Fully Automated Tumor Segmentation for Brain MRI data using Multiplanner UNet

Publikation: Working paperPreprintForskning

Standard

Fully Automated Tumor Segmentation for Brain MRI data using Multiplanner UNet. / Pandey, Sumit; Changdar, Satyasaran; Perslev, Mathias; Dam, Erik B.

2024.

Publikation: Working paperPreprintForskning

Harvard

Pandey, S, Changdar, S, Perslev, M & Dam, EB 2024 'Fully Automated Tumor Segmentation for Brain MRI data using Multiplanner UNet'.

APA

Pandey, S., Changdar, S., Perslev, M., & Dam, E. B. (2024). Fully Automated Tumor Segmentation for Brain MRI data using Multiplanner UNet.

Vancouver

Pandey S, Changdar S, Perslev M, Dam EB. Fully Automated Tumor Segmentation for Brain MRI data using Multiplanner UNet. 2024 jan. 12.

Author

Pandey, Sumit ; Changdar, Satyasaran ; Perslev, Mathias ; Dam, Erik B. / Fully Automated Tumor Segmentation for Brain MRI data using Multiplanner UNet. 2024.

Bibtex

@techreport{85125b38ed9c4c79931a1bbedec2a533,
title = "Fully Automated Tumor Segmentation for Brain MRI data using Multiplanner UNet",
abstract = "Automated segmentation of distinct tumor regions is critical for accurate diagnosis and treatment planning in pediatric brain tumors. This study evaluates the efficacy of the Multi-Planner U-Net (MPUnet) approach in segmenting different tumor subregions across three challenging datasets: Pediatrics Tumor Challenge (PED), Brain Metastasis Challenge (MET), and Sub-Sahara-Africa Adult Glioma (SSA). These datasets represent diverse scenarios and anatomical variations, making them suitable for assessing the robustness and generalization capabilities of the MPUnet model. By utilizing multi-planar information, the MPUnet architecture aims to enhance segmentation accuracy. Our results show varying performance levels across the evaluated challenges, with the tumor core (TC) class demonstrating relatively higher segmentation accuracy. However, variability is observed in the segmentation of other classes, such as the edema and enhancing tumor (ET) regions. These findings emphasize the complexity of brain tumor segmentation and highlight the potential for further refinement of the MPUnet approach and inclusion of MRI more data and preprocessing.",
keywords = "eess.IV, cs.CV, cs.LG",
author = "Sumit Pandey and Satyasaran Changdar and Mathias Perslev and Dam, {Erik B}",
year = "2024",
month = jan,
day = "12",
language = "English",
type = "WorkingPaper",

}

RIS

TY - UNPB

T1 - Fully Automated Tumor Segmentation for Brain MRI data using Multiplanner UNet

AU - Pandey, Sumit

AU - Changdar, Satyasaran

AU - Perslev, Mathias

AU - Dam, Erik B

PY - 2024/1/12

Y1 - 2024/1/12

N2 - Automated segmentation of distinct tumor regions is critical for accurate diagnosis and treatment planning in pediatric brain tumors. This study evaluates the efficacy of the Multi-Planner U-Net (MPUnet) approach in segmenting different tumor subregions across three challenging datasets: Pediatrics Tumor Challenge (PED), Brain Metastasis Challenge (MET), and Sub-Sahara-Africa Adult Glioma (SSA). These datasets represent diverse scenarios and anatomical variations, making them suitable for assessing the robustness and generalization capabilities of the MPUnet model. By utilizing multi-planar information, the MPUnet architecture aims to enhance segmentation accuracy. Our results show varying performance levels across the evaluated challenges, with the tumor core (TC) class demonstrating relatively higher segmentation accuracy. However, variability is observed in the segmentation of other classes, such as the edema and enhancing tumor (ET) regions. These findings emphasize the complexity of brain tumor segmentation and highlight the potential for further refinement of the MPUnet approach and inclusion of MRI more data and preprocessing.

AB - Automated segmentation of distinct tumor regions is critical for accurate diagnosis and treatment planning in pediatric brain tumors. This study evaluates the efficacy of the Multi-Planner U-Net (MPUnet) approach in segmenting different tumor subregions across three challenging datasets: Pediatrics Tumor Challenge (PED), Brain Metastasis Challenge (MET), and Sub-Sahara-Africa Adult Glioma (SSA). These datasets represent diverse scenarios and anatomical variations, making them suitable for assessing the robustness and generalization capabilities of the MPUnet model. By utilizing multi-planar information, the MPUnet architecture aims to enhance segmentation accuracy. Our results show varying performance levels across the evaluated challenges, with the tumor core (TC) class demonstrating relatively higher segmentation accuracy. However, variability is observed in the segmentation of other classes, such as the edema and enhancing tumor (ET) regions. These findings emphasize the complexity of brain tumor segmentation and highlight the potential for further refinement of the MPUnet approach and inclusion of MRI more data and preprocessing.

KW - eess.IV

KW - cs.CV

KW - cs.LG

M3 - Preprint

BT - Fully Automated Tumor Segmentation for Brain MRI data using Multiplanner UNet

ER -

ID: 383560469