Your search keyword '"COVID-19 prediction"' showing total 112 results

1. Nature-Inspired Algorithms-Based Optimal Features Selection Strategy for COVID-19 Detection Using Medical Images.

Author

Singh, Law Kumar, Khanna, Munish, Monga, Himanshu, singh, Rekha, and Pandey, Gaurav

Subjects

*CLINICAL decision support systems, *OPTIMIZATION algorithms, *FEATURE selection, *COMPUTED tomography, *COMMUNICABLE diseases

Abstract

In the case of communicable diseases, such as COVID-19, effective and quick testing techniques make it easier to identify a contaminated person, so that he or she can be easily isolated. To predict COVID-19-infected individuals through chest computed tomography scans, this study suggests an effective feature selection technique incorporated in clinical decision support system that may be used for testing. After pre-processing, we retrieved 213 features from the chest computed tomography images of a public data set with 2482 images. Then, in a two-step process, the most significant features for recognizing the difference between COVID patients and healthy individuals are selected. Initially, the Chi-square test selects 75% of the initial extracted features, which are then forwarded to three nature-inspired computing algorithms: the cuckoo search optimization algorithm, a teaching–learning-based optimization algorithm, and a hybrid of these two for further optimization. The finally selected reduced feature set and five machine learning classifiers are then employed to classify these computed tomography images. Twenty-four experiments using fivefold and tenfold cross-validation have been performed to find the best values for eight statistical efficiency evaluation metrics. Our suggested approach achieves a notable accuracy of 95.99%, the best mean intersection over union of 0.9655, and the highest area under curve of 0.9966. XGBoost delivers more effective, promising, and comparable results when compared to other ML classifiers. Our suggested testing approach will benefit frontline workers and the state by providing routine and cost-effective testing, and faster results. [ABSTRACT FROM AUTHOR]

Published

2024

2. Coot–Lion optimized deep learning algorithm for COVID-19 point mutation rate prediction using genome sequences.

Author

Gugulothu, Praveen and Bhukya, Raju

Subjects

*MACHINE learning, *FEATURE extraction, *COVID-19, *ALGORITHMS

Abstract

In this study, a deep quantum neural network (DQNN) based on the Lion-based Coot algorithm (LBCA-based Deep QNN) is employed to predict COVID-19. Here, the genome sequences are subjected to feature extraction. The fusion of features is performed using the Bray-Curtis distance and the deep belief network (DBN). Lastly, a deep quantum neural network (Deep QNN) is used to predict COVID-19. The LBCA is obtained by integrating Coot algorithm and LOA. The COVID-19 predictions are done with mutation points. The LBCA-based Deep QNN outperformed with testing accuracy of 0.941, true positive rate of 0.931, and false positive rate of 0.869. [ABSTRACT FROM AUTHOR]

Published

2024

3. Prediction models for COVID-19 disease outcomes

Author

Cynthia Y. Tang, Cheng Gao, Kritika Prasai, Tao Li, Shreya Dash, Jane A. McElroy, Jun Hang, and Xiu-Feng Wan

Subjects

Long COVID, machine learning, personalized medicine, predictive model for COVID-19, COVID-19 prediction, disease outcome prediction, Infectious and parasitic diseases, RC109-216, Microbiology, QR1-502

Abstract

SARS-CoV-2 has caused over 6.9 million deaths and continues to produce lasting health consequences. COVID-19 manifests broadly from no symptoms to death. In a retrospective cross-sectional study, we developed personalized risk assessment models that predict clinical outcomes for individuals with COVID-19 and inform targeted interventions. We sequenced viruses from SARS-CoV-2-positive nasopharyngeal swab samples between July 2020 and July 2022 from 4450 individuals in Missouri and retrieved associated disease courses, clinical history, and urban-rural classification. We integrated this data to develop machine learning-based predictive models to predict hospitalization, ICU admission, and long COVID.The mean age was 38.3 years (standard deviation = 21.4) with 55.2% (N = 2453) females and 44.8% (N = 1994) males (not reported, N = 4). Our analyses revealed a comprehensive set of predictors for each outcome, encompassing human, environment, and virus genome-wide genetic markers. Immunosuppression, cardiovascular disease, older age, cardiac, gastrointestinal, and constitutional symptoms, rural residence, and specific amino acid substitutions were associated with hospitalization. ICU admission was associated with acute respiratory distress syndrome, ventilation, bacterial co-infection, rural residence, and non-wild type SARS-CoV-2 variants. Finally, long COVID was associated with hospital admission, ventilation, and female sex.Overall, we developed risk assessment models that offer the capability to identify patients with COVID-19 necessitating enhanced monitoring or early interventions. Of importance, we demonstrate the value of including key elements of virus, host, and environmental factors to predict patient outcomes, serving as a valuable platform in the field of personalized medicine with the potential for adaptation to other infectious diseases.Model summary and motivation. Individuals infected with SARS-CoV-2 experience a wide spectrum of clinical manifestations ranging from no symptoms to death. Using the Virus-Human Outcomes Prediction (ViHOP) algorithm, we aim to utilize the individual’s clinical characteristics, the individual’s location, and the infecting SARS-CoV-2 virus characteristics obtained by whole genome sequencing to determine their likelihood of admission to the hospital, admission to the intensive care unit (ICU), or experiencing long COVID. This model allows clinicians to identify at-risk patients for further monitoring and/or early treatment.

Published

2024

4. A robust innovative pipeline-based machine learning framework for predicting COVID-19 in Mexican patients.

Author

Farnoosh, Rahman and Abnoosian, Karlo

Abstract

The emergence of COVID-19 in late 2019 in Wuhan, China, has led to a global health crisis that has claimed many lives worldwide. A thorough understanding of the available COVID-19 datasets can enable healthcare professionals to identify cases at an early stage. This study presents an innovative pipeline-based framework for predicting survival and mortality in patients with COVID-19 by leveraging the Mexican COVID-19 patient dataset (COVID-19-MPD dataset). Preprocessing plays a pivotal role in ensuring that the framework delivers high-quality outcomes. We deploy various machine learning models with optimized hyperparameters within the framework. Through consistent experimental conditions and dataset utilization, we conducted multiple experiments employing diverse preprocessing techniques and models to maximize the area under the receiver operating characteristic curve (AUC) for COVID-19 prediction. Given the considerable dimensions of the dataset, feature selection is crucial for identifying factors influencing COVID-19 mortality or survival. We employ feature dimension reduction methods, such as principal component analysis and independent component analysis, in addition to feature selection techniques such as maximum relevance minimum redundancy and permutation feature importance. Impactful features related to patient outcomes can significantly aid experts in disease management by enhancing treatment efficacy and control measures. Following various experiments with standardized data and AUC assessment using the k-nearest neighbor algorithm with four components, the proposed framework achieves optimal results, attaining an AUC of 100%. Given its effectiveness in COVID-19 prediction, this framework has the potential for integration into medical decision support systems. [ABSTRACT FROM AUTHOR]

Published

2024

5. An efficient covid-19 prediction using Penguin Pelican optimization-based recurrent dropout-enabled hybrid deep CNN-BILSTM classifier.

Author

Dandge, Sangram Sanjayrao and Harshavardhanan, Pon

Subjects

COVID-19 pandemic, OPTIMIZATION algorithms, CONVOLUTIONAL neural networks, COVID-19, FEATURE extraction

Abstract

Problem statement: The global COVID-19 pandemic has had devastating consequences, emphasizing the need for swift and reliable coronavirus patient detection to enhance treatment and reduce transmission. Methodology: The extracted features are fed into a hybrid deep classifier that combines Convolutional Neural Networks (CNN) and Bidirectional Long Short-Term Memory (BiLSTM) layers. The recurrent dropout technique is employed within the BiLSTM layer as a regularization method to prevent overfitting. This architecture leverages the strength of CNNs in feature extraction and the sequential memory handling of BiLSTMs. The research introduces a specialized optimization algorithm, the Penguin Pelican Optimizer (PPO), which is a fusion of characteristics from the Emperor penguin optimizer and the Pelican Optimization algorithm. This algorithm is designed to fine-tune and enhance the efficiency of the system by optimizing model parameters, weights, and biases. Results: The findings of this study are highly encouraging. The proposed Penguin Pelican Optimization-based recurrent dropout-enabled hybrid deep CNN-BILSTM approach achieved remarkable results, with accuracy rates of 95.57%, 96.08%, and 95.54% for training percentage, and 95.75%, 96.28%, and 95.70% for k-fold. These outcomes surpass the performance of existing methods. This research underscores the practicality and efficiency of the developed methodology for COVID-19 prediction. It offers valuable insights that can be instrumental in ensuring timely and accurate patient management, thus contributing significantly to the global effort to combat the pandemic. Conclusion: This research underscores the effectiveness and efficiency of the developed approach for COVID-19 prediction, providing valuable insights for improved patient management in the battle against the pandemic. [ABSTRACT FROM AUTHOR]

