Establishment of a predictive model for antidepressant efficacy based on machine learning | Health Decision

Establishment of a predictive model for antidepressant efficacy based on machine learning

Authors

  • Yiyao Liu
  • Huitong Ni
  • Teng Zhi
  • Ziqi Zhao
  • Xiaoxi Zeng
  • Ming Hu
  • Zhiang Wu

DOI:

https://doi.org/10.54844/hd.2024.0012

Keywords:

predictive model, machine learning, antidepressant efficacy, depressive patients, clinical practice

Abstract

Objective: Establishing a model can accurately predict the depressive patient’s response to different drugs, thereby providing

personalized treatment plans to improve treatment outcomes.

Methods: Depressive patients who have taken Paroxetine hydrochloride or Venlafaxine hydrochloride or Agomelatine at a

hospital in Sichuan Province are the subjects. By analyzing their medical records, medication histories, and basic information,

an predictive model is constructed to predict the efficacy of antidepressant medications based on eXtreme Gradient Boosting.

Results: For the prediction model of Paroxetine hydrochloride, 52 variables selected by the model were used to construct an

efficient predictive model. In the training set, the model achieved an AUC value of 0.6354 and a K-S value of 0.1944, indicating

good performance in correctly classifying positive and negative samples and distinguishing different predictive probability

thresholds. In the validation set, the AUC was 0.6065, and K-S was 0.1847, confirming the model’s effectiveness on new data.

Compared to actual clinical data, the efficacy of sertraline hydrochloride was approximately 61.9%. The model’s predictions

aligned well with real-world data, reinforcing its reliability and practicality. As for venlafaxine hydrochloride, the model achieved

an AUC of 0.5745 and K-S of 0.149 on the training set, while the validation set showed an AUC of 0.5298 and K-S of 0.0597.

These results suggest that the model’s performance in predicting venlafaxine hydrochloride is mediocre. Comparing with

clinical data, the efficacy of venlafaxine hydrochloride was approximately 68.9%, indicating a discrepancy between the model’s

predictions and actual outcomes, possibly due to the uneven distribution of the training set samples. As for agomelatine, due

to the insufficient number of agomelatine samples collected at the sample hospital (less than 200), an effective predictive model

could not be established.

Conclusion: In clinical practice, doctors can make more informed treatment decisions and achieve personalized antidepressant

therapy with the assistance of this model.

Key words: predictive model, machine learning, antidepressant efficacy, depressive patients, clinical practice

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Published

2024-07-12

How to Cite

1.
Liu Y, Ni H, Zhi T, Zhao Z, Zeng X, Hu M, Wu Z. Establishment of a predictive model for antidepressant efficacy based on machine learning. Health Decision. 2024;2(S1). doi:10.54844/hd.2024.0012

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ABSTRACT

Establishment of a predictive model for antidepressant efficacy based on machine learning


Yiyao Liu1,2, Huitong Ni1, Teng Zhi1, Ziqi Zhao1, Xiaoxi Zeng2, Ming Hu1*, Zhiang Wu3*

1West China School of Pharmacy, Sichuan University, Chengdu 610041, Sichuang Province, China

2West China Biomedical Big Data Center, West China Hospital, Sichuan University, Chengdu 610041, Sichuang Province, China

3Yeehong Business School, Shenyang Pharmaceutical University, Beijing 100055, China


*Corresponding Author:

Zhiang Wu, E-mail: wuzhiang@yeehongedu.cn; Ming Hu, E-mail: huming@scu.edu.cn


Received: 15 June 2024 Published: 15 July 2024


ABSTRACT

Objective: Establishing a model can accurately predict the depressive patient’s response to different drugs, thereby providing personalized treatment plans to improve treatment outcomes.

Methods: Depressive patients who have taken Paroxetine hydrochloride or Venlafaxine hydrochloride or Agomelatine at a hospital in Sichuan Province are the subjects. By analyzing their medical records, medication histories, and basic information, an predictive model is constructed to predict the efficacy of antidepressant medications based on eXtreme Gradient Boosting.

Results: For the prediction model of Paroxetine hydrochloride, 52 variables selected by the model were used to construct an efficient predictive model. In the training set, the model achieved an AUC value of 0.6354 and a K-S value of 0.1944, indicating good performance in correctly classifying positive and negative samples and distinguishing different predictive probability thresholds. In the validation set, the AUC was 0.6065, and K-S was 0.1847, confirming the model’s effectiveness on new data. Compared to actual clinical data, the efficacy of sertraline hydrochloride was approximately 61.9%. The model’s predictions aligned well with real-world data, reinforcing its reliability and practicality. As for venlafaxine hydrochloride, the model achieved an AUC of 0.5745 and K-S of 0.149 on the training set, while the validation set showed an AUC of 0.5298 and K-S of 0.0597. These results suggest that the model’s performance in predicting venlafaxine hydrochloride is mediocre. Comparing with clinical data, the efficacy of venlafaxine hydrochloride was approximately 68.9%, indicating a discrepancy between the model’s predictions and actual outcomes, possibly due to the uneven distribution of the training set samples. As for agomelatine, due to the insufficient number of agomelatine samples collected at the sample hospital (less than 200), an effective predictive model could not be established.

Conclusion: In clinical practice, doctors can make more informed treatment decisions and achieve personalized antidepressant therapy with the assistance of this model.

Key words: predictive model, machine learning, antidepressant efficacy, depressive patients, clinical practice