal-use groups than in the pathological-use group; however, the two groups were not statistically different. Family relationships were lower in the pathological-use and problematic-use groups than in the pleasure-seeking group; however, the difference between the pathological-use and problematic-use groups was non-significant. Leisure activity scores were the highest in the pleasure-seeking group; however, the differences among the three other groups were non-significant.

Table 7.

Psychosocial variable of the four groups based on DIA items (N = 190)

Class 1

(n = 15)
Class 2

(n = 34)
Class 3

(n = 71)
Class 4

(n = 70)
FDuncan
M (SD) [95% CI]
CDI

(n = 51)
13.00 (4.726)

[8.63–17.37]
12.50 (7.346)

[8.26–16.74]
10.68 (5.067)

[8.24–13.13]
14.70 (8.667)

[8.50–20.90]
0.864
BDI-Ⅱ

(n = 139)
4.25 (4.166)

[0.77–7.73]
9.15 (9.675)

[4.62–13.68]
16.10 (12.701)

[12.49–19.71]
15.83 (12.148)

[12.63–19.02]
3.951*1 < 3, 4
BIS-Ⅱ53.57 (11.359)

[47.01–60.13]
52.44 (7.110)

[49.96–54.92]
56.38 (11.140)

[53.70–59.05]
56.53 (9.764)

[54.17–58.89]
1.645
AQ58.57 (17.531)

[48.45–68.69]
56.76 (10.462)

[53.11–60.42]
60.39 (15.267)

[56.66–64.11]
62.38 (18.300)

[57.95–66.81]
1.001
DHQ58.36 (14.913)

[49.75–66.97]
60.24 (16.644)

[54.43–66.04]
68.41 (17.402)

[64.23–72.59]
69.95 (18.903)

[65.07–74.22]
3.397*1 < 4
Happiness: total66.14 (13.444)

[58.38–73.91]
60.44 (14.262)

[55.46–65.42]
54.84 (14.601)

[51.33–58.35]
50.79 (16.214)

[46.84–54.75]
5.751**4 < 1
Happiess: self-concept24.21 (6.693)

[20.35–28.08]
23.79 (5.897)

[21.74–25.85]
20.70 (6.680)

[19.09–22.30]
18.58 (7.320)

[16.80–20.37]
5.769**4 < 2, 1
Happiness: family relationships24.14 (5.503)

[20.97–27.32]
21.26 (7.296)

[18.72–23.81]
18.87 (6.526)

[17.30–20.44]
18.15 (7.099)

[16.42–19.88]
3.991*4, 3 < 1
Happiness: leisure activities9.50 (2.029)

[8.33–10.67]
7.88 (2.240)

[7.10–8.66]
7.72 (2.733)

[7.07–8.38]
7.09 (2.248)

[6.54–7.64]
4.027*4, 3, 2 < 1
Happiness: friendship8.29 (1.858)

[7.21–9.36]
7.50 (2.585)

[6.60–8.40]
7.55 (2.862)

[6.86–8.24]
6.97 (2.674)

[6.32–7.62]
1.170

* p < 0.05, ** p < 0.01, *** p < 0.001.

DIA: Diagnostic interview for Internet, game, SNS, etc. addiction; CDI: Children Depression Inventory; BDI-II: Beck Depression Inventory-II; BIS-II: Barratt Impulsiveness Scale-II; AQ: Aggression Questionnaire; DHQ: Daily Hassles Questionnaire; Happy: Happiness index of Korean adolescents. M: mean, SD: standard deviation.

Changes at the six-month follow-up

Table 8 shows the results of the correspondence sample t-test regarding the changes in Internet, game, and smartphone addiction symptoms and Internet use after six months. In the pleasure-seeking group, 10 out of 15 people completed six-month follow-up evaluations, and the 3-point DIA threshold scores and use times were statistically the same over time.

Table 8.

