Classification of Heart Failure Using Machine Learning: A Comparative Study

被引:1
作者
Chulde-Fernandez, Bryan [1 ]
Enriquez-Ortega, Denisse [1 ]
Guevara, Cesar [2 ]
Navas, Paulo [1 ]
Tirado-Espin, Andres [3 ]
Vizcaino-Imacana, Paulina [4 ]
Villalba-Meneses, Fernando [1 ]
Cadena-Morejon, Carolina [3 ]
Almeida-Galarraga, Diego [1 ]
Acosta-Vargas, Patricia [5 ]
机构
[1] Yachay Tech Univ, Sch Biol Sci & Engn, Hacienda San Jose S-N, San Miguel De Urcuqui 100119, Ecuador
[2] Cunef Univ, Quantitat Methods Dept, Madrid 28040, Spain
[3] Univ Yachay Tech, Sch Math & Computat Sci, San Miguel De Urcuqui 100119, Ecuador
[4] UIDE Int Univ Ecuador, Fac Tech Sci, Sch Comp Sci, Quito 170501, Ecuador
[5] Univ Las Amer, Intelligent & Interact Syst Lab, Quito 170125, Ecuador
来源
LIFE-BASEL | 2025年 / 15卷 / 03期
关键词
heart failure; machine learning; classification; feature extraction; diagnosis; CHALLENGES; MANAGEMENT; DISEASE;
D O I
10.3390/life15030496
中图分类号
Q [生物科学];
学科分类号
07 ; 0710 ; 09 ;
摘要
Several machine learning classification algorithms were evaluated using a dataset focused on heart failure. Results obtained from logistic regression, random forest, decision tree, K-nearest neighbors, and multilayer perceptron (MLP) were compared to obtain the best model. The random forest method obtained specificity = 0.93, AUC = 0.97, and Matthews correlation coefficient (MCC) = 0.83. The accuracy was high; therefore, it was considered the best model. On the other hand, K-nearest neighbors and MLP (multi-layer perceptron) showed lower accuracy rates. These results confirm the effectiveness of the random forest method in identifying heart failure cases. This study underlines that the number of features, feature selection and quality, model type, and hyperparameter fit are also critical in these studies, as well as the importance of using machine learning techniques.
引用
收藏
页数:18
相关论文
共 48 条
[31]  
Pedrero V, 2021, REV MED CHILE, V149, P248, DOI 10.4067/s0034-98872021000200248
[32]   Heart failure: preventing disease and death worldwide [J].
Ponikowski, Piotr ;
Anker, Stefan D. ;
AlHabib, Khalid F. ;
Cowie, Martin R. ;
Force, Thomas L. ;
Hu, Shengshou ;
Jaarsma, Tiny ;
Krum, Henry ;
Rastogi, Vishal ;
Rohde, Luis E. ;
Samal, Umesh C. ;
Shimokawa, Hiroaki ;
Siswanto, Bambang Budi ;
Sliwa, Karen ;
Filippatos, Gerasimos .
ESC HEART FAILURE, 2014, 1 (01) :4-25
[33]  
Princy RJP, 2020, PROCEEDINGS OF THE INTERNATIONAL CONFERENCE ON INTELLIGENT COMPUTING AND CONTROL SYSTEMS (ICICCS 2020), P570, DOI [10.1109/ICICCS48265.2020.9121169, 10.1109/iciccs48265.2020.9121169]
[34]   PREDICTIVE ANALYSIS OF HEART DISEASES WITH MACHINE LEARNING APPROACHES [J].
Ramesh, T. R. ;
Lilhore, Umesh Kumar ;
Poongodi, M. ;
Simaiya, Sarita ;
Kaur, Amandeep ;
Hamdi, Mounir .
MALAYSIAN JOURNAL OF COMPUTER SCIENCE, 2022, :132-150
[35]   ASSESSING PREDICTIVE ACCURACY - HOW TO COMPARE BRIER SCORES [J].
REDELMEIER, DA ;
BLOCH, DA ;
HICKAM, DH .
JOURNAL OF CLINICAL EPIDEMIOLOGY, 1991, 44 (11) :1141-1146
[36]  
Rigatti Steven J, 2017, J Insur Med, V47, P31, DOI 10.17849/insm-47-01-31-39.1
[37]  
Saikumar K., 2020, International Journal of Pharmaceutical Research, V12, P3904, DOI [10.31838/IJPR/2020.SP2.482, DOI 10.31838/IJPR/2020.SP2.482, 10.31838/ijpr/2020.SP2.482]
[38]   Active learning for logistic regression: an evaluation [J].
Schein, Andrew I. ;
Ungar, Lyle H. .
MACHINE LEARNING, 2007, 68 (03) :235-265
[39]  
Shah D., 2020, SN COMPUT SCI, V1, P1, DOI [10.1007/s42979-020-00365-y, DOI 10.1007/S42979-020-00365-Y]
[40]  
Shinde PP, 2018, 2018 FOURTH INTERNATIONAL CONFERENCE ON COMPUTING COMMUNICATION CONTROL AND AUTOMATION (ICCUBEA)
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