Focal Modulation and Bidirectional Feature Fusion Network for Medical Image Segmentation
- URL: http://arxiv.org/abs/2510.20933v1
- Date: Thu, 23 Oct 2025 18:52:24 GMT
- Title: Focal Modulation and Bidirectional Feature Fusion Network for Medical Image Segmentation
- Authors: Moin Safdar, Shahzaib Iqbal, Mehwish Mehmood, Mubeen Ghafoor, Tariq M. Khan, Imran Razzak,
- Abstract summary: Medical image segmentation is essential for clinical applications such as disease diagnosis, treatment planning, and disease development monitoring.<n>Since convolution operations are local, capturing global contextual information and long-range dependencies is still challenging.<n>We propose FM-BFF-Net to overcome these challenges.
- Score: 14.99493755212616
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Medical image segmentation is essential for clinical applications such as disease diagnosis, treatment planning, and disease development monitoring because it provides precise morphological and spatial information on anatomical structures that directly influence treatment decisions. Convolutional neural networks significantly impact image segmentation; however, since convolution operations are local, capturing global contextual information and long-range dependencies is still challenging. Their capacity to precisely segment structures with complicated borders and a variety of sizes is impacted by this restriction. Since transformers use self-attention methods to capture global context and long-range dependencies efficiently, integrating transformer-based architecture with CNNs is a feasible approach to overcoming these challenges. To address these challenges, we propose the Focal Modulation and Bidirectional Feature Fusion Network for Medical Image Segmentation, referred to as FM-BFF-Net in the remainder of this paper. The network combines convolutional and transformer components, employs a focal modulation attention mechanism to refine context awareness, and introduces a bidirectional feature fusion module that enables efficient interaction between encoder and decoder representations across scales. Through this design, FM-BFF-Net enhances boundary precision and robustness to variations in lesion size, shape, and contrast. Extensive experiments on eight publicly available datasets, including polyp detection, skin lesion segmentation, and ultrasound imaging, show that FM-BFF-Net consistently surpasses recent state-of-the-art methods in Jaccard index and Dice coefficient, confirming its effectiveness and adaptability for diverse medical imaging scenarios.
Related papers
- MAMBO-NET: Multi-Causal Aware Modeling Backdoor-Intervention Optimization for Medical Image Segmentation Network [51.68708264694361]
Confusion factors can affect medical images, such as complex anatomical variations and imaging modality limitations.<n>We propose a multi-causal aware modeling backdoor-intervention optimization network for medical image segmentation.<n>Our method significantly reduces the influence of confusion factors, leading to enhanced segmentation accuracy.
arXiv Detail & Related papers (2025-05-28T01:40:10Z) - CFFormer: Cross CNN-Transformer Channel Attention and Spatial Feature Fusion for Improved Segmentation of Heterogeneous Medical Images [29.68616115427831]
Medical image segmentation plays an important role in computer-aided diagnosis.<n>Due to limitations of medical imaging devices, medical images exhibit significant heterogeneity, posing challenges for segmentation.<n>We propose a hybrid CNN-Transformer model,called CFFormer, which leverages effective channel feature extraction.
arXiv Detail & Related papers (2025-01-07T08:59:20Z) - Advancing Medical Image Segmentation: Morphology-Driven Learning with Diffusion Transformer [4.672688418357066]
We propose a novel Transformer Diffusion (DTS) model for robust segmentation in the presence of noise.
Our model, which analyzes the morphological representation of images, shows better results than the previous models in various medical imaging modalities.
arXiv Detail & Related papers (2024-08-01T07:35:54Z) - BEFUnet: A Hybrid CNN-Transformer Architecture for Precise Medical Image
Segmentation [0.0]
This paper proposes an innovative U-shaped network called BEFUnet, which enhances the fusion of body and edge information for precise medical image segmentation.
The BEFUnet comprises three main modules, including a novel Local Cross-Attention Feature (LCAF) fusion module, a novel Double-Level Fusion (DLF) module, and dual-branch encoder.
The LCAF module efficiently fuses edge and body features by selectively performing local cross-attention on features that are spatially close between the two modalities.
arXiv Detail & Related papers (2024-02-13T21:03:36Z) - Dual-scale Enhanced and Cross-generative Consistency Learning for Semi-supervised Medical Image Segmentation [49.57907601086494]
Medical image segmentation plays a crucial role in computer-aided diagnosis.
We propose a novel Dual-scale Enhanced and Cross-generative consistency learning framework for semi-supervised medical image (DEC-Seg)
arXiv Detail & Related papers (2023-12-26T12:56:31Z) - Self-supervised Semantic Segmentation: Consistency over Transformation [3.485615723221064]
We propose a novel self-supervised algorithm, textbfS$3$-Net, which integrates a robust framework based on the proposed Inception Large Kernel Attention (I-LKA) modules.
We leverage deformable convolution as an integral component to effectively capture and delineate lesion deformations for superior object boundary definition.
Our experimental results on skin lesion and lung organ segmentation tasks show the superior performance of our method compared to the SOTA approaches.
arXiv Detail & Related papers (2023-08-31T21:28:46Z) - Scale-aware Super-resolution Network with Dual Affinity Learning for
Lesion Segmentation from Medical Images [50.76668288066681]
We present a scale-aware super-resolution network to adaptively segment lesions of various sizes from low-resolution medical images.
Our proposed network achieved consistent improvements compared to other state-of-the-art methods.
arXiv Detail & Related papers (2023-05-30T14:25:55Z) - TransAttUnet: Multi-level Attention-guided U-Net with Transformer for
Medical Image Segmentation [33.45471457058221]
This paper proposes a novel Transformer based medical image semantic segmentation framework called TransAttUnet.
In particular, we establish additional multi-scale skip connections between decoder blocks to aggregate the different semantic-scale upsampling features.
Our method consistently outperforms the state-of-the-art baselines.
arXiv Detail & Related papers (2021-07-12T09:17:06Z) - Medical Transformer: Gated Axial-Attention for Medical Image
Segmentation [73.98974074534497]
We study the feasibility of using Transformer-based network architectures for medical image segmentation tasks.
We propose a Gated Axial-Attention model which extends the existing architectures by introducing an additional control mechanism in the self-attention module.
To train the model effectively on medical images, we propose a Local-Global training strategy (LoGo) which further improves the performance.
arXiv Detail & Related papers (2021-02-21T18:35:14Z) - TransUNet: Transformers Make Strong Encoders for Medical Image
Segmentation [78.01570371790669]
Medical image segmentation is an essential prerequisite for developing healthcare systems.
On various medical image segmentation tasks, the u-shaped architecture, also known as U-Net, has become the de-facto standard.
We propose TransUNet, which merits both Transformers and U-Net, as a strong alternative for medical image segmentation.
arXiv Detail & Related papers (2021-02-08T16:10:50Z) - Unsupervised Bidirectional Cross-Modality Adaptation via Deeply
Synergistic Image and Feature Alignment for Medical Image Segmentation [73.84166499988443]
We present a novel unsupervised domain adaptation framework, named as Synergistic Image and Feature Alignment (SIFA)
Our proposed SIFA conducts synergistic alignment of domains from both image and feature perspectives.
Experimental results on two different tasks demonstrate that our SIFA method is effective in improving segmentation performance on unlabeled target images.
arXiv Detail & Related papers (2020-02-06T13:49:47Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.