Potential and limitations of machine meta-learning (ensemble) methods for predicting COVID-19 mortality in a large inhospital Brazilian dataset

Paiva, Bruno Barbosa Miranda de; Pereira, Polianna Delfino; Andrade, Cláudio Moisés Valiense de; Gomes, Virginia Mara Reis; Silva, Maira Viana Rego Souza e; Martins, Karina Paula Medeiros Prado; Sales, Thaís Lorenna Souza; Carvalho, Rafael Lima Rodrigues de; Pires, Magda Carvalho; Ramos, Lucas Emanuel Ferreira; Silva, Rafael Tavares; Vieira, Alessandra de Freitas Martins; Nunes, Aline Gabrielle Sousa; Jorge, Alzira de Oliveira; Maurílio, Amanda de Oliveira; Scotton, Ana Luiza Bahia Alves; Silva, Carla Thaís Cândida Alves da; Cimini, Christiane Corrêa Rodrigues; Ponce, Daniela; Pereira, Elayne Crestani; Manenti, Euler Roberto Fernandes; Rodrigues, Fernanda d’Athayde; Anschau, Fernando; Botoni, Fernando Antônio; Bartolazzi, Frederico; Grizende, Genna Maira Santos; Noal, Helena Carolina; Duani, Helena; Gomes, Isabela Moraes; Costa, Jamille Hemétrio Salles Martins; Guimaraes, Julia Di Sabatino Santos; Tupinambás, Julia Teixeira; Machado-Rugolo, Juliana; Batista, Joana; Alvarenga, Joice Coutinho de; Chatkin, José Miguel; Ruschel, Karen Brasil; Zandoná, Liege Barella; Pinheiro, Leonel de Oliveira; Menezes, Luanna Silva Monteiro; Oliveira, Lucas Moyses Carvalho de; Kopittke, Luciane; Assis, Luisa Argolo; Marques, Luiza Margoto; Raposo, Magda Cesar; Floriani, Maiara Anschau; Bicalho, Maria Aparecida Camargos; Nogueira, Matheus Carvalho Alves; Oliveira, Neimy Ramos de; Ziegelmann, Patrícia Klarmann; Paraíso, Pedro Gibson; Martelli, Petrônio José de Lima; Senger, Roberta; Menezes, Rochele Mosmann; Francisco, Saionara Cristina; Araújo, Silvia Ferreira; Kurtz, Tatiana; Fereguetti, Tatiani Oliveira; Oliveira, Thainara Conceição de; Ribeiro, Yara Cristina Neves Marques Barbosa; Ramires, Yuri Carlotto; Lima, Maria Clara Pontello Barbosa; Carneiro, Marcelo; Bezerra, Adriana Falangola Benjamin; Schwarzbold, Alexandre Vargas; Costa, André Soares de Moura; Farace, Bárbara Lopes; Silveira, Daniel Vitório; Cenci, Evelin Paola de Almeida; Lucas, Fernanda Barbosa; Aranha, Fernando Graça; Bastos, Gisele Alsina Nader; Vietta, Giovanna Grünewald; Nascimento, Guilherme Fagundes; Vianna, Heloísa Reniers; Guimarães, Henrique Cerqueira; Morais, Júlia Drumond Parreiras de; Moreira, Leila Beltrami; Oliveira, Leonardo Seixas de; Sousa, Lucas de Deus; Viana, Luciano de Souza; Cabral, Máderson Alvares de Souza; Ferreira, Maria Angélica Pires; Godoy, Mariana Frizzo de; Figueiredo, Meire Pereira de; Júnior, Milton Henriques Guimarães; Sordi, Mônica de Paula de Aparecida; Sampaio, Natália da Cunha Severino; Assaf, Pedro Ledic; Lutkmeier, Raquel; Valácio, Reginaldo Aparecido; Finger, Renan Goulart; Silva, Rufino de Freitas; Guimarães, Silvana Mangeon Meirelles; Oliveira, Talita Fischer; Diniz, Thulio Henrique Oliveira; Gonçalves, Marcos André; Marcolino, Milena Soriano

doi:10.1038/s41598-023-28579-z

Cited by 5 publications

(3 citation statements)

References 39 publications

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“…While the above-mentioned techniques for reducing the number of variables can eliminate redundant and irrelevant features, de Paiva, Pereira, and de Andrade argue that it is not always clear whether these methods result in improvements in the predictive power of ML models [65]. Furthermore, as these methods project the features to a new dimension and the features in the new dimension become mixed features, these new features might not necessarily provide a strong explanatory basis [66].…”

Section: Methods [Source] Explanationmentioning

confidence: 99%

Towards Improved XAI-Based Epidemiological Research into the Next Potential Pandemic

Khalili,

Wimmer

2024

Life

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By applying AI techniques to a variety of pandemic-relevant data, artificial intelligence (AI) has substantially supported the control of the spread of the SARS-CoV-2 virus. Along with this, epidemiological machine learning studies of SARS-CoV-2 have been frequently published. While these models can be perceived as precise and policy-relevant to guide governments towards optimal containment policies, their black box nature can hamper building trust and relying confidently on the prescriptions proposed. This paper focuses on interpretable AI-based epidemiological models in the context of the recent SARS-CoV-2 pandemic. We systematically review existing studies, which jointly incorporate AI, SARS-CoV-2 epidemiology, and explainable AI approaches (XAI). First, we propose a conceptual framework by synthesizing the main methodological features of the existing AI pipelines of SARS-CoV-2. Upon the proposed conceptual framework and by analyzing the selected epidemiological studies, we reflect on current research gaps in epidemiological AI toolboxes and how to fill these gaps to generate enhanced policy support in the next potential pandemic.