Comparison of DIA threshold scores and use time of the four latent groups over time

VariableMSDTdf
Pleasure-seeking (Class 1)

n = 10
DIA 3-point scoreBaseline1.401.7760.8859
6 mo. FU1.001.563
Usage time: weekdays (min/day)Baseline195.00177.904−0.546
6 mo. FU208.50215.691
Usage time; weekend (min/day)Baseline258.00171.5810.499
6 mo. FU243.00202.707
Internal-use (Class 2)

n = 28
DIA 3-point scoreBaseline1.641.026−0.11227
6 mo. FU1.681.588
Usage time: weekdays (min/day)Baseline222.50163.0181.501
6 mo. FU181.43121.067
Usage time: weekend (min/day)Baseline326.79165.5981.907
6 mo. FU258.21154.777
Problematic-use (Class 3) n = 43DIA 3-point scoreBaseline4.371.1134.896***42
6 mo. FU2.931.82
Usage time: weekdays (min/day)Baseline246.43113.3271.836
6 mo. FU206.90140.634
Using time: weekend (min/day)Baseline396.43151.6062.464*
6 mo. FU324.05182.370
Pathological-use (Class 4) n = 48DIA 3-point scoreBaseline6.900.9947.292***47
6 mo. FU4.252.410
Usage time: weekdays (min/day)Baseline249.39156.1040.195
6 mo. FU245.61137.271
Using time: weekend (min/day)Baseline381.43198.1480.114
6 mo. FU377.76217.471

* p < 0.05, ** p < 0.01, *** p < 0.001.

DIA: Diagnostic interview for Internet, game, SNS, etc. addiction, M: mean, SD: standard deviation, FU: follow-up.

In the internal-use group, 28 out of 34 people completed six-month follow-up evaluations, the 3-point DIA threshold scores and use times remained statistically unchanged.

On the other hand, the problematic-use group showed a significant change in the 3-point DIA threshold scores and average weekend Internet use time. Specifically, when compared to the 3-point DIA threshold scores and average weekend Internet use at the six-month follow-up, the 3-point DIA threshold scores and average weekend Internet use were significantly higher at baseline (Table 8).

The pathological-use group showed a significant change in the 3-point DIA threshold scores. Specifically, when compared to the 3-point DIA threshold scores at the six-month follow-up, the 3-point DIA threshold scores were significantly higher at baseline. The average weekly and weekend Internet use times of the pathological-use group did not change significantly.

Discussion

This study identified four latent classes of children and adolescents who were Internet, gaming, and smartphone users through a semi-structured assessment using the DIA developed by the c-CURE research team. Further, this study examined differences across the latent classes for variables related to Internet, gaming, and smartphone addiction.

We found that the Internet, gaming, and smartphone usage patterns of children and adolescents could be classified into four latent classes: pleasure-seeking group (Class 1: 8.11%), internal-use group (Class 2: 17.63%), problematic-use group (Class 3: 37.28%), and pathological-use group (Class 4: 36.98%). Using the 3-point DIA threshold scores, the pleasure-seeking (Class 1) and internal-use group (Class 2) were mild-risk groups, the problematic-use group was a moderate-risk group, and the pathological-use group was an addicted group. The moderate-risk and addicted group together accounted for 74.26%— significantly higher than the mild-risk group—which is in contrast with previous studies reporting only 20–30% of the participants to be problematic users (Kwon & Kwon, 2017; Wang et al., 2018). However, this study's data were collected through a clinical cohort study, where only participants who exceeded the cutoff criteria for self-reported addiction were included. Using the DSM-5 diagnostic criteria for IGD and ICD-11 diagnostic criteria for GD, we found that the IGD group accounted for 32.4%, and the GD group accounted for 6.4% (Jo et al., 2019), suggesting that the pathological-use group (Class 4) is a high-risk group for Internet, gaming, and smartphone addiction. The IGD of DSM-5 and GD of ICD-11 were proposed for the diagnostic criteria, but did not include the severity criteria (APA, 2013; WHO, 2019). The four latent classes can be interpreted as the severity of symptoms caused by the use of the Internet, games, and smartphones, providing clinical implications.

When examining each latent class and the characteristics of addiction-related variables, the pleasure-seeking group (Class 1) showed slightly higher levels of “difficulty regulating use” and “persistent use despite negative consequences.” Consistent with this, the average Internet, gaming, and smartphone use time was the lowest in this group, and the 3-point DIA threshold score was relatively lower compared to the other groups. This group was experiencing the joy of use. The internal-use group (Class 2) showed significantly higher levels of “cognitive salience,” “craving,” and a slight increase in “deceiving.” This group had internal desires rather than displaying outward behaviors. Their average weekday/weekend Internet use was the second lowest, next to that of the pleasure-seeking group (Class 1).

