An Automated Diagnosis of Parkinson's Disease from MRI Scans Based on Enhanced Residual Dense Network with Attention Mechanism.

Hakan Acikgoz, Deniz Korkmaz, Tarık Talan
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Abstract

The increasing prevalence of neurodegenerative diseases has recently heightened interest in research on early diagnosis of these diseases. Parkinson's disease (PD), among the most prominent of these conditions, is a neurological disorder causing the loss of nerve cells and significantly affecting movement control. Detection of PD in early stages is of critical importance to prevent the progression of the disease and improve treatment processes. The aim of the current study is to develop a deep learning model that can perform accurate classification for early diagnosis of PD from MRI images. In this study, a densely connected feature fusion network with residual learning is designed to diagnose PD patients. The designed network consists of a serial dense block with skip connections and efficient attention mechanisms. In this architecture, squeeze-excitation (SE) blocks with ResNeXt (SE-ResNeXt block) modules are utilized to extract distinctive and high-level features. In the experiments, a publicly available T2-weighted MRI dataset is used, and an offline augmentation process is applied to limited data to increase the generalization ability and classification performance. The proposed method is evaluated and compared with current state-of-the-art deep learning methods. The obtained results show that the proposed model gives higher classification performance with an overall accuracy of 94.44%, precision of 91.67%, sensitivity of 91.67%, specificity of 95.83%, F1-score of 91.67%, and Matthew's correlation coefficient of 87.50% for the PD and healthy control subjects.

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基于注意力机制的增强残差密集网络从核磁共振扫描中自动诊断帕金森病
近来,神经退行性疾病的发病率越来越高,这提高了人们对这些疾病早期诊断研究的兴趣。帕金森病(Parkinson's disease,PD)是这些疾病中最突出的一种,是一种导致神经细胞丧失并严重影响运动控制的神经系统疾病。早期发现帕金森病对防止病情恶化和改善治疗过程至关重要。本研究的目的是开发一种深度学习模型,该模型可对核磁共振成像图像进行准确分类,以用于早期诊断帕金森病。本研究设计了一个具有残差学习功能的密集连接特征融合网络,用于诊断帕金森病患者。所设计的网络由具有跳转连接和高效注意机制的串行密集块组成。在这一架构中,挤压激励(SE)区块与 ResNeXt(SE-ResNeXt 区块)模块被用来提取独特的高级特征。实验中使用了公开的 T2 加权磁共振成像数据集,并对有限的数据进行了离线增强处理,以提高泛化能力和分类性能。实验对所提出的方法进行了评估,并将其与当前最先进的深度学习方法进行了比较。结果表明,所提出的模型具有更高的分类性能,对PD和健康对照组受试者的总体准确率为94.44%,精确度为91.67%,灵敏度为91.67%,特异度为95.83%,F1分数为91.67%,马修相关系数为87.50%。
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