Development of interpretable machine learning models to predict in‐hospital prognosis of acute heart failure patients-Reference-Cited by-同舟云学术

Development of interpretable machine learning models to predict in‐hospital prognosis of acute heart failure patients

Published:2024-05-15 Issue: Volume: Page:
ISSN:2055-5822
Container-title:ESC Heart Failure
language:en
Short-container-title:ESC Heart Failure

Author:

Tanaka Munekazu¹²,Kohjitani Hirohiko¹²,Yamamoto Erika¹,Morimoto Takeshi³,Kato Takao¹,Yaku Hidenori¹,Inuzuka Yasutaka⁴,Tamaki Yodo⁵,Ozasa Neiko¹,Seko Yuta¹,Shiba Masayuki¹,Yoshikawa Yusuke¹,Yamashita Yugo¹,Kitai Takeshi⁶,Taniguchi Ryoji⁷,Iguchi Moritake⁸,Nagao Kazuya⁹,Kawai Takafumi¹⁰,Komasa Akihiro¹¹,Kawase Yuichi¹²,Morinaga Takashi¹³,Toyofuku Mamoru¹⁴,Furukawa Yutaka¹⁵,Ando Kenji¹³,Kadota Kazushige¹²,Sato Yukihito⁷,Kuwahara Koichiro¹⁶,Okuno Yasushi²,Kimura Takeshi¹¹⁷,Ono Koh¹,

Affiliation:

1. Department of Cardiovascular Medicine Kyoto University Graduate School of Medicine 54 Shogoin Kawahara‐cho, Sakyo‐ku Kyoto 606‐8507 Japan

2. Department of Artificial Intelligence in Healthcare and Medicine Kyoto University Graduate School of Medicine Kyoto Japan

3. Department of Clinical Epidemiology Hyogo College of Medicine Nishinomiya Japan

4. Department of Cardiovascular Medicine Shiga General Hospital Moriyama Japan

5. Division of Cardiology Tenri Hospital Tenri Japan

6. Department of Cardiovascular Medicine National Cerebral and Cardiovascular Center Suita Japan

7. Department of Cardiology Hyogo Prefectural Amagasaki General Medical Center Amagasaki Japan

8. Department of Cardiology National Hospital Organization Kyoto Medical Center Kyoto Japan

9. Department of Cardiology Osaka Red Cross Hospital Osaka Japan

10. Department of Cardiology Kishiwada City Hospital Kishiwada Japan

11. Department of Cardiology Kansai Electric Power Hospital Osaka Japan

12. Department of Cardiology Kurashiki Central Hospital Kurashiki Japan

13. Department of Cardiology Kokura Memorial Hospital Kitakyushu Japan

14. Department of Cardiology Japanese Red Cross Wakayama Medical Center Wakayama Japan

15. Department of Cardiovascular Medicine Kobe City Medical Center General Hospital Kobe Japan

16. Department of Cardiovascular Medicine Shinshu University Graduate School of Medicine Matsumoto Japan

17. Department of Cardiology Hirakata Kohsai Hospital Hirakata Japan

Abstract

AbstractAimsIn recent years, there has been remarkable development in machine learning (ML) models, showing a trend towards high prediction performance. ML models with high prediction performance often become structurally complex and are frequently perceived as black boxes, hindering intuitive interpretation of the prediction results. We aimed to develop ML models with high prediction performance, interpretability, and superior risk stratification to predict in‐hospital mortality and worsening heart failure (WHF) in patients with acute heart failure (AHF).Methods and resultsBased on the Kyoto Congestive Heart Failure registry, which enrolled 4056 patients with AHF, we developed prediction models for in‐hospital mortality and WHF using information obtained on the first day of admission (demographics, physical examination, blood test results, etc.). After excluding 16 patients who died on the first or second day of admission, the original dataset (n = 4040) was split 4:1 into training (n = 3232) and test datasets (n = 808). Based on the training dataset, we developed three types of prediction models: (i) the classification and regression trees (CART) model; (ii) the random forest (RF) model; and (iii) the extreme gradient boosting (XGBoost) model. The performance of each model was evaluated using the test dataset, based on metrics including sensitivity, specificity, area under the receiver operating characteristic curve (AUC), Brier score, and calibration slope. For the complex structure of the XGBoost model, we performed SHapley Additive exPlanations (SHAP) analysis, classifying patients into interpretable clusters. In the original dataset, the proportion of females was 44.8% (1809/4040), and the average age was 77.9 ± 12.0. The in‐hospital mortality rate was 6.3% (255/4040) and the WHF rate was 22.3% (900/4040) in the total study population. In the in‐hospital mortality prediction, the AUC for the XGBoost model was 0.816 [95% confidence interval (CI): 0.815–0.818], surpassing the AUC values for the CART model (0.683, 95% CI: 0.680–0.685) and the RF model (0.755, 95% CI: 0.753–0.757). Similarly, in the WHF prediction, the AUC for the XGBoost model was 0.766 (95% CI: 0.765–0.768), outperforming the AUC values for the CART model (0.688, 95% CI: 0.686–0.689) and the RF model (0.713, 95% CI: 0.711–0.714). In the XGBoost model, interpretable clusters were formed, and the rates of in‐hospital mortality and WHF were similar among each cluster in both the training and test datasets.ConclusionsThe XGBoost models with SHAP analysis provide high prediction performance, interpretability, and reproducible risk stratification for in‐hospital mortality and WHF for patients with AHF.

Funder

Japan Agency for Medical Research and Development

Publisher

Wiley

Link

https://onlinelibrary.wiley.com/doi/pdf/10.1002/ehf2.14834

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