Transfer Learning-Based Multi-Scale Denoising Convolutional Neural Network for Prostate Cancer Detection

Chui, Kwok Tai; Gupta, Brij B.; Ran, Hao; Arya, Varsha; Alhalabi, Wadee; Torres-Ruiz, Miguel; Shen, Chien Wen

doi:10.3390/cancers14153687

Cited by 27 publications

(18 citation statements)

References 41 publications

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“…This report compares and contrasts the efficacy of deep learning and machine learning approaches to the study of breast cancer [4]. Our work here was informed by algorithms developed for the CAMELYON 17 competition.…”

Section: Methodsmentioning

confidence: 99%

“…Project features are extracted into a lower-dimensional feature space, and the newly produced features are frequently composites of the original features. Principle component analysis (PCA) is one example of feature extraction techniques [4]. Both feature extraction and feature selection have the potential to improve learning performance, reduce computational complexity, develop more generalizable models, and reduce storage requirements.…”

Section: Classifier Selection In Machine Learningmentioning

confidence: 99%

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CAMELYON 17 Challenge: A Comparison of Traditional Machine Learning (SVM) with the Deep Learning Method

Sun

Meng

Liu

2022

Wireless Communications and Mobile Computing

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The pathologist’s diagnosis is crucial in identifying and categorizing pathological cancer sections, as well as in the physician’s subsequent evaluation of the patient’s condition and therapy. It is recognised as the “gold standard”; however, both objective and subjective pathological diagnoses have limits, such as tissue corruption resulting from the nonstandard collection of diseased tissue, nonstandard tissue fixation or delivery, or a lack of necessary clinical data. In addition, diagnostic pathology encompasses too much information; thus, it requires time and effort to grow a trained pathologist. Consequently, computer-assisted diagnosis has become an essential tool for replacing or assisting pathologists with computer technology and graphical development. In this regard, the CAMELYON 17 competition was designed to identify the best algorithm for detecting cancer metastases in the lymph. Each participant was given 899 whole-slide photos for the development of their algorithms. More than 300 people enrolled on the competition. CAMELYON 17 is primarily focused on the categorization of lymph node metastases. The TNM classification system is the primary classification system. Participants at CAMELYON 17 mostly use categorization and learning techniques in deep learning and machine learning. In order to get a better understanding of the top-selected algorithms, we examine the advantages and limitations of traditional machine learning and deep learning for classifying breast cancer metastases.

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Section: Methodsmentioning

confidence: 99%

Section: Classifier Selection In Machine Learningmentioning

confidence: 99%

CAMELYON 17 Challenge: A Comparison of Traditional Machine Learning (SVM) with the Deep Learning Method

Sun

Meng

Liu

2022

Wireless Communications and Mobile Computing

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“…In recent decades, many artificially assisted systems for cancer diagnosis have been thoroughly investigated, either through medical imaging analysis [19] or omic data analysis [5], [9], [20]. Although the incredible advancements brought about by AI in clinical applications cannot be understated, another need that must be met to improve genetic diagnosis, prognosis, and drug development is to provide models that assist biologists, clinicians, and the pharmaceutical industry in selecting molecular biomarkers with potential diagnosis, prognosis, and therapeutic targets.…”

Section: Related Workmentioning

confidence: 99%

Efficient Bioinspired Feature Selection and Machine Learning Based Framework Using Omics Data and Biological Knowledge Data Bases in Cancer Clinical Endpoint Prediction

et al. 2023

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Cancer Research has advanced during the past few years. Using high throughput technology and advances in artificial intelligence, it is now possible to improve cancer diagnosis and targeted therapy, by integrating the investigation and analysis of clinical and omics profiles. The high dimensionality and class imbalance of the majority of available data sets represent a serious challenge to the development of computational methods and tools for cancer diagnosis and biomarker discovery. Taking into account multi-omics data further complicates the undertaking. In this paper, we describe a five-step integrative architecture for dealing with the three aforementioned problems by incorporating proteomics data, proteinprotein interaction networks, and signaling pathways in order to identify protein biomarkers with a direct association to cancerous patients' overall survival (OS) and progression free interval (PFI). The core parts of this architecture are a cluster based grey wolf optimization algorithm (CB-GWO) for feature selection and a deep stacked canonical correlation autoencoder (DSCC-AE) for clinical endpoint prediction. A thorough experimental study was carried out to evaluate the performance of the proposed optimization algorithm for feature selection, as well as the performance of the deep learning model in terms of Mathew coefficient correlation (MCC) and Area under the curve (AUC) on breast, lung, colon, and rectum cancers. The results were compared to other methods in the literature. The results are very promising and show the effectiveness of the proposed framework and its ability to outperform the other algorithms and models in terms of AUC (0.91) and MCC (0.64).

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“…To examine the issue of model overftting and better fne-tuning the models, 5-fold cross-validation is adopted that has been justifed as a common setting of k-fold crossvalidation (with k � 5) [33,34]. Since 10 benchmark datasets are chosen, at most, the target model performs 9-round of MTL-MGAN from nine source datasets.…”

Section: Performance Evaluation Of the Mtl-mganmentioning

confidence: 99%

Multiround Transfer Learning and Modified Generative Adversarial Network for Lung Cancer Detection

Chui¹,

Gupta

Jhaveri

et al. 2023

International Journal of Intelligent Systems

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Lung cancer has been the leading cause of cancer death for many decades. With the advent of artificial intelligence, various machine learning models have been proposed for lung cancer detection (LCD). Typically, challenges in building an accurate LCD model are the small-scale datasets, the poor generalizability to detect unseen data, and the selection of useful source domains and prioritization of multiple source domains for transfer learning. In this paper, a multiround transfer learning and modified generative adversarial network (MTL-MGAN) algorithm is proposed for LCD. The MTL transfers the knowledge between the prioritized source domains and target domain to get rid of exhaust search of datasets prioritization among multiple datasets, maximizing the transferability with a multiround transfer learning process, and avoiding negative transfer via customization of loss functions in the aspects of domain, instance, and feature. In regard to the MGAN, it not only generates additional training data but also creates intermediate domains to bridge the gap between the source domains and target domains. 10 benchmark datasets are chosen for the performance evaluation and analysis of the MTL-MGAN. The proposed algorithm has significantly improved the accuracy compared with related works. To examine the contributions of the individual components of the MTL-MGAN, ablation studies are conducted to confirm the effectiveness of the prioritization algorithm, the MTL, the negative transfer avoidance via loss functions, and the MGAN. The research implications are to confirm the feasibility of multiround transfer learning to enhance the optimal solution of the target model and to provide a generic approach to bridge the gap between the source domain and target domain using MGAN.

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Transfer Learning-Based Multi-Scale Denoising Convolutional Neural Network for Prostate Cancer Detection

Cited by 27 publications

References 41 publications

CAMELYON 17 Challenge: A Comparison of Traditional Machine Learning (SVM) with the Deep Learning Method

CAMELYON 17 Challenge: A Comparison of Traditional Machine Learning (SVM) with the Deep Learning Method

Efficient Bioinspired Feature Selection and Machine Learning Based Framework Using Omics Data and Biological Knowledge Data Bases in Cancer Clinical Endpoint Prediction

Multiround Transfer Learning and Modified Generative Adversarial Network for Lung Cancer Detection

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