Published

2024

6. Application of Machine Learning Techniques for the Characterization and Early Diagnosis of Respiratory Diseases Such as COVID-19

Author

Alfonso Jose Lopez Rivero, Carlos Chinchilla Corbacho, Tatiana Romero Arias, Manuel Martin-Merino, and Paulo Vaz

Subjects

Feature selection, machine learning, acoustic markers, biomechanical markers, COVID-19 diagnosis, COVID-19 prediction, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper presents a robust methodology for the early and cost-effective diagnosis of COVID-19 based on vocal features and machine learning techniques. The proposed methodology addresses all challenges inherent to the prediction of COVID-19, including those related to feature extraction and selection, the imbalance problem, and predictor training. In contrast to existing methodologies that rely solely on acoustic attributes of the voice, such as intensity or frequency, our approach represents a pioneering investigation that incorporates biomechanical aspects of vocal production. These include muscle tension, the coordination of articulatory movements, and respiration. The relationship between these characteristics and the presence of the virus is investigated rigorously using robust feature selection techniques. To this end, we have constructed an original dataset comprising patients with confirmed cases of COVID-19 infection and a control group, incorporating both acoustic and biomechanical features using Voice Clinical Software. The robustness and reproducibility of the experimental results have been enhanced through the rigorous comparison of several classifiers and feature selection algorithms, as well as the employment of resampling strategies. The application of random forests for feature selection has revealed that a limited set of biomechanical markers are significantly associated with the presence of COVID-19 infection. Moreover, a random forest classifier based on a subset of biomechanical and acoustic features demonstrates high efficacy in predicting cases of COVID-19 infection, achieving a sensitivity of S = ( $0.9212~\pm ~0.0775$ ) while maintaining a specificity of Sp = ( $0.9150~\pm ~0.0649$ ). Considering these findings, the proposed methodology can be regarded as a non-invasive and cost-effective alternative for the diagnosis of COVID-19 infection. Furthermore, it can be extended to the diagnosis of other respiratory diseases, provided that the vocal cords are affected.

Published

2024

7. Enhancing COVID-19 Classification Accuracy with a Hybrid SVM-LR Model.

Author

Nordin, Noor Ilanie, Mustafa, Wan Azani, Lola, Muhamad Safiih, Madi, Elissa Nadia, Kamil, Anton Abdulbasah, Nasution, Marah Doly, K. Abdul Hamid, Abdul Aziz, Zainuddin, Nurul Hila, Aruchunan, Elayaraja, and Abdullah, Mohd Tajuddin

Subjects

*STANDARD deviations, *MACHINE learning, *COVID-19

Abstract

Support ector achine (SVM) is a newer machine learning algorithm for classification, while logistic regression (LR) is an older statistical classification method. Despite the numerous studies contrasting SVM and LR, new improvements such as bagging and ensemble have been applied to them since these comparisons were made. This study proposes a new hybrid model based on SVM and LR for predicting small events per variable (EPV). The performance of the hybrid, SVM, and LR models with different EPV values was evaluated using COVID-19 data from December 2019 to May 2020 provided by the WHO. The study found that the hybrid model had better classification performance than SVM and LR in terms of accuracy, mean squared error (MSE), and root mean squared error (RMSE) for different EPV values. This hybrid model is particularly important for medical authorities and practitioners working in the face of future pandemics. [ABSTRACT FROM AUTHOR]

Published

2023

8. Virus Symptoms Prediction: Role of Machine Learning in Supporting Healthcare Informatics

Author

Vajjhala, Narasimha Rao, Strang, Kenneth David, Bansal, Jagdish Chand, Series Editor, Deep, Kusum, Series Editor, Nagar, Atulya K., Series Editor, Kumar, Sandeep, editor, Hiranwal, Saroj, editor, Purohit, S.D., editor, and Prasad, Mukesh, editor

Published

2023

9. Prediction of COVID-19 Pandemic Spread Using Graph Neural Networks

Author

Gopalapillai, Radhakrishnan, Prabhu, Shreekanth M., Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Kumar, Sandeep, editor, Sharma, Harish, editor, Balachandran, K., editor, Kim, Joong Hoon, editor, and Bansal, Jagdish Chand, editor

Published

2023

10. Predicting COVID-19 Occurrences from MDL-based Segmented Comorbidities and Logistic Regression

Author

de Sousa, Ana Patrícia, Times, Valéria Cesário, Araújo, André, Kacprzyk, Janusz, Series Editor, Pal, Nikhil R., Advisory Editor, Bello Perez, Rafael, Advisory Editor, Corchado, Emilio S., Advisory Editor, Hagras, Hani, Advisory Editor, Kóczy, László T., Advisory Editor, Kreinovich, Vladik, Advisory Editor, Lin, Chin-Teng, Advisory Editor, Lu, Jie, Advisory Editor, Melin, Patricia, Advisory Editor, Nedjah, Nadia, Advisory Editor, Nguyen, Ngoc Thanh, Advisory Editor, Wang, Jun, Advisory Editor, and Latifi, Shahram, editor

Published

2023

11. Prediction of COVID-19 Data Using Improved ARIMA-LSTM Hybrid Forecast Models

Author

Yong-Chao Jin, Qian Cao, Ke-Nan Wang, Yuan Zhou, Yan-Peng Cao, and Xi-Yin Wang

Subjects

COVID-19 prediction, ARIMA, LSTM, BPNN, MLR, PSO, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

COVID-19 has developed into a global public health emergency and has led to restrictions in numerous nations. Thousands of deaths have resulted from the infection of millions of individuals globally. Additionally, COVID-19 has had a significant impact on social and economic activity around the world. The elderly and those with existing medical issues, however, are particularly vulnerable to the effects of COVID-19. Pneumonia, acute respiratory distress syndrome, organ failure, death, etc. are all possible outcomes in severe cases…Traditional prediction approaches like the ARIMA model and multiple linear regression model to handle the linear prediction problem because the new crown virus is in the process of continual mutation. Deep learning models that can take into account nonlinear elements include BP neural network prediction and LSTM neural network prediction. To combine the benefits of traditional and deep learning predictive models and create superior predictive models, we can blend traditional and deep learning predictive models. When the MSE, RMSE, and MAE of these three combined models, PSO-LSTM-ARIMA, MLR-LSTM-ARIMA, and BPNN-LSTM-ARIMA, are compared. We discovered that the third model, which included MSE, RMSE, and MAE, had the best prediction accuracy. The LSTM model and the ARIMA model were selected for this investigation. To begin, it employed a single model to forecast pandemic data in Germany. The BP neural network, particle swarm method, and multiple linear regression were then utilized to merge it. To corroborate this finding, we re-predicted the epidemic data from Japan and retrieved the MSE, RMSE, and MAE values of the BPNN-LSTM-ARIMA model, which were 6141895.956, 2478.285 and 1249.832. The most accurate model is still this integrated model. The BP neural network coupled LSTM model and ARIMA model offers the highest accurate prediction effect, according to our research. Combinatorial models anticipate outbreak data through our study, which can aid governments and public health authorities in improving their responses and educating the public about pandemic trends and potential future directions. As a result, industries and enterprises may make better risk-management decisions to protect the health and safety of their operations and personnel. It also helps healthcare facilities better prepare and deploy medical resources to better meet the demands from the pandemic.

Published

2023

12. Forecasting COVID‐19 cases using dynamic time warping and incremental machine learning methods.

Author

Miralles‐Pechuán, Luis, Kumar, Ankit, and Suárez‐Cetrulo, Andrés L.

Subjects

*MACHINE learning, *COVID-19 pandemic, *WARPING machines, *BOX-Jenkins forecasting, *TIME management

Abstract

The investment of time and resources for developing better strategies is key to dealing with future pandemics. In this work, we recreated the situation of COVID‐19 across the year 2020, when the pandemic started spreading worldwide. We conducted experiments to predict the coronavirus cases for the 50 countries with the most cases during 2020. We compared the performance of state‐of‐the‐art machine learning algorithms, such as long‐short‐term memory networks, against that of online incremental machine learning algorithms. To find the best strategy, we performed experiments to test three different approaches. In the first approach (single‐country), we trained each model using data only from the country we were predicting. In the second one (multiple‐country), we trained a model using the data from the 50 countries, and we used that model to predict each of the 50 countries. In the third experiment, we first applied clustering to calculate the nine most similar countries to the country that we were predicting. We consider two countries to be similar if the differences between the curve that represents the COVID‐19 time series are small. To do so, we used time series similarity measures (TSSM) such as Euclidean Distance (ED) and Dynamic Time Warping (DTW). TSSM return a real value that represents the distance between the points in two time series which can be interpreted as how similar they are. Then, we trained the models with the data from the nine more similar countries to the one that was predicted and the predicted one. We used the model ARIMA as a baseline for our results. Results show that the idea of using TSSM is a very effective approach. By using it with the ED, the obtained RMSE in the single‐country and multiple‐country approaches was reduced by 74.21% and 74.70%, respectively. And by using the DTW, the RMSE was reduced by 74.89% and 75.36%. The main advantage of our methodology is that it is very simple and fast to apply since it is only based on time series data, as opposed to more complex methodologies that require a deep and thorough study to consider the number of parameters involved in the spread of the virus and their corresponding values. We made our code public to allow other researchers to explore our proposed methodology. [ABSTRACT FROM AUTHOR]

