High-resolution MRI synthesis using a data-driven framework with denoising diffusion probabilistic modeling.
Chih-Wei ChangJunbo PengMojtaba SafariElahheh SalariShaoyan PanJustin RoperRichard L J QiuYuan GaoHui-Kuo ShuHui MaoXiaofeng YangPublished in: Physics in medicine and biology (2024)
High-resolution magnetic resonance imaging (MRI) can enhance lesion diagnosis, prognosis, and delineation. However, gradient power and hardware limitations prohibit recording thin slices or sub-1 mm resolution. Furthermore, long scan time is not clinically acceptable. Conventional high-resolution images generated using statistical or analytical methods include the limitation of capturing complex, high-dimensional image data with intricate patterns and structures. This study aims to harness cutting-edge diffusion probabilistic deep learning techniques to create a framework for generating high-resolution MRI from low-resolution counterparts, improving the denoising diffusion probabilistic model (DDPM) by minimizing its unpredictability and uncertainty. DDPM includes two processes. The forward process employs a Markov chain to systematically introduce Gaussian noise to low-resolution MRI images. In the reverse process, a U-Net model is trained to denoise the forward process images and produce high-resolution images conditioned on the features of their low-resolution counterparts. The proposed framework was demonstrated using T2-weighted MRI images from institutional prostate patients and brain patients collected in the Brain Tumor Segmentation Challenge 2020 (BraTS2020). For the prostate dataset, the bicubic interpolation model (Bicubic), conditional generative-adversarial network (CGAN), and our proposed DDPM framework improved the noise quality measure from low-resolution images by 4.4%, 5.7%, and 12.8%, respectively. Our method enhanced the signal-to-noise ratios by 11.7%, surpassing Bicubic (9.8%) and CGAN (8.1%). In the BraTS2020 dataset, the proposed framework and Bicubic enhanced PSNR from resolution-degraded images by 9.1% and 5.8%. The multi-scale structural similarity indexes were 0.970±0.019, 0.968±0.022, and 0.967±0.023 for the proposed method, CGAN, and Bicubic, respectively. This study explores a deep learning-based diffusion probabilistic framework for improving MR image resolution. Such a framework can be used to improve clinical workflow by obtaining high-resolution images without penalty of the long scan time. Future investigation will likely focus on prospectively testing the efficacy of this framework with different clinical indications.
Keyphrases
- deep learning
- high resolution
- convolutional neural network
- contrast enhanced
- magnetic resonance imaging
- artificial intelligence
- single molecule
- computed tomography
- machine learning
- diffusion weighted imaging
- prostate cancer
- mass spectrometry
- end stage renal disease
- ejection fraction
- magnetic resonance
- optical coherence tomography
- high speed
- big data
- prognostic factors
- multiple sclerosis
- tandem mass spectrometry
- liquid chromatography
- peritoneal dialysis
- subarachnoid hemorrhage
- cerebral ischemia