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Section: Methods [Source] Explanationmentioning

confidence: 99%

Towards Improved XAI-Based Epidemiological Research into the Next Potential Pandemic

Khalili,

Wimmer

2024

Life

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“…Ensemble learning, which combines the predictive abilities of two or more base learner models to reduce bias and variance, thereby improving overall prediction performance, has seen recent application in analyzing COVID-19 data. However, determining the optimal combination of models for optimal performance remains challenging, with most researchers manually constructing stacking ensemble models to predict COVID-19's clinical severity [32][33][34][35]. Additionally, some studies opted for simplified severity classifications related only to survival and death, rather than attempting to classify a diverse range of clinical severities [36,37].…”

Section: Related Workmentioning

confidence: 99%

Adaptive Stacking Ensemble Techniques for Early Severity Classification of COVID-19 Patients

Kim,

Ju,

Seok

et al. 2024

Applied Sciences

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During outbreaks of infectious diseases, such as COVID-19, it is critical to rapidly determine treatment priorities and identify patients requiring hospitalization based on clinical severity. Although various machine learning models have been developed to predict COVID-19 severity, most have limitations, such as small dataset sizes, the limited availability of clinical variables, or a constrained classification of severity levels by a single classifier. In this paper, we propose an adaptive stacking ensemble technique that identifies various COVID-19 patient severity levels and separates them into three formats: Type 1 (low or high severity), Type 2 (mild, severe, critical), and Type 3 (asymptomatic, mild, moderate, severe, fatal). To enhance the model’s generalizability, we utilized a nationwide dataset from the South Korean government, comprising data from 5644 patients across over 100 hospitals. To address the limited availability of clinical variables, our technique employs data-driven strategies and a proposed feature selection method. This ensures the availability of clinical variables across diverse hospital environments. To construct optimal stacking ensemble models, our technique adaptively selects candidate base classifiers by analyzing the correlation between their predicted outcomes and performance. It then automatically determines the optimal multi-layer combination of base and meta-classifiers using a greedy search algorithm. To further improve the performance, we applied various techniques, including imputation of missing values and oversampling. The experimental results demonstrate that our stacking ensemble models significantly outperform existing single classifiers and AutoML approaches, with improvements of 6.42% and 8.86% in F1 and AUC scores for Type 1, 9.59% and 6.68% for Type 2, and 11.94% and 9.24% for Type 3, respectively. Consequently, our approach improves the prediction of COVID-19 severity levels and potentially assists frontline healthcare providers in making informed decisions.

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“…When this occurs, the boosting algorithm may ignore the vast majority of the training data in favor of the few misclassified observations. As a result, general accuracy in classification tends to drop (17) . In such situation, good solution is using robust boosting (RobustBoost).…”

Section: Classifiermentioning

confidence: 99%

HOG Ensembled Boosting Machine Learning Approach for Violent Video Classification

Jaiswal,

Mohod,

Sharma

2023

IJST

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Background: With the proliferation of machine learning and its applications in a variety of spheres that are important to humans in their day-to-day lives, there is a pressing need for automatic detection models that can identify abnormal behaviors or acts of violence. Methods: This study examines a machine learning model that uses ensemble boosting and histograms of oriented gradients (HOG) to detect violent content from a feature vector with a single parameter. Findings: The tests performed on two benchmark datasets, such as the Hockey Dataset and the Peliculas dataset, reveal a high level of performance accuracy for the classification of violent videos. The experiment findings show that the suggested violence detection model performs well in terms of average metrics, with accuracy, precision, and recall being 90.50%, 91.80%, and 89.70%, respectively. Novelty and applications: The proposed method is capable of striking a balance between high performance and a limited number of parameters, and as a result, it can be implemented with a minimal investment of computational resources.

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Potential and limitations of machine meta-learning (ensemble) methods for predicting COVID-19 mortality in a large inhospital Brazilian dataset

Cited by 5 publications

References 39 publications

Towards Improved XAI-Based Epidemiological Research into the Next Potential Pandemic

Towards Improved XAI-Based Epidemiological Research into the Next Potential Pandemic

Adaptive Stacking Ensemble Techniques for Early Severity Classification of COVID-19 Patients

HOG Ensembled Boosting Machine Learning Approach for Violent Video Classification

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