基于深度卷积神经网络的低剂量计算机断层图像去噪定量评价。

4区 计算机科学 Q1 Arts and Humanities
Keisuke Usui, Koichi Ogawa, Masami Goto, Yasuaki Sakano, Shinsuke Kyougoku, Hiroyuki Daida
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引用次数: 9

摘要

为了最大限度地降低辐射风险,在计算机断层扫描(CT)的诊断和治疗应用中,降低剂量是很重要的。然而,由于x射线剂量的减少和诊断性能的降低,图像噪声会降低图像质量。卷积神经网络(cnn)的深度学习方法已被提出用于自然图像去噪;然而,这些方法可能会导致图像模糊或失去原有的梯度。本研究的目的是比较基于cnn的低剂量CT去噪方法与其他降噪方法在独特的CT噪声模拟图像上的剂量依赖特性。为了模拟低剂量CT图像,将泊松噪声分布引入到正常剂量图像中,同时对CT单元特定的调制传递函数进行卷积。采用从公共数据库获取的100张腹部CT图像,并以原始剂量为基础,以相同的10步剂量减少间隔,以1/100的最终剂量创建模拟剂量减少图像。这些图像使用CNN的去噪网络结构(DnCNN)作为一般CNN模型并进行迁移学习。为了评价图像质量,对去噪后的图像计算由结构相似指数(SSIM)和峰值信噪比(PSNR)确定的图像相似度。在SSIM和PSNR方面,DnCNN的去噪效果明显优于其他图像去噪方法,特别是在用于生成10%和5%剂量当量图像的超低剂量水平下。此外,所开发的CNN模型可以在这些剂量水平下消除噪声并保持图像清晰度,并且SSIM比原始方法提高了约10%。相反,在小剂量减少条件下,该模型也会导致图像过度平滑。在定量评价中,CNN去噪方法改进了低剂量CT,并通过剪裁CNN模型防止了过度平滑。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Quantitative evaluation of deep convolutional neural network-based image denoising for low-dose computed tomography.

Quantitative evaluation of deep convolutional neural network-based image denoising for low-dose computed tomography.

Quantitative evaluation of deep convolutional neural network-based image denoising for low-dose computed tomography.

Quantitative evaluation of deep convolutional neural network-based image denoising for low-dose computed tomography.

To minimize radiation risk, dose reduction is important in the diagnostic and therapeutic applications of computed tomography (CT). However, image noise degrades image quality owing to the reduced X-ray dose and a possible unacceptably reduced diagnostic performance. Deep learning approaches with convolutional neural networks (CNNs) have been proposed for natural image denoising; however, these approaches might introduce image blurring or loss of original gradients. The aim of this study was to compare the dose-dependent properties of a CNN-based denoising method for low-dose CT with those of other noise-reduction methods on unique CT noise-simulation images. To simulate a low-dose CT image, a Poisson noise distribution was introduced to normal-dose images while convoluting the CT unit-specific modulation transfer function. An abdominal CT of 100 images obtained from a public database was adopted, and simulated dose-reduction images were created from the original dose at equal 10-step dose-reduction intervals with a final dose of 1/100. These images were denoised using the denoising network structure of CNN (DnCNN) as the general CNN model and for transfer learning. To evaluate the image quality, image similarities determined by the structural similarity index (SSIM) and peak signal-to-noise ratio (PSNR) were calculated for the denoised images. Significantly better denoising, in terms of SSIM and PSNR, was achieved by the DnCNN than by other image denoising methods, especially at the ultra-low-dose levels used to generate the 10% and 5% dose-equivalent images. Moreover, the developed CNN model can eliminate noise and maintain image sharpness at these dose levels and improve SSIM by approximately 10% from that of the original method. In contrast, under small dose-reduction conditions, this model also led to excessive smoothing of the images. In quantitative evaluations, the CNN denoising method improved the low-dose CT and prevented over-smoothing by tailoring the CNN model.

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来源期刊
Visual Computing for Industry, Biomedicine, and Art
Visual Computing for Industry, Biomedicine, and Art Arts and Humanities-Visual Arts and Performing Arts
CiteScore
5.60
自引率
0.00%
发文量
28
审稿时长
5 weeks
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