Radiomics Analysis of Computed Tomography helps predict poor prognostic outcome in COVID-19

Rationale: Given the rapid spread of COVID-19, an updated risk-stratify prognostic tool could help clinicians identify the high-risk patients with worse prognoses. We aimed to develop a non-invasive and easy-to-use prognostic signature by chest CT to individually predict poor outcome (death, need for mechanical ventilation, or intensive care unit admission) in patients with COVID-19. Methods: From November 29, 2019 to February 19, 2020, a total of 492 patients with COVID-19 from four centers were retrospectively collected. Since different durations from symptom onsets to the first CT scanning might affect the prognostic model, we designated the 492 patients into two groups: 1) the early-phase group: CT scans were performed within one week after symptom onset (0-6 days, n = 317); and 2) the late-phase group: CT scans were performed one week later after symptom onset (≥7 days, n = 175). In each group, we divided patients into the primary cohort (n = 212 in the early-phase group, n = 139 in the late-phase group) and the external independent validation cohort (n = 105 in the early-phase group, n = 36 in the late-phase group) according to the centers. We built two separate radiomics models in the two patient groups. Firstly, we proposed an automatic segmentation method to extract lung volume for radiomics feature extraction. Secondly, we applied several image preprocessing procedures to increase the reproducibility of the radiomics features: 1) applied a low-pass Gaussian filter before voxel resampling to prevent aliasing; 2) conducted ComBat to harmonize radiomics features per scanner; 3) tested the stability of the features in the radiomics signature by several image transformations, such as rotating, translating, and growing/shrinking. Thirdly, we used least absolute shrinkage and selection operator (LASSO) to build the radiomics signature (RadScore). Afterward, we conducted a Fine-Gray competing risk regression to build the clinical model and the clinic-radiomics signature (CrrScore). Finally, performances of the three prognostic signatures (clinical model, RadScore, and CrrScore) were estimated from the two aspects: 1) cumulative poor outcome probability prediction; 2) 28-day poor outcome prediction. We also did stratified analyses to explore the potential association between the CrrScore and the poor outcomes regarding different age, type, and comorbidity subgroups. Results: In the early-phase group, the CrrScore showed the best performance in estimating poor outcome (C-index = 0.850), and predicting the probability of 28-day poor outcome (AUC = 0.862). In the late-phase group, the RadScore alone achieved similar performance to the CrrScore in predicting poor outcome (C-index = 0.885), and 28-day poor outcome probability (AUC = 0.976). Moreover, the RadScore in both groups successfully stratified patients with COVID-19 into low- or high-RadScore groups with significantly different survival time in the training and validation cohorts (all P < 0.05). The CrrScore in both groups can also significantly stratify patients with different prognoses regarding different age, type, and comorbidities subgroups in the combined cohorts (all P < 0.05). Conclusions: This research proposed a non-invasive and quantitative prognostic tool for predicting poor outcome in patients with COVID-19 based on CT imaging. Taking the insufficient medical recourse into account, our study might suggest that the chest CT radiomics signature of COVID-19 is more effective and ideal to predict poor outcome in the late-phase COVID-19 patients. For the early-phase patients, integrating radiomics signature with clinical risk factors can achieve a more accurate prediction of individual poor prognostic outcome, which enables appropriate management and surveillance of COVID-19.

[1]  Y. Hu,et al.  [Asymptomatic infection of COVID-19 and its challenge to epidemic prevention and control]. , 2020, Zhonghua liu xing bing xue za zhi = Zhonghua liuxingbingxue zazhi.

[2]  W. Liang,et al.  Clinically Applicable AI System for Accurate Diagnosis, Quantitative Measurements, and Prognosis of COVID-19 Pneumonia Using Computed Tomography , 2020, Cell.

[3]  Jun Zhang,et al.  Predictive factors for disease progression in hospitalized patients with coronavirus disease 2019 in Wuhan, China , 2020, Journal of Clinical Virology.

[4]  Z. Zhao,et al.  Multicenter cohort study demonstrates more consolidation in upper lungs on initial CT increases the risk of adverse clinical outcome in COVID-19 patients , 2020, Theranostics.

[5]  F. Shan,et al.  CT quantification of pneumonia lesions in early days predicts progression to severe illness in a cohort of COVID-19 patients , 2020, Theranostics.

[6]  Hangyuan Guo,et al.  Risk factors of critical & mortal COVID-19 cases: A systematic literature review and meta-analysis , 2020, Journal of Infection.

[7]  Yaling Shi,et al.  A Tool to Early Predict Severe Corona Virus Disease 2019 (COVID-19) : A Multicenter Study using the Risk Nomogram in Wuhan and Guangdong, China , 2020, Clinical infectious diseases : an official publication of the Infectious Diseases Society of America.

[8]  C. Eastin,et al.  Characteristics and Outcomes of 21 Critically Ill Patients with COVID-19 in Washington State , 2020, The Journal of Emergency Medicine.

[9]  Ran Yang,et al.  Chest CT Severity Score: An Imaging Tool for Assessing Severe COVID-19 , 2020, Radiology. Cardiothoracic imaging.

[10]  Jian-feng Xie,et al.  Development and external validation of a prognostic multivariable model on admission for hospitalized patients with COVID-19 , 2020, medRxiv.

[11]  Yaling Shi,et al.  A Tool to Early Predict Severe 2019-Novel Coronavirus Pneumonia (COVID-19) : A Multicenter Study using the Risk Nomogram in Wuhan and Guangdong, China , 2020, medRxiv.

[12]  Heshui Shi,et al.  Temporal Changes of CT Findings in 90 Patients with COVID-19 Pneumonia: A Longitudinal Study , 2020, Radiology.

