Sample

The study was approved by the research ethical committee of the First Affiliated Hospital of Zhengzhou University. For each participant, written informed consent was obtained before experiment. We recruited first-episode untreated patients with depression (n = 195) from out-patient services of the Department of Psychiatry, the First Affiliated Hospital of Zhengzhou University, Zhengzhou, China. The diagnosis was done by one chief physician and one well-trained psychiatrist according to Diagnostic and Statistical Manual of Mental Disorders, Fourth Edition (DSM-IV) for depression. Patients would be excluded if they met one of the exclusion criteria: (1) comorbidity with other mental (psychotic) disorders and (2) a history of manic symptoms. All patients were during depressed phase. The clinical states were evaluated using the 17-items Hamilton Depression scale (HAMD). Matched HCs (n = 78) were recruited from the community through poster advertisement. All HCs were Han Chinese and right handedness. None of them had a history of serious medical, neuropsychiatric illness, family history of major psychiatric or neurological illness in their first-degree relatives.

In addition, all participants must meet the following exclusion criteria: (1) taking drugs such as anesthesia, sleeping and analgesia in the past 1 month; (2) substance abuse; (3) a history of brain tumor, trauma, surgery or other organic body disease; (4) suffering from cardiovascular diseases, diabetes or hypertension; (5) contraindications for magnetic resonance imaging (MRI) scanning and (6) other structural brain abnormalities revealed by MRI scan.

Data acquisition

T1-weighted anatomical images of participants in dataset 1 were acquired using on 3-Tesla GE Discovery MR750 scanner (General Electric, Fairfield Connecticut, USA). Using an eight-channel prototype quadrature birdcage head coil, we acquired structural T1-weighted images with 3D-spoiled gradient echo scan sequence with the following parameters: repetition time = 8164 ms, echo time = 3.18 ms, inversion time = 900 ms, flip angle = 7 degrees, resolution matrix = 256 × 256, slices = 188, thickness = 1.0 mm, voxel size = 1 × 1 × 1 mm³.

Voxel-based morphometry analysis

All scans were processed following the standard pipeline of CAT12 toolbox (http://dbm.neuro.uni-jena.de/cat12/). Main steps included: bias-field correction, segmentation (gray and white matter and cerebrospinal fluid), adjustment for partial volume effects, normalization into Montreal Neurological Institute space, resampled to 1.5 mm × 1.5 mm × 1.5 mm and nonlinear modulation. Finally, the gray matter maps were smoothed using 6 mm full width at half maximum Gaussian kernel. The total intracranial volume (TIV) of each participant was also calculated for the following analysis.

Morphological heterogeneity and group difference

We explored whether patients with depression exhibited higher morphological heterogeneity than HCs adopting the following steps: (1) constructing a group-level M × M (M, the number of brain regions in brain atlas) structural covariance network (SCN) for each group. The 268 brain atlas was chosen for the reason that functional connectome built based on it turned out a ‘fingerprint’ (Finn et al., Reference Finn, Shen, Scheinost, Rosenberg, Huang, Chun and Constable2015; Shen, Tokoglu, Papademetris, & Constable, Reference Shen, Tokoglu, Papademetris and Constable2013). (2) A jackknife-bias estimation procedure was used to determine individual's contribution to the overall group-level SCN, thus deriving individualized SCN for each subject (Das et al., Reference Das, Borgwardt, Hauke, Harrisberger, Lang, Riecher-Rössler and Schmidt2018; Miller & Rupert, Reference Miller and Rupert1974). (3) The Euclidean distance value was calculated to measure the deviation between subject-level and group-level SCNs for each subject. The average distance (heterogeneity) value determined the degree of morphological heterogeneity for one group (Fig. 1a). Heterogeneity values were compared between patients with depression and HCs using Wilcoxon rank sum test controlling for age, sex, education level and TIV. We also validated this result with another brain atlas (200 regions) (Craddock, James, Holtzheimer, Hu, & Mayberg, Reference Craddock, James, Holtzheimer, Hu and Mayberg2012).

Fig. 1. Workflow for calculating individualized SCN. (a) Procedure of calculating individualized SCN. First, we obtained original group-level SCN (oSCN) and new group-level SCN (nSCN) by removing subject k from original group. Then, the individual SCN for subject k was defined as: nSCN − oSCN. This procedure was done in patients and HCs separately. (b) We calculated Euclidean distance between individualized SCN and group-level SCN for each subject. The heterogeneity (variability) values were compared between patients with depression and HCs using two-sample t test.

