An Enhanced Transfer Learning Based Classification for Diagnosis of Skin Cancer

Anand, Vatsala; Gupta, Sheifali; Altameem, Ayman; Nayak, Soumya Ranjan; Poonia, Ramesh Chandra; Saudagar, Abdul Khader Jilani

doi:10.3390/diagnostics12071628

Cited by 80 publications

(10 citation statements)

References 35 publications

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“…Finally, LeakyReLU was selected in hidden layers because (1) it is more efficient than sigmoid and tanh, rendering faster training, and (2) it allows for a small gradient for negative outputs, which helps prevent the vanishing gradient problem. These choices are supported by previous work that used similar settings [13, 26, 27] and empirical results from our early optimization experiments.…”

Section: Methodssupporting

confidence: 69%

Adversarial Learning for MRI Reconstruction and Classification of Cognitively Impaired Individuals

Zhou,

Balachandra,

Romano

et al. 2023

Preprint

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Game theory-inspired deep learning using a generative adversarial network provides an environment to competitively interact and accomplish a goal. In the context of medical imaging, most work has focused on achieving single tasks such as improving image resolution, segmenting images, and correcting motion artifacts. We present a dual-objective adversarial learning framework that simultaneously (1) reconstructs higher quality brain magnetic resonance images (MRIs) that (2) retain disease-specific imaging features critical for predicting progression from mild cognitive impairment (MCI) to Alzheimer’s disease (AD). We obtained 3-Tesla, T1-weighted brain MRIs of participants from the Alzheimer’s Disease Neuroimaging Initiative (ADNI, N=342) and the National Alzheimer’s Coordinating Center (NACC, N=190) datasets. We simulated MRIs with missing data by removing 50% of sagittal slices from the original scans (i.e., diced scans). The generator was trained to reconstruct brain MRIs using the diced scans as input. We introduced a classifier into the GAN architecture to discriminate between stable (i.e., sMCI) and progressive MCI (i.e., pMCI) based on the generated images to facilitate encoding of AD-related information during reconstruction. The framework was trained using ADNI data and externally validated on NACC data. In the NACC cohort, generated images had better image quality than the diced scans (SSIM: 0.553 ± 0.116 versus 0.348 ± 0.108). Furthermore, a classifier utilizing the generated images distinguished pMCI from sMCI more accurately than with the diced scans (F1-score: 0.634 ± 0.019 versus 0.573 ± 0.028). Competitive deep learning has potential to facilitate disease-oriented image reconstruction in those at risk of developing Alzheimer’s disease.

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Section: Methodssupporting

confidence: 69%

Adversarial Learning for MRI Reconstruction and Classification of Cognitively Impaired Individuals

Zhou,

Balachandra,

Romano

et al. 2023

Preprint

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“…To better represent the good performance of HI-MViT in skin lesion classification, we selected six latest networks 70 – 75 specifically designed for skin lesion classification for comparison, and the results are shown in Table 8 . As can be seen, Table 8 covers CNN-based, Transformer-based, and lightweight networks, and in comparison, our method has a better accuracy score on the ISIC-2018 dataset.…”

Section: Resultsmentioning

confidence: 99%

HI-MViT: A lightweight model for explainable skin disease classification based on modified MobileViT

