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一种加速深度学习模型能够准确识别解剖型关节置换术前和术后所获得的X线平片上具有临床重要意义的肱骨和肩胛标志点。

An accelerated deep learning model can accurately identify clinically important humeral and scapular landmarks on plain radiographs obtained before and after anatomic arthroplasty.

作者信息

Crutcher William L, Dane Ishan, Whitson Anastasia J, Matsen Iii Frederick A, Hsu Jason E

机构信息

University of Washington, Seattle, USA.

出版信息

Int Orthop. 2025 Feb;49(2):455-460. doi: 10.1007/s00264-024-06401-3. Epub 2025 Jan 6.

DOI:10.1007/s00264-024-06401-3
PMID:39760903
Abstract

PURPOSE

Accurate identification of radiographic landmarks is fundamental to characterizing glenohumeral relationships before and sequentially after shoulder arthroplasty, but manual annotation of these radiographs is laborious. We report on the use of artificial intelligence, specifically computer vision and deep learning models (DLMs), in determining the accuracy of DLM-identified and surgeon identified (SI) landmarks before and after anatomic shoulder arthroplasty.

MATERIALS & METHODS: 240 true anteroposterior radiographs were annotated using 11 standard osseous landmarks to train a deep learning model. Radiographs were modified to allow for a training model consisting of 2,260 images. The accuracy of DLM landmarks was compared to manually annotated radiographs using 60 radiographs not used in the training model. In addition, we also performed 14 different measurements of component positioning and compared these to measurements made based on DLM landmarks.

RESULTS

The mean deviation between DLM vs. SI cortical landmarks was 1.9 ± 1.9 mm. Scapular landmarks had slightly lower deviations compared to humeral landmarks (1.5 ± 1.8 mm vs. 2.1 ± 2.0 mm, p < 0.001). The DLM was also found to be accurate with respect to 14 measures of scapular, humeral, and glenohumeral measurements with a mean deviation of 2.9 ± 2.7 mm.

CONCLUSIONS

An accelerated deep learning model using a base of only 240 annotated images was able to achieve low levels of deviation in identifying common humeral and scapular landmarks on preoperative and postoperative radiographs. The reliability and efficiency of this deep learning model represents a powerful tool to analyze preoperative and postoperative radiographs while avoiding human observer bias.

LEVEL OF EVIDENCE

IV.

摘要

目的

准确识别影像学标志是在肩关节置换术前及术后依次表征盂肱关系的基础,但对这些X线片进行手动标注很费力。我们报告了人工智能,特别是计算机视觉和深度学习模型(DLM)在确定解剖型肩关节置换术前和术后DLM识别的和外科医生识别的(SI)标志准确性方面的应用。

材料与方法

使用11个标准骨性标志对240张真实前后位X线片进行标注,以训练深度学习模型。对X线片进行修改,以形成一个由2260张图像组成的训练模型。使用60张未用于训练模型的X线片,将DLM标志的准确性与手动标注的X线片进行比较。此外,我们还对假体位置进行了14种不同的测量,并将这些测量结果与基于DLM标志的测量结果进行比较。

结果

DLM与SI皮质标志之间的平均偏差为1.9±1.9毫米。肩胛标志的偏差略低于肱骨标志(1.5±1.8毫米对2.1±2.0毫米,p<0.001)。还发现DLM在14种肩胛、肱骨和盂肱测量中是准确的,平均偏差为2.9±2.7毫米。

结论

一个仅基于240张标注图像的加速深度学习模型能够在识别术前和术后X线片上常见的肱骨和肩胛标志时实现低偏差水平。这种深度学习模型的可靠性和效率代表了一种强大的工具,可用于分析术前和术后X线片,同时避免人为观察者偏差。

证据水平

IV级。

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Radiol Artif Intell. 2024 May;6(3):e230094. doi: 10.1148/ryai.230094.
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