DDSB: An Unsupervised and Training-free Method for Phase Detection in Echocardiography

Standalone Note here

Introduction:

• Accurate identification of End-Diastolic (ED) and End-Systolic (ES) frames is crucial for cardiac function assessment through echocardiography.
• Traditional methods face limitations like data dependency, expert annotations, and lack of robustness.

Early Techniques:

• Manual selection or simplistic criteria failed to capture heart dynamics accurately.
• QRS complex onset and T wave's end were used but lacked practicality in emergency scenarios.
• Attempts at quantifying similarity between ED and ES frames required manual selection.

Deep Learning Advancements:

• Classification-based and regression-based models evolved significantly.
• Recurrent Neural Networks (RNNs) integrated with CNNs showed promise.
• Various models like TempReg-Net, DenseNet, GRU were explored for optimal results.

Proposed Method - DDSB:

• Unsupervised and training-free approach for phase detection.
• Utilizes distance-based strategy to enhance model robustness.
• Achieves comparable performance on Echo-dynamic and CAMUS datasets.

Dataset and Metrics:

• Adjustments made to CAMUS and Echo-dynamic datasets for experiments.
• Evaluation based on mean absolute error (MAE) in frames for ED/ES detection.

Results and Discussion:

• Comparative analysis with state-of-the-art methods on CAMUS and Echo-dynamic datasets.
• Cross-dataset evaluation showcasing generalization capabilities of DDSB.

Ablation Study:

• Effects of k directions on model performance stability.
• Impact of change threshold α on method effectiveness.

Conclusion:

• DDSB offers accurate phase detection without the need for extensive resources or training data.