WGCAMNet: Wasserstein Generative Adversarial Network Augmented and Custom Attention Mechanism Based Deep Neural Network for Enhanced Brain Tumor Detection and Classification
Abstract
:1. Introduction
- A new deep learning framework for brain tumor detection and classification has been proposed, in which modified VGG19 and Inception v3 architectures, custom attention mechanism in the feature extraction along with classification layers are implemented.
- In the data preprocessing, images in the dataset have been balanced and augmented using Wasserstein Generative Adversarial Network (WGAN) to generate synthetic images, and a Gaussian filter has also been used for the noise reduction and enhancement of the quality of MRI images.
- After training the proposed model, the performance evaluation metrics have shown excellent results which will be very promising with the comparison of the existing models for brain tumor detection and classification.
- The model’s explainability through t-SNE plots shows distinct tumor clusters and Grad-CAM highlights crucial areas in MRI scans.
2. Related Works
2.1. Convolutional Neural Network (CNN)-Based Methods
2.2. Hybrid Models
2.3. Lightweight Models
3. Materials and Methods
3.1. Dataset
3.2. Data Loading and Preparation
- Standard Normalization:
- Min-Max Normalization:
- GAN Normalization:
3.3. WGAN for Data Augmentation
3.4. Proposed Classifier Model
3.5. Training and Evaluation
4. Results
4.1. Experimental Setup
4.2. Data Filtering Impact
4.3. Data Augmentation Results
4.4. Classifier Performance
- Loss: 0.0153
- Accuracy: 0.9961
- Precision: 0.9960
- Recall: 0.9960
- AUC: 0.9999
4.5. Confusion Matrix and Visualization
5. Discussion
6. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Reference | Methods | Performance Metrics |
---|---|---|
Hossain et al. [16] | Fuzzy C-Means clustering, traditional classifiers (SVM, KNN, MLP, etc.), CNN | CNN accuracy: 97.87% |
Khan et al. [17] | 23-layer CNN, transfer learning with VGG16 | Accuracy: 97.8% (binary), 100% (multiclass) |
Shah et al. [18] | Fine-tuned EfficientNet-B0, data augmentation, image enhancement | Accuracy: 98.87% |
Saeedi et al. [19] | 2D CNN, convolutional auto-encoder, traditional ML methods (MLP, KNN, etc.) | 2D CNN Accuracy: 96.47%, Auto-encoder Accuracy: 95.63%, AUC: 0.99, Recall: 95% |
Aggarwal et al. [20] | Improved ResNet for segmentation | >10% improvement in accuracy, recall, F1-score |
Khaliki et al. [21] | CNN, Inception-V3, EfficientNetB4, VGG19, transfer learning | Best accuracy: 98% (VGG16), F-score: 97%, AUC: 99%, Recall: 98%, Precision: 98% |
Alsubai et al. [22] | Hybrid CNN-LSTM, data preprocessing, CNN feature extraction | Accuracy: 99.1%, Precision: 98.8%, Recall: 98.9%, F1-score: 99.0% |
Mahum et al. [23] | Mayfly optimization, ResNet-V2, BiLSTM | High accuracy, precision, recall, F1 score, AUC |
Sailunaz et al. [24] | CNN, U-Net, U-Net++ for 2D and 3D MRI segmentation | Accuracy and Dice scores above 90% |
Asiri et al. [25] | Fine-tuned CNN with ResNet50, U-Net for segmentation | IoU: 0.91, DSC: 0.95, SI: 0.95 |
Saad et al. [26] | Hybrid algorithm for brain tumor detection, CAD | Detection accuracy: 96.6% |
Anantharajan et al. [27] | Ensemble Deep Neural SVM, Fuzzy C-means, GLCM | Accuracy: 97.93%, Sensitivity: 92%, Specificity: 98% |
Mahmud et al. [28] | CNN architecture compared with ResNet-50, VGG16, Inception V3 | Accuracy: 93.3%, AUC: 98.43%, Recall: 91.19%, Loss: 0.25 |
Hammad et al. [29] | CNN-based model for IoMT applications, lightweight design | Accuracy: 99.48% (binary), 96.86% (multi-class) |
Ghauri et al. [30] | Clean-energy cloud-based DL platform, multi-layer CNN | Precision: 96.8% |
