A Novel and Effective Brain Tumor Classification Model Using Deep Feature Fusion and Famous Machine Learning Classifiers

Kibriya, Hareem; Amin, Rashid; Alshehri, Asma Hassan; Masood, Momina; Alshamrani, Sultan S.; Alshehri, Abdullah

doi:10.1155/2022/7897669

Cited by 55 publications

(35 citation statements)

References 46 publications

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“…In this work, various isolated trained CNNs (19, 22, and 25 layers) were utilized to extract the deep features. The deep features were extracted using the transfer learning method, as discussed in [ 26 , 35 ]. The authors computed the deep features of the pre-trained model for the brain MRI dataset and concatenated various features for better classification performance.…”

Section: Methodsmentioning

confidence: 99%

Isolated Convolutional-Neural-Network-Based Deep-Feature Extraction for Brain Tumor Classification Using Shallow Classifier

et al. 2022

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In today’s world, a brain tumor is one of the most serious diseases. If it is detected at an advanced stage, it might lead to a very limited survival rate. Therefore, brain tumor classification is crucial for appropriate therapeutic planning to improve patient life quality. This research investigates a deep-feature-trained brain tumor detection and differentiation model using classical/linear machine learning classifiers (MLCs). In this study, transfer learning is used to obtain deep brain magnetic resonance imaging (MRI) scan features from a constructed convolutional neural network (CNN). First, multiple layers (19, 22, and 25) of isolated CNNs are constructed and trained to evaluate the performance. The developed CNN models are then utilized for training the multiple MLCs by extracting deep features via transfer learning. The available brain MRI datasets are employed to validate the proposed approach. The deep features of pre-trained models are also extracted to evaluate and compare their performance with the proposed approach. The proposed CNN deep-feature-trained support vector machine model yielded higher accuracy than other commonly used pre-trained deep-feature MLC training models. The presented approach detects and distinguishes brain tumors with 98% accuracy. It also has a good classification rate (97.2%) for an unknown dataset not used to train the model. Following extensive testing and analysis, the suggested technique might be helpful in assisting doctors in diagnosing brain tumors.

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Section: Methodsmentioning

confidence: 99%

Isolated Convolutional-Neural-Network-Based Deep-Feature Extraction for Brain Tumor Classification Using Shallow Classifier

et al. 2022

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“…In the past decade, with the rise of CNNs and emerging leading computational resources (e.g., graphics processing unit and tensor processing unit, multiple strategies have been put forth for BT classification by calibrating the CNN models, such as VGG16, AlexNet, ResNets, DenseNets, Inception, and Xception, which had already been successfully applied for various computer‐based visualizations) [57–62] . The above pre‐trained localized convolution‐based CNN models indicated excellent BT classification capability across vast datasets [63–65] . However, despite their tremendous success, they carry inductive biases, such as the local receptive field's translation equivariance.…”

Section: The Roles Of Transformers In Mri‐ and Histopathology‐based B...mentioning

confidence: 99%

“…[57][58][59][60][61][62] The above pre-trained localized convolution-based CNN models indicated excellent BT classification capability across vast datasets. [63][64][65] However, despite their tremendous success, they carry inductive biases, such as the local receptive field's translation equivariance. Because of these biases, CNN models present difficulties while learning long-range information; furthermore, CNNs generally require data augmentation for better performance owing to their need for local pixel differentiation during learning.…”

Section: The Roles Of Transformers In Mri-and Histopathology-based Br...mentioning

confidence: 99%

Potential roles of transformers in brain tumor diagnosis and treatment

Lan

Zou

Qin

et al. 2023

Brain-X

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Brain tumor (BT) is one of many malignancies that have substantially enhanced global human morbidity and mortality rates. Early detection and characterization of glioma are essential for effective preventive strategies. Currently, the use of Transformers, a deep learning model for BT diagnosis and treatment, is attracting significant attention. The transformer self‐attention mechanism automatically learns the associations between input data for efficient processing and analysis. Research indicates that Transformers could play an essential role in the BT segmentation of magnetic resonance imaging (MRI) images, the MRI and histopathology‐based grading of brain cancer, BT molecular expression prediction, the classification of primary brain metastasis sites, voxel‐level dose and BT radiotherapy outcome prediction, synergistic prediction, and the pathway deconvolution of drug combinations. In this review, the feasibility, accuracy, and applicability of various algorithms are systematically analyzed and their prospects are discussed. Overall, this review aimed to discuss and provide an overview of the increasing applications of Transformers in real‐time BT detection and therapy, indicating their broad prospects and potential. In the future, Transformers are expected to be increasingly used for the diagnosis and subsequent treatment of BT because of the continuous development and improvement of Transformer‐based deep learning technology. However, more work is required to investigate their properties for anomaly detection, medical image classification, network design development, and application to other medical data.

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“…The study places significant emphasis on the critical importance of brain cancer categorization, which has traditionally relied upon the expertise of clinicians [14]. The authors emphasize the need for improved automated tumour categorization systems to assist radiologists in achieving precise diagnostic outcomes.…”

Section: Brain Tumour Classification Based On Feature Extraction Tech...mentioning

confidence: 99%

MEHW‐SVM multi‐kernel approach for improved brain tumour classification

Dheepak,

Anita Christaline,

Vaishali

2023

IET Image Processing

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The human brain, the primary constituent of the nervous system, exhibits distinctive complexities that present considerable difficulties for healthcare practitioners, specifically in categorizing brain tumours. Magnetic resonance imaging is a widely favoured imaging modality for detecting brain tumours due to its extensive range of image characteristics and utilization of non‐ionizing radiation. The primary objective of the current investigation is to differentiate between three distinct classifications of brain tumours by introducing a novel methodology. The utilization of a combined feature extraction technique that integrates novel global grey level co‐occurrence matrix and local binary patterns is employed, thereby offering a comprehensive representation of the structural and textural information contained within the images. Principal component analysis is used to improve the model's efficiency for effective feature selection and dimensionality reduction. This study presents a novel framework incorporating four separate kernel functions, Minkowski–Gaussian, exponential support vector machine (SVM), histogram intersection SVM, and wavelet kernel, into a SVM classifier. The ensemble kernel employed in this study is specifically designed to classify glioma, meningioma, and pituitary tumours. Its implementation enhances the model's robustness and adaptability, surpassing the performance of conventional single‐kernel SVM approaches. This study substantially contributes to medical image classification by utilizing innovative kernel functions and advanced machine‐learning techniques. The findings demonstrate the potential for enhanced diagnostic accuracy in brain tumour cases. The presented approach shows promise in effectively addressing the intricate challenges associated with classifying brain tumours.

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A Novel and Effective Brain Tumor Classification Model Using Deep Feature Fusion and Famous Machine Learning Classifiers

Cited by 55 publications

References 46 publications

Isolated Convolutional-Neural-Network-Based Deep-Feature Extraction for Brain Tumor Classification Using Shallow Classifier

Isolated Convolutional-Neural-Network-Based Deep-Feature Extraction for Brain Tumor Classification Using Shallow Classifier

Potential roles of transformers in brain tumor diagnosis and treatment

MEHW‐SVM multi‐kernel approach for improved brain tumour classification

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