Published

2023

13. Multi-weight susceptible-infected model for predicting COVID-19 in China.

Author

Zhang, Jun, Zheng, Nanning, Liu, Mingyu, Yao, Dingyi, Wang, Yusong, Wang, Jianji, and Xin, Jingmin

Subjects

*COVID-19, *COVID-19 pandemic, *SARS-CoV-2 Omicron variant, *SARS-CoV-2, *FORECASTING

Abstract

The mutant strains of COVID-19 caused a global explosion of infections, including many cities of China. In 2020, a hybrid AI model was proposed by Zheng et al., which accurately predicted the epidemic in Wuhan. As the main part of the hybrid AI model, ISI method makes two important assumptions to avoid over-fitting. However, the assumptions cannot be effectively applied to new mutant strains. In this paper, a more general method, named the multi-weight susceptible-infected model (MSI) is proposed to predict COVID-19 in Chinese Mainland. First, a Gaussian pre-processing method is proposed to solve the problem of data fluctuation based on the quantity consistency of cumulative infection number and the trend consistency of daily infection number. Then, we improve the model from two aspects: changing the grouped multi-parameter strategy to the multi-weight strategy, and removing the restriction of weight distribution of viral infectivity. Experiments on the outbreaks in many places in China from the end of 2021 to May 2022 show that, in China, an individual infected by Delta or Omicron strains of SARS-CoV-2 can infect others within 3–4 days after he/she got infected. Especially, the proposed method effectively predicts the trend of the epidemics in Xi'an, Tianjin, Henan, and Shanghai from December 2021 to May 2022. [ABSTRACT FROM AUTHOR]

Published

2023

14. A novel online multi-task learning for COVID-19 multi-output spatio-temporal prediction

Author

Zipeng Wu, Chu Kiong Loo, Unaizah Obaidellah, and Kitsuchart Pasupa

Subjects

Online learning, Multivariate time series, Multi-task learning, COVID-19 prediction, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

In light of the ongoing COVID-19 pandemic, predicting its trend would significantly impact decision-making. However, this is not a straightforward task due to three main difficulties: temporal autocorrelation, spatial dependency, and concept drift caused by virus mutations and lockdown policies. Although machine learning has been extensively used in related work, no previous research has successfully addressed all three challenges simultaneously. To overcome this challenge, we developed a novel online multi-task regression algorithm that incorporates a chain structure to capture spatial dependency, the ADWIN drift detector to adapt to concept drift, and the lag time series feature to capture temporal autocorrelation. We conducted several comparative experiments based on the number of daily confirmed cases in 20 areas in California and affiliated cities. The results from our experiments demonstrate that our proposed model is superior in adapting to concept drift in COVID-19 data and capturing spatial dependencies across various regions. This leads to a significant improvement in prediction accuracy when compared to existing state-of-the-art batch machine learning methods, such as N-Beats, DeepAR, TCN, and LSTM.

Published

2023

15. COVID-19 Detection Using X-Ray Images by Using Convolutional Neural Network

Author

Jany Shabu, S. L., Bharath Vinay Reddy, S., Satya Ranga Vara Prasad, R., Refonaa, J., Dhamodaran, S., Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Raj, Jennifer S., editor, Shi, Yong, editor, Pelusi, Danilo, editor, and Balas, Valentina Emilia, editor

Published

2022

16. Data Mining in Healthcare and Prediction Model Using Data Mining Technique on COVID-19

Author

Prakash, Chandra, Saini, Rakesh Kumar, Chlamtac, Imrich, Series Editor, Tomar, Ravi, editor, Hina, Manolo Dulva, editor, Zitouni, Rafik, editor, and Ramdane-Cherif, Amar, editor

Published

2022

17. Deep learning framework for rapid and accurate respiratory COVID-19 prediction using chest X-ray images

Author

Chiagoziem C. Ukwuoma, Dongsheng Cai, Md Belal Bin Heyat, Olusola Bamisile, Humphrey Adun, Zaid Al-Huda, and Mugahed A. Al-antari

Subjects

COVID-19 prediction, Hybrid ensemble deep feature extraction, Multi-head self-attention network, Visual explainable saliency maps, Explainable Artificial Intelligence (XAI), Electronic computers. Computer science, QA75.5-76.95

Abstract

COVID-19 is a contagious disease that affects the human respiratory system. Infected individuals may develop serious illnesses, and complications may result in death. Using medical images to detect COVID-19 from essentially identical thoracic anomalies is challenging because it is time-consuming, laborious, and prone to human error. This study proposes an end-to-end deep-learning framework based on deep feature concatenation and a Multi-head Self-attention network. Feature concatenation involves fine-tuning the pre-trained backbone models of DenseNet, VGG-16, and InceptionV3, which are trained on a large-scale ImageNet, whereas a Multi-head Self-attention network is adopted for performance gain. End-to-end training and evaluation procedures are conducted using the COVID-19_Radiography_Dataset for binary and multi-classification scenarios. The proposed model achieved overall accuracies (96.33% and 98.67%) and F1_scores (92.68% and 98.67%) for multi and binary classification scenarios, respectively. In addition, this study highlights the difference in accuracy (98.0% vs. 96.33%) and F_1 score (97.34% vs. 95.10%) when compared with feature concatenation against the highest individual model performance. Furthermore, a virtual representation of the saliency maps of the employed attention mechanism focusing on the abnormal regions is presented using explainable artificial intelligence (XAI) technology. The proposed framework provided better COVID-19 prediction results outperforming other recent deep learning models using the same dataset.

Published

2023

18. Learning effective embedding for automated COVID-19 prediction from chest X-ray images.

Author

T N, Sree Ganesh, Satish, Rishi, and Sridhar, Rajeswari

Subjects

*X-rays, *X-ray imaging, *CONVOLUTIONAL neural networks, *DEEP learning, *COVID-19, *DATA augmentation, *IMAGE recognition (Computer vision)

Abstract

The pandemic that the SARS-CoV-2 originated in 2019 is continuing to cause serious havoc on the global population's health, economy, and livelihood. A critical way to suppress and restrain this pandemic is the early detection of COVID-19, which will help to control the virus. Chest X-rays are one of the more straightforward ways to detect the COVID-19 virus compared to the standard methods like CT scans and RT-PCR diagnosis, which are very complex, expensive, and take much time. Our research on various papers shows that the currently researchers are actively working for an efficient Deep Learning model to produce an unbiased detection of COVID-19 through chest X-ray images. In this work, we propose a novel convolution neural network model based on supervised classification that simultaneously computes identification and verification loss. We adopt a transfer learning approach using pretrained models trained on imagenet dataset such as Alex Net and VGG16 as back-bone models and use data augmentation techniques to solve class imbalance and boost the classifier's performance. Finally, our proposed classifier architecture model ensures unbiased and high accuracy results, outperforming existing deep learning models for COVID-19 detection from chest X-ray images producing State of the Art performance. It shows strong and robust performance and proves to be easily deployable and scalable, therefore increasing the efficiency of analyzing chest X-ray images with high accuracy in detection of Coronavirus. [ABSTRACT FROM AUTHOR]

Published

2023

19. COVID-19 Outbreak Prediction by Using Machine Learning Algorithms.

Author

Sher, Tahir, Rehman, Abdul, and Dongsun Kim

Subjects

MACHINE learning, COVID-19 pandemic, STANDARD deviations, COMMUNICABLE diseases, K-nearest neighbor classification, SMART devices

Abstract

COVID-19 is a contagious disease and its several variants put under stress in all walks of life and economy as well. Early diagnosis of the virus is a crucial task to prevent the spread of the virus as it is a threat to life in the whole world. However, with the advancement of technology, the Internet of Things (IoT) and social IoT (SIoT), the versatile data produced by smart devices helped a lot in overcoming this lethal disease. Data mining is a technique that could be used for extracting useful information from massive data. In this study, we used five supervised ML strategies for creating a model to analyze and forecast the existence of COVID-19 using the Kaggle dataset" COVID-19 Symptoms and Presence." RapidMiner Studio ML software was used to apply the Decision Tree (DT), Random Forest (RF), K-Nearest Neighbors (K-NNs) and Naive Bayes (NB), Integrated Decision Tree (ID3) algorithms. To develop the model, the performance of each model was tested using 10-fold cross-validation and compared to major accuracy measures, Cohan's kappa statistics, properly or mistakenly categorized cases and root means square error. The results demonstrate that DT outperforms other methods, with an accuracy of 98.42% and a root mean square error of 0.11. In the future, a devisedmodel will be highly recommendable and supportive for early prediction/diagnosis of disease by providing different data sets. [ABSTRACT FROM AUTHOR]

