Robust prediction of mortality of COVID-19 patients based on quantitative, operator-independent, lung CT densitometry

Martina Mori; Diego Palumbo; Rebecca De Lorenzo; Sara Broggi; Nicola Compagnone; Giorgia Guazzarotti; Pier Giorgio Esposito; Aldo Mazzilli; Stephanie Steidler; Giordano Pietro Vitali; Antonella Del Vecchio; Patrizia Rovere Querini; Francesco De Cobelli; Claudio Fiorino

doi:10.1016/j.ejmp.2021.04.022

Robust prediction of mortality of COVID-19 patients based on quantitative, operator-independent, lung CT densitometry

Phys Med. 2021 May:85:63-71. doi: 10.1016/j.ejmp.2021.04.022. Epub 2021 Apr 30.

Authors

Affiliations

¹ Medical Physics, San Raffaele Scientific Institute, Milano, Italy.
² Radiology, San Raffaele Scientific Institute, Milano, Italy.
³ Internal Medecine, San Raffaele Scientific Institute, Milano, Italy.
⁴ Internal Medecine, San Raffaele Scientific Institute, Milano, Italy; Faculty of Medecine and Surgery, Vita-Salute San Raffaele University, Milano, Italy.
⁵ Radiology, San Raffaele Scientific Institute, Milano, Italy; Faculty of Medecine and Surgery, Vita-Salute San Raffaele University, Milano, Italy.
⁶ Medical Physics, San Raffaele Scientific Institute, Milano, Italy. Electronic address: fiorino.claudio@hsr.it.

Abstract

Purpose: To train and validate a predictive model of mortality for hospitalized COVID-19 patients based on lung densitometry.

Methods: Two-hundred-fifty-one patients with respiratory symptoms underwent CT few days after hospitalization. "Aerated" (AV), "consolidated" (CV) and "intermediate" (IV) lung sub-volumes were quantified by an operator-independent method based on individual HU maximum gradient recognition. AV, CV, IV, CV/AV, IV/AV, and HU of the first peak position were extracted. Relevant clinical parameters were prospectively collected. The population was composed by training (n = 166) and validation (n = 85) consecutive cohorts, and backward multi-variate logistic regression was applied on the training group to build a CT_model. Similarly, models including only clinical parameters (CLIN_model) and both CT/clinical parameters (COMB_model) were developed. Model's performances were assessed by goodness-of-fit (H&L-test), calibration and discrimination. Model's performances were tested in the validation group.

Results: Forty-three patients died (25/18 in training/validation). CT_model included AVmax (i.e. maximum AV between lungs), CV and CV/AE, while CLIN_model included random glycemia, C-reactive protein and biological drugs (protective). Goodness-of-fit and discrimination were similar (H&L:0.70 vs 0.80; AUC:0.80 vs 0.80). COMB_model including AVmax, CV, CV/AE, random glycemia, biological drugs and active cancer, outperformed both models (H&L:0.91; AUC:0.89, 95%CI:0.82-0.93). All models showed good calibration (R²:0.77-0.97). Despite several patient's characteristics were different between training and validation cohorts, performances in the validation cohort confirmed good calibration (R²:0-70-0.81) and discrimination for CT_model/COMB_model (AUC:0.72/0.76), while CLIN_model performed worse (AUC:0.64).

Conclusions: Few automatically extracted densitometry parameters with clear functional meaning predicted mortality of COVID-19 patients. Combined with clinical features, the resulting predictive model showed higher discrimination/calibration.

Keywords: COVID-19; CT; Lung densitometry; Respiratory distress syndrome.

MeSH terms

COVID-19*
Densitometry
Humans
Lung
Retrospective Studies
SARS-CoV-2
Tomography, X-Ray Computed