This study undertook analyses utilizing the data from a randomized controlled, evaluator-blind trial (NCT04585282) titled "CBT for Insomnia with Anxiety and Depression." The original research aims to investigate the effectiveness of an enhanced cognitive behavioral therapy for insomnia (CBT-I plus) compared to CBT-I in insomniac patients with symptoms of anxiety or depression. The participants were recruited from the sleep disorder clinic of Shanghai Mental Health Center in China from August 1, 2020, to March 1, 2023. The study design was approved by the ethical committee of Shanghai Mental Health Center. All participants signed an informed consent.

Inclusion criteria encompassed individuals between 18 and 65 years who, as evaluated by a research psychiatrist, met the diagnostic criteria for insomnia disorder according to DSM-5. Eligible participants had a total score of ≥ 10 on the Pittsburgh Sleep Quality Index (PSQI) and exhibited moderate levels of anxiety or depressive symptoms, with scores ranging from 14 to 29 on the Hamilton Anxiety Scale (HAMA) and/or scores ranging from 14 to 23 on the 17-item Hamilton Depression Scale (HRSD-17). To ensure consistency, participants refrained from using sedative hypnotics, antidepressants, anxiolytics, antipsychotics, or relevant medications for at least two weeks prior to enrollment, or they maintained stable medication type and dosage for at least four weeks before enrollment.

Those with other sleep disorders as specified by DSM-5 or other severe physical illnesses were excluded, as well as patients with substance abuse, pregnancy, a history diagnosis of depression, anxiety, or other mental disorders, or previous psychological therapy for a period exceeding three months.

Following informed consent, participants were randomly allocated in a 2:1 ratio to either the CBT-I plus intervention group (experimental group) or the CBT-I intervention group (control group). Ten uniformly trained therapists were randomly assigned to conduct the interventions. The therapy commenced with a comprehensive assessment, aimed at establishing therapeutic rapport, followed by eight weekly individualized sessions lasting 45–50 min each. The experimental group received the CBT-I plus program, while the control group received the standard CBT-I program. Table 1 provides an overview of the interventions, with detailed descriptions available in the Supplemental Methods. Throughout the intervention period, participants were required to maintain a stable dosage of their pre-existing medication and refrain from utilizing antidepressants, anxiolytics, or antipsychotic medications. Limited utilization of zopiclone, zolpidem (Ambien), or eszopiclone (Lunesta) was permissible, with a frequency not exceeding three times per week and a cumulative duration not surpassing two weeks.

We collected baseline demographic information, including age, gender, years of education, marital status, and body mass index (BMI). To assess sleep-related characteristics, we administered the Pittsburgh Sleep Quality Index (PSQI), which provided data on self-reported sleep quality and self-reported total sleep time (sTST), and other sleep indices (Sleep Latency; Sleep Efficiency; and Time in Bed). The PSQI ranges from 0 to 21, with higher scores indicating poorer sleep quality. Our primary analyses mainly focused on sTST to evaluate participants’ sleep quality. The severity of depressive and anxiety symptoms was quantified using the 17-item Hamilton Depression Rating Scale (HRSD-17) and Hamilton Anxiety Rating Scale (HAMA), respectively. The HRSD-17 ranges from 0 to 52, with higher scores reflecting greater severity of depressive symptoms, while the HAMA ranges from 0 to 56, with higher scores indicating more severe anxiety symptoms. Daytime sleepiness was measured with the Epworth Sleepiness Scale (ESS), which ranges from 0 to 24, with higher scores representing greater daytime sleepiness. We also used the Dysfunctional Beliefs and Attitudes about Sleep Scale (DBAS-16) to probe maladaptive cognitive patterns and attitudes about sleep; this scale ranges from 16 to 90, with higher scores suggesting more dysfunctional beliefs about sleep, which is contrary to the scoring rules used in most other studies. We conducted the assessments at baseline, including the PSQI, the HRSD-17, the HAMA, the ESS, and the DBAS-16. The PSQI, the HRSD-17. To evaluate CBT-I treatment outcomes, the HAMA were re-assessed at week 8.