Published

2023

20. RECENT DEVELOPMENTS IN SOFT COMPUTING BASED TECHNIQUES FOR FEATURE SELECTION AND DISEASE CLASSIFICATION.

Author

Iqbal, Naiyar and Kumar, Pradeep

Subjects

*FEATURE selection, *NOSOLOGY, *SOFT computing, *GENE expression profiling, *PHYSICIANS, *VIRUS diseases

Abstract

Computational prediction of diseases is vital in medical research that contributes to computer-aided diagnostics and helps doctors and medical practitioners in critical decision-making for various diseases such as bacterial and viral kinds of disease, including COVID-19 of the current pandemic situation. Feature selection techniques function as a preprocessing phase for classification and prediction algorithms. For disease prediction, these features may be the patient's clinical profiles or genomic features such as gene expression profiles from microarray and read counts from RNA-Seq. The performance of a classifier depends primarily on the selected features. In addition, genomic features are too large in numbers, resulting in the curse of dimensionality problem. In the last few years, several feature selection algorithms have been developed to overcome the existing problems to get rid of eliminating chronic diseases, such as various cancers, Zika virus, Ebola virus, and the COVID-19 pandemic. In this review article, we systematically associate soft computing-based approaches for feature selection and disease prediction by applying three data types: patients' clinical profiles, microarray gene expression profiles, and RNA-Seq sample profiles. According to related work, when the discussion took place, the percentage of medical data types highlighted through pictorial representation and the respective ratio of percentages mentioned were 52%, 27%, 9% and 12% for clinical symptoms, gene expression, MRI-Image and other data types such as signal or text-based utilized, respectively. We also highlight the significant challenges and future directions in this research domain. [ABSTRACT FROM AUTHOR]

Published

2023

21. Transformer-based Deep Learning for COVID-19 Prediction Based on Climate Variables in Indonesia.

Author

Kurnianingsih, Wirasatriya, Anindya, Lazuardi, Lutfan, Wibowo, Adi, Pradekso, Beno Kunto, Prasetyo, Sigit, Aji, Nurseno Bayu, and Eri Sato-Shimokawara

Subjects

DEEP learning, COVID-19 pandemic, COVID-19, WIND speed, CLIMATE change

Abstract

Recent research on the effect of climate variables on coronavirus (COVID-19) transmission has emerged. Climate change can potentially cause new viral outbreaks, illness, and death. This study contributes to COVID-19 disease prevention efforts. This study makes two contributions: (1) we investigated the impact of climate variables on the number of COVID-19 cases in 34 Indonesian provinces, and (2) we developed a transformer-based deep learning model for time series forecasting for the number of positive COVID-19 cases the following day based on climate variables in 34 Indonesian provinces. We obtained data from March 15, 2020, to July 22, 2021, on the number of positive COVID-19 cases and climate change variables (wind, temperature, humidity) in Indonesia. To examine the effect of climate change on the number of positive COVID-19 cases, we employed 15 scenarios for training. The experiment results of the proposed model show that the combination of wind speed and humidity has a weakly positive correlation with positive COVID-19 incidence; however, the temperature has a considerably negative association with positive COVID-19 incidences. Compared to the other testing scenarios, the transformer-based deep learning model produced the lowest MAE of 175.96 and the lowest RMSE of 375.81. This study demonstrates that the transformer model works well in several provinces, such as Sumatra, Java, Papua, Bali, West Nusa Tenggara, East Nusa Tenggara, East Kalimantan, and Sulawesi, but not in Central Kalimantan, West Sulawesi, South Sulawesi, and North Sulawesi. [ABSTRACT FROM AUTHOR]

Published

2023

22. Deep Feature Meta-Learners Ensemble Models for COVID-19 CT Scan Classification.

Author

Thomas, Jibin B., K. V., Shihabudheen, Sulthan, Sheik Mohammed, and Al-Jumaily, Adel

Subjects

MEDICAL screening, COVID-19, AUTOMATIC classification, DEEP learning, CLASSIFICATION, COMPUTED tomography

Abstract

The infectious nature of the COVID-19 virus demands rapid detection to quarantine the infected to isolate the spread or provide the necessary treatment if required. Analysis of COVID-19-infected chest Computed Tomography Scans (CT scans) have been shown to be successful in detecting the disease, making them essential in radiology assessment and screening of infected patients. Single-model Deep CNN models have been used to extract complex information pertaining to the CT scan images, allowing for in-depth analysis and thereby aiding in the diagnosis of the infection by automatically classifying the chest CT scan images as infected or non-infected. The feature maps obtained from the final convolution layer of the Deep CNN models contain complex and positional encoding of the images' features. The ensemble modeling of these Deep CNN models has been proved to improve the classification performance, when compared to a single model, by lowering the generalization error, as the ensemble can meta-learn from a broader set of independent features. This paper presents Deep Ensemble Learning models to synergize Deep CNN models by combining these feature maps to create deep feature vectors or deep feature maps that are then trained on meta shallow and deep learners to improve the classification. This paper also proposes a novel Attentive Ensemble Model that utilizes an attention mechanism to focus on significant feature embeddings while learning the Ensemble feature vector. The proposed Attentive Ensemble model provided better generalization, outperforming Deep CNN models and conventional Ensemble learning techniques, as well as Shallow and Deep meta-learning Ensemble CNNs models. Radiologists can use the presented automatic Ensemble classification models to assist identify infected chest CT scans and save lives. [ABSTRACT FROM AUTHOR]

Published

2023

23. A process mining- deep learning approach to predict survival in a cohort of hospitalized COVID‐19 patients

Author

M. Pishgar, S. Harford, J. Theis, W. Galanter, J. M. Rodríguez-Fernández, L. H Chaisson, Y. Zhang, A. Trotter, K. M. Kochendorfer, A. Boppana, and H. Darabi

Subjects

Mortality prediction, Process mining, Deep learning, COVID-19 prediction, Machine learning, SARS-CoV-2, Computer applications to medicine. Medical informatics, R858-859.7

Abstract

Abstract Background Various machine learning and artificial intelligence methods have been used to predict outcomes of hospitalized COVID-19 patients. However, process mining has not yet been used for COVID-19 prediction. We developed a process mining/deep learning approach to predict mortality among COVID-19 patients and updated the prediction in 6-h intervals during the first 72 h after hospital admission. Methods The process mining/deep learning model produced temporal information related to the variables and incorporated demographic and clinical data to predict mortality. The mortality prediction was updated in 6-h intervals during the first 72 h after hospital admission. Moreover, the performance of the model was compared with published and self-developed traditional machine learning models that did not use time as a variable. The performance was compared using the Area Under the Receiver Operator Curve (AUROC), accuracy, sensitivity, and specificity. Results The proposed process mining/deep learning model outperformed the comparison models in almost all time intervals with a robust AUROC above 80% on a dataset that was imbalanced. Conclusions Our proposed process mining/deep learning model performed significantly better than commonly used machine learning approaches that ignore time information. Thus, time information should be incorporated in models to predict outcomes more accurately.

Published

2022

24. Enhancing COVID-19 Classification Accuracy with a Hybrid SVM-LR Model

Author

Noor Ilanie Nordin, Wan Azani Mustafa, Muhamad Safiih Lola, Elissa Nadia Madi, Anton Abdulbasah Kamil, Marah Doly Nasution, Abdul Aziz K. Abdul Hamid, Nurul Hila Zainuddin, Elayaraja Aruchunan, and Mohd Tajuddin Abdullah

Subjects

support vector machine, logistic regression, hybrid modeling, small EPV classification, COVID-19 prediction, machine learning classification, Technology, Biology (General), QH301-705.5

Abstract

Support ector achine (SVM) is a newer machine learning algorithm for classification, while logistic regression (LR) is an older statistical classification method. Despite the numerous studies contrasting SVM and LR, new improvements such as bagging and ensemble have been applied to them since these comparisons were made. This study proposes a new hybrid model based on SVM and LR for predicting small events per variable (EPV). The performance of the hybrid, SVM, and LR models with different EPV values was evaluated using COVID-19 data from December 2019 to May 2020 provided by the WHO. The study found that the hybrid model had better classification performance than SVM and LR in terms of accuracy, mean squared error (MSE), and root mean squared error (RMSE) for different EPV values. This hybrid model is particularly important for medical authorities and practitioners working in the face of future pandemics.

