Rahul J, Sharma D, Sharma LD, Nanda U, Sarkar AK. A systematic review of EEG-based automated schizophrenia classification through machine learning and deep learning. Front Hum Neurosci. 2024;18:1347082.
Article
Google Scholar
Tyagi A, Singh VP, Gore MM. Towards artificial intelligence in mental health: a comprehensive survey on the detection of schizophrenia. Multimed Tools Appl. 2023;82(13):20343–405.
Article
Google Scholar
Ochilov U, Turayev B, Sharapova D, Shernazarov F. The main forms of aggressive manifestations in the clinic of mental disorders of children and adolescents and factors affecting their occurrence. Sci Innov. 2023;2(D11):42–8.
Google Scholar
McGrath JJ, Al-Hamzawi A, Alonso J, Altwaijri Y, Andrade LH, Bromet EJ, et al. Age of onset and increasing risk of mental disorders: a cross-national analysis of population reviews from 29 states. Lancet Psychiatry. 2023;10(9):668–81.
Article
Google Scholar
Almutairi S, Abohashrh M, Razzaq HH, Zulqarnain M, Namoun A, Khan F. A hybrid deep learning model for predicting depression symptoms from large-scale textual dataset. IEEE Access. 2024. https://doi.org/10.1109/ACCESS.2024.3496741.
Article
Google Scholar
Battaglia S, Nazzi C, Thayer JF. Fear-induced bradycardia in mental disorders: foundations, current advances, future perspectives. Neurosci Biobehav Rev. 2023;149:105163.
Article
Google Scholar
Ravan M, Noroozi A, Sanchez MM, Borden L, Alam N, Flor-Henry P, et al. Diagnostic deep learning models that utilize resting EEG to differentiate key depressive disorder, bipolar disorder, and schizophrenia from each other and healthy volunteers. J Affect Disord. 2024;346:285–98.
Article
Google Scholar
Tamilarasi K, Pavitra S. Detecting schizophrenia from healthy control using machine learning and EEG signals. In: 2024 international conference on expert clouds and applications (ICOECA). IEEE; 2024. pp. 434–442.
Zulqarnain M, Shah H, Ghazali R, Alqahtani O, Sheikh R, Asadullah M. Attention aware deep learning approaches for an efficient stress classification model. Brain Sci. 2023;13(7):994.
Article
Google Scholar
Jalan A, Mishra D, Marisha, Gupta M. Diagnosis of schizophrenia using feature extraction from EEG signals based on Markov transition fields and deep learning. J Biomimetics. 2025;10(7):449.
Article
Google Scholar
Bajpai A, Kesaria A, Briskilal J. Schizophrenia detection using electroencephalography signals using deep learning. In: 2024 International conference on current trends in advanced computing (ICCTAC). IEEE; 2024. pp. 1–6.
Türk Ö, Aldemir E, Acar E, Ertuğrul ÖF. Diagnosis of schizophrenia based on transformation from EEG sub-bands to the image with deep learning architecture. Soft Comput. 2024;28(9):6607–17.
Article
Google Scholar
Ranjan R, Sahana BC, Bhandari AK. Deep learning models for diagnosis of schizophrenia using EEG signals: emerging trends, challenges, and prospects. Arch Comput Methods Eng. 2024;31(4):2345–84.
Article
Google Scholar
Zhang J, Rao VM, Tian Y, Yang Y, Acosta N, Wan Z, et al. Detecting schizophrenia with 3D structural brain MRI using deep learning. Sci Rep. 2023;13(1):14433.
Article
Google Scholar
Shen M, Wen P, Song B, Li Y. 3D convolutional neural network for schizophrenia detection using as EEG-based functional brain network. Biomed Signal Process Control. 2024;89:105815.
Article
Google Scholar
Tamilarasi S, Rajangam V. Multimodal MRI analysis for schizophrenia classification using machine learning algorithm. In: 2024 international conference on emerging techniques in computational intelligence (ICETCI). IEEE; 2024. pp. 451–458.
Shoeibi A, Sadeghi D, Moridian P, Ghassemi N, Heras J, Alizadehsani R, et al. Automatic diagnosis of schizophrenia in EEG signals using CNN-LSTM models. Front Neuroinform. 2021;15:777977.
Article
Google Scholar
Jafari M, Sadeghi D, Shoeibi A, Alinejad-Rokny H, Beheshti A, García DL, et al. Empowering precision medicine: AI-driven schizophrenia diagnosis via EEG signals: a comprehensive review from 2002–2023. Appl Intell. 2024;54(1):35–79.
Article
Google Scholar
Sharma M, Patel RK, Garg A, SanTan R, Acharya UR. Automated detection of schizophrenia using deep learning: a review for the last decade. Physiol Meas. 2023;44(3):03TR01.
Article
Google Scholar
Sun J, Cao R, Zhou M, Hussain W, Wang B, Xue J, et al. A hybrid deep neural network for classification of schizophrenia using EEG data. Sci Rep. 2021;11(1):4706.
Article
Google Scholar
Zhu C, Tan Y, Yang S, Miao J, Zhu J, Huang H, et al. Temporal dynamic synchronous functional brain network for schizophrenia classification and lateralization analysis. IEEE Trans Med Imaging. 2024. https://doi.org/10.1109/TMI.2024.3419041.
Article
Google Scholar
Wang S, Tang H, Himeno R, Solé-Casals J, Caiafa CF, Han S, et al. Optimizing graph neural network architectures for schizophrenia spectrum disorder prediction using evolutionary algorithms. Comput Methods Programs Biomed. 2024;257:108419.
Article
Google Scholar
Shams AM, Jabbari S. A deep learning approach for diagnosis of schizophrenia disorder via data augmentation based on convolutional neural network and long short-term memory. Biomed Eng Lett. 2024;14(4):663–75.