We calculated descriptive statistics to overview the participants' baseline demographic and clinical characteristics. We presented continuous variables as means and standard deviations, and express categorical variables as frequencies and percentages. For missing data, we employed multiple imputation. Specifically, the missing data proportions for the key variables were as follows: PSQI (0.85 %), HRSD (0.85 %), HAMA (0 %), DBAS (9.32 %), and ESS (9.32 %). Because some participants completed treatment but only partially filled out the self-reported scales, multiple imputation was chosen to retain as many cases as possible, minimize bias from missingness, and preserve statistical power—essential for subtyping analyses requiring full variable inclusion.

A data-driven methodology was implemented to discern subtypes within the study cohort. K-means clustering analysis was applied to baseline features, incorporating sTST and total scores of the PSQI, HRSD-17, HAMA, DBAS-16, and ESS. Before analysis, we standardized the features using z-score scaling to ensure comparability across different measurement scales. The optimal number of clusters, we selected the value that yielded the highest silhouette coefficient, which assesses the separation distance between resulting clusters. Subsequently, dimensionality reduction was performed using Principal Component Analysis (PCA), retaining components that accounted for at least 70 % of the variance in the data.

We used T-tests to compare baseline and follow-up characteristics between subtypes and among participants receiving different interventions. We assessed the changes in sTST (csTST), PSQI (cPSQI), HRSD (cHRSD), and HAMA (cHAMA) scores following the treatment. Specifically, csTST was calculated as the difference between the post-intervention and baseline values (post-intervention minus baseline), with positive values indicating an increase in total sleep time. In contrast, cPSQI, cHRSD, and cHAMA were calculated as the difference between the baseline and post-intervention values (baseline minus post-intervention), where positive values represent improvements, such as better sleep quality, reduced depressive symptoms, or reduced anxiety symptoms.

The analyses were conducted using Python 3.9 with packages "sklearn", "scypi", "statsmodels", "pandas", and "numpy". The visualizations were crafted using Python packages "matplotlib" and "Axes3D". We set α = 0.05 as the significance level to determine the statistical significance of the results.

Four hundred and eleven individuals were screened for the study. Among them, 76 individuals declined further evaluation, 187 individuals did not meet the inclusion criteria, and 148 eligible participants were included for further assessment and treatment. Ultimately, 118 individuals completed the 8-week intervention. The baseline demographic and clinical characteristics are shown in Table 2. Among the participants, 78 out of 118 participants (66.1 %) received CBT-I plus therapy. There were no significant differences in baseline characteristics between the CBT-I group and the CBT-I plus group.

After using z-score scaling to ensure consistent scaling across variables, a two-cluster solution was selected based on the highest silhouette coefficient, indicating optimal cluster separation (Fig. 1A). Furthermore, dimension reduction was executed using PCA, revealing three principal components that accounted for 73 % of the variations in the data (Fig. 1B). The visualization of K means clustering was depicted in a three-dimensional space (Fig. 1C). Cluster analysis identified two subtypes, with Subtype 1 making up 48.3 % of the sample (Fig. 1D).

Fig. 1.

The visualization of the data-driven clustering process. (A) The silhouette coefficient score by number of clusters. (B) The principal component analysis (PCA) and the variance explained by the number of components. (C) The spatial representation of clusters formed through K-means clustering in three dimensions. (D) The distribution percentage of sample in each subtype.

Compared to Subtype 1, Subtype 2 demonstrated significantly shorter self-reported total sleep time (sTST: 4.67 vs. 6.09 h, t = 8.31, p < 0.01), worse sleep quality (PSQI: 16.59 vs 12.74, t=−9.90, p < 0.01), more severe depressive symptoms (HRSD: 18.47 vs 13.21, t=−8.37, p < 0.01), anxiety symptoms (HAMA: 17.47 vs 13.46, t=−6.23, p < 0.01), and sleepiness (ESS: 6.98 vs 4.51, t=−3.54, p < 0.01) (Fig. 2). No significant differences were found between Subtype 1 and Subtype 2 in BMI (T = 0.03, p = 0.976), age (35.18 ± 9.96 vs. 34.92 ± 10.13; T = 0.13, p = 0.900), sex (63.1 % vs. 62.2 % female; U = 1719.5, p = 0.903), education level (16.46 ± 2.28 vs. 16.89 ± 2.25 years; U = 1899.5, p = 0.100), marital status (45.21 % vs. 45.95 % married; U = 1822.0, p = 0.611), employment status (χ² = 1.35, p = 0.2445), hypnotic use (U = 1524.0, p = 0.179), or dysfunctional beliefs about sleep (DBAS: 34.95 vs. 34.79; T=−0.08, p = 0.936).

