Survival and grade of the glioma prediction using transfer learning

Valbuena Rubio, Santiago; García-Ordás, María Teresa; García-Olalla Olivera, Oscar; Alaiz-Moretón, Héctor; González-Alonso, Maria-Inmaculada; Benítez-Andrades, José Alberto

doi:10.7717/peerj-cs.1723

PeerJ Computer Science

2023

DOI: 10.7717/peerj-cs.1723

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Survival and grade of the glioma prediction using transfer learning

Santiago Valbuena Rubio,

María Teresa García-Ordás,

Oscar García-Olalla Olivera

et al.

Abstract: Glioblastoma is a highly malignant brain tumor with a life expectancy of only 3–6 months without treatment. Detecting and predicting its survival and grade accurately are crucial. This study introduces a novel approach using transfer learning techniques. Various pre-trained networks, including EfficientNet, ResNet, VGG16, and Inception, were tested through exhaustive optimization to identify the most suitable architecture. Transfer learning was applied to fine-tune these models on a glioblastoma image dataset,… Show more

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2024

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Cited by 2 publications

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Advancing glioma diagnosis: Integrating custom U-Net and VGG-16 for improved grading in MR imaging

Saluja,

Trivedi,

Sarangdevot

2024

MBE

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<abstract> <p>In the realm of medical imaging, the precise segmentation and classification of gliomas represent fundamental challenges with profound clinical implications. Leveraging the BraTS 2018 dataset as a standard benchmark, this study delves into the potential of advanced deep learning models for addressing these challenges. We propose a novel approach that integrates a customized U-Net for segmentation and VGG-16 for classification. The U-Net, with its tailored encoder-decoder pathways, accurately identifies glioma regions, thus improving tumor localization. The fine-tuned VGG-16, featuring a customized output layer, precisely differentiates between low-grade and high-grade gliomas. To ensure consistency in data pre-processing, a standardized methodology involving gamma correction, data augmentation, and normalization is introduced. This novel integration surpasses existing methods, offering significantly improved glioma diagnosis, validated by high segmentation dice scores (WT: 0.96, TC: 0.92, ET: 0.89), and a remarkable overall classification accuracy of 97.89%. The experimental findings underscore the potential of integrating deep learning-based methodologies for tumor segmentation and classification in enhancing glioma diagnosis and formulating subsequent treatment strategies.</p> </abstract>

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Advancing glioma diagnosis: Integrating custom U-Net and VGG-16 for improved grading in MR imaging

Saluja,

Trivedi,

Sarangdevot

2024

MBE

View full text Add to dashboard Cite

show abstract

Deep CNNs for glioma grading on conventional MRIs: Performance analysis, challenges, and future directions

Saluja,

Trivedi,

Saha

2024

MBE

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<abstract> <p>The increasing global incidence of glioma tumors has raised significant healthcare concerns due to their high mortality rates. Traditionally, tumor diagnosis relies on visual analysis of medical imaging and invasive biopsies for precise grading. As an alternative, computer-assisted methods, particularly deep convolutional neural networks (DCNNs), have gained traction. This research paper explores the recent advancements in DCNNs for glioma grading using brain magnetic resonance images (MRIs) from 2015 to 2023. The study evaluated various DCNN architectures and their performance, revealing remarkable results with models such as hybrid and ensemble based DCNNs achieving accuracy levels of up to 98.91%. However, challenges persisted in the form of limited datasets, lack of external validation, and variations in grading formulations across diverse literature sources. Addressing these challenges through expanding datasets, conducting external validation, and standardizing grading formulations can enhance the performance and reliability of DCNNs in glioma grading, thereby advancing brain tumor classification and extending its applications to other neurological disorders.</p> </abstract>

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Survival and grade of the glioma prediction using transfer learning

Cited by 2 publications

References 55 publications

Advancing glioma diagnosis: Integrating custom U-Net and VGG-16 for improved grading in MR imaging

Advancing glioma diagnosis: Integrating custom U-Net and VGG-16 for improved grading in MR imaging

Deep CNNs for glioma grading on conventional MRIs: Performance analysis, challenges, and future directions

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