BLENet: A Bio-Inspired Lightweight and Efficient Network for Left Ventricle Segmentation in Echocardiography

IF 11.1 1区工程技术 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Circuits and Systems for Video Technology Pub Date : 2025-04-07 DOI:10.1109/TCSVT.2025.3558496

Xintao Pang;Fengjuan Yao;Yanming Zhang;Yue Sun;Edmundo Patricio Lopes Lao;Chuan Lin;Patrick Cheong-Iao Pang;Wei Wang;Wei Li;Zhifan Gao;Tao Tan

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引用次数: 0

Abstract

In echocardiography, accurate segmentation of the left ventricle at end-diastole (ED) and end-systole (ES) is crucial for quantitative assessment of left ventricular ejection fraction. However, as a dynamic imaging modality requiring real-time analysis and frequently performed in various clinical settings with portable devices, this challenges mainstream approaches that primarily enhance model performance by increasing the number of parameters and computational costs, while lacking targeted optimization for its characteristics. To address these challenges, we propose BLENet, a lightweight segmentation model inspired by biological vision mechanisms. By integrating key mechanisms from biological vision systems with medical image features, our model achieves efficient and accurate segmentation. Specifically, the center-surround antagonism of retinal ganglion cells and the lateral geniculate nucleus exhibits high sensitivity to contrast variations, corresponding to the distinct contrast between the ventricular chamber (hypoechoic) and myocardial wall (hyperechoic) in ultrasound images. Based on this, we designed an antagonistic module to enhance feature extraction in target regions. Subsequently, the directional selectivity mechanism in the V1 cortex aligns with the variable directional features of the ventricular boundary, inspiring our direction-selective module to improve segmentation accuracy. Finally, we introduce an adaptive wavelet fusion module in the decoding network to address the limited receptive field of convolutions and enhance feature integration in cardiac ultrasound. Experiments demonstrate that our model contains only 0.16M parameters and requires no pre-training. On the CAMUS dataset, it achieves Dice coefficient values of 0.951 and 0.927 for ED and ES phases respectively, while on the EchoNet-Dynamic dataset, it achieves 0.933 and 0.909, with an inference speed of 112 FPS on NVIDIA RTX 2080 Ti. Evaluation on an external clinical dataset indicates our model’s promising generalization and potential for clinical application.

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BLENet：一种生物启发的、轻量级的、高效的超声心动图左心室分割网络

超声心动图中，左心室舒张末期（ED）和收缩末期（ES）的准确分割对于左心室射血分数的定量评估至关重要。然而，作为一种动态成像模式，需要实时分析，并且经常在各种临床环境中使用便携式设备进行，这对主要通过增加参数数量和计算成本来提高模型性能的主流方法提出了挑战，同时缺乏对其特性的针对性优化。为了解决这些挑战，我们提出了BLENet，一个受生物视觉机制启发的轻量级分割模型。该模型通过将生物视觉系统的关键机制与医学图像特征相结合，实现了高效、准确的分割。具体来说，视网膜神经节细胞和外侧膝状核的中心-周围拮抗作用对对比度变化表现出高度敏感性，对应于超声图像中室室（低回声）和心肌壁（高回声）之间的明显对比。在此基础上，我们设计了一个拮抗模块来增强目标区域的特征提取。随后，V1皮层的方向选择机制与心室边界的可变方向特征相一致，启发我们的方向选择模块提高分割精度。最后，我们在解码网络中引入了自适应小波融合模块，以解决卷积接受域有限的问题，增强心脏超声的特征集成。实验表明，我们的模型只包含0.16M个参数，不需要预训练。在CAMUS数据集上，ED和ES阶段的Dice系数分别达到0.951和0.927，在EchoNet-Dynamic数据集上，该算法达到0.933和0.909，在NVIDIA RTX 2080 Ti上的推理速度达到112 FPS。外部临床数据集的评估表明，我们的模型具有良好的推广前景和临床应用潜力。

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来源期刊

IEEE Transactions on Circuits and Systems for Video Technology 工程技术-工程：电子与电气

CiteScore

13.80

自引率

27.40%

发文量

660

审稿时长

5 months

期刊介绍： The IEEE Transactions on Circuits and Systems for Video Technology (TCSVT) is dedicated to covering all aspects of video technologies from a circuits and systems perspective. We encourage submissions of general, theoretical, and application-oriented papers related to image and video acquisition, representation, presentation, and display. Additionally, we welcome contributions in areas such as processing, filtering, and transforms; analysis and synthesis; learning and understanding; compression, transmission, communication, and networking; as well as storage, retrieval, indexing, and search. Furthermore, papers focusing on hardware and software design and implementation are highly valued. Join us in advancing the field of video technology through innovative research and insights.