Implicit Shape Modeling for Anatomical Structure Refinement of Volumetric Medical Images

Shape modeling of volumetric data is essential for medical image analysis and computer-aided intervention. In practice, automated shape reconstruction cannot always achieve satisfactory results due to limited image resolution and a lack of sufficiently detailed shape priors used as constraints. In this paper, a unified framework is proposed for 3D shape modelling and segmentation refinement based on implicit neural networks. To learn a sharable shape prior from different instances within the same category during training, physical details of volumetric data are firstly used to construct Physical-Informed Continuous Coordinate Transform (PICCT) for implicit shape modeling. For improved shape representation, implicit shape constraints based on Signed Distance Function (SDF) are used for both instances and latent templates. For inference, a Template Interaction Module (TIM) is proposed to refine 3D shapes produced by Convolutional Neural Networks (CNNs) via deforming deep implicit templates with latent codes. Experimental results on validation datasets involving liver, pancreas and lung segmentation demonstrate the superiority of our approach in shape refinement and reconstruction. The Chamfer Distance/Earth Mover's Distance achieved by the proposed method are 0.232/0.087 for the Liver dataset, 0.128/0.069 for the Pancreas dataset, and 0.417/0.100 for the Lung Lobe dataset, respectively.