Quantitative chest CT analysis in COVID-19 to predict the need for oxygenation support and intubation

Lanza, Ezio; Muglia, Riccardo; Bolengo, Isabella; Santonocito, Orazio Giuseppe; Lisi, Costanza; Angelotti, Giovanni; Morandini, Pierandrea; Savevski, Victor; Politi, Letterio S.; Balzarini, Luca

doi:10.1007/s00330-020-07013-2

Cited by 116 publications

(137 citation statements)

References 34 publications

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“…Recently, Lessmann et al developed an AI system that accurately identified COVID-19 patients with high diagnostic performance and assigned SS in good agreement with the experienced radiologist 17 . Lanza et al also used computer-aided quantitative analysis of CT images to determine compromised lung volumes and predict the need for oxygenation support and intubation 18 . They found that patients with compromised lung volumes of > 23% were at risk for intubation.…”

Section: Discussionmentioning

confidence: 99%

Validation of Chest Computed Tomography Artificial Intelligence to Determine the Requirement for Mechanical Ventilation and Risk of Mortality in Hospitalized Coronavirus Disease-19 Patients in a Tertiary Care Center In Mexico City

Kimura-Sandoval¹,

Arévalo-Molina²,

Cristancho-Rojas³

et al. 2021

RIC

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Background: Artificial intelligence (AI) in radiology has improved diagnostic performance and shortened reading times of coronavirus disease 2019 (COVID-19) patients' studies. Objectives: The objectives pf the study were to analyze the performance of a chest computed tomography (CT) AI quantitative algorithm for determining the risk of mortality/mechanical ventilation (MV) in hospitalized COVID-19 patients and explore a prognostic multivariate model in a tertiary-care center in Mexico City. Methods: Chest CT images of 166 COVID-19 patients hospitalized from April 1 to 20, 2020, were retrospectively analyzed using AI algorithm software. Data were collected from their medical records. We analyzed the diagnostic yield of the relevant CT variables using the area under the ROC curve (area under the curve [AUC]). Optimal thresholds were obtained using the Youden index. We proposed a predictive logistic model for each outcome based on CT AI measures and predetermined laboratory and clinical characteristics. Results: The highest diagnostic yield of the assessed CT variables for mortality was the percentage of total opacity (threshold >51%; AUC = 0.88, sensitivity = 74%, and specificity = 91%). The AUC of the CT severity score (threshold > 12.5) was 0.88 for MV (sensitivity = 65% and specificity = 92%). The proposed prognostic models include the percentage of opacity and lactate dehydrogenase level for mortality and troponin I and CT severity score for MV requirement. Conclusion: The AI-calculated CT severity score and total opacity percentage showed good diagnostic accuracy for mortality and met MV criteria. The proposed prognostic models using biochemical variables and imaging data measured by AI on chest CT showed good risk classification in our population of hospitalized COVID-19 patients. (REV INVEST CLIN. [AHEAD OF PRINT])

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Section: Discussionmentioning

confidence: 99%

Validation of Chest Computed Tomography Artificial Intelligence to Determine the Requirement for Mechanical Ventilation and Risk of Mortality in Hospitalized Coronavirus Disease-19 Patients in a Tertiary Care Center In Mexico City

Kimura-Sandoval¹,

Arévalo-Molina²,

Cristancho-Rojas³

et al. 2021

RIC

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“…Another approach was applied by Colombi et al [ 18 ] and Lanza et al [ 19 ] determining the value of quantifying the extent of well-aerated lung at baseline chest CT in COVID-19 patients. Both groups used an open-source (not deep learning-based) 3D slicer software to quantify the percentage and absolute volume of well aerated lung in SARS-CoV-2 positive patients at baseline CT.…”

Section: Discussionmentioning

confidence: 99%

“…Comparing our results to that from Colombi et al [ 18 ], the deep learning algorithm provided a faster (120 s vs. 270 s) and more accurate segmentation with post-hoc corrections only necessary in 7% of cases (vs. 61 %). Lanza et al [ 19 ] reported a median time for segmentation of 11 min. The automatic chest CT analysis in our study was carried out on a standard PACS workstation of our institution.…”

Section: Discussionmentioning

confidence: 99%

Deep learning for automatic quantification of lung abnormalities in COVID-19 patients: First experience and correlation with clinical parameters

Mergen¹,

Kobe²,

Blüthgen³

et al. 2020

European Journal of Radiology Open

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“…The potential prognostic role of CT-based assessment of lung disease extension has been suggested [13][14][15][16]27], and a few studies have included it in combined prognostic models [17][18][19][20]. Colombi et al found a slightly higher increase in AUC (from 0.83 to 0.86) when adding CT disease extension to a clinical model predictive of intensive care unit admission and/or death [17].…”

Section: Both Models Performed Better In Less Severe Patients In Termmentioning

confidence: 99%

A Prognostic Model for Death in COVID-19 Patients Presenting to the Emergency Room: The Added Value of Computed Tomography.

Besutti

Ottone

Fasano

et al. 2020

Preprint

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Objective: The added value of CT in prognostic models for coronavirus disease 2019 (COVID-19) patients is unclear. The aim of this study was to develop a prognostic model for death in COVID-19 patients using clinical and CT variables.Methods: Consecutive patients who presented to the emergency room between February 27 and March 23, 2020 for suspected COVID-19, underwent chest CT, and had a positive swab within 10 days were included in this retrospective study. Age, sex, comorbidities, days from symptom onset, and laboratory data were retrieved from institutional information systems. CT disease extension was visually graded as < 20%, 20-39%, 40-59%, or ≥ 60%. The association between clinical and CT variables with death was estimated with univariable and multivariable Cox proportional hazards models; model performance was assessed using k-fold cross-validation for the area under the ROC curve (CvAUC).Results: Of the 866 included patients (median age 59.8, women 39.2%), 93 (10.74%) died. Clinical variables significantly associated with death in multivariable model were age, male sex, HDL cholesterol, dementia, heart failure, vascular diseases, time from symptom onset, neutrophils, LDH, and oxygen saturation level (SO2). CT disease extension was also independently associated with death (HR=7.56, 95% CI=3.49; 16.38 for ≥ 60% extension). CvAUCs were 0.927 (bootstrap bias corrected-95%CI=0.899-0.947) for the clinical model and 0.936 (bootstrap bias corrected-95%CI=0.912-0.953) when adding CT extension.Conclusions: A prognostic model based on clinical variables is highly accurate in predicting death in COVID-19 patients. Adding CT disease extension to the model scarcely improves its accuracy.

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Quantitative chest CT analysis in COVID-19 to predict the need for oxygenation support and intubation

Cited by 116 publications

References 34 publications

Validation of Chest Computed Tomography Artificial Intelligence to Determine the Requirement for Mechanical Ventilation and Risk of Mortality in Hospitalized Coronavirus Disease-19 Patients in a Tertiary Care Center In Mexico City

Validation of Chest Computed Tomography Artificial Intelligence to Determine the Requirement for Mechanical Ventilation and Risk of Mortality in Hospitalized Coronavirus Disease-19 Patients in a Tertiary Care Center In Mexico City

Deep learning for automatic quantification of lung abnormalities in COVID-19 patients: First experience and correlation with clinical parameters

A Prognostic Model for Death in COVID-19 Patients Presenting to the Emergency Room: The Added Value of Computed Tomography.

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