CGO-ensemble: Chaos game optimization algorithm-based fusion of deep neural networks for accurate Mpox detection.

The rising global incidence of human Mpox cases necessitates prompt and accurate identification for effective disease control. Previous studies have predominantly delved into traditional ensemble methods for detection, we introduce a novel approach by leveraging a metaheuristic-based ensemble framework. In this research, we present an innovative CGO-Ensemble framework designed to elevate the accuracy of detecting Mpox infection in patients. Initially, we employ five transfer learning base models that integrate feature integration layers and residual blocks. These components play a crucial role in capturing significant features from the skin images, thereby enhancing the models' efficacy. In the next step, we employ a weighted averaging scheme to consolidate predictions generated by distinct models. To achieve the optimal allocation of weights for each base model in the ensemble process, we leverage the Chaos Game Optimization (CGO) algorithm. This strategic weight assignment enhances classification outcomes considerably, surpassing the performance of randomly assigned weights. Implementing this approach yields notably enhanced prediction accuracy compared to using individual models. We evaluate the effectiveness of our proposed approach through comprehensive experiments conducted on two widely recognized benchmark datasets: the Mpox Skin Lesion Dataset (MSLD) and the Mpox Skin Image Dataset (MSID). To gain insights into the decision-making process of the base models, we have performed Gradient Class Activation Mapping (Grad-CAM) analysis. The experimental results showcase the outstanding performance of the CGO-ensemble, achieving an impressive accuracy of 100% on MSLD and 94.16% on MSID. Our approach significantly outperforms other state-of-the-art optimization algorithms, traditional ensemble methods, and existing techniques in the context of Mpox detection on these datasets. These findings underscore the effectiveness and superiority of the CGO-Ensemble in accurately identifying Mpox cases, highlighting its potential in disease detection and classification.

Metaheuristics optimization-based ensemble of deep neural networks for Mpox disease detection.

The rising number of cases of human Mpox has emerged as a major global concern due to the daily increase of cases in several countries. The disease presents various skin symptoms in infected individuals, making it crucial to promptly identify and isolate them to prevent widespread community transmission. Rapid determination and isolation of infected individuals are therefore essential to curb the spread of the disease. Most research in the detection of Mpox disease has utilized convolutional neural network (CNN) models and ensemble methods. However, to the best of our knowledge, none have utilized a meta-heuristic-based ensemble approach. To address this gap, we propose a novel metaheuristics optimization-based weighted average ensemble model (MO-WAE) for detecting Mpox disease. We first train three transfer learning (TL)-based CNNs (DenseNet201, MobileNet, and DenseNet169) by adding additional layers to improve their classification strength. Next, we use a weighted average ensemble technique to fuse the predictions from each individual model, and the particle swarm optimization (PSO) algorithm is utilized to assign optimized weights to each model during the ensembling process. By using this approach, we obtain more accurate predictions than individual models. To gain a better understanding of the regions indicating the onset of Mpox, we performed a Gradient Class Activation Mapping (Grad-CAM) analysis to explain our model's predictions. Our proposed MO-WAE ensemble model was evaluated on a publicly available Mpox dataset and achieved an impressive accuracy of 97.78%. This outperforms state-of-the-art (SOTA) methods on the same dataset, thereby providing further evidence of the efficacy of our proposed model.

A deep learning-based framework for detecting COVID-19 patients using chest X-rays.

Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) has caused outbreaks of new coronavirus disease (COVID-19) around the world. Rapid and accurate detection of COVID-19 coronavirus is an important step in limiting the spread of the COVID-19 epidemic. To solve this problem, radiography techniques (such as chest X-rays and computed tomography (CT)) can play an important role in the early prediction of COVID-19 patients, which will help to treat patients in a timely manner. We aimed to quickly develop a highly efficient lightweight CNN architecture for detecting COVID-19-infected patients. The purpose of this paper is to propose a robust deep learning-based system for reliably detecting COVID-19 from chest X-ray images. First, we evaluate the performance of various pre-trained deep learning models (InceptionV3, Xception, MobileNetV2, NasNet and DenseNet201) recently proposed for medical image classification. Second, a lightweight shallow convolutional neural network (CNN) architecture is proposed for classifying X-ray images of a patient with a low false-negative rate. The data set used in this work contains 2,541 chest X-rays from two different public databases, which have confirmed COVID-19 positive and healthy cases. The performance of the proposed model is compared with the performance of pre-trained deep learning models. The results show that the proposed shallow CNN provides a maximum accuracy of 99.68% and more importantly sensitivity, specificity and AUC of 99.66%, 99.70% and 99.98%. The proposed model has fewer parameters and low complexity compared to other deep learning models. The experimental results of our proposed method show that it is superior to the existing state-of-the-art methods. We believe that this model can help healthcare professionals to treat COVID-19 patients through improved and faster patient screening.