Literature DB >> 32134388

A Deep-Learning Algorithm (ECG12Net) for Detecting Hypokalemia and Hyperkalemia by Electrocardiography: Algorithm Development.

Chin-Sheng Lin1, Chin Lin2,3,4, Wen-Hui Fang5, Chia-Jung Hsu6, Sy-Jou Chen7,8, Kuo-Hua Huang6, Wei-Shiang Lin1, Chien-Sung Tsai9, Chih-Chun Kuo10, Tom Chau11, Stephen Jh Yang12, Shih-Hua Lin2,13.   

Abstract

BACKGROUND: The detection of dyskalemias-hypokalemia and hyperkalemia-currently depends on laboratory tests. Since cardiac tissue is very sensitive to dyskalemia, electrocardiography (ECG) may be able to uncover clinically important dyskalemias before laboratory results.
OBJECTIVE: Our study aimed to develop a deep-learning model, ECG12Net, to detect dyskalemias based on ECG presentations and to evaluate the logic and performance of this model.
METHODS: Spanning from May 2011 to December 2016, 66,321 ECG records with corresponding serum potassium (K+) concentrations were obtained from 40,180 patients admitted to the emergency department. ECG12Net is an 82-layer convolutional neural network that estimates serum K+ concentration. Six clinicians-three emergency physicians and three cardiologists-participated in human-machine competition. Sensitivity, specificity, and balance accuracy were used to evaluate the performance of ECG12Net with that of these physicians.
RESULTS: In a human-machine competition including 300 ECGs of different serum K+ concentrations, the area under the curve for detecting hypokalemia and hyperkalemia with ECG12Net was 0.926 and 0.958, respectively, which was significantly better than that of our best clinicians. Moreover, in detecting hypokalemia and hyperkalemia, the sensitivities were 96.7% and 83.3%, respectively, and the specificities were 93.3% and 97.8%, respectively. In a test set including 13,222 ECGs, ECG12Net had a similar performance in terms of sensitivity for severe hypokalemia (95.6%) and severe hyperkalemia (84.5%), with a mean absolute error of 0.531. The specificities for detecting hypokalemia and hyperkalemia were 81.6% and 96.0%, respectively.
CONCLUSIONS: A deep-learning model based on a 12-lead ECG may help physicians promptly recognize severe dyskalemias and thereby potentially reduce cardiac events. ©Chin-Sheng Lin, Chin Lin, Wen-Hui Fang, Chia-Jung Hsu, Sy-Jou Chen, Kuo-Hua Huang, Wei-Shiang Lin, Chien-Sung Tsai, Chih-Chun Kuo, Tom Chau, Stephen JH Yang, Shih-Hua Lin. Originally published in JMIR Medical Informatics (http://medinform.jmir.org), 05.03.2020.

Entities:  

Keywords:  artificial intelligence; electrocardiogram; machine learning; potassium homeostasis; sudden cardiac death

Year:  2020        PMID: 32134388     DOI: 10.2196/15931

Source DB:  PubMed          Journal:  JMIR Med Inform


  17 in total

1.  Development and Validation of an Artificial Intelligence Electrocardiogram Recommendation System in the Emergency Department.

Authors:  Dung-Jang Tsai; Shih-Hung Tsai; Hui-Hsun Chiang; Chia-Cheng Lee; Sy-Jou Chen
Journal:  J Pers Med       Date:  2022-04-27

2.  Noninvasive Screening Tool for Hyperkalemia Using a Single-Lead Electrocardiogram and Deep Learning: Development and Usability Study.

Authors:  Erdenebayar Urtnasan; Jung Hun Lee; Byungjin Moon; Hee Young Lee; Kyuhee Lee; Hyun Youk
Journal:  JMIR Med Inform       Date:  2022-06-03

Review 3.  Artificial Intelligence in Cardiology-A Narrative Review of Current Status.

Authors:  George Koulaouzidis; Tomasz Jadczyk; Dimitris K Iakovidis; Anastasios Koulaouzidis; Marc Bisnaire; Dafni Charisopoulou
Journal:  J Clin Med       Date:  2022-07-05       Impact factor: 4.964

4.  Artificial intelligence for detecting electrolyte imbalance using electrocardiography.

Authors:  Joon-Myoung Kwon; Min-Seung Jung; Kyung-Hee Kim; Yong-Yeon Jo; Jae-Hyun Shin; Yong-Hyeon Cho; Yoon-Ji Lee; Jang-Hyeon Ban; Ki-Hyun Jeon; Soo Youn Lee; Jinsik Park; Byung-Hee Oh
Journal:  Ann Noninvasive Electrocardiol       Date:  2021-03-15       Impact factor: 1.468

5.  Monitoring blood potassium concentration in hemodialysis patients by quantifying T-wave morphology dynamics.

Authors:  Flavio Palmieri; Pedro Gomis; Dina Ferreira; José Esteban Ruiz; Beatriz Bergasa; Alba Martín-Yebra; Hassaan A Bukhari; Esther Pueyo; Juan Pablo Martínez; Julia Ramírez; Pablo Laguna
Journal:  Sci Rep       Date:  2021-02-16       Impact factor: 4.379

6.  Detecting Digoxin Toxicity by Artificial Intelligence-Assisted Electrocardiography.

Authors:  Da-Wei Chang; Chin-Sheng Lin; Tien-Ping Tsao; Chia-Cheng Lee; Jiann-Torng Chen; Chien-Sung Tsai; Wei-Shiang Lin; Chin Lin
Journal:  Int J Environ Res Public Health       Date:  2021-04-06       Impact factor: 3.390

7.  Deep learning and the electrocardiogram: review of the current state-of-the-art.

Authors:  Sulaiman Somani; Adam J Russak; Felix Richter; Shan Zhao; Akhil Vaid; Fayzan Chaudhry; Jessica K De Freitas; Nidhi Naik; Riccardio Miotto; Girish N Nadkarni; Jagat Narula; Edgar Argulian; Benjamin S Glicksberg
Journal:  Europace       Date:  2021-02-10       Impact factor: 5.214

8.  Electrocardiogram-Based Heart Age Estimation by a Deep Learning Model Provides More Information on the Incidence of Cardiovascular Disorders.

Authors:  Chiao-Hsiang Chang; Chin-Sheng Lin; Yu-Sheng Luo; Yung-Tsai Lee; Chin Lin
Journal:  Front Cardiovasc Med       Date:  2022-02-08

9.  Point-of-care artificial intelligence-enabled ECG for dyskalemia: a retrospective cohort analysis for accuracy and outcome prediction.

Authors:  Chin Lin; Tom Chau; Chin-Sheng Lin; Hung-Sheng Shang; Wen-Hui Fang; Ding-Jie Lee; Chia-Cheng Lee; Shi-Hung Tsai; Chih-Hung Wang; Shih-Hua Lin
Journal:  NPJ Digit Med       Date:  2022-01-19

10.  Artificial Intelligence-Assisted Electrocardiography for Early Diagnosis of Thyrotoxic Periodic Paralysis.

Authors:  Chin Lin; Chin-Sheng Lin; Ding-Jie Lee; Chia-Cheng Lee; Sy-Jou Chen; Shi-Hung Tsai; Feng-Chih Kuo; Tom Chau; Shih-Hua Lin
Journal:  J Endocr Soc       Date:  2021-06-29
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