The addiction-related scales, self-reported by children and adolescents, were the lowest among the pleasure-seeking group, whereas the observer's scale of addiction was higher than that of the internal-use group (Class 2). It was the opposite for the internal-use group (Class 2). The DIA point threshold level also showed less variation and a lower level than the pleasure-seeking group (Class 1), suggesting that the caregivers may have strict standards, such as supervising Internet, games, and smartphones use (Park & Noh, 2019), even though the pleasure-seeking group's (Class 1) use was comparable to their peers. As the internal-use group (Class 2) primarily had internal desires, their responses to items about behavioral aspects were lower than the pleasure-seeking group (Class 1), indicating that internal desires may not lead to actual behaviors. In other words, the “denial” defense mechanism, a characteristic of addiction, may have been involved (Pickard, 2016). In addition, caregivers may not have noticed usage problems as their children's/adolescents' internal desires were not visible.

The problematic-use group (Class 3) scored 0 on the item “inference with role performance”; however, they showed significantly higher levels of “difficulty regulating use” and “persistent use despite negative consequences.” The pathological-use group (Class 4) showed the most increase across all three items and scored the highest among the groups on other items. The 3-point DIA threshold scores for these groups were high with mean weekend use being significantly higher than in the pleasure-seeking group (Class 1). In other words, because of excessive use, the problematic-use group (Class 3) showed some functional impairment, and the problematic behaviors were manifesting externally. The pathological-use group (Class 4) showed severe functional impairment displaying external problematic behaviors as well as internal desires. The problematic-use group (Class 3) showed a higher ratio of using a single smartphone device or using two devices by pairing a smartphone with a personal computer or tablet. In addition, their average weekday/weekend Internet use was higher than the pathological-use group (Class 4) and the highest of all four groups. Further, the problematic-use group (Class 3) had the highest scores on the smartphone addiction-related scales. We posit that the problematic-use group (Class 3) began to show problematic behaviors owing to ease of access to their smartphones.

As for the gender characteristics, there was no statistically significant difference among classes, but considering the characteristics of the study participants who show more game use problems, there is a higher frequency of boys than girls in the group with high severity (Table 3). Previous studies also show that boys report the game use problem more frequently than girls, whereas girls have more social network service (SNS) use problems (Dufour et al., 2016; Kuss, Griffiths, Karila, & Billieux, 2013; Stavropoulos et al., 2018). When children and adolescents were compared according to age, the frequency of adolescents increased significantly as the severity of use problems increased (Tables 2 and 3). As adolescents tend to pursue their private needs, they appear to be at a relatively high risk of developing Internet addiction (Stavropoulos et al., 2018). In this study, we cannot conclude that the characteristics of the four groups explain the development of the use problem, but we can assume that the severity of Internet, game, and smartphone addiction problems increases with age.

Concerning the differences in psychosocial variables between latent classes, the pleasure-seeking group (Class 1) had the lowest level of depression and daily stress and the highest level of happiness. Self-concept, family relationships, and leisure activities—sub-factors of the adolescent happiness index—were all significantly higher than other groups. On the other hand, the pathological-use group (Class 4) showed the highest levels of depression and daily stress and lowest levels of happiness compared to the pleasure-seeking group (Class 1). This is consistent with previous studies (Jo et al., 2019; Kim & Yu, 2017; Lee et al., 2018b, 2018a; Liu et al., 2018; Muusses et al., 2014; Park & Jo, 2018; Ryu et al., 2019; Wang et al., 2018). Depression and stress were risk factors for problematic use of the Internet, games, and smartphones, whereas happiness (including self-concept), family relationships, and leisure activities were protective factors. The internal-use group (Class 2) had the highest happiness index related to self-concept, similar to the pleasure-seeking group (Class 1). Leisure activities were the lowest; similar to the problematic-use (Class 3) and pathological-use (Class 4) groups. This implies that the internal-use group (Class 2) may only have internal desires for the use of Internet, games, and smartphones, showing no outward functional impairment; however, they may transition to the problematic-use group if the condition persists. Therefore, participants in the internal-use group (Class 2) should not be overlooked.

