{"title":"基于深度卷积神经网络的元搜索自动骨龄评估模型","authors":"Thangam Palaniswamy","doi":"10.1016/j.asej.2024.102942","DOIUrl":null,"url":null,"abstract":"<div><p>The evaluation of X-ray images of hands serves as the basis for Bone Age Assessment (BAA), a critical component in the prediction and analysis of medical disorders. The key areas of interest in this examination are the epiphyseal ossification centres and the carpal bones. Human BAA models, although necessary, are time-consuming and prone to mistakes, emphasising the need for a more efficient computerised BAA model. This study introduces ODL-BAAM, a novel Deep Learning-based Bone Age Assessment Model, aimed at enhancing efficiency and accuracy in medical image analysis. Given the critical role of Bone Age Assessment (BAA) in predicting medical disorders, particularly based on hand X-ray images, there’s a pressing need for more streamlined and reliable computerized BAA models. Leveraging Deep Learning methodologies over classical Machine Learning approaches, ODL-BAAM offers a comprehensive solution. The model begins with preprocessing steps to standardize and normalize X-ray data, crucial for managing the inherent complexities of such images. By integrating Faster RCNN with MobileNet, feature extraction becomes more effective, while the Tunicate Swarm Algorithm optimizes model hyperparameters. Age determination is facilitated through SoftMax layers applied to feature vectors. Through extensive simulation studies, ODL-BAAM demonstrates promising results, showcasing heightened sensitivity, specificity, and overall accuracy compared to existing BAA models. 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引用次数: 0
摘要
手部 X 射线图像评估是骨龄评估(BAA)的基础,也是预测和分析疾病的重要组成部分。这项检查的重点部位是骺骨化中心和腕骨。人体 BAA 模型虽然必要,但耗时且容易出错,因此需要更高效的计算机化 BAA 模型。本研究介绍了基于深度学习的新型骨龄评估模型 ODL-BAAM,旨在提高医学图像分析的效率和准确性。鉴于骨龄评估(BAA)在预测疾病(尤其是基于手部 X 光图像的疾病)中的关键作用,人们迫切需要更精简、更可靠的计算机化骨龄评估模型。与传统的机器学习方法相比,ODL-BAAM 利用深度学习方法提供了一种全面的解决方案。该模型从预处理步骤开始,对 X 射线数据进行标准化和规范化处理,这对管理此类图像固有的复杂性至关重要。通过将 Faster RCNN 与 MobileNet 集成,特征提取变得更加有效,同时 Tunicate Swarm 算法优化了模型的超参数。通过应用于特征向量的 SoftMax 层,年龄测定变得更加容易。通过广泛的模拟研究,ODL-BAAM 取得了令人满意的结果,与现有的 BAA 模型相比,灵敏度、特异性和总体准确性都有了提高。ODL-BAAM 的准确率高达 96.5%,代表了计算机化 BAA 领域的重大进步,有效解决了之前的局限性,为医学图像分析设定了新标准。
An automated metaheuristic tunicate swarm algorithm based deep convolutional neural network for bone age assessment model
The evaluation of X-ray images of hands serves as the basis for Bone Age Assessment (BAA), a critical component in the prediction and analysis of medical disorders. The key areas of interest in this examination are the epiphyseal ossification centres and the carpal bones. Human BAA models, although necessary, are time-consuming and prone to mistakes, emphasising the need for a more efficient computerised BAA model. This study introduces ODL-BAAM, a novel Deep Learning-based Bone Age Assessment Model, aimed at enhancing efficiency and accuracy in medical image analysis. Given the critical role of Bone Age Assessment (BAA) in predicting medical disorders, particularly based on hand X-ray images, there’s a pressing need for more streamlined and reliable computerized BAA models. Leveraging Deep Learning methodologies over classical Machine Learning approaches, ODL-BAAM offers a comprehensive solution. The model begins with preprocessing steps to standardize and normalize X-ray data, crucial for managing the inherent complexities of such images. By integrating Faster RCNN with MobileNet, feature extraction becomes more effective, while the Tunicate Swarm Algorithm optimizes model hyperparameters. Age determination is facilitated through SoftMax layers applied to feature vectors. Through extensive simulation studies, ODL-BAAM demonstrates promising results, showcasing heightened sensitivity, specificity, and overall accuracy compared to existing BAA models. With a remarkable 96.5% accuracy rate, ODL-BAAM represents a significant advancement in the realm of computerized BAA, effectively addressing prior limitations and setting a new standard for medical image analysis.
期刊介绍:
in Shams Engineering Journal is an international journal devoted to publication of peer reviewed original high-quality research papers and review papers in both traditional topics and those of emerging science and technology. Areas of both theoretical and fundamental interest as well as those concerning industrial applications, emerging instrumental techniques and those which have some practical application to an aspect of human endeavor, such as the preservation of the environment, health, waste disposal are welcome. The overall focus is on original and rigorous scientific research results which have generic significance.
Ain Shams Engineering Journal focuses upon aspects of mechanical engineering, electrical engineering, civil engineering, chemical engineering, petroleum engineering, environmental engineering, architectural and urban planning engineering. Papers in which knowledge from other disciplines is integrated with engineering are especially welcome like nanotechnology, material sciences, and computational methods as well as applied basic sciences: engineering mathematics, physics and chemistry.