What is the clinical evidence from this study?

Study design: Observational. Population: acute chest pain (n=1188). Intervention: deep learning model based on 12-lead ECGs vs. physician interpretation. Primary outcome: diagnostic performance for STEMI and NSTEMI (null, 95% CI null, p=<0.001).

What question did this study set out to answer?

The aim is to develop and evaluate an AI-based model for interpreting ECGs in emergency chest pain cases.

March 13, 2026Open Access

Development and evaluation of an artificial intelligence-based electrocardiogram prediction model for emergency chest pain patients

Q: What are the key findings of this study?

The deep learning model achieved a diagnostic accuracy of 96.0% for STEMI and 89.1% for NSTEMI, significantly faster than physician interpretation (0.24 ± 0.08s vs. 23.84 ± 9.45s, p < 0.001).

Q: What question did this study set out to answer?

The aim is to develop and evaluate an AI-based model for interpreting ECGs in emergency chest pain cases.

Key Result

The deep learning model achieved a diagnostic accuracy of 96.0% for STEMI and 89.1% for NSTEMI, significantly faster than physician interpretation (0.24 ± 0.08s vs. 23.84 ± 9.45s, p < 0.001).

Key Points

The aim is to develop and evaluate an AI-based model for interpreting ECGs in emergency chest pain cases.
Included 1,188 patients with acute chest pain from an emergency department.
Used standard 12-lead ECGs, clinical information, and diagnoses for model training.
Developed a convolutional neural network with a channel attention mechanism.
Assessed model performance using accuracy, precision, recall, F1-score, and AUC.
Model achieved AUC values of 0.986 for STEMI and 0.916 for NSTEMI.
Superior diagnostic accuracy compared to traditional interpretation methods.
Inference time of 0.24 seconds was significantly faster than manual interpretation.
Detection for UA and AD showed high sensitivity but low precision.

Study Design

Type

Observational (n=1,188)

Multicenter

Yes

Structured PICO

Does an AI-based 12-lead ECG prediction model improve diagnostic accuracy and speed for emergency department patients with acute chest pain compared to expert cardiologists?

Population

1.188 pacientes adultos (≥18 anos) apresentando dor no peito aguda no pronto-socorro do Segundo Hospital Xiangya da Universidade Central do Sul. Exclusões: histórico de cirurgia cardíaca nos últimos 3 meses, uso atual de digoxina ou agentes antiarrítmicos, e gravidez ou lactação.

Intervention

Rede neural convolucional de aprendizado profundo (CNN) incorporando um mecanismo de atenção a canais para interpretação automatizada de ECG de 12 derivações.

Comparator

Interpretação manual por dois cardiologistas independentes e cegos (avaliada em um subconjunto de 550 ECGs).

Outcome

Desempenho diagnóstico (acurácia, precisão, recall, F1-score, AUC) para diferenciar infarto do miocárdio com elevação do segmento ST (STEMI), infarto do miocárdio sem elevação do segmento ST (NSTEMI), angina instável (UA) e dissecção aórtica (AD) de ECGs normais.

Um modelo de ECG de 12 derivações baseado em IA fornece detecção rápida e altamente precisa de STEMI e NSTEMI em pacientes com dor no peito na emergência, embora tenha dificuldades com os recursos não específicos do ECG de angina instável e dissecção aórtica.

Main Result

Effect estimate: null (95% CI null)

Absolute Event Rate: 96% vs 94.5%

p-value: p=<0.001

Limitations

The model's performance for unstable angina and aortic dissection was limited due to non-specific ECG features.
Single-center study limits generalizability.

Abstract

Background/Objectives Rapid triage and etiological differentiation are critical for patients with acute chest pain in the emergency department. The 12-lead electrocardiogram (ECG), as a non-invasive, readily available, and cost-effective diagnostic modality, provides immediate information and serves as the first-line tool for clinical evaluation. However, ECG interpretation remains highly dependent on clinician expertise and is subject to inter-observer variability. Artificial intelligence (AI)-based analytical methods can deliver automated, consistent, and real-time assessment, thereby potentially enhancing diagnostic accuracy and facilitating timely clinical decision-making. Methods This study included 1,188 patients with acute chest pain who visited the emergency department in the Second Xiangya Hospital of Central South University, between March 2024 and March 2025. Standard 12-lead ECGs, clinical information, and final diagnoses were collected. After data preprocessing, a convolutional neural network (CNN) incorporating a channel attention mechanism was developed and trained. Model performance was assessed using accuracy, precision, recall, F1-score, area under the curve (AUC), and confusion matrices. Additionally, a blinded comparative evaluation was conducted against expert cardiologists. Results The model demonstrated excellent discriminative capability for ST-elevation myocardial infarction (STEMI) and non-ST-elevation myocardial infarction (NSTEMI), with AUC values of 0.986 and 0.916, respectively. For STEMI, all performance metrics indicated superior diagnostic accuracy, and inference time was significantly shorter than manual interpretation (0.24 ± 0.08 s, p 0.001). However, detection performance for unstable angina (UA) and aortic dissection (AD) remained suboptimal, characterized by high sensitivity but relatively low precision. Conclusions The deep learning model based on 12-lead ECGs enables rapid and reliable detection of STEMI and NSTEMI, highlighting its potential as a valuable clinical decision-support tool in emergency department. Nevertheless, the recognition of UA and AD remains limited due to non-specific or transient electrophysiological features.

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