Depression levels were significant only among adolescents (Class 1<Classes 3 and 4). Adolescents cope with physical, emotional, and behavioral changes, and experience a variety of adaptation challenges (Achenbach & Edelbrock, 1983). Adolescents, rather than children, have severe mood swings and emotional instability, and are subjected to full-scale academic stress because of the environmentally oriented education system and competitive school atmosphere. Consequently, children and adolescents spend their leisure time playing games or watching videos, which can be accessed easily and do not take much time (Kim & Yu, 2017). Therefore, teenagers and children should be encouraged to engage in leisure activities other than the Internet, gaming, and smartphones, for which a supportive environment should be created (Chung, Lee, Lee, & Lee, 2017).

Concerning the six-month follow-up, the overall levels of addiction and use decreased. In this c-CURE study, after the baseline evaluation, the psychiatrists explained the evaluation results and briefly provided face-to-face counseling on parenting and the use of Internet, games, and smartphones. By conducting three- and six-month face-to-face follow-up evaluations, participants could monitor their own Internet, gaming, and smartphone usage patterns and self-manage their behaviors with encouragement and advice from clinical psychologists. This seems to have worked as a short-term education and counseling intervention. Specifically, the 3-point DIA threshold scores showed a significant reduction in the problematic-use (Class 3) and pathological-use (Class 4) groups. The average weekday/weekend Internet use of the problematic-use group (Class 3) significantly decreased, whereas the average Internet use time of the pathological-use group (Class 4) remained statistically the same as baseline. The average weekday/weekend Internet use time of the internal-use group did not decrease significantly. For the problematic-use (Class 3) and internal-use (Class 2) groups, we posit that the problematic tendencies in Internet, gaming, and smartphone usage could be addressed to prevent potential- or high-risk users by proactively identifying future problems and providing short-term psychoeducation (Park, Jon, Hong, Jung, & Hong, 2017; Park, & Noh, 2019; Yang, & Kim, 2018). Guidelines on use of Internet, games, and smartphones are needed to cultivate healthy use habits as a primary prevention and intervention for high-risk groups. Furthermore, a community-based prevention system providing psychological services and education on these matters is needed in the community (Chung et al., 2017).

Although the 3-point DIA threshold scores decreased in the pathological-use group (Class 4), their Internet, gaming, and smartphone use remained constant, suggesting that the symptoms were temporarily alleviated. Addiction symptoms are difficult to treat at once, as they tend to worsen over time, or may relapse after recovery (Marlatt & Gordon, 1980). One study reported that two-thirds of 367 patients with IGD, who had completed a 5-year follow-up, received cognitive behavioral therapy for IGD, and medicated for comorbid conditions for eight weeks, did not fully recover and experienced ongoing difficulties (Han, Yoo, Renshaw, & Petry, 2018). Therefore, the pathological-use group (Class 3), a high-risk group, may require extensive intervention, including basic psychoeducation, cognitive behavioral therapy, coexisting disease treatment, and drug treatment (Kim et al., 2018; Young, 2007). There is also a need for a long-term, therapeutic approach over a sufficient period, rather than a one-time, short-term therapeutic intervention. In other words, it is necessary to apply differentiated intervention methods and establish a dual intervention system depending on the Internet, gaming, and smartphone usage patterns of children and adolescents.

This study included only those who exceeded the screening threshold, and did not include a typical comparison group. Further, the sample size comprised only 190 participants, and the ratios of children to adolescents and girls to boys were about 1:3. Therefore, further research with more participants who are gender- and age-matched is required. Additionally, an extended follow-up could identify the patterns of change for each class, which could improve differentiation strategies.

This study provided data on the patterns of Internet, gaming, and smartphone overuse in children and adolescents by identifying characteristics of four latent classes using clinical cohort data. The results can be useful to develop differentiated intervention strategies according to the usage patterns of children and adolescents.

Funding Sources

This work was supported by a grant from the Korea Healthcare Technology R&D Project, Ministry for Health and Welfare, Republic of Korea (HM14C2603).

