Application of machine learning in prognosis and trajectory of post-traumatic stress disorder in children

doi:10.3724/SP.J.1042.2022.00851

Abstract

Abstract:

Post-traumatic stress disorder (PTSD) could have negative effects on the development of children, and its impact can even last into adulthood. The traditional method to identify and diagnose PTSD in children is for the clinician or researcher to compares the symptoms with the criteria in the diagnostic manual. Therefore, the child who meets the symptom criteria could be diagnosed with PTSD. In addition, risk factors for PTSD in children are identified by traditional multiple regression methods using hypotheses based on previous literature or experience. However, these methods rely on clinicians or researchers' personal experience greatly. Moreover, identifying child PTSD is subjective, and the selected statistical method could impact the predicted risk factors. Generally, researchers use prediction method based on regression models. However, the identification of risk factors is not comprehensive enough, which needs a lot of empirical data to discuss. Thus, machine learning, as an emerging method to deal with big data, is a data-driven method to summarize rules and features based on existing data. Through continuous data training, the program could make its own judgment on whether children in new data have PTSD, which is more objective, faster and more efficient than human diagnosis. When predicting risk factors, machine learning models have also developed from traditional decision trees and regression to the field of deep learning, with greatly improves the accuracy of diagnosis and simultaneous processing of multi-dimensional variables. Therefore, using machine learning to predict children's PTSD could make up for the disadvantages of traditional prognosis investigation, which is difficult to follow for a long time and has large missing values, etc. Machine learning may also better solve other related problems, such as failing to detect PTSD symptoms in time and missing the optimal healing period due to the late-onset of PTSD in children. The application of machine learning in predicting the outcome of children’s PTSD results could be divided into two methods. One is the "classification" of supervised learning, which is the possible classification result of the artificially set training data sets. The other is "clustering", that is, the data in the training set would be automatically divided into several groups based on characteristics or some potential concepts. Each group is called a cluster, and then the commonalities of these clusters are artificially summarized through unsupervised learning. Although machine learning has some advantages in the diagnosis and recognition of PTSD in children, its application is still in the initial stage, with opportunities and challenges coexisting. It is worth noting that machine learning also has limitations such as a single algorithm, limited accuracy of prediction, different prediction results based on different models, relatively insufficient research on treatment methods, and difficulty in collecting children's PTSD indicators. In the future, researchers need to further improve the accuracy of machine learning diagnosis and children’s PTSD recognition, and explore more combinations of machine learning and traditional diagnosis methods. With the development of the Chinese medical industry, machine learning has shown great potential in the field of psychiatry. It is believed that the practical applications of machine learning in children’s PTSD would be developed rapidly in the future, which could provide guidance and suggestions for the early prevention or treatment of children’s PTSD.

Key words: machine learning, post-traumatic stress disorder, prognosis, children

CLC Number:

R395

LIU Xiaohan, CHEN Minglong, GUO Jing. Application of machine learning in prognosis and trajectory of post-traumatic stress disorder in children[J]. Advances in Psychological Science, 2022, 30(4): 851-862.

Figures/Tables 3

References 55

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时间	国家	文献	样本量	年龄	主要变量	变量数量	因变量测量	分类器	训练方法	评价指标
2017	美国	Saxe et al., 2017	165	7~18	儿童发展、人口统计学信息、父母症状、压力、基因、神经内分泌和心理生理反应、受伤程度、儿童症状和功能	105个	加州大学洛杉矶分校创伤后应激障碍反应指数	SVM;RF; Lasso回归	5折交叉验证	AUC = 0.75
2020	中国	Ge et al., 2020	2099	8~19	人口统计学信息、地震经历、睡眠、心情、躯体症状和日常功能	5个方面	修订版儿童事件影响量表	CART	5折交叉验证	AUC = 0.66 ~ 0.80
2020	中国	Li et al., 2020	46	11~16	静息态功能磁共振成像：海马亚区——CA1、CA2、CA3、CA4、齿状回、下托及海马伞等	1个方面	创伤后应激障碍评估表	RF	5折交叉验证	AUC = 0.65
2020	土耳其	Ucuz et al., 2020	170	5~17	年龄等人口统计学信息、虐待类型、虐待次数等虐待相关信息、事件报告者	10个	精神障碍诊断和统计手册	ANNs	3折交叉验证	准确度：99.2%
2020	土耳其	Gokten & Uyulan, 2021	372	均数13.77	性别年龄等人口统计学信息、吸烟饮酒等生活习惯信息、被虐待的经历程度信息、精神状态	20个	精神障碍诊断和统计手册	RF	10折交叉验证	AUC = 0.76

时间	国家	文献	样本量	年龄	主要变量	变量数量	因变量测量	分类器	训练方法	评价指标
2017	美国	Saxe et al., 2017	165	7~18	儿童发展、人口统计学信息、父母症状、压力、基因、神经内分泌和心理生理反应、受伤程度、儿童症状和功能	105个	加州大学洛杉矶分校创伤后应激障碍反应指数	SVM;RF; Lasso回归	5折交叉验证	AUC = 0.75
2020	中国	Ge et al., 2020	2099	8~19	人口统计学信息、地震经历、睡眠、心情、躯体症状和日常功能	5个方面	修订版儿童事件影响量表	CART	5折交叉验证	AUC = 0.66 ~ 0.80
2020	中国	Li et al., 2020	46	11~16	静息态功能磁共振成像：海马亚区——CA1、CA2、CA3、CA4、齿状回、下托及海马伞等	1个方面	创伤后应激障碍评估表	RF	5折交叉验证	AUC = 0.65
2020	土耳其	Ucuz et al., 2020	170	5~17	年龄等人口统计学信息、虐待类型、虐待次数等虐待相关信息、事件报告者	10个	精神障碍诊断和统计手册	ANNs	3折交叉验证	准确度：99.2%
2020	土耳其	Gokten & Uyulan, 2021	372	均数13.77	性别年龄等人口统计学信息、吸烟饮酒等生活习惯信息、被虐待的经历程度信息、精神状态	20个	精神障碍诊断和统计手册	RF	10折交叉验证	AUC = 0.76