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一种基于多任务学习的肋骨骨折愈合阶段判定模型OA

A prediction model for rib-fracture healing period on the basis of multi-task learning

中文摘要英文摘要

肋骨骨折是胸部创伤中常见的损伤类型,通常通过胸部CT影像进行诊断.然而,由于骨折区域通常较小,形态多变且与周围组织对比度低,导致骨折类型分类和愈合阶段判定在临床和智能分析中均面临巨大挑战.针对上述问题,本文围绕肋骨骨折的类型分类与愈合阶段判定展开研究,提出一种基于多任务学习的肋骨骨折愈合阶段判定模型.具体来说,首先,在骨折类型分类方面,本文设计了一种三分支分层多尺度融合模型,充分融合不同层次和尺度的特征信息,以提升模型对细微骨折差异的识别能力.其次,在骨折愈合阶段判定方面,针对样本数量少、分布不均等问题,构建了基于深度可分离卷积的扩展长短期记忆网络,该网络不仅增强了图像空间特征的提取能力,同时也提高了对时间序列中长期依赖信息的建模能力,实现了空间与时间双维度的特征整合.实验结果表明,该方法具有良好的分类性能,准确率与召回率均达到 0.95 以上,而且在判定不同愈合阶段时表现出较高的稳定性和准确性,阶段判定的准确率与召回率均达到 0.91 以上.

Rib fractures are a prevalent consequence of thoracic trauma and typically identified through chest CT imaging.However,their accurate analysis is hindered by challenges such as small size,morphological variability,and low contrast with surrounding tissues.These factors complicate both the classification of fracture types and determination of healing stages in clinical and computational settings.To address these issues,we have proposed a novel multi-task learning framework designed to simultaneously perform fracture type classification and healing stage assessment.The multi-task learning approach is strategically chosen to leverage the intrinsic relatedness between the two tasks.By learning them jointly,the model develops more robust and generalizable feature representations,which is particularly advantageous given the common constraints of medical imaging data,such as limited sample sizes and class imbalance.Our methodology consists of two core components,each engineered to overcome specific challenges.For the task of fracture type classification(e.g.,simple,displaced,comminuted),we designed a three-branch hierarchical multi-scale fusion model.This architecture explicitly extracts and integrates feature information from different hierarchical levels and spatial scales within the CT d ata.One branch captures fine-grained,high-resolution details essential for identifying subtle fracture lines.The second branch processes intermediate features for contextual information,whereas the third branch focuses on high-level semantic features.Then,a dedicated fusion module combines these multi-scale representations,significantly enhancing the model's ability to discern subtle morphological differences between fracture types.For the more complex task of healing stage determination,we confronted obstacles such as limited longitudinal data,class imbalance across stages,and the need to model temporal dependencies.Our solution was a novel depthwise separable convolution-enhanced long short-term memory(DSC-xLSTM)network.This hybrid module first utilizes depthwise separable convolutions for efficient and powerful spatial-feature extraction from individual scans,reducing parameter count and overfitting risk.Then,these spatial features are processed by an LSTM network,which excels at modeling long-range sequential dependencies.This integration allows the model to perform a robust spatio-temporal analysis,learning the progression of healing from acute injury to bony union.The proposed model was rigorously evaluated using a substantial dataset of clinical rib fracture CT scans,annotated by expert radiologists for fracture type and healing stage.The results demonstrate the framework's high efficacy.For fracture type classification,the model achieved exceptional accuracy and recall rates,both exceeding 0.95.Importantly,in the challenging task of healing stage determination,it also exhibited remarkable stability and accuracy,with both metrics consistently surpassing 0.91 across different healing phases.These results underscore the model's capability to overcome data limitations and effectively learn the complex features required for accurate spatio-temporal analysis.In conclusion,this study introduces an effective multi-task learning framework that addresses key challenges in automated rib-fracture analysis.The proposed three-branch model for multi-scale feature fusion and innovative DSC-xLSTM network for spatio-temporal integration together enable state-of-the-art performance in classifying fracture types and determining healing stages.The model's high accuracy and robustness highlight its potential as a valuable tool to support clinical decision-making and enhance diagnostic precision in managing rib fractures.Future studies need to focus on further validation with expanded datasets and steps toward clinical integration.

卢琪;张雄;上官宏;杨婕;路正;高亮海

太原科技大学电子信息工程学院,太原 030024太原科技大学电子信息工程学院,太原 030024太原科技大学电子信息工程学院,太原 030024山西中医药大学分子中医药学国家级国际联合研究中心,中医脑病学山西省重点实验室,太原 030619太原科技大学电子信息工程学院,太原 030024太原科技大学电子信息工程学院,太原 030024

信息技术与安全科学

多任务学习网络愈合阶段判定肋骨骨折分类多尺度特征融合星网络

multi-task learning networkhealing stage determinationclassification of rib fracturesmulti-scale feature fusionStarNet

《工程科学学报》 2026 (3)

574-585,12

山西省自然科学基金面上资助项目(202403021221140)山西省留学回国人员科技活动择优资助项目(20250025)山西省科技合作交流专项资助项目(202404041101009)

10.13374/j.issn2095-9389.2025.06.06.009

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