[13]  K. Cao,et al.  Artificial Intelligence Distinguishes COVID-19 from Community Acquired Pneumonia on Chest CT , 2020, Radiology.

[14]  Yu Zhou,et al.  Predicting COVID-19 malignant progression with AI techniques , 2020, medRxiv.

[15]  Jun Liu,et al.  CT Scans of Patients with 2019 Novel Coronavirus (COVID-19) Pneumonia , 2020, Theranostics.

[16]  Xiang Xie,et al.  COVID-19 and the cardiovascular system , 2020, Nature Reviews Cardiology.

[17]  L. Xia,et al.  CT Features of Coronavirus Disease 2019 (COVID-19) Pneumonia in 62 Patients in Wuhan, China. , 2020, AJR. American journal of roentgenology.

[18]  X. Qi,et al.  Machine learning-based CT radiomics model for predicting hospital stay in patients with pneumonia associated with SARS-CoV-2 infection: A multicenter study , 2020, medRxiv.

[19]  J. Xiang,et al.  Clinical course and risk factors for mortality of adult inpatients with COVID-19 in Wuhan, China: a retrospective cohort study , 2020, The Lancet.

[20]  Chuanming Li,et al.  The Clinical and Chest CT Features Associated With Severe and Critical COVID-19 Pneumonia , 2020, Investigative radiology.

[21]  K. Yuen,et al.  Clinical Characteristics of Coronavirus Disease 2019 in China , 2020, The New England journal of medicine.

[22]  Q. Tao,et al.  Correlation of Chest CT and RT-PCR Testing in Coronavirus Disease 2019 (COVID-19) in China: A Report of 1014 Cases , 2020, Radiology.

[23]  Ting Yu,et al.  Clinical course and outcomes of critically ill patients with SARS-CoV-2 pneumonia in Wuhan, China: a single-centered, retrospective, observational study , 2020, The Lancet Respiratory Medicine.

[24]  Heshui Shi,et al.  Radiological findings from 81 patients with COVID-19 pneumonia in Wuhan, China: a descriptive study , 2020, The Lancet Infectious Diseases.

[25]  Z. Fayad,et al.  Chest CT Findings in Coronavirus Disease-19 (COVID-19): Relationship to Duration of Infection , 2020, Radiology.

[26]  C. Zheng,et al.  Time Course of Lung Changes On Chest CT During Recovery From 2019 Novel Coronavirus (COVID-19) Pneumonia , 2020, Radiology.

[27]  Yan Zhao,et al.  Clinical Characteristics of 138 Hospitalized Patients With 2019 Novel Coronavirus-Infected Pneumonia in Wuhan, China. , 2020, JAMA.

[28]  Z. Fayad,et al.  CT Imaging Features of 2019 Novel Coronavirus (2019-nCoV) , 2020, Radiology.

[29]  Jing Zhao,et al.  Early Transmission Dynamics in Wuhan, China, of Novel Coronavirus–Infected Pneumonia , 2020, The New England journal of medicine.

[30]  Bin Zhang,et al.  Association of MRI-derived radiomic biomarker with disease-free survival in patients with early-stage cervical cancer , 2020, Theranostics.

[31]  Tianye Niu,et al.  A radiomics approach based on support vector machine using MR images for preoperative lymph node status evaluation in intrahepatic cholangiocarcinoma , 2019, Theranostics.

[32]  Fanny Orlhac,et al.  Validation of A Method to Compensate Multicenter Effects Affecting CT Radiomics. , 2019, Radiology.

[33]  Jianhua Ma,et al.  Radiomic signature of 18F fluorodeoxyglucose PET/CT for prediction of gastric cancer survival and chemotherapeutic benefits , 2018, Theranostics.

[34]  Steffen Löck,et al.  Assessing robustness of radiomic features by image perturbation , 2018, Scientific Reports.

[35]  Andriy Fedorov,et al.  Computational Radiomics System to Decode the Radiographic Phenotype. , 2017, Cancer research.

[36]  Laurence Court,et al.  Harmonizing the pixel size in retrospective computed tomography radiomics studies , 2017, PloS one.

[37]  R. Steenbakkers,et al.  The Image Biomarker Standardization Initiative: Standardized Quantitative Radiomics for High-Throughput Image-based Phenotyping. , 2016, Radiology.

[38]  Valery Naranjo,et al.  Comparing algorithms for automated vessel segmentation in computed tomography scans of the lung: the VESSEL12 study , 2014, Medical Image Anal..

[39]  Andre Dekker,et al.  Radiomics: the process and the challenges. , 2012, Magnetic resonance imaging.

[40]  Patrick Granton,et al.  Radiomics: extracting more information from medical images using advanced feature analysis. , 2012, European journal of cancer.

[41]  F. Aversa,et al.  Regression modeling of competing risk using R: an in depth guide for clinicians , 2010, Bone Marrow Transplantation.

[42]  Fei-Fei Li,et al.  ImageNet: A large-scale hierarchical image database , 2009, 2009 IEEE Conference on Computer Vision and Pattern Recognition.

[43]  F. Aversa,et al.  Competing risk analysis using R: an easy guide for clinicians , 2007, Bone Marrow Transplantation.

[44]  Y. Chan,et al.  Short term outcome and risk factors for adverse clinical outcomes in adults with severe acute respiratory syndrome (SARS) , 2003, Thorax.

[45]  Elizabeth Rea,et al.  Clinical features and short-term outcomes of 144 patients with SARS in the greater Toronto area. , 2003, JAMA.

[46]  Li Yan,et al.  A machine learning-based model for survival prediction in patients with severe COVID-19 infection , 2020 .

[47]  R. Tibshirani Regression Shrinkage and Selection via the Lasso , 1996 .