Published

2023

25. Covid-19 Intervention Policy Optimization Using a Multi-population Evolutionary Algorithm

Author

Bi, Luning, Fili, Mohammad, Hu, Guiping, Kimms, Alf, Editorial Board Member, Zopounidis, Constantin, Editorial Board Member, Barbosa-Povoa, Ana Paula, Editorial Board Member, Nickel, Stefan, Editorial Board Member, Slowiński, Roman, Editorial Board Member, Qiu, Robin, Editorial Board Member, Tang, Christopher S., Editorial Board Member, Gans, Noah, Editorial Board Member, Zhu, Joe, Editorial Board Member, Heim, Gregory R., Editorial Board Member, Gupta, Jatinder N. D., Editorial Board Member, Shankar, Ravi, Editorial Board Member, Guowei, Hua, Editorial Board Member, Li, Xiang, Editorial Board Member, Wu, Yuzhe, Editorial Board Member, de Almeida-Filho, Adiel Teixeira, Editorial Board Member, Lyons, Kelly, editor, and Chen, Weiwei, editor

Published

2021

26. Image Enhancement in Healthcare Applications: A Review

Author

Dimililer, Kamil, Kayalı, Devrim, Kacprzyk, Janusz, Series Editor, and Al-Turjman, Fadi, editor

Published

2021

27. Analysis, Modelling and Prediction of COVID-19 Outbreaks Using Machine Learning Algorithms

Author

Ajantha Devi, V., Bansal, Jagdish Chand, Series Editor, Deep, Kusum, Series Editor, Nagar, Atulya K., Series Editor, Niranjanamurthy, M., editor, Bhattacharyya, Siddhartha, editor, and Kumar, Neeraj, editor

Published

2021

28. Prediction and Analysis on COVID-19 Using Positive and Negative Association Rule Mining

Author

Chakraborty, Sujit, Biswas, Sudarsan, Debnath, Sourav, Kacprzyk, Janusz, Series Editor, Pal, Nikhil R., Advisory Editor, Bello Perez, Rafael, Advisory Editor, Corchado, Emilio S., Advisory Editor, Hagras, Hani, Advisory Editor, Kóczy, László T., Advisory Editor, Kreinovich, Vladik, Advisory Editor, Lin, Chin-Teng, Advisory Editor, Lu, Jie, Advisory Editor, Melin, Patricia, Advisory Editor, Nedjah, Nadia, Advisory Editor, Nguyen, Ngoc Thanh, Advisory Editor, Wang, Jun, Advisory Editor, Pan, Indrajit, editor, Mukherjee, Anirban, editor, and Piuri, Vincenzo, editor

Published

2021

29. Prediction models for COVID-19 disease outcomes.

Author

Tang CY, Gao C, Prasai K, Li T, Dash S, McElroy JA, Hang J, and Wan XF

Subjects

Humans, Male, Female, Middle Aged, Adult, Retrospective Studies, Cross-Sectional Studies, Aged, Missouri epidemiology, Young Adult, Risk Assessment, Machine Learning, Adolescent, COVID-19 epidemiology, COVID-19 virology, SARS-CoV-2 genetics, SARS-CoV-2 isolation & purification, Hospitalization statistics & numerical data

Abstract

SARS-CoV-2 has caused over 6.9 million deaths and continues to produce lasting health consequences. COVID-19 manifests broadly from no symptoms to death. In a retrospective cross-sectional study, we developed personalized risk assessment models that predict clinical outcomes for individuals with COVID-19 and inform targeted interventions. We sequenced viruses from SARS-CoV-2-positive nasopharyngeal swab samples between July 2020 and July 2022 from 4450 individuals in Missouri and retrieved associated disease courses, clinical history, and urban-rural classification. We integrated this data to develop machine learning-based predictive models to predict hospitalization, ICU admission, and long COVID.The mean age was 38.3 years (standard deviation = 21.4) with 55.2% ( N  = 2453) females and 44.8% ( N  = 1994) males (not reported, N  = 4). Our analyses revealed a comprehensive set of predictors for each outcome, encompassing human, environment, and virus genome-wide genetic markers. Immunosuppression, cardiovascular disease, older age, cardiac, gastrointestinal, and constitutional symptoms, rural residence, and specific amino acid substitutions were associated with hospitalization. ICU admission was associated with acute respiratory distress syndrome, ventilation, bacterial co-infection, rural residence, and non-wild type SARS-CoV-2 variants. Finally, long COVID was associated with hospital admission, ventilation, and female sex.Overall, we developed risk assessment models that offer the capability to identify patients with COVID-19 necessitating enhanced monitoring or early interventions. Of importance, we demonstrate the value of including key elements of virus, host, and environmental factors to predict patient outcomes, serving as a valuable platform in the field of personalized medicine with the potential for adaptation to other infectious diseases.

Published

2024

30. COVID-19 forecasting and intervention planning using gated recurrent unit and evolutionary algorithm.

Author

Bi, Luning, Fili, Mohammad, and Hu, Guiping

Subjects

*SARS-CoV-2, *COVID-19, *DIFFERENTIAL evolution, *COVID-19 pandemic, *PREDICTION models

Abstract

The rapid spread of COVID-19, caused by the SARS-CoV-2 virus, has had and continues to pose a significant threat to global health. We propose a predictive model based on the gated recurrent unit (GRU) that investigates the influence of non-pharmaceutical interventions (NPIs) on the progression of COVID-19. The proposed model is validated by case studies for multiple states in the United States. It should be noted that the proposed model can be generalized to other regions of interest. The results show that the predictive model can achieve accurate forecasts across the US. The forecast is then utilized to identify the optimal mitigation policies. The goal is to identify the best stringency level for each policy that can minimize the total number of new COVID-19 cases while minimizing the mitigation costs. A meta-heuristics method, named multi-population evolutionary algorithm with differential evolution (MPEA-DE), has been developed to identify optimal mitigation strategies that minimize COVID-19 infection cases while reducing economic and other negative implications. We compared the optimal mitigation strategies identified by the MPEA-DE model with three baseline search strategies. The results show that MPEA-DE performs better than other baseline models based on prescription dominance. [ABSTRACT FROM AUTHOR]

Published

2022

31. Coronavirus disease situation analysis and prediction using machine learning: a study on Bangladeshi population.

Author

Nayan, Al-Akhir, Kijsirikul, Boonserm, and Yuji Iwahori

Subjects

COVID-19, MACHINE learning, DEATH rate, THERAPEUTICS, REGRESSION analysis, FORECASTING

Abstract

During a pandemic, early prognostication of patient infected rates can reduce the death by ensuring treatment facility and proper resource allocation. In recent months, the number of death and infected rates has increased more distinguished than before in Bangladesh. The country is struggling to provide moderate medical treatment to many patients. This study distinguishes machine learning models and creates a prediction system to anticipate the infected and death rate for the coming days. Equipping a dataset with data from March 1, 2020, to August 10, 2021, a multi-layer perceptron (MLP) model was trained. The data was managed from a trusted government website and concocted manually for training purposes. Several test cases determine the model's accuracy and prediction capability. The comparison between specific models assumes that the MLP model has more reliable prediction capability than the support vector regression (SVR) and linear regression model. The model presents a report about the risky situation and impending coronavirus disease (COVID-19) attack. According to the prediction produced by the model, Bangladesh may suffer another COVID-19 attack, where the number of infected cases can be between 929 to 2443 and death cases between 19 to 57. [ABSTRACT FROM AUTHOR]

Published

2022

32. Real-Time Analysis of Predictors of COVID-19 Infection Spread in Countries in the European Union Through a New Tool

Author

Aniko Balogh, Anna Harman, and Frauke Kreuter

Subjects

machine learning, time series cross-validation, interactive visualization, COVID-19 prediction, comparative analyses, COVID-19 non-pharmaceutical interventions, Public aspects of medicine, RA1-1270

Abstract

Objectives: Real-time data analysis during a pandemic is crucial. This paper aims to introduce a novel interactive tool called Covid-Predictor-Tracker using several sources of COVID-19 data, which allows examining developments over time and across countries. Exemplified here by investigating relative effects of vaccination to non-pharmaceutical interventions on COVID-19 spread.Methods: We combine >100 indicators from the Global COVID-19 Trends and Impact Survey, Johns Hopkins University, Our World in Data, European Centre for Disease Prevention and Control, National Centers for Environmental Information, and Eurostat using random forests, hierarchical clustering, and rank correlation to predict COVID-19 cases.Results: Between 2/2020 and 1/2022, we found among the non-pharmaceutical interventions “mask usage” to have strong effects after the percentage of people vaccinated at least once, followed by country-specific measures such as lock-downs. Countries with similar characteristics share ranks of infection predictors. Gender and age distribution, healthcare expenditures and cultural participation interact with restriction measures.Conclusion: Including time-aware machine learning models in COVID-19 infection dashboards allows to disentangle and rank predictors of COVID-19 cases per country to support policy evaluation. Our open-source tool can be updated daily with continuous data streams, and expanded as the pandemic evolves.

Published

2022

33. A process mining- deep learning approach to predict survival in a cohort of hospitalized COVID-19 patients.

Author

Pishgar, M., Harford, S., Theis, J., Galanter, W., Rodríguez-Fernández, J. M., Chaisson, L. H, Zhang, Y., Trotter, A., Kochendorfer, K. M., Boppana, A., and Darabi, H.