Type of Brain Tumor | Training Set | Testing Set |
---|---|---|
Glioma | 1321 | 300 |
Meningioma | 1339 | 306 |
No tumor | 1595 | 405 |
Pituitary | 1457 | 300 |
Total | 5712 | 1270 |
Metric | Equation | Notes |
---|---|---|
Accuracy | TP: True Positives | |
Precision | TN: True Negatives | |
Recall (Sensitivity) | FP: False Positives | |
F1 Score | FN: False Negatives |
Augmentation Method | Loss | Accuracy | Precision | Recall | AUC |
---|---|---|---|---|---|
No Augmentation | 0.1889 | 93.12% | 0.9348 | 0.9304 | 0.9923 |
Traditional Augmentation | 0.1666 | 95.50% | 0.9561 | 0.9525 | 0.9936 |
WGAN Augmentation | 0.0153 | 99.60% | 0.9960 | 0.9960 | 0.9999 |
Fold | Accuracy | Loss | Precision | Recall | AUC |
---|---|---|---|---|---|
Fold 1 | 0.9920 | 0.0375 | 0.9910 | 0.9905 | 0.9990 |
Fold 2 | 0.9875 | 0.0405 | 0.9860 | 0.9880 | 0.9980 |
Fold 3 | 0.9905 | 0.0380 | 0.9880 | 0.9920 | 0.9996 |
Fold 4 | 0.9915 | 0.0380 | 0.9900 | 0.9890 | 0.9998 |
Fold 5 | 0.9890 | 0.0395 | 0.9885 | 0.9875 | 0.9995 |
Average | 0.9902 | 0.0389 | 0.9889 | 0.9894 | 0.9996 |
Reference | Dataset | Preprocessing Method | Model Architecture | Performance Metrics |
---|---|---|---|---|
Chaki et al. [34] | [31] | Fuzzy Inference System | Deep Brain INCEP Res Architecture 2.0 Based Reinforcement Learning Network | Accuracy: 97.5% |
Arumugam et al. [35] | [31] | Cropping and denoising by Gaussian filter | CNN with Multi Layer Perception | Accuracy: 98.5%, Sensitivity: 98.6%, Specificity: 98.4% |
Amarnath et al. [36] | [31] | Traditional Augmentation | ResNet50 | Accuracy: 87.9%, F1 Score: 79.6% |
Amarnath et al. [36] | [31] | Traditional Augmentation | Xception | Accuracy: 98.1%, F1 Score: 98.1% |
Amarnath et al. [36] | [31] | Traditional Augmentation | EfficientNetV2-S | Accuracy: 96.1%, F1 Score: 96.2% |
Amarnath et al. [36] | [31] | Traditional Augmentation | ResNet152V2 | Accuracy: 78.5%, F1 Score: 79.9% |
Amarnath et al. [36] | [31] | Traditional Augmentation | VGG16 | Accuracy: 76.8%, F1 Score: 77.5% |
Vu et al. [37] | [31] | Smoothing with a Kernel, Bilateral Filtering, Gray scale conversion and Traditional Augmentation | Modified ResNet50 | Accuracy: 75% |
Proposed Model | [31] | WGAN and Gaussian Filter | WGCAMNet | Accuracy: 99.61%, Precision: 99.60%, Recall: 99.60%, AUC: 99.99%, Loss: 0.0153 |
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Share and Cite
Alam, F.B.; Fahim, T.A.; Asef, M.; Hossain, M.A.; Dewan, M.A.A. WGCAMNet: Wasserstein Generative Adversarial Network Augmented and Custom Attention Mechanism Based Deep Neural Network for Enhanced Brain Tumor Detection and Classification. Information 2024, 15, 560. https://doi.org/10.3390/info15090560
Alam FB, Fahim TA, Asef M, Hossain MA, Dewan MAA. WGCAMNet: Wasserstein Generative Adversarial Network Augmented and Custom Attention Mechanism Based Deep Neural Network for Enhanced Brain Tumor Detection and Classification. Information. 2024; 15(9):560. https://doi.org/10.3390/info15090560
Chicago/Turabian StyleAlam, Fatema Binte, Tahasin Ahmed Fahim, Md Asef, Md Azad Hossain, and M. Ali Akber Dewan. 2024. "WGCAMNet: Wasserstein Generative Adversarial Network Augmented and Custom Attention Mechanism Based Deep Neural Network for Enhanced Brain Tumor Detection and Classification" Information 15, no. 9: 560. https://doi.org/10.3390/info15090560
APA StyleAlam, F. B., Fahim, T. A., Asef, M., Hossain, M. A., & Dewan, M. A. A. (2024). WGCAMNet: Wasserstein Generative Adversarial Network Augmented and Custom Attention Mechanism Based Deep Neural Network for Enhanced Brain Tumor Detection and Classification. Information, 15(9), 560. https://doi.org/10.3390/info15090560