Fig. 2.

The baseline sleep and emotional

characteristics of the data-driven ID subtypes. * indicates a statistically significant difference between Subtype 1 and Subtype 2 (p < 0.05).

After 8 weeks of CBT-I or CBT-I plus intervention, both subtypes displayed changes in sleep and emotional characteristics (Fig. 3A). Here, the prefix “c” indicates “change” and represents the difference between baseline and post-treatment values for each variable. Participants in Subtype 2 had a larger increase in sleep duration (csTST in Subtype 2 vs Subtype 1: 1.77 vs 0.58 h, t = −7.18, p < 0.01) and greater improvement in self-reported sleep quality (cPSQI score in Subtype 2 vs.1: 8.88 vs. 6.92, t = −3.57, p < 0.001). Participants in Subtype 2 demonstrated significant larger reductions in depressive symptoms (cHRSD in Subtype 2 vs. 1: 10.59 vs. 8.07, t = −2.71, p = 0.008) and anxiety symptoms (cHAMA in Subtype 2 vs. 1: 11.22 vs. 9.28, t = −2.56, p = 0.012). No significant difference in self-reported sleep duration was observed between participants in Subtype 1 and Subtype 2 at 8 weeks (6.68 h vs 6.44 h, p = 0.119). However, participants in Subtype 1 exhibited significantly better outcomes in terms of sleep quality (PSQI_8w: 5.81 vs 7.71, p < 0.01), depression levels (HRSD_8w: 5.14 vs 7.89, p < 0.01), and anxiety levels (HAMA_8w: 4.18 vs 6.25, p < 0.01) compared to those in Subtype 2. These results, as visualized in Fig. 3B, underscore the more pronounced treatment benefits experienced by Subtype 2 participants, particularly in terms of sleep and emotional improvements.

Fig. 3.

Characteristics and changes in sleep and emotion between ID Subtypes Following CBT-I Treatment (A) The changes in sleep and emotional characteristics of the data-driven ID subtypes after CBT-I. (B) Sleep and emotional characteristics of ID subtypes at baseline and 8 weeks post-CBT-I. * indicates a statistically significant difference between Subtype 1 and Subtype 2 (p < 0.05).

In our analysis, we found no significant differences in baseline characteristics between the groups receiving either CBT-I alone or CBT-I plus within both Subtype 1 and Subtype 2. This suggests homogeneity in initial sleep and emotional conditions across the two treatment modalities. Detailed statistical results, including t-values and p-values for measures such as sTST, PSQI, HRSD, and HAMA, are provided in Supplemental Table 1.

In the results presented in Fig. 4, within Subtype 1, comparisons between CBT-I and CBT-I plus revealed no significant differences in csTST (t = 0.139, p = 0.890), cPSQI (t = −1.94, p = 0.057), or cHAMA (t = −0.136, p = 0.893). However, a statistically significant difference was observed in the reduction of depressive symptoms (cHRSD: t = −2.48, p = 0.016), indicating that CBT-I plus was more effective in improving depressive symptoms among participants in Subtype 1. For Subtype 2, the analysis indicated that CBT-I resulted in a greater increase in csTST than CBT-I plus (t = 2.01, p = 0.049), but no significant differences were found in cPSQI (t = 0.74, p = 0.462), cHRSD (t = −0.892, p = 0.376), or cHAMA (t = 0.364, p = 0.717) between the two interventions. The findings indicated that CBT-I plus more effectively reduced depressive symptoms in Subtype 1, while CBT-I enhanced self-reported sleep duration more in Subtype 2, with no significant differences in other measures between treatments.

Fig. 4.

Differential Impact of CBT-I vs. CBT-I plus on Sleep and Emotion Outcomes Across Subtypes. * indicates a statistically significant difference between Subtype 1 and Subtype 2 from baseline to 8 weeks (p < 0.05).