<p>Early and accurate detection of breast tumors via ultrasound imaging is paramount for effective clinical intervention. While single-stage object detectors offer vital real-time processing capabilities, their efficacy in the medical domain is severely constrained by spatial information degradation during downsampling, insufficient multi-scale feature representation, and high susceptibility to false positives amidst complex anatomical backgrounds. To overcome these inherent limitations, we present an efficient, lightweight single-stage detection architecture designed for breast ultrasound analysis. Built upon a foundational YOLOv8n framework, our network integrates a triad of structural innovations: (1) introducing the ADown downsampling module that rigorously preserves fine-grained edge details and critical structural textures; (2) a specifically designed Multi-Scale Dilation-Wise Residual (C2f_DWR) module that dynamically calibrates receptive fields to capture highly variable tumor morphologies; and (3) incorporating a dual-branch Context-Aware Feature Module (CAFM) designed to actively suppress background glandular noise while isolating localized tumor features. Comprehensive evaluations on the BUSI benchmark demonstrate that our model achieves a precision of 80.6% and an mAP@0.5 of 71.9%. Crucially, this robust diagnostic performance is attained with exceptional computational efficiency, requiring a mere 2.88&#xa0;M parameters and 7.6 GFLOPs. By demonstrating a favorable accuracy-efficiency trade-off compared to recent state-of-the-art architectures, including YOLOv10, YOLO11, and YOLO12, our proposed network provides a viable and scalable solution for next-generation, real-time clinical Computer-Aided Diagnosis systems.</p>

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Multi-scale and context-aware enhanced YOLOv8 for breast tumor detection in ultrasound images

  • Ziqiong He,
  • Chen Zhang,
  • Wenyue Li,
  • Xue Yang,
  • Baiyang Wu,
  • Chen Liang,
  • Zhiqiang Zheng

摘要

Early and accurate detection of breast tumors via ultrasound imaging is paramount for effective clinical intervention. While single-stage object detectors offer vital real-time processing capabilities, their efficacy in the medical domain is severely constrained by spatial information degradation during downsampling, insufficient multi-scale feature representation, and high susceptibility to false positives amidst complex anatomical backgrounds. To overcome these inherent limitations, we present an efficient, lightweight single-stage detection architecture designed for breast ultrasound analysis. Built upon a foundational YOLOv8n framework, our network integrates a triad of structural innovations: (1) introducing the ADown downsampling module that rigorously preserves fine-grained edge details and critical structural textures; (2) a specifically designed Multi-Scale Dilation-Wise Residual (C2f_DWR) module that dynamically calibrates receptive fields to capture highly variable tumor morphologies; and (3) incorporating a dual-branch Context-Aware Feature Module (CAFM) designed to actively suppress background glandular noise while isolating localized tumor features. Comprehensive evaluations on the BUSI benchmark demonstrate that our model achieves a precision of 80.6% and an mAP@0.5 of 71.9%. Crucially, this robust diagnostic performance is attained with exceptional computational efficiency, requiring a mere 2.88 M parameters and 7.6 GFLOPs. By demonstrating a favorable accuracy-efficiency trade-off compared to recent state-of-the-art architectures, including YOLOv10, YOLO11, and YOLO12, our proposed network provides a viable and scalable solution for next-generation, real-time clinical Computer-Aided Diagnosis systems.