Constructing the IDSCN

To measure the individualized differential structural covariance, we adopted a newly proposed method named IDSCN analysis (Liu et al., Reference Liu, Palaniyappan, Wu, Zhang, Du, Zhao and Lin2021). Here, we just briefly described the main steps; more details could be seen in Liu et al. (Reference Liu, Palaniyappan, Wu, Zhang, Du, Zhao and Lin2021). (1) Constructing the reference structural covariance network (rSCN) using all HCs by calculating partial correlation between regional gray matter volume (GMV) for each pair of brain regions where age, gender and educational level and TIV were treated as covariates. (2) Adding one patient k into HCs as a new group. A perturbed structural covariance network (pSCN) was built with the new group. (3) The difference (ΔSCN) between the pSCN and rSCN was calculated: ΔSCN = pSCN − rSCN. (4) Calculating the Z-score of ΔSCN according to the following formula:

$$Z = \displaystyle{{\Delta {\rm SCN}} \over {( 1-{\rm rSC}{\rm N}^2) /( n-1) }}$$

The IDSCN for patient k was constructed with the Z-scores obtained from the Z test. Positive Z-scores represented higher structural covariance edges strength in patient k against the reference HCs or vice versa. The p values of edges were obtained from the Z-scores. Then, we identified individualized differential structural covariance edges that were significantly different from the reference SCN in each patient with p < 0.05, Bonferroni corrected for 268 × 267/2 = 35 778 edges (Fig. 2).

Fig. 2. Workflow of IDSCN and network definition in this study: (a) description of obtaining IDSCN for patient k and (b) nodes and networks in 268 brain atlas.

Subtyping patients with depression

Then, we clustered patients with depression by adopting the k-means method where the top 100 differential structural covariance edges as features. The optimal cluster number ranging from 2 to 10 was determined by silhouette values (Liu et al., Reference Liu, Palaniyappan, Wu, Zhang, Du, Zhao and Lin2021). We did not choose the top edges shared by 5% of patients as done in Liu et al. (Reference Liu, Palaniyappan, Wu, Zhang, Du, Zhao and Lin2021) for the reason that there was only one edge shared more than 10 patients (5% of 195 patients). The k-means was repeated 100 times to avoid local minima resulted from random in initialization of centroid positions (Allen et al., Reference Allen, Damaraju, Plis, Erhardt, Eichele and Calhoun2014).

Reproducibility analysis

To further inquire the reproducibility of subtyping results, we adopted different strategies. (1) Using another brain atlas (200 regions). (2) Using different numbers of top differential edges (80 or 120). The adjusted Rand index (ARI) was used to quantify the consistency of subtyping results between these subtyping results (Hu Be Rt & Arabie, Reference Hu Be Rt and Arabie1985). (3) To exclude the change that subtyping results were driven by a few subjects, we randomly selected 80% of patients and performed the same subtyping results on the sub-samples. ARI value was calculated between the subtyping results obtained from sub-samples and that from the whole dataset (all patients). This procedure was repeated 100 times.

Clinical and IDSCN examination of depression subtypes

Then, we examined differences between subtypes of depression in terms of age, sex, education level, TIV, duration of illness and the total score of HAMD with two sample t test or chi-square test accordingly. The top 100 differential edges were organized into between- and within-network edges defined in the previous study (Finn et al., Reference Finn, Shen, Scheinost, Rosenberg, Huang, Chun and Constable2015) and then compared between subtypes of depression using two sample t test.

Functional annotation of altered structural covariance edges

Integrating results of a great number of neuroimaging studies, Yarkoni et al. provided probabilistic (activation) mappings supporting quantitative inferences about association between cognitive process with regional brain activity (Neurosynth, https://neurosynth.org/) (Yarkoni, Poldrack, Nichols, Van Essen, & Wager, Reference Yarkoni, Poldrack, Nichols, Van Essen and Wager2011). Each voxel in one activation map was associated with the numbers of terms/tasks helping to interpret the function of that region (Yarkoni et al., Reference Yarkoni, Poldrack, Nichols, Van Essen and Wager2011). There were more than 3000 search terms with their activation maps provided by Neurosynth. Among these, 217 terms bore clear biological significance (details of the selection criteria were described in Cheng et al., Reference Cheng, Rolls, Zhang, Sheng, Ma, Wan and Feng2017). To provide a further interpretation for identified differential structural covariance edges in each subtype, functional annotation analysis was performed to investigate association between altered structural covariance edges and cognitive states using activation maps provided by Neurosynth (Han et al., Reference Han, Xu, Guo, Fang, Wei, Liu and Cheng2022). Differential structural covariance edges were determined where p < 0.005 (uncorrected) for each subtype compared with HCs. The tolerant p value was determined to include the potential altered edges in each subtype in consideration of high level of heterogeneity in depression (see below). Altered edges were associated with functional terms using the mean co-activation ratio measuring the extent of edges for a functional term, the significance were determined using permutation test (Liu et al., Reference Liu, Rolls, Liu, Zhang, Yang, Du and Feng2019). This procedure was done using brain annotation toolbox (BAT, http://123.56.224.61/softwares) (Liu et al., Reference Liu, Rolls, Liu, Zhang, Yang, Du and Feng2019).