BrainNormalizer: Anatomy-Informed Pseudo-Healthy Brain Reconstruction from Tumor MRI via Edge-Guided ControlNet
- URL: http://arxiv.org/abs/2511.12853v1
- Date: Mon, 17 Nov 2025 00:48:30 GMT
- Title: BrainNormalizer: Anatomy-Informed Pseudo-Healthy Brain Reconstruction from Tumor MRI via Edge-Guided ControlNet
- Authors: Min Gu Kwak, Yeonju Lee, Hairong Wang, Jing Li,
- Abstract summary: BrainNormalizer is an anatomy-informed diffusion framework that reconstructs pseudo-healthy MRIs directly from tumorous scans.<n>BrainNormalizer achieves strong quantitative performance and qualitatively produces anatomically plausible reconstructions in tumor-affected regions.
- Score: 5.014281623202397
- License: http://creativecommons.org/licenses/by-nc-nd/4.0/
- Abstract: Brain tumors are among the most clinically significant neurological diseases and remain a major cause of morbidity and mortality due to their aggressive growth and structural heterogeneity. As tumors expand, they induce substantial anatomical deformation that disrupts both local tissue organization and global brain architecture, complicating diagnosis, treatment planning, and surgical navigation. Yet a subject-specific reference of how the brain would appear without tumor-induced changes is fundamentally unobtainable in clinical practice. We present BrainNormalizer, an anatomy-informed diffusion framework that reconstructs pseudo-healthy MRIs directly from tumorous scans by conditioning the generative process on boundary cues extracted from the subject's own anatomy. This boundary-guided conditioning enables anatomically plausible pseudo-healthy reconstruction without requiring paired non-tumorous and tumorous scans. BrainNormalizer employs a two-stage training strategy. The pretrained diffusion model is first adapted through inpainting-based fine-tuning on tumorous and non-tumorous scans. Next, an edge-map-guided ControlNet branch is trained to inject fine-grained anatomical contours into the frozen decoder while preserving learned priors. During inference, a deliberate misalignment strategy pairs tumorous inputs with non-tumorous prompts and mirrored contralateral edge maps, leveraging hemispheric correspondence to guide reconstruction. On the BraTS2020 dataset, BrainNormalizer achieves strong quantitative performance and qualitatively produces anatomically plausible reconstructions in tumor-affected regions while retaining overall structural coherence. BrainNormalizer provides clinically reliable anatomical references for treatment planning and supports new research directions in counterfactual modeling and tumor-induced deformation analysis.
Related papers
- The Brain Resection Multimodal Image Registration (ReMIND2Reg) 2025 Challenge [42.51640997446028]
The ReMIND2Reg 2025 Challenge provides the largest public benchmark for this task, built upon the ReMIND dataset.<n>It offers 99 training cases, 5 validation cases, and 10 private test cases comprising paired 3D ceT1 MRI, T2 MRI, and post-resection 3D iUS volumes.<n>Data are provided without annotations for training, while validation and test performance are evaluated on manually annotated anatomical landmarks.
arXiv Detail & Related papers (2025-08-13T09:31:06Z) - Physics-Regularized Multi-Modal Image Assimilation for Brain Tumor Localization [3.666412718346211]
We introduce a novel method that integrates data-driven and physics-based cost functions.
We propose a unique discretization scheme that quantifies how well the learned distributions of tumor and brain tissues adhere to their respective growth and elasticity equations.
arXiv Detail & Related papers (2024-09-30T15:36:14Z) - Hybrid Multihead Attentive Unet-3D for Brain Tumor Segmentation [0.0]
Brain tumor segmentation is a critical task in medical image analysis, aiding in the diagnosis and treatment planning of brain tumor patients.
Various deep learning-based techniques have made significant progress in this field, however, they still face limitations in terms of accuracy due to the complex and variable nature of brain tumor morphology.
We propose a novel Hybrid Multihead Attentive U-Net architecture, to address the challenges in accurate brain tumor segmentation.
arXiv Detail & Related papers (2024-05-22T02:46:26Z) - MindBridge: A Cross-Subject Brain Decoding Framework [60.58552697067837]
Brain decoding aims to reconstruct stimuli from acquired brain signals.
Currently, brain decoding is confined to a per-subject-per-model paradigm.
We present MindBridge, that achieves cross-subject brain decoding by employing only one model.
arXiv Detail & Related papers (2024-04-11T15:46:42Z) - Spatio-spectral classification of hyperspectral images for brain cancer
detection during surgical operations [0.0]
Surgery for brain cancer is a major problem in neurosurgery.
The identification of the tumor boundaries during surgery is challenging.
This study presents the development of a novel classification method taking into account the spatial and spectral characteristics of the hyperspectral images.
arXiv Detail & Related papers (2024-02-11T12:58:42Z) - Prediction of brain tumor recurrence location based on multi-modal
fusion and nonlinear correlation learning [55.789874096142285]
We present a deep learning-based brain tumor recurrence location prediction network.
We first train a multi-modal brain tumor segmentation network on the public dataset BraTS 2021.
Then, the pre-trained encoder is transferred to our private dataset for extracting the rich semantic features.
Two decoders are constructed to jointly segment the present brain tumor and predict its future tumor recurrence location.
arXiv Detail & Related papers (2023-04-11T02:45:38Z) - Patched Diffusion Models for Unsupervised Anomaly Detection in Brain MRI [55.78588835407174]
We propose a method that reformulates the generation task of diffusion models as a patch-based estimation of healthy brain anatomy.
We evaluate our approach on data of tumors and multiple sclerosis lesions and demonstrate a relative improvement of 25.1% compared to existing baselines.
arXiv Detail & Related papers (2023-03-07T09:40:22Z) - Learn-Morph-Infer: a new way of solving the inverse problem for brain
tumor modeling [1.1214822628210914]
We introduce a methodology for inferring patient-specific spatial distribution of brain tumor from T1Gd and FLAIR MRI medical scans.
Coined as itLearn-Morph-Infer, the method achieves real-time performance in the order of minutes on widely available hardware.
arXiv Detail & Related papers (2021-11-07T13:45:35Z) - Triplet Contrastive Learning for Brain Tumor Classification [99.07846518148494]
We present a novel approach of directly learning deep embeddings for brain tumor types, which can be used for downstream tasks such as classification.
We evaluate our method on an extensive brain tumor dataset which consists of 27 different tumor classes, out of which 13 are defined as rare.
arXiv Detail & Related papers (2021-08-08T11:26:34Z) - Scale-Space Autoencoders for Unsupervised Anomaly Segmentation in Brain
MRI [47.26574993639482]
We show improved anomaly segmentation performance and the general capability to obtain much more crisp reconstructions of input data at native resolution.
The modeling of the laplacian pyramid further enables the delineation and aggregation of lesions at multiple scales.
arXiv Detail & Related papers (2020-06-23T09:20:42Z)
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.