DDFC: deep learning approach for deep feature extraction and classification of brain tumors using magnetic resonance imaging in E-healthcare system

Saboor, Abdus; Li, Jian Ping; Ul Haq, Amin; Shehzad, Umer; Khan, Shakir; Aotaibi, Reemiah Muneer; Alajlan, Saad Abdullah

doi:10.1038/s41598-024-56983-6

Sci Rep

2024

DOI: 10.1038/s41598-024-56983-6

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DDFC: deep learning approach for deep feature extraction and classification of brain tumors using magnetic resonance imaging in E-healthcare system

Abdus Saboor,

Jian Ping Li,

Amin Ul Haq

et al.

Abstract: This research explores the use of gated recurrent units (GRUs) for automated brain tumor detection using MRI data. The GRU model captures sequential patterns and considers spatial information within individual MRI images and the temporal evolution of lesion characteristics. The proposed approach improves the accuracy of tumor detection using MRI images. The model’s performance is benchmarked against conventional CNNs and other recurrent architectures. The research addresses interpretability concerns by employi… Show more

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Cited by 6 publications

References 36 publications

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A systematic review of trending technologies in non-invasive automatic brain tumor detection

Jyoti,

Kumar

2024

Multimed Tools Appl

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A systematic review of trending technologies in non-invasive automatic brain tumor detection

Jyoti,

Kumar

2024

Multimed Tools Appl

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Optimized deep learning model for comprehensive medical image analysis across multiple modalities

Khan,

Asif,

Zhao

et al. 2025

Neurocomputing

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Ultra-wideband Imaging of Breast Tumors Based on Global Back Projection Algorithm

Fan,

Li,

et al. 2024

J. Phys.: Conf. Ser.

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Tumor imaging in medicine requires consideration of human safety, image quality clarity, and cost of imaging. Ultra-wideband (UWB) technology employs large bandwidth channels that enable high-speed data transmission. This determines that it can provide high-quality images quickly while still being a harmless imaging method. Therefore, it is essential to construct a UWB microwave detection tumor system. The creation of a vector network analyzer (VNA) based microwave imaging system in this work. To adapt to breast imaging, this paper improved the imaging algorithm of global back projection (GBP) based on the classical back projection algorithm. To verify the system’s feasibility, this paper performed UWB detection experiments using a breast tumor model. By comparing the simulation results, the final imaging results show that the UWB imaging system can detect tumors located at two different locations in the model and that high-quality images can be obtained in the near field using the GBP algorithm. This paper provides a reliable and low-cost method for medical diagnosis.

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DDFC: deep learning approach for deep feature extraction and classification of brain tumors using magnetic resonance imaging in E-healthcare system

Cited by 6 publications

References 36 publications

A systematic review of trending technologies in non-invasive automatic brain tumor detection

A systematic review of trending technologies in non-invasive automatic brain tumor detection

Optimized deep learning model for comprehensive medical image analysis across multiple modalities

Ultra-wideband Imaging of Breast Tumors Based on Global Back Projection Algorithm

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