Authors' contribution

Y.S.K and Y.S.J designed the study and Y.S.J., Y.S.K., S.Y.B., J.S.C. designed the protocol. Y.S.J performed statistical analysis and interpretation of data. Y.S.J. and Y.S.K. wrote the first draft of the manuscript. Y.S.K., S.Y.B., J.S.C., H.K.L., and S.Y.L provided study supervision. Y.S.K. managed the entire study process. All authors contributed to and have approved the final manuscript.

Conflict of interests

The authors declare no conflicts of interest with respect to the content of the manuscript.

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  • Kwon, H. S., & Kwon, K. I. (2017). Study on the developmental steps of adolescent gaming addiction according to the level of engagement and addiction: Separating steps: Through latent class analysis and the role of related variables. Korean Journal of Youth Counseling, 25(1), 155175. https://doi.org/10.35151/kyci.2017.25.1.008.

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    • Crossref
    • Search Google Scholar
    • Export Citation
  • Lee, S. Y., Lee, D., Nam, C. R., Kim, D. Y., Park, S., Kwon, J. G. et al. (2018a). Distinct patterns of Internet and smartphone-related problems among adolescents by gender: Latent class analysis. Journal of Behavioral Addictions, 7(2), 454465. https://doi.org/10.1556/2006.7.2018.28.

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  • Liu, L., Yao, Y. W., Li, C. R., Zhang, J. T., Xia, C. C., Lan, J. et al. (2018). The comorbidity between internet gaming disorder and depression: Interrelationship and neural mechanisms. Frontiers in Psychiatry, 9, 154. https://doi.org/10.3389/fpsyt.2018.00154.

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    • Export Citation
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    • Crossref
    • Search Google Scholar
    • Export Citation
  • Magnusson, D. (2003). The person approach: Concepts, measurement models, and research strategy. New Directions for Child and Adolescent Development, 101(2003), 323. https://doi.org/10.1002/cd.79.

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    • Export Citation
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    • Search Google Scholar
    • Export Citation
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  • Meyer, J. P., & Morin, A. J. S. (2016). A person‐centered approach to commitment research: Theory, research, and methodology. Journal of Organizational Behavior, 37(4), 584612. https://doi.org/10.1002/job.2085.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Muthén, B. (2004). The sage handbook of quantitative methodology for the social sciences (pp. 345368). Thousand Oaks, CA, USA: Sage Publications.

    • Search Google Scholar
    • Export Citation
  • Muthén, B., & Muthén, L. K. (2000). Integrating person‐centered and variable‐centered analyses: Growth mixture modeling with latent trajectory classes. Alcoholism: Clinical and Experimental Research, 24(6), 882891. https://doi.org/10.1111/j.1530-0277.2000.tb02070.x.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Muusses, L. D., Finkenauer, C., Kerkhof, P., & Billedo, C. J. (2014). A longitudinal study of the association between compulsive Internet use and wellbeing. Computers in Human Behavior, 36, 2128. https://doi.org/10.1016/j.chb.2014.03.035.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Nylund, K. L., Asparouhov, T., & Muthén, B. O. (2007). Deciding on the number of classes in latent class analysis and growth mixture modeling: A Monte Carlo simulation study. Structural Equation Modeling, 14(4), 535569. https://doi.org/10.1080/10705510701575396.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Park, S.-G., & Jo, H. S. (2018). The relationship between happiness, depression and smart phone addiction. Korean Journal of Health Psychology, 23(4), 10951102. https://doi.org/10.17315/kjhp.2018.23.4.014.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Park, M. S., Jon, D. I., Hong, H. J., Jung, M. H., & Hong, N. (2017). The effect of the internet addiction prevention program. Korean Association of Social Psychiatry, 22(2), 8490.