Ding,

Yi,

et al. 2023

DIGITAL HEALTH

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Objective To develop an explainable lightweight skin disease high-precision classification model that can be deployed to the mobile terminal. Methods In this study, we present HI-MViT, a lightweight network for explainable skin disease classification based on Modified MobileViT. HI-MViT is mainly composed of ordinary convolution, Improved-MV2, MobileViT block, global pooling, and fully connected layers. Improved-MV2 uses the combination of shortcut and depth classifiable convolution to substantially decrease the amount of computation while ensuring the efficient implementation of information interaction and memory. The MobileViT block can efficiently encode local and global information. In addition, semantic feature dimensionality reduction visualization and class activation mapping visualization methods are used for HI-MViT to further understand the attention area of the model when learning skin lesion images. Results The International Skin Imaging Collaboration has assembled and made available the ISIC series dataset. Experiments using the HI-MViT model on the ISIC-2018 dataset achieved scores of 0.931, 0.932, 0.961, and 0.977 on F1-Score, Accuracy, Average Precision (AP), and area under the curve (AUC). Compared with the top five algorithms of ISIC-2018 Task 3, Marco's average F1-Score, AP, and AUC have increased by 6.9%, 6.8%, and 0.8% compared with the suboptimal performance model. Compared with ConvNeXt, the most competitive convolutional neural network architecture, our model is 5.0%, 3.4%, 2.3%, and 2.2% higher in F1-Score, Accuracy, AP, and AUC, respectively. The experiments on the ISIC-2017 dataset also achieved excellent results, and all indicators were better than the top five algorithms of ISIC-2017 Task 3. Using the trained model to test on the PH2 dataset, an excellent performance score is obtained, which shows that it has good generalization performance. Conclusions The skin disease classification model HI-MViT proposed in this article shows excellent classification performance and generalization performance in experiments. It demonstrates how the classification outcomes can be applied to dermatologists’ computer-assisted diagnostics, enabling medical professionals to classify various dermoscopic images more rapidly and reliably.

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“…VGG16 with transfer learning was found to outperform other techniques in terms of accuracy and efficiency. This is attributed to its deep network structure and the ability to adapt to specific tasks through the use of pre-trained weights, resulting in better performance in the classification of skin lesions, as has been documented in various investigations ( Anand et al., 2022 ). Alwakid et al (2022) proposed an approach that incorporates ESRGAN, segmentation techniques, and a CNN along with a modified version of Resnet-50 for accurate classification.…”

Section: Introductionmentioning

confidence: 88%

The effect of hair removal and filtering on melanoma detection: a comparative deep learning study with AlexNet CNN

Quishpe-Usca,

Cuenca-Dominguez,

Arias-Viñansaca

et al. 2024

PeerJ Computer Science

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Melanoma is the most aggressive and prevalent form of skin cancer globally, with a higher incidence in men and individuals with fair skin. Early detection of melanoma is essential for the successful treatment and prevention of metastasis. In this context, deep learning methods, distinguished by their ability to perform automated and detailed analysis, extracting melanoma-specific features, have emerged. These approaches excel in performing large-scale analysis, optimizing time, and providing accurate diagnoses, contributing to timely treatments compared to conventional diagnostic methods. The present study offers a methodology to assess the effectiveness of an AlexNet-based convolutional neural network (CNN) in identifying early-stage melanomas. The model is trained on a balanced dataset of 10,605 dermoscopic images, and on modified datasets where hair, a potential obstructive factor, was detected and removed allowing for an assessment of how hair removal affects the model’s overall performance. To perform hair removal, we propose a morphological algorithm combined with different filtering techniques for comparison: Fourier, Wavelet, average blur, and low-pass filters. The model is evaluated through 10-fold cross-validation and the metrics of accuracy, recall, precision, and the F1 score. The results demonstrate that the proposed model performs the best for the dataset where we implemented both a Wavelet filter and hair removal algorithm. It has an accuracy of 91.30%, a recall of 87%, a precision of 95.19%, and an F1 score of 90.91%.

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An Enhanced Transfer Learning Based Classification for Diagnosis of Skin Cancer

Cited by 80 publications

References 35 publications

Adversarial Learning for MRI Reconstruction and Classification of Cognitively Impaired Individuals

Adversarial Learning for MRI Reconstruction and Classification of Cognitively Impaired Individuals

HI-MViT: A lightweight model for explainable skin disease classification based on modified MobileViT

The effect of hair removal and filtering on melanoma detection: a comparative deep learning study with AlexNet CNN

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