An IoT-Based Framework and Ensemble Optimized Deep Maxout Network Model for Breast Cancer Classification

Peta, Jyothi; Koppu, Srinivas

doi:10.3390/electronics11244137

Cited by 12 publications

(8 citation statements)

References 46 publications

(78 reference statements)

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“…Its ability to securely transmit, store and analyze data in real-time may assist radiologists in detection and characterization of breast lesions with increased efficiency and accuracy. Peta et al [ 42 ] proposed an IoT-based model using data from bio-thermal sensors for the classification of breast cancer. The model achieved an accuracy of above 90%.…”

Section: Discussionmentioning

confidence: 99%

‘Earlier than Early’ Detection of Breast Cancer in Israeli BRCA Mutation Carriers Applying AI-Based Analysis to Consecutive MRI Scans

Anaby,

Shavin,

Zimmerman-Moreno

et al. 2023

Cancers

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Female BRCA1/BRCA2 (=BRCA) pathogenic variants (PVs) carriers are at a substantially higher risk for developing breast cancer (BC) compared with the average risk population. Detection of BC at an early stage significantly improves prognosis. To facilitate early BC detection, a surveillance scheme is offered to BRCA PV carriers from age 25–30 years that includes annual MRI based breast imaging. Indeed, adherence to the recommended scheme has been shown to be associated with earlier disease stages at BC diagnosis, more in-situ pathology, smaller tumors, and less axillary involvement. While MRI is the most sensitive modality for BC detection in BRCA PV carriers, there are a significant number of overlooked or misinterpreted radiological lesions (mostly enhancing foci), leading to a delayed BC diagnosis at a more advanced stage. In this study we developed an artificial intelligence (AI)-network, aimed at a more accurate classification of enhancing foci, in MRIs of BRCA PV carriers, thus reducing false-negative interpretations. Retrospectively identified foci in prior MRIs that were either diagnosed as BC or benign/normal in a subsequent MRI were manually segmented and served as input for a convolutional network architecture. The model was successful in classification of 65% of the cancerous foci, most of them triple-negative BC. If validated, applying this scheme routinely may facilitate ‘earlier than early’ BC diagnosis in BRCA PV carriers.

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Section: Discussionmentioning

confidence: 99%

‘Earlier than Early’ Detection of Breast Cancer in Israeli BRCA Mutation Carriers Applying AI-Based Analysis to Consecutive MRI Scans

Anaby,

Shavin,

Zimmerman-Moreno

et al. 2023

Cancers

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“…The enhanced Deep Maxout model's mathematical formulation is explained in [29]. To improve model robustness, it adds the modified softmax activation function (G-SM) to Eq.…”

Section: Methodsmentioning

confidence: 99%

Deep Learning Approach for Workload Prediction and Balancing in Cloud Computing

Karimunnisa,

Pachipala

2024

IJACSA

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Cloud Computing voted as one of the most revolutionized technologies serving huge user demand engrosses a prominent place in research. Despite several parameters that influence the cloud performance, factors like Workload prediction and scheduling are triggering challenges for researchers in leveraging the system proficiency. Contributions by practitioners given workload prophesy left scope for further enhancement in terms of makespan, migration efficiency, and cost. Anticipating the future workload in due to avoid unfair allocation of cloud resources is a crucial aspect of efficient resource allocation. Our work aims to address this gap and improve efficiency by proposing a Deep Max-out prediction model, which predicts the future workload and facilitates workload balancing paving the path for enhanced scheduling with a hybrid Tasmanian Devil-assisted Bald Eagle Search (TES) optimization algorithm. The results evaluated proved that the TES scored efficiency in makespan with 16.342%, and migration efficiency of 14.75% over existing approaches like WACO, MPSO, and DBOA (Weighted Ant Colony Optimization Modified Particle Swarm Optimization, Discrete Butterfly Optimization Algorithm). Similarly, the error analysis during the evaluation of prediction performance has been figured out using different approaches like MSE, RMSE, MAE, and MSLE, among which our proposed method overwhelms with less error than the traditional methods.

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“…Tested on realworld datasets, the results indicate the algorithm's potential in large-scale, privacy-conscious survival analysis with maximum cumulative AUC of 95.6%. Finally, a recent study [36] proposed a comprehensive disease diagnosis system using federated and deep learning. It encompasses image acquisition, encryption for confidentiality using the E-EIE method, optimized key generation, secure data storage using federated learning, and classification using the C2T2Net model.…”

Section: Related Workmentioning

confidence: 99%

Federated Learning Approach for Breast Cancer Detection Based on DCNN

AlSalman,

Al-Rakhami,

Alfakih

et al. 2024

IEEE Access

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Breast cancer stands as one of the predominant health challenges globally, affecting millions of women every year and necessitating early and accurate detection to optimize patient outcomes. Currently, while deep convolutional neural networks (DCNNs) have shown promise in breast cancer detection, their application is often hampered by privacy concerns associated with sharing patient data and the limitation of training on small, localized datasets. Addressing these challenges, this manuscript introduces an effective federated learning approach tailored for breast cancer detection, leveraging DCNNs across diverse and large datasets without compromising data privacy. Our experimental findings underscore significant advancements in detection accuracy of 98.9% on three large scale datasets which are VINDR-MAMMO, CMMD, and INBREAST. Additionally, we tested the proposed federated learning performance, showcasing the potential of our approach as a robust and privacy-preserving solution for future breast cancer diagnostic strategies.

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An IoT-Based Framework and Ensemble Optimized Deep Maxout Network Model for Breast Cancer Classification

Cited by 12 publications

References 46 publications

‘Earlier than Early’ Detection of Breast Cancer in Israeli BRCA Mutation Carriers Applying AI-Based Analysis to Consecutive MRI Scans

‘Earlier than Early’ Detection of Breast Cancer in Israeli BRCA Mutation Carriers Applying AI-Based Analysis to Consecutive MRI Scans

Deep Learning Approach for Workload Prediction and Balancing in Cloud Computing

Federated Learning Approach for Breast Cancer Detection Based on DCNN

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