Abstract

Background: Various machine learning and artificial intelligence methods have been used to predict outcomes of hospitalized COVID-19 patients. However, process mining has not yet been used for COVID-19 prediction. We developed a process mining/deep learning approach to predict mortality among COVID-19 patients and updated the prediction in 6-h intervals during the first 72 h after hospital admission.Methods: The process mining/deep learning model produced temporal information related to the variables and incorporated demographic and clinical data to predict mortality. The mortality prediction was updated in 6-h intervals during the first 72 h after hospital admission. Moreover, the performance of the model was compared with published and self-developed traditional machine learning models that did not use time as a variable. The performance was compared using the Area Under the Receiver Operator Curve (AUROC), accuracy, sensitivity, and specificity.Results: The proposed process mining/deep learning model outperformed the comparison models in almost all time intervals with a robust AUROC above 80% on a dataset that was imbalanced.Conclusions: Our proposed process mining/deep learning model performed significantly better than commonly used machine learning approaches that ignore time information. Thus, time information should be incorporated in models to predict outcomes more accurately. [ABSTRACT FROM AUTHOR]

Published

2022

34. Development of a Smartphone-Based Expert System for COVID-19 Risk Prediction at Early Stage.

Author

Raihan, M., Hassan, Md. Mehedi, Hasan, Towhid, Bulbul, Abdullah Al-Mamun, Hasan, Md. Kamrul, Hossain, Md. Shahadat, Roy, Dipa Shuvo, and Awal, Md. Abdul

Subjects

*WEB-based user interfaces, *SMARTPHONES, *COVID-19, *ELECTRONIC equipment, *FEATURE selection, *EXPERT systems

Abstract

COVID-19 has imposed many challenges and barriers on traditional healthcare systems due to the high risk of being infected by the coronavirus. Modern electronic devices like smartphones with information technology can play an essential role in handling the current pandemic by contributing to different telemedical services. This study has focused on determining the presence of this virus by employing smartphone technology, as it is available to a large number of people. A publicly available COVID-19 dataset consisting of 33 features has been utilized to develop the aimed model, which can be collected from an in-house facility. The chosen dataset has 2.82 % positive and 97.18 % negative samples, demonstrating a high imbalance of class populations. The Adaptive Synthetic (ADASYN) has been applied to overcome the class imbalance problem with imbalanced data. Ten optimal features are chosen from the given 33 features, employing two different feature selection algorithms, such as K Best and recursive feature elimination methods. Mainly, three classification schemes, Random Forest (RF), eXtreme Gradient Boosting (XGB), and Support Vector Machine (SVM), have been applied for the ablation studies, where the accuracy from the XGB, RF, and SVM classifiers achieved 97.91 % , 97.81 % , and 73.37 % , respectively. As the XGB algorithm confers the best results, it has been implemented in designing the Android operating system base and web applications. By analyzing 10 users' questionnaires, the developed expert system can predict the presence of COVID-19 in the human body of the primary suspect. The preprocessed data and codes are available on the GitHub repository. [ABSTRACT FROM AUTHOR]

Published

2022

35. Prediction of Covid-19 Based on Chest X-Ray Images Using Deep Learning with CNN.

Author

Meem, Anika Tahsin, Khan, Mohammad Monirujjaman, Masud, Mehedi, and Aljahdali, Sultan

Subjects

DEEP learning, COVID-19 pandemic, X-rays, ARTIFICIAL neural networks, MACHINE learning

Abstract

The COVID-19 pandemic has caused trouble in people's daily lives and ruined several economies around the world, killing millions of people thus far. It is essential to screen the affected patients in a timely and cost-effective manner in order to fight this disease. This paper presents the prediction of COVID-19 with Chest X-Ray images, and the implementation of an image processing system operated using deep learning and neural networks. In this paper, a Deep Learning, Machine Learning, and Convolutional Neural Network-based approach for predicting Covid-19 positive and normal patients using Chest X-Ray pictures is proposed. In this study, machine learning tools such as TensorFlow were used for building and training neural nets. Scikit-learn was used for machine learning from end to end. Various deep learning features are used, such as Conv2D, Dense Net, Dropout, Maxpooling2D for creating the model. The proposed approach had a classification accuracy of 96.43 percent and a validation accuracy of 98.33 percent after training and testing the X-Ray pictures. Finally, a web application has been developed for general users, which will detect chest x-ray images either as covid or normal. A GUI application for the Covid prediction framework was run. A chest X-ray image can be browsed and fed into the program by medical personnel or the general public. [ABSTRACT FROM AUTHOR]

Published

2022

36. Novel deep learning approach to model and predict the spread of COVID-19

Author

Devante Ayris, Maleeha Imtiaz, Kye Horbury, Blake Williams, Mitchell Blackney, Celine Shi Hui See, and Syed Afaq Ali Shah

Subjects

COVID-19 prediction, Machine learning, Regression, MAE, Cybernetics, Q300-390, Electronic computers. Computer science, QA75.5-76.95

Abstract

SARS-CoV2, which causes coronavirus disease (COVID-19) is continuing to spread globally, producing new variants and has become a pandemic. People have lost their lives not only due to the virus but also because of the lack of counter measures in place. Given the increasing caseload and uncertainty of spread, there is an urgent need to develop robust artificial intelligence techniques to predict the spread of COVID-19. In this paper, we propose a deep learning technique, called Deep Sequential Prediction Model (DSPM) and machine learning based Non-parametric Regression Model (NRM) to predict the spread of COVID-19. Our proposed models are trained and tested on publicly available novel coronavirus dataset. The proposed models are evaluated by using Mean Absolute Error and compared with the existing methods for the prediction of the spread of COVID-19. Our experimental results demonstrate the superior prediction performance of the proposed models. The proposed DSPM and NRM achieve MAEs of 388.43 (error rate 1.6%) and 142.23 (0.6%), respectively compared to 6508.22 (27%) achieved by baseline SVM, 891.13 (9.2%) by Time-Series Model (TSM), 615.25 (7.4%) by LSTM-based Data-Driven Estimation Method (DDEM) and 929.72 (8.1%) by Maximum-Hasting Estimation Method (MHEM).

Published

2022

37. Multiple Output and Multi-Steps Prediction of COVID-19 Spread Using Weather and Vaccination Data.

Author

Berhich, Asmae, Jebli, Imane, Mbilong, Paul Menounga, El Kassiri, Asmae, and Belouadha, Fatima-Zahra

Subjects

COVID-19 pandemic, VACCINATION, PREDICTION models

Abstract

In recent days, the world has seen an expansion of the COVID-19 outbreak, especially the number of deaths. The mobility, the laziness to take necessary precautions, the new variants, and many other factors made the situation worse. It is thus important to study coronavirus spread to prevent people from its severity and face its danger. This paper is an investigation of the COVID-19 outbreak in six different countries. It discusses correlations and statistical analysis of the COVID-19 with weather conditions and vaccinations to explain how these factors impact the coronavirus spread. In addition, it predicts the new cases and deaths of the incoming seven days for Morocco. The predictive models applied in this paper use multi-step and multi-output prediction with both machine learning and deep learning algorithms that are specialized in time series problems. Our model algorithms give decisionmakers a smart tool, using input features, to simulate different disaster situations, predict new infections, and expected deaths. It's useful for future pandemics or new variants to be more proactive. Predicting the epidemic situation in the future using the current conditions will allow humanity to be ready for the necessary sanitary measures. This work is typically useful for any time and any pandemic crisis. [ABSTRACT FROM AUTHOR]

Published

2021

38. NSGA-II as feature selection technique and AdaBoost classifier for COVID-19 prediction using patient's symptoms.

Author

Soui, Makram, Mansouri, Nesrine, Alhamad, Raed, Kessentini, Marouane, and Ghedira, Khaled

Abstract

Nowadays, humanity is facing one of the most dangerous pandemics known as COVID-19. Due to its high inter-person contagiousness, COVID-19 is rapidly spreading across the world. Positive patients are often suffering from different symptoms that can vary from mild to severe including cough, fever, sore throat, and body aches. In more dire cases, infected patients can experience severe symptoms that can cause breathing difficulties which lead to stern organ failure and die. The medical corps all over the world are overloaded because of the exponentially myriad number of contagions. Therefore, screening for the disease becomes overwrought with the limited tools of test. Additionally, test results may take a long time to acquire, leaving behind a higher potential for the prevalence of the virus among other individuals by the patients. To reduce the chances of infection, we suggest a prediction model that distinguishes the infected COVID-19 cases based on clinical symptoms and features. This model can be helpful for citizens to catch their infection without the need for visiting the hospital. Also, it helps the medical staff in triaging patients in case of a deficiency of medical amenities. In this paper, we use the non-dominated sorting genetic algorithm (NSGA-II) to select the interesting features by finding the best trade-offs between two conflicting objectives: minimizing the number of features and maximizing the weights of selected features. Then, a classification phase is conducted using an AdaBoost classifier. The proposed model is evaluated using two different datasets. To maximize results, we performed a natural selection of hyper-parameters of the classifier using the genetic algorithm. The obtained results prove the efficiency of NSGA-II as a feature selection algorithm combined with AdaBoost classifier. It exhibits higher classification results that outperformed the existing methods. [ABSTRACT FROM AUTHOR]

