Kurmi Yashwant, Viswanathan Malvika, Zu Zhongliang
Vanderbilt University Institute of Imaging Science, Vanderbilt University Medical Center, Nashville, USA.
Department of Radiology and Radiological Sciences, Vanderbilt University Medical Center, Nashville, USA.
bioRxiv. 2024 Jun 21:2024.06.07.597818. doi: 10.1101/2024.06.07.597818.
To develop a SNR enhancement method for chemical exchange saturation transfer (CEST) imaging using a denoising convolutional autoencoder (DCAE), and compare its performance with state-of-the-art denoising methods.
The DCAE-CEST model encompasses an encoder and a decoder network. The encoder learns features from the input CEST Z-spectrum via a series of 1D convolutions, nonlinearity applications and pooling. Subsequently, the decoder reconstructs an output denoised Z-spectrum using a series of up-sampling and convolution layers. The DCAE-CEST model underwent multistage training in an environment constrained by Kullback-Leibler divergence, while ensuring data adaptability through context learning using Principal Component Analysis processed Z-spectrum as a reference. The model was trained using simulated Z-spectra, and its performance was evaluated using both simulated data and in-vivo data from an animal tumor model. Maps of amide proton transfer (APT) and nuclear Overhauser enhancement (NOE) effects were quantified using the multiple-pool Lorentzian fit, along with an apparent exchange-dependent relaxation metric.
In digital phantom experiments, the DCAE-CEST method exhibited superior performance, surpassing existing denoising techniques, as indicated by the peak SNR and Structural Similarity Index. Additionally, in vivo data further confirms the effectiveness of the DCAE-CEST in denoising the APT and NOE maps when compared to other methods. While no significant difference was observed in APT between tumors and normal tissues, there was a significant difference in NOE, consistent with previous findings.
The DCAE-CEST can learn the most important features of the CEST Z-spectrum and provide the most effective denoising solution compared to other methods.
开发一种使用去噪卷积自动编码器(DCAE)的化学交换饱和转移(CEST)成像的信噪比增强方法,并将其性能与现有最先进的去噪方法进行比较。
DCAE-CEST模型包括一个编码器和一个解码器网络。编码器通过一系列一维卷积、非线性应用和池化从输入的CEST Z谱中学习特征。随后,解码器使用一系列上采样和卷积层重建输出的去噪Z谱。DCAE-CEST模型在由库尔贝克-莱布勒散度约束的环境中进行多阶段训练,同时通过使用主成分分析处理的Z谱作为参考进行上下文学习来确保数据适应性。该模型使用模拟的Z谱进行训练,并使用模拟数据和来自动物肿瘤模型的体内数据评估其性能。使用多池洛伦兹拟合以及表观交换相关弛豫度量对酰胺质子转移(APT)和核Overhauser增强(NOE)效应图进行量化。
在数字体模实验中,DCAE-CEST方法表现出卓越的性能,在峰值信噪比和结构相似性指数方面超过了现有的去噪技术。此外,与其他方法相比,体内数据进一步证实了DCAE-CEST在去噪APT和NOE图方面的有效性。虽然肿瘤组织和正常组织之间的APT没有观察到显著差异,但NOE存在显著差异,这与先前的研究结果一致。
与其他方法相比,DCAE-CEST可以学习CEST Z谱的最重要特征并提供最有效的去噪解决方案。
