Valsamis Jake J, Luciw Nicholas J, Haq Nandinee, Atwi Sarah, Duchesne Simon, Cameron William, MacIntosh Bradley J
Hurvitz Brain Sciences Program, and Physical Sciences Platform, Sunnybrook Research Institute, Toronto, Ontario, Canada.
Department of Medical Biophysics, University of Toronto, Toronto, Ontario, Canada.
Magn Reson Med. 2023 Jul;90(1):343-352. doi: 10.1002/mrm.29639. Epub 2023 Mar 17.
Cardiac-related intracranial pulsatility may relate to cerebrovascular health, and this information is contained in BOLD MRI data. There is broad interest in methods to isolate BOLD pulsatility, and the current study examines a deep learning approach.
Multi-echo BOLD images, respiratory, and cardiac recordings were measured in 55 adults. Ground truth BOLD pulsatility maps were calculated with an established method. BOLD fast Fourier transform magnitude images were used as temporal-frequency image inputs to a U-Net deep learning model. Model performance was evaluated by mean squared error (MSE), mean absolute error (MAE), structural similarity index (SSIM), and mutual information (MI). Experiments evaluated the influence of input channel size, an age group effect during training, dependence on TE, performance without the U-Net architecture, and importance of respiratory preprocessing.
The U-Net model generated BOLD pulsatility maps with lower MSE as additional fast Fourier transform input images were used. There was no age group effect for MSE (P > 0.14). MAE and SSIM metrics did not vary across TE (P > 0.36), whereas MI showed a significant TE dependence (P < 0.05). The U-Net versus no U-Net comparison showed no significant difference for MAE (P = 0.059); however, SSIM and MI were significantly different between models (P < 0.001). Within the insula, the cross-correlation values were high (r > 0.90) when comparing the U-Net model trained with/without respiratory preprocessing.
Multi-echo BOLD pulsatility maps were synthesized from a U-net model that was trained to use temporal-frequency BOLD image inputs. This work adds to the deep learning methods that characterize BOLD physiological signals.
与心脏相关的颅内搏动性可能与脑血管健康有关,而这些信息包含在血氧水平依赖性功能磁共振成像(BOLD MRI)数据中。人们对分离BOLD搏动性的方法有着广泛的兴趣,当前的研究考察了一种深度学习方法。
对55名成年人测量了多回波BOLD图像、呼吸和心脏记录。用一种既定方法计算了真实的BOLD搏动性图。BOLD快速傅里叶变换幅度图像被用作U-Net深度学习模型的时频图像输入。通过均方误差(MSE)、平均绝对误差(MAE)、结构相似性指数(SSIM)和互信息(MI)来评估模型性能。实验评估了输入通道大小的影响、训练期间的年龄组效应、对回波时间(TE)的依赖性、没有U-Net架构时的性能以及呼吸预处理的重要性。
随着使用额外的快速傅里叶变换输入图像,U-Net模型生成的BOLD搏动性图具有更低的MSE。MSE不存在年龄组效应(P>0.14)。MAE和SSIM指标在不同TE之间没有变化(P>0.36),而MI显示出显著的TE依赖性(P<0.05)。U-Net与无U-Net的比较显示MAE没有显著差异(P = 0.059);然而,模型之间的SSIM和MI存在显著差异(P<0.001)。在脑岛内部,比较有/无呼吸预处理训练的U-Net模型时,互相关值很高(r>0.90)。
多回波BOLD搏动性图由一个经过训练以使用时频BOLD图像输入的U-Net模型合成。这项工作补充了用于表征BOLD生理信号的深度学习方法。
