Development of Deep Learning with RDA U-Net Network for Bladder Cancer Segmentation.
Ming-Chan LeeShao-Yu WangCheng-Tang PanMing-Yi ChienWei-Ming LiJin-Hao XuChi-Hung LuoYow-Ling Shirley ShiuePublished in: Cancers (2023)
In today's high-order health examination, imaging examination accounts for a large proportion. Computed tomography (CT), which can detect the whole body, uses X-rays to penetrate the human body to obtain images. Its presentation is a high-resolution black-and-white image composed of gray scales. It is expected to assist doctors in making judgments through deep learning based on the image recognition technology of artificial intelligence. It used CT images to identify the bladder and lesions and then segmented them in the images. The images can achieve high accuracy without using a developer. In this study, the U-Net neural network, commonly used in the medical field, was used to extend the encoder position in combination with the ResBlock in ResNet and the Dense Block in DenseNet, so that the training could maintain the training parameters while reducing the overall identification operation time. The decoder could be used in combination with Attention Gates to suppress the irrelevant areas of the image while paying attention to significant features. Combined with the above algorithm, we proposed a Residual-Dense Attention (RDA) U-Net model, which was used to identify organs and lesions from CT images of abdominal scans. The accuracy ( ACC ) of using this model for the bladder and its lesions was 96% and 93%, respectively. The values of Intersection over Union ( IoU ) were 0.9505 and 0.8024, respectively. Average Hausdorff distance ( AVGDIST ) was as low as 0.02 and 0.12, respectively, and the overall training time was reduced by up to 44% compared with other convolution neural networks.
Keyphrases
- deep learning
- neural network
- artificial intelligence
- computed tomography
- convolutional neural network
- dual energy
- contrast enhanced
- high resolution
- image quality
- machine learning
- positron emission tomography
- big data
- healthcare
- working memory
- spinal cord injury
- magnetic resonance imaging
- endothelial cells
- virtual reality
- public health
- magnetic resonance
- case report
- risk assessment
- health information
- fluorescence imaging
- muscle invasive bladder cancer