    • Search Google Scholar
    • Export Citation
  • Park, S. M., Kim, E. H., & Kang, M. C. (2013). Latent profile analysis and related factors of Internet addiction in adolescents. Korean Journal of Counseling, 14(5), 29873002. https://doi.org/10.15703/kjc.14.5.201310.2987.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Park, S. M., & Lee, J. Y. (2018). Analysis of latent profiles and influencing factors on adolescents' internet game addiction. Korean Journal of Counseling, 19(6), 203224. https://doi.org/10.15703/kjc.19.6.201812.203.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Park, B. K., & Noh, J. U. (2019). Effects of parenting behaviors and children’s happiness on media device addiction. Korean Journal of Child Studies, 40(3), 87103. https://doi.org/10.5723/kjcs.2019.40.3.87.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Pickard, H. (2016). Denial in addiction. Mind & Language, 31(3), 277299. https://doi.org/10.1111/mila.12106.

  • Ramaswamy, V., DeSarbo, W., Reibstein, D., & Robinson, W. (1993). An empirical pooling approach for estimating marketing mix elasticities with PIMS data. Marketing Science, 12(1), 103124. https://doi.org/10.1287/mksc.12.1.103.

    • Crossref
    • Search Google Scholar
    • Export Citation
  • Rost, J. (2006). Latent class analyses. In F. Petermann & M. Eid (Eds.), Handbook of psychological assessment (pp. 275287). Gottingen, Germany: Hogrefe.

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Dr. Zsolt Demetrovics
Institute of Psychology, ELTE Eötvös Loránd University
Address: Izabella u. 46. H-1064 Budapest, Hungary
Phone: +36-1-461-2681
E-mail: jba@ppk.elte.hu

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2023  
Web of Science  
Journal Impact Factor 6.6
Rank by Impact Factor Q1 (Psychiatry)
Journal Citation Indicator 1.59
Scopus  
CiteScore 12.3
CiteScore rank Q1 (Clinical Psychology)
SNIP 1.604
Scimago  
SJR index 2.188
SJR Q rank Q1

Journal of Behavioral Addictions
Publication Model Gold Open Access
Submission Fee none
Article Processing Charge 990 EUR/article
Effective from  1st Feb 2025:
1400 EUR/article
Regional discounts on country of the funding agency World Bank Lower-middle-income economies: 50%
World Bank Low-income economies: 100%
Further Discounts Corresponding authors, affiliated to an EISZ member institution subscribing to the journal package of Akadémiai Kiadó: 100%.
Subscription Information Gold Open Access

Journal of Behavioral Addictions
Language English
Size A4
Year of
Foundation
2011
Volumes
per Year
1
Issues
per Year
4
Founder Eötvös Loránd Tudományegyetem
Founder's
Address
H-1053 Budapest, Hungary Egyetem tér 1-3.
Publisher Akadémiai Kiadó
Publisher's
Address
H-1117 Budapest, Hungary 1516 Budapest, PO Box 245.
Responsible
Publisher
Chief Executive Officer, Akadémiai Kiadó
ISSN 2062-5871 (Print)
ISSN 2063-5303 (Online)

Senior editors

Editor(s)-in-Chief: Zsolt DEMETROVICS

Assistant Editor(s): 

Csilla ÁGOSTON

Dana KATZ

Associate Editors

  • Stephanie ANTONS (Universitat Duisburg-Essen, Germany)
  • Joel BILLIEUX (University of Lausanne, Switzerland)
  • Beáta BŐTHE (University of Montreal, Canada)
  • Matthias BRAND (University of Duisburg-Essen, Germany)
  • Daniel KING (Flinders University, Australia)
  • Gyöngyi KÖKÖNYEI (ELTE Eötvös Loránd University, Hungary)
  • Ludwig KRAUS (IFT Institute for Therapy Research, Germany)
  • Marc N. POTENZA (Yale University, USA)
  • Hans-Jurgen RUMPF (University of Lübeck, Germany)
  • Ruth J. VAN HOLST (Amsterdam UMC, The Netherlands)