Published

2021

39. Cellular Automata in Covid-19 prediction.

Author

Podolski, Piotr and Nguyen, Hung Son

Subjects

COVID-19, CELLULAR automata, SARS-CoV-2, PANDEMICS, TWO-dimensional models, FORECASTING

Abstract

At the end of 2019 a new coronavirus emerged, turning into a world pandemic. The new coronavirus is called COVID-19. Different countries handled the pandemic differently and our main focus in this article is on Poland. For better counteracting and managing the situation a model for predicting the dynamics of the pandemic is needed. In this article we present a model for simulating future infections taking into account various preventive measures and locations in Poland. We based the model on a two-dimensional cellular automata, with spatial dependencies between regions, different population and size of simulated regions. [ABSTRACT FROM AUTHOR]

Published

2021

40. Predictability of COVID-19 Infections Based on Deep Learning and Historical Data

Author

Rafat Zrieq, Souad Kamel, Sahbi Boubaker, Fahad D. Algahtani, Mohamed Ali Alzain, Fares Alshammari, Badr Khalaf Aldhmadi, Fahad Saud Alshammari, and Marcos J. Araúzo-Bravo

Subjects

COVID-19 prediction, deep learning (DL), long short-term memory (LSTM), gated recurrent unit (GRU), recurrent neural network (RNN), performance metrics, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The COVID-19 disease has spread worldwide since 2020, causing a high number of deaths as well as infections, and impacting economic, social and health systems. Understanding its dynamics may facilitate a better understanding of its behavior, reducing the impact of similar diseases in the future. Classical modeling techniques have failed in predicting the behavior of this disease, since they have been unable to capture hidden features in the data collected about the disease. The present research benefits from the high capacity of modern computers and new trends in artificial intelligence (AI), specifically three deep learning (DL) neural networks: recurrent neural network (RNN), gated recurrent unit (GRU), and long short-term memory (LSTM). We thus modelled daily new infections of COVID-19 in four countries (Saudi Arabia, Egypt, Italy, and India) that vary in their climates, cultures, populations, and health systems. The results show that a simple-structure RNN algorithm is better at predicting daily new infections and that DL techniques have promising potential in disease modeling and can be used efficiently even in the case of limited datasets.

Published

2022

41. Spatial drivers of COVID-19 vulnerability in Nigeria

Author

Mayowa Johnson Fasona, Chukwuma John Okolie, and Adebayo Akeem Otitoloju

Subjects

covid-19, risk factors, vulnerability maps, covid-19 prediction, geographic information system, nigeria, Medicine

Abstract

INTRODUCTION: The spread and diffusion of COVID-19 undoubtedly shows strong spatial connotations and alignment with the physical indices of civilization and globalization. Several spatial risk factors have possible influence on its dispersal trajectory. Understanding their influence is critical for mobilization, sensitization and managing non-pharmaceutical interventions at the appropriate spatial-administrative units. METHODS: on 01 April 2020, we constructed a rapid spatial diagnostics and generated vulnerability map for COVID-19 infection spread at state level using 12 core spatial drivers. The risk factors used include established COVID-19 cases (as at 01 April 2020), population, proximity to the airports, inter-state road traffic, intra-state road traffic, intra city traffic, international road traffic, possibility of elite influx from abroad, preponderance of high risk political elite, likelihood of religious gathering, likelihood of other social gatherings, and proximity to existing COVID-19 test centers. These were also tested as predictors of COVID-19 spread using multiple regression analysis. RESULTS: the results show that 6 States - Lagos, Kano, Katsina, Kaduna, Oyo and Rivers - and the Federal Capital Territory have very high vulnerability, 17 states have high vulnerability and 13 states have medium vulnerability to COVID-19 transmission. The drivers indicate a good level of prediction for COVID-19 with the coefficient of correlation ranging from 0.983 - 0.995. The regression analysis indicates that between 96.6 and 99.0 percent of the variance in the COVID-19 infections across Nigeria can be explained by the predictors. CONCLUSION: the spatial pattern of infection across the states are substantially consistent with the predicted pattern of vulnerability.

Published

2021

42. Development of a Smartphone-Based Expert System for COVID-19 Risk Prediction at Early Stage

Author

M. Raihan, Md. Mehedi Hassan, Towhid Hasan, Abdullah Al-Mamun Bulbul, Md. Kamrul Hasan, Md. Shahadat Hossain, Dipa Shuvo Roy, and Md. Abdul Awal

Subjects

adaptive synthetic sampling, Android or web-based user applications, COVID-19 prediction, feature selection methods, machine learning classifiers, Technology, Biology (General), QH301-705.5

Abstract

COVID-19 has imposed many challenges and barriers on traditional healthcare systems due to the high risk of being infected by the coronavirus. Modern electronic devices like smartphones with information technology can play an essential role in handling the current pandemic by contributing to different telemedical services. This study has focused on determining the presence of this virus by employing smartphone technology, as it is available to a large number of people. A publicly available COVID-19 dataset consisting of 33 features has been utilized to develop the aimed model, which can be collected from an in-house facility. The chosen dataset has 2.82% positive and 97.18% negative samples, demonstrating a high imbalance of class populations. The Adaptive Synthetic (ADASYN) has been applied to overcome the class imbalance problem with imbalanced data. Ten optimal features are chosen from the given 33 features, employing two different feature selection algorithms, such as K Best and recursive feature elimination methods. Mainly, three classification schemes, Random Forest (RF), eXtreme Gradient Boosting (XGB), and Support Vector Machine (SVM), have been applied for the ablation studies, where the accuracy from the XGB, RF, and SVM classifiers achieved 97.91%, 97.81%, and 73.37%, respectively. As the XGB algorithm confers the best results, it has been implemented in designing the Android operating system base and web applications. By analyzing 10 users’ questionnaires, the developed expert system can predict the presence of COVID-19 in the human body of the primary suspect. The preprocessed data and codes are available on the GitHub repository.

Published

2022

43. ON THE USE OF MACHINE LEARNING FOR PREDICTING COVID--19 CASES: AN OVERVIEW OF EVOLVING DATASETS AND DISCRIMINATIVE FEATURES.

Author

A. M., Oyellakiin, T. T., Sallau-Ibrahiim, B. S., Ogiidan, R. D., Azeez, and I. K., Ajiiboye

Subjects

COVID-19 pandemic, MACHINE learning, COVID-19, VIRUS diseases, PANDEMICS

Abstract

The corona virus pandemic is one of the largest global health crises in recent times. Several studies are being proposed to demonstrate how Machine Learning techniques can be used for the prediction of the disease. While some of the studies focus on the prediction of the diseases in patients, some other ones focus on predicting its mode of spread across countries of the world. Corona virus was formally announced in China in December, 2019. Since then, the disease has been spreading in large number. More than 3.4 million people have been infected as at 3rd May, 2020. As parts of the efforts to help in predicting the presence of the disease in patients as well as its geographical spread, some Machine Learning-based techniques are being proposed. This study first explores the various promises of Machine Learning as a sub field of Artificial Intelligence in the prediction of corona virus disease. We provided information on how Machine Learning approaches can aid for predictive analytics. We equally emphasized the use of comprehensive and reliable datasets for reliable predictive modeling of the virus. However, since the disease is novel, it is of interest to study some of the datasets that are evolving. This is because having representative datasets for training and testing predictive COVID-19 models is very important. It is believed that future researchers in the area of corona virus classification and prediction can benefit immensely from the findings of this study. [ABSTRACT FROM AUTHOR]

Published

2020

44. Deep Learning Based Early Detection Framework for Preliminary Diagnosis of COVID-19 via Onboard Smartphone Sensors

Author

Hayat Khaloufi, Karim Abouelmehdi, Abderrahim Beni-Hssane, Furqan Rustam, Anca Delia Jurcut, Ernesto Lee, and Imran Ashraf

Subjects

COVID-19 prediction, smartphone sensors, prediction framework, deep learning, Chemical technology, TP1-1185

Abstract

The COVID-19 pandemic has affected almost every country causing devastating economic and social disruption and stretching healthcare systems to the limit. Furthermore, while being the current gold standard, existing test methods including NAAT (Nucleic Acid Amplification Tests), clinical analysis of chest CT (Computer Tomography) scan images, and blood test results, require in-person visits to a hospital which is not an adequate way to control such a highly contagious pandemic. Therefore, top priority must be given, among other things, to enlisting recent and adequate technologies to reduce the adverse impact of this pandemic. Modern smartphones possess a rich variety of embedded MEMS (Micro-Electro-Mechanical-Systems) sensors capable of recording movements, temperature, audio, and video of their carriers. This study leverages the smartphone sensors for the preliminary diagnosis of COVID-19. Deep learning, an important breakthrough in the domain of artificial intelligence in the past decade, has huge potential for extracting apt and appropriate features in healthcare. Motivated from these facts, this paper presents a new framework that leverages advanced machine learning and data analytics techniques for the early detection of coronavirus disease using smartphone embedded sensors. The proposal provides a simple to use and quickly deployable screening tool that can be easily configured with a smartphone. Experimental results indicate that the model can detect positive cases with an overall accuracy of 79% using only the data from the smartphone sensors. This means that the patient can either be isolated or treated immediately to prevent further spread, thereby saving more lives. The proposed approach does not involve any medical tests and is a cost-effective solution that provides robust results.

