Related papers: Airway Segmentation Network for Enhanced Tubular Feature Extraction

Airway Segmentation Network for Enhanced Tubular Feature Extraction

URL: http://arxiv.org/abs/2507.06581v1
Date: Wed, 09 Jul 2025 06:15:20 GMT
Title: Airway Segmentation Network for Enhanced Tubular Feature Extraction
Authors: Qibiao Wu, Yagang Wang, Qian Zhang,
Abstract summary: This study proposes a novel tubular feature extraction network, named TfeNet.<n>TfeNet introduces a novel direction-aware convolution operation that first applies spatial rotation transformations to adjust the sampling positions of linear convolution kernels.<n>Extensive experiments conducted on one public dataset and two datasets used in airway segmentation challenges demonstrate that the proposed TfeNet achieves more accuracy and continuous airway structure predictions.
Score: 2.3354223046061016
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Manual annotation of airway regions in computed tomography images is a time-consuming and expertise-dependent task. Automatic airway segmentation is therefore a prerequisite for enabling rapid bronchoscopic navigation and the clinical deployment of bronchoscopic robotic systems. Although convolutional neural network methods have gained considerable attention in airway segmentation, the unique tree-like structure of airways poses challenges for conventional and deformable convolutions, which often fail to focus on fine airway structures, leading to missed segments and discontinuities. To address this issue, this study proposes a novel tubular feature extraction network, named TfeNet. TfeNet introduces a novel direction-aware convolution operation that first applies spatial rotation transformations to adjust the sampling positions of linear convolution kernels. The deformed kernels are then represented as line segments or polylines in 3D space. Furthermore, a tubular feature fusion module (TFFM) is designed based on asymmetric convolution and residual connection strategies, enhancing the network's focus on subtle airway structures. Extensive experiments conducted on one public dataset and two datasets used in airway segmentation challenges demonstrate that the proposed TfeNet achieves more accuracy and continuous airway structure predictions compared with existing methods. In particular, TfeNet achieves the highest overall score of 94.95% on the current largest airway segmentation dataset, Airway Tree Modeling(ATM22), and demonstrates advanced performance on the lung fibrosis dataset(AIIB23). The code is available at https://github.com/QibiaoWu/TfeNet.

Related papers

FLEX: A Backbone for Diffusion-Based Modeling of Spatio-temporal Physical Systems [51.15230303652732]
FLEX (F Low EXpert) is a backbone architecture for generative modeling of-temporal physical systems.<n>It reduces the variance of the velocity field in the diffusion model, which helps stabilize training.<n>It achieves accurate predictions for super-resolution and forecasting tasks using as few features as two reverse diffusion steps.
arXiv Detail & Related papers (2025-05-23T00:07:59Z)
Flow reconstruction in time-varying geometries using graph neural networks [1.0485739694839669]
The model incorporates a feature propagation algorithm as a preprocessing step to handle extremely sparse inputs. A binary indicator is introduced as a validity mask to distinguish between the original and propagated data points. The model is trained on a unique data set of Direct Numerical Simulations (DNS) of a motored engine at a technically relevant operating condition.
arXiv Detail & Related papers (2024-11-13T16:49:56Z)
MDFI-Net: Multiscale Differential Feature Interaction Network for Accurate Retinal Vessel Segmentation [3.152646316470194]
This paper proposes a feature-enhanced interaction network based on DPCN, named MDFI-Net. The proposed MDFI-Net achieves segmentation performance superior to state-of-the-art methods on public datasets.
arXiv Detail & Related papers (2024-10-20T16:42:22Z)
Make it more specific: A novel uncertainty based airway segmentation application on 3D U-Net and its variants [7.510433578643361]
The most popular algorithms in medical segmentation, 3D U-Net and its variants, can directly implement the task of lung trachea segmentation. A research gap exists because a great amount of state-of-the-art DL algorithms are vanilla 3D U-Net structures. We propose two different network structures Branch-Level U-Net (B-UNet) and Branch-Level CE-UNet (B-CE-UNet) which are based on U-Net structure.
arXiv Detail & Related papers (2024-02-12T04:40:19Z)
Leveraging Frequency Domain Learning in 3D Vessel Segmentation [50.54833091336862]
In this study, we leverage Fourier domain learning as a substitute for multi-scale convolutional kernels in 3D hierarchical segmentation models. We show that our novel network achieves remarkable dice performance (84.37% on ASACA500 and 80.32% on ImageCAS) in tubular vessel segmentation tasks.
arXiv Detail & Related papers (2024-01-11T19:07:58Z)
Joint Bayesian Inference of Graphical Structure and Parameters with a Single Generative Flow Network [59.79008107609297]
We propose in this paper to approximate the joint posterior over the structure of a Bayesian Network. We use a single GFlowNet whose sampling policy follows a two-phase process. Since the parameters are included in the posterior distribution, this leaves more flexibility for the local probability models.
arXiv Detail & Related papers (2023-05-30T19:16:44Z)
Fuzzy Attention Neural Network to Tackle Discontinuity in Airway Segmentation [67.19443246236048]
Airway segmentation is crucial for the examination, diagnosis, and prognosis of lung diseases. Some small-sized airway branches (e.g., bronchus and terminaloles) significantly aggravate the difficulty of automatic segmentation. This paper presents an efficient method for airway segmentation, comprising a novel fuzzy attention neural network and a comprehensive loss function.
arXiv Detail & Related papers (2022-09-05T16:38:13Z)
CAINNFlow: Convolutional block Attention modules and Invertible Neural Networks Flow for anomaly detection and localization tasks [28.835943674247346]
In this study, we design a complex function model with alternating CBAM embedded in a stacked $3times3$ full convolution, which is able to retain and effectively extract spatial structure information. Experiments show that CAINNFlow achieves advanced levels of accuracy and inference efficiency based on CNN and Transformer backbone networks as feature extractors.
arXiv Detail & Related papers (2022-06-04T13:45:08Z)
Automated airway segmentation by learning graphical structure [0.76146285961466]
We put forward an advanced method for airway segmentation based on the existent convolutional neural network (CNN) and graph neural network (GNN) The proposed model shows that compared with the CNN-only method, the combination of CNN and GNN has a better performance in that the bronchi in the chest CT scans can be detected in most cases.
arXiv Detail & Related papers (2021-09-30T01:37:31Z)
Crowd Counting via Perspective-Guided Fractional-Dilation Convolution [75.36662947203192]
This paper proposes a novel convolution neural network-based crowd counting method, termed Perspective-guided Fractional-Dilation Network (PFDNet) By modeling the continuous scale variations, the proposed PFDNet is able to select the proper fractional dilation kernels for adapting to different spatial locations. It significantly improves the flexibility of the state-of-the-arts that only consider the discrete representative scales.
arXiv Detail & Related papers (2021-07-08T07:57:00Z)
A Point-Cloud Deep Learning Framework for Prediction of Fluid Flow Fields on Irregular Geometries [62.28265459308354]
Network learns end-to-end mapping between spatial positions and CFD quantities. Incompress laminar steady flow past a cylinder with various shapes for its cross section is considered. Network predicts the flow fields hundreds of times faster than our conventional CFD.
arXiv Detail & Related papers (2020-10-15T12:15:02Z)

This list is automatically generated from the titles and abstracts of the papers in this site.