Your search keyword '"Graziano Alessandro"' showing total 2 results

1. COVID-19 ICU mortality prediction: a machine learning approach using SuperLearner algorithm

Author

Lorenzoni, Giulia, Sella, Nicolò, Boscolo, Annalisa, Azzolina, Danila, Bartolotta, Patrizia, Pasin, Laura, Pettenuzzo, Tommaso, De Cassai, Alessandro, Baratto, Fabio, Toffoletto, Fabio, De Rosa, Silvia, Fullin, Giorgio, Peta, Mario, Rosi, Paolo, Polati, Enrico, Zanella, Alberto, Grasselli, Giacomo, Pesenti, Antonio, Navalesi, Paolo, Gregori, Dario, Tocco, Martina, Pretto, Chiara, Tamburini, Enrico, Fregolent, Davide, Pirelli, Pier Francesco, Marchesin, Davide, Perona, Matteo, Franchetti, Nicola, Paolera, Michele Della, Simoni, Caterina, Falcioni, Tatiana, Tresin, Alessandra, Schiavolin, Chiara, Schiavi, Aldo, Vathi, Sonila, Sartori, Daria, Sorgato, Alice, Pistollato, Elisa, Linassi, Federico, Gianoli, Sara, Gaspari, Silvia, Gruppo, Francesco, Maggiolo, Alessandra, Giurisato, Elena, Furlani, Elisa, Calore, Alvise, Serra, Eugenio, Pittarello, Demetrio, Tiberio, Ivo, Bond, Ottavia, Michieletto, Elisa, Muraro, Luisa, Peralta, Arianna, Persona, Paolo, Petranzan, Enrico, Zarantonello, Francesco, Graziano, Alessandro, Piasentini, Eleonora, Bernardi, Lorenzo, Pianon, Roberto, Mazzon, Davide, Poole, Daniele, Badii, Flavio, Bosco, Enrico, Agostini, Moreno, Trevisiol, Paride, Farnia, Antonio, Altafini, Lorella, Calò, Mauro Antonio, Meggiolaro, Marco, Lazzari, Francesco, Martinello, Ivan, Papaccio, Francesco, di Gregorio, Guido, Bonato, Alfeo, Sgarabotto, Camilla, Montacciani, Francesco, Alessandra, Parnigotto, Gagliardi, Giuseppe, Ferraro, Gioconda, Ongaro, Luigi, Baiocchi, Marco, Danzi, Vinicio, Zanatta, Paolo, Donadello, Katia, Gottin, Leonardo, Sinigaglia, Ezio, da Ros, Alessandra, Marchiotto, Simonetta, Bassanini, Silvia, Zamperini, Massimo, Daroui, Ivan, and Mosaner, Walter

Subjects

medicine.medical_specialty, medicine.medical_treatment, Socio-culturale, Machine learning, computer.software_genre, law.invention, Economica, law, Anesthesiology, Hemofiltration, Extracorporeal membrane oxygenation, medicine, Mortality, Mechanical ventilation, business.industry, COVID-19, Ambientale, Intensive care unit, Predictive model, Test set, ICU, Original Article, Observational study, Artificial intelligence, business, Algorithm, computer, Cohort study

Abstract

Background Since the beginning of coronavirus disease 2019 (COVID-19), the development of predictive models has sparked relevant interest due to the initial lack of knowledge about diagnosis, treatment, and prognosis. The present study aimed at developing a model, through a machine learning approach, to predict intensive care unit (ICU) mortality in COVID-19 patients based on predefined clinical parameters. Results Observational multicenter cohort study. All COVID-19 adult patients admitted to 25 ICUs belonging to the VENETO ICU network (February 28th 2020-april 4th 2021) were enrolled. Patients admitted to the ICUs before 4th March 2021 were used for model training (“training set”), while patients admitted after the 5th of March 2021 were used for external validation (“test set 1”). A further group of patients (“test set 2”), admitted to the ICU of IRCCS Ca’ Granda Ospedale Maggiore Policlinico of Milan, was used for external validation. A SuperLearner machine learning algorithm was applied for model development, and both internal and external validation was performed. Clinical variables available for the model were (i) age, gender, sequential organ failure assessment score, Charlson Comorbidity Index score (not adjusted for age), Palliative Performance Score; (ii) need of invasive mechanical ventilation, non-invasive mechanical ventilation, O2 therapy, vasoactive agents, extracorporeal membrane oxygenation, continuous venous-venous hemofiltration, tracheostomy, re-intubation, prone position during ICU stay; and (iii) re-admission in ICU. One thousand two hundred ninety-three (80%) patients were included in the “training set”, while 124 (8%) and 199 (12%) patients were included in the “test set 1” and “test set 2,” respectively. Three different predictive models were developed. Each model included different sets of clinical variables. The three models showed similar predictive performances, with a training balanced accuracy that ranged between 0.72 and 0.90, while the cross-validation performance ranged from 0.75 to 0.85. Age was the leading predictor for all the considered models. Conclusions Our study provides a useful and reliable tool, through a machine learning approach, for predicting ICU mortality in COVID-19 patients. In all the estimated models, age was the variable showing the most important impact on mortality.

Published

2021

2. Use of critical care resources during the first 2 weeks (February 24–March 8, 2020) of the Covid-19 outbreak in Italy.

Author

Tonetti, Tommaso, Grasselli, Giacomo, Zanella, Alberto, Pizzilli, Giacinto, Fumagalli, Roberto, Piva, Simone, Lorini, Luca, Iotti, Giorgio, Foti, Giuseppe, Colombo, Sergio, Vivona, Luigi, Rossi, Sandra, Girardis, Massimo, Agnoletti, Vanni, Campagna, Anselmo, Gordini, Giovanni, Navalesi, Paolo, Boscolo, Annalisa, Graziano, Alessandro, and Valeri, Ilaria

Subjects

COVID-19 pandemic, CRITICAL care medicine, COVID-19, COMORBIDITY, ADULT respiratory distress syndrome

Abstract

Background: A Covid-19 outbreak developed in Lombardy, Veneto and Emilia-Romagna (Italy) at the end of February 2020. Fear of an imminent saturation of available ICU beds generated the notion that rationing of intensive care resources could have been necessary. Results: In order to evaluate the impact of Covid-19 on the ICU capacity to manage critically ill patients, we performed a retrospective analysis of the first 2 weeks of the outbreak (February 24–March 8). Data were collected from regional registries and from a case report form sent to participating sites. ICU beds increased from 1545 to 1989 (28.7%), and patients receiving respiratory support outside the ICU increased from 4 (0.6%) to 260 (37.0%). Patients receiving respiratory support outside the ICU were significantly older [65 vs. 77 years], had more cerebrovascular (5.8 vs. 13.1%) and renal (5.3 vs. 10.0%) comorbidities and less obesity (31.4 vs. 15.5%) than patients admitted to the ICU. PaO2/FiO2 ratio, respiratory rate and arterial pH were higher [165 vs. 244; 20 vs. 24 breath/min; 7.40 vs. 7.46] and PaCO2 and base excess were lower [34 vs. 42 mmHg; 0.60 vs. 1.30] in patients receiving respiratory support outside the ICU than in patients admitted to the ICU, respectively. Conclusions: Increase in ICU beds and use of out-of-ICU respiratory support allowed effective management of the first 14 days of the Covid-19 outbreak, avoiding resource rationing. [ABSTRACT FROM AUTHOR]

Published

2020