_version_ 1866908490148085760
author Musah, Toufiq
Amoako-Atta, Chantelle
Otu, John Amankwaah
Ismaila, Lukman E.
Suraka, Swallah Alhaji
Williams, Oladimeji
Tigbee, Isaac
Wabbi, Kato Hussein
Katsande, Samantha
Yakubu, Kanyiri Ahmed
Lawal, Adedayo Kehinde
Donkor, Anita Nsiah
Adamu, Naeem Mwinlanaah
Akande, Adebowale
Othieno, John
Adjei, Prince Ebenezer
Dong, Zhang
Raymond, Confidence
Anazodo, Udunna C.
Mumuni, Abdul Nashirudeen
Emegoakor, Adaobi Chiazor
Opara, Chidera
Adewole, Maruf
Asiamah, Richard
author_facet Musah, Toufiq
Amoako-Atta, Chantelle
Otu, John Amankwaah
Ismaila, Lukman E.
Suraka, Swallah Alhaji
Williams, Oladimeji
Tigbee, Isaac
Wabbi, Kato Hussein
Katsande, Samantha
Yakubu, Kanyiri Ahmed
Lawal, Adedayo Kehinde
Donkor, Anita Nsiah
Adamu, Naeem Mwinlanaah
Akande, Adebowale
Othieno, John
Adjei, Prince Ebenezer
Dong, Zhang
Raymond, Confidence
Anazodo, Udunna C.
Mumuni, Abdul Nashirudeen
Emegoakor, Adaobi Chiazor
Opara, Chidera
Adewole, Maruf
Asiamah, Richard
contents Brain tumors are among the deadliest cancers worldwide, with particularly devastating impact in Sub-Saharan Africa (SSA) where limited access to medical imaging infrastructure and expertise often delays diagnosis and treatment planning. Accurate brain tumor segmentation is crucial for treatment planning, surgical guidance, and monitoring disease progression, yet manual segmentation is time-consuming and subject to inter-observer variability. Recent advances in deep learning, based on Convolutional Neural Networks (CNNs) and Transformers have demonstrated significant potential in automating this critical task. This study evaluates three state-of-the-art architectures, SwinUNETR-v2, nnUNet, and MedNeXt for automated brain tumor segmentation in multi-parametric Magnetic Resonance Imaging (MRI) scans. We trained our models on the BraTS-Africa 2024 and BraTS2021 datasets, and performed validation on the BraTS-Africa 2024 validation set. We observed that training on a mixed dataset (BraTS-Africa 2024 and BraTS2021) did not yield improved performance on the SSA validation set in all tumor regions compared to training solely on SSA data with well-validated methods. Ensembling predictions from different models also lead to notable performance increases. Our best-performing model, a finetuned MedNeXt, achieved an average lesion-wise Dice score of 0.84, with individual scores of 0.81 (enhancing tumor), 0.81 (tumor core), and 0.91 (whole tumor). While further improvements are expected with extended training and larger datasets, these results demonstrate the feasibility of deploying deep learning for reliable tumor segmentation in resource-limited settings. We further highlight the need to improve local data acquisition protocols to support the development of clinically relevant, region-specific AI tools.
format Preprint
id arxiv_https___arxiv_org_abs_2508_10905
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Brain Tumor Segmentation in Sub-Sahara Africa with Advanced Transformer and ConvNet Methods: Fine-Tuning, Data Mixing and Ensembling
Musah, Toufiq
Amoako-Atta, Chantelle
Otu, John Amankwaah
Ismaila, Lukman E.
Suraka, Swallah Alhaji
Williams, Oladimeji
Tigbee, Isaac
Wabbi, Kato Hussein
Katsande, Samantha
Yakubu, Kanyiri Ahmed
Lawal, Adedayo Kehinde
Donkor, Anita Nsiah
Adamu, Naeem Mwinlanaah
Akande, Adebowale
Othieno, John
Adjei, Prince Ebenezer
Dong, Zhang
Raymond, Confidence
Anazodo, Udunna C.
Mumuni, Abdul Nashirudeen
Emegoakor, Adaobi Chiazor
Opara, Chidera
Adewole, Maruf
Asiamah, Richard
Quantitative Methods
Brain tumors are among the deadliest cancers worldwide, with particularly devastating impact in Sub-Saharan Africa (SSA) where limited access to medical imaging infrastructure and expertise often delays diagnosis and treatment planning. Accurate brain tumor segmentation is crucial for treatment planning, surgical guidance, and monitoring disease progression, yet manual segmentation is time-consuming and subject to inter-observer variability. Recent advances in deep learning, based on Convolutional Neural Networks (CNNs) and Transformers have demonstrated significant potential in automating this critical task. This study evaluates three state-of-the-art architectures, SwinUNETR-v2, nnUNet, and MedNeXt for automated brain tumor segmentation in multi-parametric Magnetic Resonance Imaging (MRI) scans. We trained our models on the BraTS-Africa 2024 and BraTS2021 datasets, and performed validation on the BraTS-Africa 2024 validation set. We observed that training on a mixed dataset (BraTS-Africa 2024 and BraTS2021) did not yield improved performance on the SSA validation set in all tumor regions compared to training solely on SSA data with well-validated methods. Ensembling predictions from different models also lead to notable performance increases. Our best-performing model, a finetuned MedNeXt, achieved an average lesion-wise Dice score of 0.84, with individual scores of 0.81 (enhancing tumor), 0.81 (tumor core), and 0.91 (whole tumor). While further improvements are expected with extended training and larger datasets, these results demonstrate the feasibility of deploying deep learning for reliable tumor segmentation in resource-limited settings. We further highlight the need to improve local data acquisition protocols to support the development of clinically relevant, region-specific AI tools.
title Brain Tumor Segmentation in Sub-Sahara Africa with Advanced Transformer and ConvNet Methods: Fine-Tuning, Data Mixing and Ensembling
topic Quantitative Methods
url https://arxiv.org/abs/2508.10905