Enhancing pediatric distal radius fracture detection: optimizing YOLOv8 with advanced AI and machine learning techniques.

IF 3.2 3区医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

BMC Medical Imaging Pub Date : 2025-08-05 DOI:10.1186/s12880-025-01669-2

Farid Amirouche, Aashik Mathew Prosper, Majd Mzeihem

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引用次数: 0

Abstract

Background: In emergency departments, residents and physicians interpret X-rays to identify fractures, with distal radius fractures being the most common in children. Skilled radiologists typically ensure accurate readings in well-resourced hospitals, but rural areas often lack this expertise, leading to lower diagnostic accuracy and potential delays in treatment. Machine learning systems offer promising solutions by detecting subtle features that non-experts might miss. Recent advancements, including YOLOv8 and its attention-mechanism models, YOLOv8-AM, have shown potential in automated fracture detection. This study aims to refine the YOLOv8-AM model to improve the detection of distal radius fractures in pediatric patients by integrating targeted improvements and new attention mechanisms.

Methods: We enhanced the YOLOv8-AM model to improve pediatric wrist fracture detection, maintaining the YOLOv8 backbone while integrating attention mechanisms such as the Convolutional Block Attention Module (CBAM) and the Global Context (GC) block. We optimized the model through hyperparameter tuning, implementing data cleaning, augmentation, and normalization techniques using the GRAZPEDWRI-DX dataset. This process addressed class imbalances and significantly improved model performance, with mean Average Precision (mAP) increasing from 63.6 to 66.32%.

Results and discussion: The iYOLOv8 models demonstrated substantial improvements in performance metrics. The iYOLOv8 + GC model achieved the highest precision at 97.2%, with an F1-score of 67% and an mAP50 of 69.5%, requiring only 3.62 h of training time. In comparison, the iYOLOv8 + ECA model reached 96.7% precision, significantly reducing training time from 8.54 to 2.16 h. The various iYOLOv8-AM models achieved an average accuracy of 96.42% in fracture detection, although performance for detecting bone anomalies and soft tissues was lower due to dataset constraints. The improvements highlight the model's effectiveness in pathological detection of the pediatric distal radius, suggesting that integrating these AI models into clinical practice could significantly enhance diagnostic efficiency.

Conclusion: Our improved YOLOv8-AM model, incorporating the GC attention mechanism, demonstrated superior speed and accuracy in pediatric distal radius fracture detection while reducing training time. Future research should explore additional features to further enhance detection capabilities in other musculoskeletal areas, as this model has the potential to adapt to various fracture types with appropriate training.

Clinical trial number: Not applicable.

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增强小儿桡骨远端骨折检测：利用先进的人工智能和机器学习技术优化YOLOv8。

背景：在急诊科，住院医生和医生通过x光片来识别骨折，桡骨远端骨折在儿童中最为常见。在资源充足的医院，熟练的放射科医生通常会确保准确的读数，但农村地区往往缺乏这种专业知识，导致诊断准确性较低，并可能导致治疗延误。机器学习系统通过检测非专家可能忽略的细微特征，提供了有前途的解决方案。最近的进展，包括YOLOv8及其注意力机制模型YOLOv8- am，已经显示出自动化裂缝检测的潜力。本研究旨在完善YOLOv8-AM模型，结合针对性改进和新的注意机制，提高小儿桡骨远端骨折的检测水平。方法：我们对YOLOv8- am模型进行了改进，以改善儿童腕部骨折的检测，在保持YOLOv8骨干的同时集成了卷积块注意模块（CBAM）和全局上下文块（GC）等注意机制。我们通过超参数调优、使用GRAZPEDWRI-DX数据集实现数据清理、增强和规范化技术来优化模型。这个过程解决了类的不平衡，显著提高了模型的性能，平均精度（mAP）从63.6增加到66.32%。结果和讨论：iYOLOv8模型显示了性能指标的实质性改进。iYOLOv8 + GC模型的准确率最高，达到97.2%，f1得分为67%，mAP50为69.5%，只需要3.62 h的训练时间。相比之下，iYOLOv8 + ECA模型达到了96.7%的精度，将训练时间从8.54小时显著减少到2.16小时。尽管由于数据集的限制，iYOLOv8- am模型在检测骨异常和软组织方面的性能较低，但在骨折检测方面的平均准确率为96.42%。这些改进突出了该模型在小儿桡骨远端病理检测中的有效性，表明将这些人工智能模型整合到临床实践中可以显著提高诊断效率。结论：我们改进的YOLOv8-AM模型，结合GC注意机制，在儿童桡骨远端骨折检测中表现出更高的速度和准确性，同时减少了训练时间。未来的研究应该探索更多的特征，以进一步增强其他肌肉骨骼区域的检测能力，因为该模型有可能在适当的训练下适应各种骨折类型。临床试验号：不适用。

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来源期刊

BMC Medical Imaging RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING-

CiteScore

4.60

自引率

3.70%

发文量

198

审稿时长

27 weeks

期刊介绍： BMC Medical Imaging is an open access journal publishing original peer-reviewed research articles in the development, evaluation, and use of imaging techniques and image processing tools to diagnose and manage disease.