IIEEJ Transactions on Image Electronics and Visual Computing Volume 11, Issue 2

ModalityFormer for Preoperative Early Recurrence Prediction of Hepatocellular Carcinoma Using Multimodality MRI or CT and Clinical Data

Hepatocellular carcinoma (HCC), a prevalent liver cancer, poses a substantial mortality risk. Surgical resection is the primary treatment choice, but post-resection recurrence challenges patient outcomes, especially in early recurrenced cases. Developing preoperative early recurrence prediction methods is crucial for personalized treatment plans, improving survival time for HCC patiens. Existing clinical data-based predictions overlook imaging modalities, while radiomics-based methods suffer from limitations imposed by predefined features. In this light, we propose ModalityFormer, a deep learning model leveraging multimodality MRI/CT for HCC early recurrence prediction task. ModalityFormer utilize tranformer architecture to capture inter-modality context and utilize adaptive fusion module to effectively combine prediction logits of all MRI/CT modalities. Consequently, promising results are achieved in our prediction task. Furthermore, we introduce a fusion model called ModalityFormer++, which integrates multimodality MRI/CT with clinical data. Through detailed experiments, we demonstrate that our ModalityFormer model outperforms other state-of-the-art methods. Additionally, ModalityFormer++ exhibits superior performance compared to models relying solely on multimodality MRI/CT or clinical data.

Image Quality Evaluation of Computer-Generated Hologram to Compare Various Calculation Methods

Image quality of the computer-generated holograms are usually evaluated subjectively. For example, the reconstructed image from the hologram is compared with other holograms or the original image. In previous research, authors proposed image quality evaluation by peak signal-to-noise ratio and diffraction efficiency. In the present research, the structural similarity index (SSIM) is evaluated which is considered to have good agreement to perceptual image quality. Theory and numerical experimental results are shown on Fourier transform transmission hologram of both amplitude and phase modulation. From numerical simulations, bipolar intensity method, or real number calculation gives better quality than that of classical complex number calculation. Phase hologram is much brighter than amplitude hologram, however SSIM becomes lower except Kinoform that has optimized phase in the image plane.