Injury classification and level detection of the spinal cord based on the optimized recurrent neural network

IF 1.2 Q3 Computer Science

Bio-Algorithms and Med-Systems Pub Date : 2020-12-07 DOI:10.1515/bams-2019-0065

K. MunavarJasim, T. Brindha

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引用次数: 1

Abstract

Abstract Objectives Spinal cord damage is one of the traumatic situations in persons that may cause the loss of sensation and proper functioning of the muscles either temporarily or permanently. Hence, steps to assure the recovery through the early functioning and precaution could safe-guard a proper interceptive. To ensure the recovery of spinal cord damage through optimized recurrent neural network. Methods The research on the spinal cord injury classification and level detection is done using the CT images, which is initially given to the segmentation that is done using the adaptive thresholding methodology. Once the segments are formed, the disc is localized using the sparse fuzzy C-means clustering approach. In the next step, the features are extracted from the localized disc and the features include the connectivity features, statistical features, image-level features, grid-level features, Histogram of Oriented Gradients (HOG), and Linear Gradient Pattern (LGP). Then, the injury detection is done based on the Crow search Rider Optimization algorithm-based Deep Convolutional Neural Network (CS-ROA-based DCNN). Once the result regarding the presence of the injury is obtained, the injury-level classification is done based on the proposed Deep Recurrent Neural Network (Deep RNN), and in case of the absence of injury, the process is terminated. Therefore, the injury detection classifier derives the level of the injury, such as normal, wedge, biconcavity, and crush. Results The experimentation is carried out using an Osteoporotic vertebral fractures database. The performance of the injury level detection based on the proposed model is evaluated based on accuracy, sensitivity, and specificity. The proposed model achieves the maximal accuracy of 0.895, maximal sensitivity of 0.871, and the maximal specificity of 0.933 with respect to K-Fold. Conclusions The experimental results show that the proposed model is better than the existing models in terms of accuracy, sensitivity, and specificity.

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基于优化递归神经网络的脊髓损伤分类与水平检测

摘要目的脊髓损伤是一种可能导致感觉和肌肉正常功能暂时或永久丧失的创伤情况。因此，通过早期功能和预防措施确保恢复的步骤可以安全地保护适当的拦截。通过优化的递归神经网络确保脊髓损伤的恢复。方法利用CT图像对脊髓损伤的分类和水平检测进行研究，初步将其应用于自适应阈值方法进行的分割。一旦片段形成，就使用稀疏模糊C均值聚类方法对圆盘进行定位。在下一步中，从定位盘中提取特征，这些特征包括连通性特征、统计特征、图像级特征、网格级特征、定向梯度直方图（HOG）和线性梯度模式（LGP）。然后，基于Crow搜索Rider优化算法的深度卷积神经网络（基于CS ROA的DCNN）进行损伤检测。一旦获得了关于损伤存在的结果，就基于所提出的深度递归神经网络（Deep RNN）进行损伤级别分类，并且在没有损伤的情况下，终止该过程。因此，损伤检测分类器导出损伤的级别，如正常、楔形、双凹面和挤压。结果实验使用骨质疏松性脊椎骨折数据库进行。基于所提出的模型的损伤水平检测的性能基于准确性、敏感性和特异性进行评估。相对于K-Fold，所提出的模型实现了0.895的最大准确度、0.871的最大灵敏度和0.933的最大特异性。结论实验结果表明，该模型在准确性、敏感性和特异性方面优于现有模型。

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来源期刊

Bio-Algorithms and Med-Systems MATHEMATICAL & COMPUTATIONAL BIOLOGY-

CiteScore

3.80

自引率

0.00%

发文量

期刊介绍： The journal Bio-Algorithms and Med-Systems (BAMS), edited by the Jagiellonian University Medical College, provides a forum for the exchange of information in the interdisciplinary fields of computational methods applied in medicine, presenting new algorithms and databases that allows the progress in collaborations between medicine, informatics, physics, and biochemistry. Projects linking specialists representing these disciplines are welcome to be published in this Journal. Articles in BAMS are published in English. Topics Bioinformatics Systems biology Telemedicine E-Learning in Medicine Patient''s electronic record Image processing Medical databases.