Reduced orbitofrontal cortical thickness in male adolescents with internet addiction

Fifteen right-handed male adolescents with internet addiction were recruited through advertisement in Seoul National University Hospital. The recruitment was performed between February and June 2011. In order to establish the diagnosis of internet addiction we used the Young Internet Addiction Scale (YIAS) [16]. In addition, participants were confined to those reporting to have experienced typical components of addiction with their online gaming including: tolerance, withdrawal, preoccupation with playing it, repeated unsuccessful attempts to reduce or stop it, negatively influenced mood when attempting to reduce it, and neglecting important relationships or activities because of it [17, 18]. In order to exclude any comorbid psychiatric disorders, we used the Kiddie-Schedule for Affective Disorders and Schizophrenia-Present and Lifetime Version (K-SADS-PL) [19]. Healthy male adolescents were recruited through advertisement in local schools and were screened using the same assessment tools described above. Exclusion criteria for both groups were any axis I psychiatric disorder including substance abuse, epilepsy or other neurological disorders, and past history of severe head trauma. The prevalence of internet addiction has been estimated to be much higher in males than in females [1]. Given that males are over-represented in internet-addicted populations, and given time and budget limitations, we decided to focus only on male adolescents. This study was approved by the institutional review board for human subjects at the Seoul National University. All the adolescents and their parents provided written informed consent prior to study entry.

Whole brain T1-weighted MR images were acquired on a 3T Siemens scanner (Siemens Magnetom Trio Tim Syngo MR B17, Germany) with the following parameters: TR 1900 ms; TE 2.36 ms; inversion time 700 ms; flip angle 9°; voxel size 1.0 mm³; slices 224. Head motions were minimized by filling the empty space around the head with sponge material and fixing the lower jaw with tape.

Cortical thickness was estimated using FreeSurfer 5.1.0 (Massachusetts General Hospital, Boston, MA, US), a set of software tools that provides a semi-automated method to investigate brain morphometry. The surface-based stream involves (i) normalization of brain signal intensity, (ii) skull-stripping, (iii) segmentation of gray and white matter, (iv) delineation of the gray-white interface (inner surface), and (v) tracing of the pial (outer) surface. The distance between equivalent vertices in these two surfaces represents the cortical thickness. The whole cortex of each subject was visually inspected and systematically corrected for errors in a blind manner to the group status of the participants. We used our sample to generate an average target surface and the data for each participant were pre-smoothed with a full-width half-maximum Gaussian kernel of 10 mm prior to statistical analyses.

Region-of-interest (ROI)-based analyses were conducted comparing the cortical thickness of the OFC generated by FreeSurfer based on the Desikan-Killiany atlas [20]. More specifically, the Desikan-Killiany atlas defines the lateral and medial divisions of the OFC. The rostral/caudal and medial/lateral boundaries of these two structures are the rostral extent of the lateral orbital gyrus/the caudal portion of the lateral orbital gyrus and the midpoint of the olfactory sulcus/the lateral bank of the lateral orbital sulcus (and/or the circular insular sulcus) for the lateral OFC; and the rostral extent of the medial orbital gyrus/the caudal portion of the medial orbital gyrus (or gyrus rectus) and the cingulate cortex/the medial bank of the superior frontal gyrus for the medial OFC, respectively [20]. Analysis of covariance (ANCOVA) using the general linear model (GLM) was performed with SPSS 19.0 (SPSS Inc., Chicago, IL, USA), and the main effect of group (internet addiction vs. healthy control) was analyzed controlling for age, intelligence quotient (IQ), and intracranial volume (ICV). Results of this analysis were reported with a significance threshold of p<0.05 (two-tailed).

The groups of adolescents with and without internet addiction significantly differed in age (13.33±2.84 for internet addiction; 15.40±1.24 for control; p=0.018). IQ was comparable across both groups (103.80±15.84 for internet addiction; 109.06±9.84 for control; p=0.283), and a significant difference in ICV was found (1434.42±158.33 cm³ for internet addiction; 1577.21±183.12 cm³ for control; p=0.030). The YIAS score was significantly higher in the internet addiction group (57.26±16.11 for internet addiction; 37.60±9.72 for control; p=0.000).

The analysis revealed four ROIs with significant differences in cortical thickness (p<0.05), which were the lateral OFC, isthmus of the cingulate cortex, and pars orbitalis in the right hemisphere and lateral occipital cortex in the left hemisphere, all displaying cortical thinning in adolescents with internet addiction compared to healthy controls (Table 1).

To provide a complementary perspective of our finding, a surface-based whole brain analysis using FreeSurfer’s Qdec (version 1.4) was performed by fitting a between-subject GLM at each surface vertex to compare cortical thickness between the groups (uncorrected, p<0.001). As illustrated in Figure 1, reduction in lateral OFC thickness was replicated by this analysis.