Objectives
Machine learning (ML) encompasses a body of statistical approaches that can detect complex interaction patterns from multi-dimensional data. ML is gradually being adopted in medical science, for example, in treatment response prediction and diagnostic classification. Cognitive impairment is a prominent feature of schizophrenia, but is not routinely used in differential diagnosis. In this study, we investigated the predictive capacity of the Wechsler Adult Intelligence Scale IV (WAIS-IV) in differentiating schizophrenia from non-psychotic illnesses using the ML methodology. The purpose of this study was to illustrate the possibility of using ML as an aid in differential diagnosis.
Methods
The WAIS-IV test data for 434 psychiatric patients were curated from archived medical records. Using the final diagnoses based on DSM-IV as the target and the WAIS-IV scores as predictor variables, predictive diagnostic models were built using 1) linear 2) non-linear/non-parametric ML algorithms. The accuracy obtained was compared to that of the baseline model built without the WAIS-IV information.
Results
The performances of the various ML models were compared. The accuracy of the baseline model was 71.5%, but the best non-linear model showed an accuracy of 84.6%, which was significantly higher than that of non-informative random guessing (p=0.002). Overall, the models using the non-linear algorithms showed better accuracy than the linear ones.
Conclusion
The high performance of the developed models demonstrated the predictive capacity of the WAIS-IV and justified the application of ML in psychiatric diagnosis. However, the practical application of ML models may need refinement and larger-scale data collection.

1 Michel NM, "WAIS-IV profile of cognition in schizophrenia" 20 : 462-473, 2013

2 Wechsler D, "The psychometric tradition: developing the wechsler adult intelligence scale" 6 : 82-85, 1981

3 Schaefer J, "The global cognitive impairment in schizophrenia: consistent over decades and around the world" 150 : 42-50, 2013

4 Hastie T, "The elements of statistical learning:data mining, inference, and prediction" Springer Science & Business Media 2009

5 Vieta E, "The clinical implications of cognitive impairment and allostatic load in bipolar disorder" 28 : 21-29, 2013

6 Hwang ST, "Standardization of the K-WAIS-IV" Korean Psychological Association 2012

7 Seaton BE, "Sources of heterogeneity in schizophrenia:the role of neuropsychological functioning" 11 : 45-67, 2001

8 Holthausen EA, "Schizophrenic patients without neuropsychological deficits: subgroup, disease severity or cognitive compensation?" 112 : 1-11, 2002

9 Kahn RS, "Schizophrenia is a cognitive illness: time for a change in focus" 70 : 1107-1112, 2013

10 Chekroud AM, "Reevaluating the efficacy and predictability of antidepressant treatments: a symptom clustering approach" 74 : 370-378, 2017

11 R Development Core Team, "R: a language and environment for statistical computing. 3.2.4 ed"

12 Clarke B, "Principles and theory for data mining and machine learning" Springer Science & Business Media 2009

13 Fujino H, "Performance on the Wechsler Adult Intelligence Scale-III in Japanese patients with schizophrenia" 68 : 534-541, 2014

14 Dickinson D, "Overlooking the obvious: a meta-analytic comparison of digit symbol coding tasks and other cognitive measures in schizophrenia" 64 : 532-542, 2007

15 Han H, "Overcome support vector machine diagnosis overfitting" 13 (13): 145-158, 2014

16 Reichenberg A, "Neuropsychological function and dysfunction in schizophrenia and psychotic affective disorders" 35 : 1022-1029, 2009

17 Heinrichs RW, "Neurocognitive deficit in schizophrenia:a quantitative review of the evidence" 12 : 426-445, 1998

18 Koutsouleris N, "Multisite prediction of 4-week and 52-week treatment outcomes in patients with first-episode psychosis: a machine learning approach" 3 : 935-946, 2016

19 Shim M, "Machine-learningbased diagnosis of schizophrenia using combined sensor-level and source-level EEG features" 176 : 314-319, 2016

20 Jordan MI, "Machine learning: trends, perspectives, and prospects" 349 : 255-260, 2015

21 Deo RC, "Machine learning in medicine" 132 : 1920-1930, 2015

22 Johannesen JK, "Machine learning identification of EEG features predicting working memory performance in schizophrenia and healthy adults" 2 : 3-, 2016

23 McHugh ML, "Interrater reliability: the kappa statistic" 22 : 276-282, 2012

24 Harrison-Read P, "IQ tests as aids to diagnosis and management in early schizophrenia" 14 : 235-240, 2008

25 Keefe RS, "How should DSM-V criteria for schizophrenia include cognitive impairment?" 33 : 912-920, 2007

26 Dickinson D, "General and specific cognitive deficits in schizophrenia: Goliath defeats David?" 64 : 823-827, 2008

27 Dickinson D, "General and specific cognitive deficits in schizophrenia" 55 : 826-833, 2004

28 Zielesny A, "From curve fitting to machine learning: an illustrative guide to scientific data analysis and computational intelligence" Springer International Publishing 2016

29 Zhou ZH, "Ensemble methods: foundations and algorithms" CRC Press 2012

30 Sumiyoshi C, "Development of brief versions of the Wechsler Intelligence Scale for schizophrenia:considerations of the structure and predictability of intelligence" 210 : 773-779, 2013

31 Chekroud AM, "Cross-trial prediction of treatment outcome in depression:a machine learning approach" 3 : 243-250, 2016

32 Mikolas P, "Connectivity of the anterior insula differentiates participants with first-episode schizophrenia spectrum disorders from controls: a machine-learning study" 46 : 2695-2704, 2016

33 Bora E, "Cognitive impairment in euthymic major depressive disorder: a meta-analysis" 43 : 2017-2026, 2013

34 Manove E, "Cognitive impairment in bipolar disorder: an overview" 122 : 7-16, 2010

35 Kitchen H, "Cognitive impairment associated with schizophrenia: a review of the humanistic burden" 29 : 148-162, 2012

36 Bora E, "Cognitive functioning in schizophrenia, schizoaffective disorder and affective psychoses: meta-analytic study" 195 : 475-482, 2009

37 Trivedi MH, "Cognitive dysfunction in unipolar depression:implications for treatment" 152-154 : 19-27, 2014

38 Iwabuchi SJ, "Clinical utility of machinelearning approaches in schizophrenia: improving diagnostic confidence for translational neuroimaging" 4 : 95-, 2013

39 Kuhn M, "Caret: classification and regression training. R package version 6.0-68 ed"

40 Tomasik J, "Blood test for schizophrenia" 262 (262): S79-S83, 2012

41 Weickert CS, "Biomarkers in schizophrenia:a brief conceptual consideration" 35 : 3-9, 2013

42 Ravan M, "A machine learning approach using auditory odd-ball responses to investigate the effect of Clozapine therapy" 126 : 721-730, 2015

43 Keefe RS, "A longitudinal study of neurocognitive function in individuals at-risk for psychosis" 88 : 26-35, 2006

44 Allen DN, "A consideration of neuropsychologically normal schizophrenia" 9 : 56-63, 2003