Article
Google Scholar
Divya V, Kumar SS, Krishnan VG, Kumar M. Signal conducting system with effective optimization using deep learning for schizophrenia classification. Comput Syst Sci Eng. 2023;45(2):1869–86.
Article
Google Scholar
Chen Z, Yan T, Wang E, Jiang H, Tang Y, Yu X, et al. Detecting abnormal brain regions in schizophrenia using structural MRI via machine learning. Comput Intell Neurosci. 2020;2020(1):6405930.
Google Scholar
Naira CAT, Jos C. Classification of people who suffer schizophrenia and healthy people by EEG signals using deep learning. Int J Adv Comput Sci Appl. 2019;10(10).
Bagherzadeh S, Shahabi MS, Shalbaf A. Detection of schizophrenia using hybrid of deep learning and brain effective connectivity image from electroencephalogram signal. Comput Biol Med. 2022;146:105570.
Article
Google Scholar
Oh SL, Vicnesh J, Ciaccio EJ, Yuvaraj R, Acharya UR. Deep convolutional neural network model for automated diagnosis of schizophrenia using EEG signals. Appl Sci. 2019;9(14):2870.
Article
Google Scholar
Zhang R, Zeng Y, Tong L, Shu J, Lu R, Yang K, et al. ERP-wgan: a data augmentation method for EEG single-trial detection. J Neurosci Methods. 2022;376:109621.
Article
Google Scholar
Aslan Z, Akin M. Automatic detection of schizophrenia by applying deep learning over spectrogram images of EEG signals. Traitement du Signal. 2020. https://doi.org/10.18280/ts.370209.
Article
Google Scholar
Beño-Ruiz-de-la-Sierra RM, Arjona-Valladares A, Hernández-García M, Fernández-Linsenbarth I, Díez Á, Fondevila Estevez S, et al. Corollary discharge dysfunction as a possible substrate of anomalous self-experiences in schizophrenia. Schizophr Bull. 2024;50(5):1137–46.
Article
Google Scholar
Mayeli A, Al Zoubi O, Henry K, Wong CK, White EJ, Luo Q, et al. Automated pipeline for EEG artifact reduction (APPEAR) recorded during fMRI. J Neural Eng. 2021;18(4):0460b4.
Article
Google Scholar
Kang X, Handayani DOD, Yaacob H. Comparison between Butterworth bandpass and stationary wavelet transform filter for electroencephalography signal. In: IOP conference series: materials science and engineering, vol. 1077, No. 1, IOP Publishing; 2021. p. 012024.
Kumar A, Panwar AS. Human mental state detection using modified convolutional neural network with leaky rectified linear unit. In: 2024 IEEE region 10 symposium (TENSYMP). IEEE; 2024. pp. 1–6.
Zulqarnain M, Ghazali R, Shah H, Ismail LH, Alsheddy A, Mahmud M. A deep two-state gated recurrent unit for particulate matter (PM 2.5) concentration forecasting. Comput Mater Continua 2022;71(2).
Zulqarnain M, Ghazali R, Aamir M, Hassim YMM. An efficient two-state GRU based on feature attention mechanism for sentiment analysis. Multimed Tools Appl. 2024;83(1):3085–110.
Article
Google Scholar
Parmaksiz H, Yuzgec U, Dokur E, Erdogan N. Mutation based improved dragonfly optimization algorithm for a neuro-fuzzy system in short term wind speed forecasting. Knowl-Based Syst. 2023;268:110472.
Article
Google Scholar
Sobahi N, Ari B, Cakar H, Alcin OF, Sengur A. A new signal to image mapping procedure and convolutional neural networks for efficient schizophrenia detection in EEG recordings. IEEE Sens J. 2022;22(8):7913–9.
Article
Google Scholar
Phang CR, Noman F, Hussain H, Ting CM, Ombao H. A multi-domain connectome convolutional neural network for identifying schizophrenia from EEG connectivity patterns. IEEE J Biomed Health Inform. 2019;24(5):1333–43.
Article
Google Scholar
Saadatinia M, Salimi-Badr A. An explainable deep learning-based method for schizophrenia diagnosis using generative data-augmentation. IEEE Access. 2024. https://doi.org/10.1109/ACCESS.2024.3428847.
Article
Google Scholar
Siuly S, Khare SK, Bajaj V, Wang H, Zhang Y. A computerized method for automatic detection of schizophrenia using EEG signals. IEEE Trans Neural Syst Rehabil Eng. 2020;28(11):2390–400.
Article
Google Scholar
Khare SK, Bajaj V, Siuly S, Sinha GR. Classification of schizophrenia patients through empirical wavelet transformation using electroencephalogram signals. In: Modelling and Analysis of Active Biopotential Signals in Healthcare, vol. 1. Bristol, UK: IOP Publishing; 2020. p. 1–1.
Google Scholar
Agarwal M, Singhal A. A gaussian filtering approach for accurate detection of schizophrenia. Iran J Sci Technol Trans Electr Eng. 2024;48(4):1453–62.
Article
Google Scholar
Roach B. EEG data from basic sensory task in schizophrenia–button press and auditory tone event related potentials from 81 human subjects. Kaggle. Available online https://www.kaggle.com/broach/button-tone-sz. Accessed on 12 Feb 2022.
Shim M, Lee SH, Hwang HJ. Inflated prediction accuracy of neuropsychiatric biomarkers caused by data leakage in feature selection. Sci Rep. 2021;11(1):7980.
Article
Google Scholar
Rosenblatt M, Tejavibulya L, Jiang R, Noble S, Scheinost D. Data leakage inflates prediction performance in connectome-based machine learning models. Nat Commun. 2024;15(1):1829.
Article
Google Scholar
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