Published

2021

45. Assessing the Predictive Power of Online Social Media to Analyze COVID-19 Outbreaks in the 50 U.S. States

Author

Jiachen Sun and Peter A. Gloor

Subjects

online social media prediction, COVID-19 prediction, Twitter, Google Trends, Information technology, T58.5-58.64

Abstract

As the coronavirus disease 2019 (COVID-19) continues to rage worldwide, the United States has become the most affected country, with more than 34.1 million total confirmed cases up to 1 June 2021. In this work, we investigate correlations between online social media and Internet search for the COVID-19 pandemic among 50 U.S. states. By collecting the state-level daily trends through both Twitter and Google Trends, we observe a high but state-different lag correlation with the number of daily confirmed cases. We further find that the accuracy measured by the correlation coefficient is positively correlated to a state’s demographic, air traffic volume and GDP development. Most importantly, we show that a state’s early infection rate is negatively correlated with the lag to the previous peak in Internet searches and tweeting about COVID-19, indicating that earlier collective awareness on Twitter/Google correlates with a lower infection rate. Lastly, we demonstrate that correlations between online social media and search trends are sensitive to time, mainly due to the attention shifting of the public.

Published

2021

46. A novel cellular automata classifier for COVID-19 trend prediction.

Author

Sree, Pokkuluri Kiran and Nedunuri, S. S. S. N. Usha Devi

Subjects

*COVID-19, *CELLULAR automata, *FORECASTING, *SUPPORT vector machines

Abstract

Introduction: China has witnessed a new virus Corona, which is named COVID-19. It has become the world's most concern as this virus has spread over the worldat a higher speed;the world has witnessed more than one lakh cases and one thousand deaths in a span of few days. Methods: We have developed a preliminary classifier with non-linear hybrid cellular automata, which is trained and tested to predict the effect of COVID-19 in terms of deaths, the number of people affected, the number of people being could be recovered, etc. This indirectly predicts the trend of this epidemic in India. We have collected the datasets from Kaggle and other standard websites. Results: The proposed classifier, hybrid non-linear cellular automata (HNLCA), was trained with 23,078 datasets and tested with 6785 datasets. HNLCA is compared with conventional methods of long shortterm memory, AdaBoost, support vector machine, regression, and SVR and has reported an accuracy of 78.8%, which is better compared with the cited literature. This classifier can also predict the rate at which this virus spreads, transmission within the boundary, and of the boundary, etc. [ABSTRACT FROM AUTHOR]

Published

2020

47. A comprehensive review on federated learning based models for healthcare applications.

Author

Sharma, Shagun and Guleria, Kalpna

Subjects

*FEDERATED learning, *MACHINE learning, *DATA privacy, *ALZHEIMER'S disease, *EARLY diagnosis, *DEEP learning

Abstract

A disease is an abnormal condition that negatively impacts the functioning of the human body. Pathology determines the causes behind the disease and identifies its development mechanism and functional consequences. Each disease has different identification methods, including X-ray scans for pneumonia, covid-19, and lung cancer, whereas biopsy and CT-scan can identify the presence of skin cancer and Alzheimer's disease, respectively. Early disease detection leads to effective treatment and avoids abiding complications. Deep learning has provided a vast number of applications in medical sectors resulting in accurate and reliable early disease predictions. These models are utilized in the healthcare industry to provide supplementary assistance to doctors in identifying the presence of diseases. Majorly, these models are trained through secondary data sources since healthcare institutions refrain from sharing patients' private data to ensure confidentiality, which limits the effectiveness of deep learning models due to the requirement of extensive datasets for training to achieve optimal results. Federated learning deals with the data in such a way that it doesn't exploit the privacy of a patient's data. In this work, a wide variety of disease detection models trained through federated learning have been rigorously reviewed. This meta-analysis provides an in-depth review of the federated learning architectures, federated learning types, hyperparameters, dataset utilization details, aggregation techniques, performance measures, and augmentation methods applied in the existing models during the development phase. The review also highlights various open challenges associated with the disease detection models trained through federated learning for future research. • Google introduced federated learning in 2016 to intensify data privacy. • Review of the models trained through federated learning, published between 2019 and 2023. • A meta-analysis of the existing disease detection models trained through federated learning. • Illustrates the model's frameworks and performance evaluation parameters. • Highlights open research challenges associated with the models trained through federated learning. [ABSTRACT FROM AUTHOR]

Published

2023

48. Machine Learning-Based Research for COVID-19 Detection, Diagnosis, and Prediction: A Survey

Author

Meraihi, Yassine, Gabis, Asma Benmessaoud, Mirjalili, Seyedali, Ramdane-Cherif, Amar, and Alsaadi, Fawaz E.

Published

2022

49. Forecasting <scp>COVID</scp> ‐19 cases using dynamic time warping and incremental machine learning methods

Author

Luis Miralles‐Pechuán, Ankit Kumar, Andrés L. Suárez‐Cetrulo, and This research received no external funding

Subjects

Engineering, Computational Theory and Mathematics, dynamic time warping, Artificial Intelligence, Control and Systems Engineering, Medicine and Health Sciences, incremental machine learning, Computer Engineering, epidemiology curve, COVID-19 prediction, time series similarity measures, Theoretical Computer Science

Abstract

The investment of time and resources for developing better strategies is key to dealing with future pandemics. In this work, we recreated the situation of COVID-19 across the year 2020, when the pandemic started spreading worldwide. We conducted experiments to predict the coronavirus cases for the 50 countries with the most cases during 2020. We compared the performance of state-of-the-art machine learning algorithms, such as long-short-term memory networks, against that of online incremental machine learning algorithms. To find the best strategy, we performed experiments to test three different approaches. In the first approach (single-country), we trained each model using data only from the country we were predicting. In the second one (multiple-country), we trained a model using the data from the 50 countries, and we used that model to predict each of the 50 countries. In the third experiment, we first applied clustering to calculate the nine most similar countries to the country that we were predicting. We consider two countries to be similar if the differences between the curve that represents the COVID-19 time series are small. To do so, we used time series similarity measures (TSSM) such as Euclidean Distance (ED) and Dynamic Time Warping (DTW). TSSM return a real value that represents the distance between the points in two time series which can be interpreted as how similar they are. Then, we trained the models with the data from the nine more similar countries to the one that was predicted and the predicted one. We used the model ARIMA as a baseline for our results. Results show that the idea of using TSSM is a very effective approach. By using it with the ED, the obtained RMSE in the singlecountry and multiple-country approaches was reduced by 74.21% and 74.70%, respectively. And by using the DTW, the RMSE was reduced by 74.89% and 75.36%. The main advantage of our methodology is that it is very simple and fast to apply since it is only based on time series data, as opposed to more complex methodologies that require a deep and thorough study to consider the number of parameters involved in the spread of the virus and their corresponding values. We made our code public to allow other researchers to explore our proposed methodology.

Published

2023

50. An AUC-maximizing classifier for skewed and partially labeled data with an application in clinical prediction modeling.

Author

Wang, Guanjin, Kwok, Stephen Wai Hang, Axford, Daniel, Yousufuddin, Mohammed, and Sohel, Ferdous

Subjects

*SUPERVISED learning, *SUPPORT vector machines, *COVID-19, *PREDICTION models, *ANALYTICAL solutions

Abstract

Partially labeled and skewed datasets are common in many applications including healthcare, due to the high costs and time constraints of data collection and annotation. However, training machine learning classifiers on such data can undermine their prediction performances. In this paper, we propose a novel classifier to address this problem by focusing on the Area Under the Curve (AUC), which is widely recognized as a more robust performance metric for skewed datasets than other metrics such as accuracy and error rate. We introduce a new classifier called PSVM-AUC Maximizer (PSVM-AUCMax) which is based on Proximal Support Vector Machines (PSVM) and directly maximizes a new AUC-based metric in its learning objective. PSVM-AUCMax has several merits. First, by directly integrating the maximization of the proposed AUC-based metric, PSVM-AUCMax can be proved to have the enhanced generalization capability on the partially labeled and skewed dataset. Second, it simplifies the model selection process with fewer tuning hyperparameters. Third, PSVM-AUCMax's analytical solution remains the same form as traditional PSVM, preserving its advantages such as fast incremental updating in incremental learning scenarios. The efficacy of PSVM-AUCMax has been demonstrated through extensive experiments on several public datasets and a healthcare case study using data collected at the US Mayo Clinic. In the healthcare case study, we utilized PSVM-AUCMax to develop a clinical prediction model for forecasting composite outcomes in hospitalized COVID-19 patients which yielded promising results. [ABSTRACT FROM AUTHOR]

Published

2023