Editorial Board

  • Sophia ACHAB (Faculty of Medicine, University of Geneva, Switzerland)
  • Alex BALDACCHINO (St Andrews University, United Kingdom)
  • Judit BALÁZS (ELTE Eötvös Loránd University, Hungary)
  • Maria BELLRINGER (Auckland University of Technology, Auckland, New Zealand)
  • Henrietta BOWDEN-JONES (Imperial College, United Kingdom)
  • Damien BREVERS (University of Luxembourg, Luxembourg)
  • Julius BURKAUSKAS (Lithuanian University of Health Sciences, Lithuania)
  • Gerhard BÜHRINGER (Technische Universität Dresden, Germany)
  • Silvia CASALE (University of Florence, Florence, Italy)
  • Luke CLARK (University of British Columbia, Vancouver, B.C., Canada)
  • Jeffrey L. DEREVENSKY (McGill University, Canada)
  • Geert DOM (University of Antwerp, Belgium)
  • Nicki DOWLING (Deakin University, Geelong, Australia)
  • Hamed EKHTIARI (University of Minnesota, United States)
  • Jon ELHAI (University of Toledo, Toledo, Ohio, USA)
  • Ana ESTEVEZ (University of Deusto, Spain)
  • Fernando FERNANDEZ-ARANDA (Bellvitge University Hospital, Barcelona, Spain)
  • Naomi FINEBERG (University of Hertfordshire, United Kingdom)
  • Sally GAINSBURY (The University of Sydney, Camperdown, NSW, Australia)
  • Belle GAVRIEL-FRIED (The Bob Shapell School of Social Work, Tel Aviv University, Israel)
  • Biljana GJONESKA (Macedonian Academy of Sciences and Arts, Republic of North Macedonia)
  • Marie GRALL-BRONNEC (University Hospital of Nantes, France)
  • Jon E. GRANT (University of Minnesota, USA)
  • Mark GRIFFITHS (Nottingham Trent University, United Kingdom)
  • Joshua GRUBBS (University of New Mexico, Albuquerque, NM, USA)
  • Anneke GOUDRIAAN (University of Amsterdam, The Netherlands)
  • Susumu HIGUCHI (National Hospital Organization Kurihama Medical and Addiction Center, Japan)
  • David HODGINS (University of Calgary, Canada)
  • Eric HOLLANDER (Albert Einstein College of Medicine, USA)
  • Zsolt HORVÁTH (Eötvös Loránd University, Hungary)
  • Susana JIMÉNEZ-MURCIA (Clinical Psychology Unit, Bellvitge University Hospital, Barcelona, Spain)
  • Yasser KHAZAAL (Geneva University Hospital, Switzerland)
  • Orsolya KIRÁLY (Eötvös Loránd University, Hungary)
  • Chih-Hung KO (Faculty of Medicine, College of Medicine, Kaohsiung Medical University, Taiwan)
  • Shane KRAUS (University of Nevada, Las Vegas, NV, USA)
  • Hae Kook LEE (The Catholic University of Korea, Republic of Korea)
  • Bernadette KUN (Eötvös Loránd University, Hungary)
  • Katerina LUKAVSKA (Charles University, Prague, Czech Republic)
  • Giovanni MARTINOTTI (‘Gabriele d’Annunzio’ University of Chieti-Pescara, Italy)
  • Gemma MESTRE-BACH (Universidad Internacional de la Rioja, La Rioja, Spain)
  • Astrid MÜLLER (Hannover Medical School, Germany)
  • Daniel Thor OLASON (University of Iceland, Iceland)
  • Ståle PALLESEN (University of Bergen, Norway)
  • Afarin RAHIMI-MOVAGHAR (Teheran University of Medical Sciences, Iran)
  • József RÁCZ (Hungarian Academy of Sciences, Hungary)
  • Michael SCHAUB (University of Zurich, Switzerland)
  • Marcantanio M. SPADA (London South Bank University, United Kingdom)
  • Daniel SPRITZER (Study Group on Technological Addictions, Brazil)
  • Dan J. STEIN (University of Cape Town, South Africa)
  • Sherry H. STEWART (Dalhousie University, Canada)
  • Attila SZABÓ (Eötvös Loránd University, Hungary)
  • Hermano TAVARES (Instituto de Psiquiatria do Hospital das Clínicas da Faculdade de Medicina, Universidade de São Paulo, São Paulo, Brazil)
  • Wim VAN DEN BRINK (University of Amsterdam, The Netherlands)
  • Alexander E. VOISKOUNSKY (Moscow State University, Russia)
  • Aviv M. WEINSTEIN (Ariel University, Israel)
  • Anise WU (University of Macau, Macao, China)
  • Ágnes ZSILA (ELTE Eötvös Loránd University, Hungary)

 

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