key: cord-308302-5yns1hg9
authors: Wu, Gang; Zhou, Shuchang; Wang, Yujin; Lv, Wenzhi; Wang, Shili; Wang, Ting; Li, Xiaoming
title: A prediction model of outcome of SARS-CoV-2 pneumonia based on laboratory findings
date: 2020-08-20
journal: Sci Rep
DOI: 10.1038/s41598-020-71114-7
sha: 
doc_id: 308302
cord_uid: 5yns1hg9

The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has resulted in thousands of deaths in the world. Information about prediction model of prognosis of SARS-CoV-2 infection is scarce. We used machine learning for processing laboratory findings of 110 patients with SARS-CoV-2 pneumonia (including 51 non-survivors and 59 discharged patients). The maximum relevance minimum redundancy (mRMR) algorithm and the least absolute shrinkage and selection operator logistic regression model were used for selection of laboratory features. Seven laboratory features selected in the model were: prothrombin activity, urea, white blood cell, interleukin-2 receptor, indirect bilirubin, myoglobin, and fibrinogen degradation products. The signature constructed using the seven features had 98% [93%, 100%] sensitivity and 91% [84%, 99%] specificity in predicting outcome of SARS-CoV-2 pneumonia. Thus it is feasible to establish an accurate prediction model of outcome of SARS-CoV-2 pneumonia based on laboratory findings.

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All methods were carried out in accordance with relevant guidelines and regulations.

Study design and participants. This study was approved by the Ethics Commission of Hospital (TJ-2020-075). Written informed consent was waived by the Ethics Commission of hospital. The author's center was the designated hospital for severe and critical SARS-CoV-2 pneumonia. Patients underwent repeated RT-PCR tests to confirm SARS-CoV-2. Laboratory tests for SARS-CoV-2 pneumonia included: blood routine test, serum biochemical (including glucose, renal and liver function, creatine kinase, lactate dehydrogenase, and electrolytes), coagulation profile, cytokine test, markers of myocardial injury, infection-related makers, and other enzymes. Repeated tests were done every 3-6 days for monitoring the patient's condition.

Oxygen support (from nasal cannula to invasive mechanical ventilation) was administered to patients according to the severity of hypoxaemia. All patients were administered with empirical antibiotic treatment, and received antiviral therapy. Most of patients improved after treatment. However, a few critical patients continued to deteriorate and eventually died.

Data collection. 58 fatal cases of SARS-CoV-2 pneumonia (39 male, median age 66 years) were collected by the electronic medical record system. 68 discharged patients with SARS-CoV-2 pneumonia whose age and gender matched the non-survivors were selected (46 male, median age 66 years). The admission date of these patients was from Feb 16, 2020 to Mar 20, 2020 . We reviewed all laboratory findings for each patient. Results of repeated tests were carefully compared to find the greatest deviation from normal value. In general, the greatest number in series of values was recorded. However, for platelets, red blood cell, lymphocytes, hemoglobin, calcium, total protein, albumin, estimated glomerular filtration rate (eGFR), and prothrombin activity (PTA), the minimum was recorded. Laboratory findings at the day of mortality were not used. These recorded laboratory findings were considered as lab features of a patient. A initial data set of 126 patients (non-survivor 58, discharge 68) was thus built.

There were 16 patients who did not have the entire group of laboratory features, thus their data were deleted from the dataset. The remaining data of 110 patients (51 non-survivor, 59 discharge) were analyzed by machine learning.

Statistical analysis and modeling. First, all the variables were compared between non-survivors and discharged patients using the Mann-Whitney U test for non-normally distributed features or the independent t test for normally distributed features 16, 17 . Features with P < 0.05 were considered significant variables and selected 16, 17 . Second, Spearman's correlation coefficient was used to compute the relevance and redundancy of the features 16, 17 . Third, we applied the maximum relevance minimum redundancy (mRMR) algorithm to assess the relevance and redundancy of the features 16, 17 . The features were ranked according to their mRMR scores 16, 17 . Fourth, the top 15 features with high-relevance and low-redundancy were selected for least absolute shrinkage and selection operator (LASSO) logistic regression model. The LASSO logistic regression model was adopted for further features selection 16, 17 . Some candidate features coefficients were shrunk to zero and the remaining variables with non-zero coefficients were finally selected 16, 17 . The model was used for calculating signature for each patient. Mann-Whitney U test was used for comparing signature between two groups 16, 17 . Receiver operator characteristic (ROC), precision recall curve (PRC) analysis and Hosmer-Lemeshow test were used for further evaluation of model.

The statistical analyses were performed using R software (version 3.3.4; https ://www.r-proje ct.org) 16, 17 . The following R packages were used: the "corrplot" package was used to calculate Spearman's correlation coefficient; the "mRMRe" package was used to implement the mRMR algorithm; the "glmnet" was used to perform the LASSO logistic regression model, and the "pROC" package was used to construct the ROC curve 16, 17 .

Nine laboratory features were eliminated in the first step of feature selection because of non-significance. The remaining thirty-eight lab features were significantly different between two groups (P < 0.05), and then mRMR scores were obtained for them. There were seven features having non-zero coefficients after LASSO algorithm, and were selected for the model. Table 1 shows the fifteen features with the highest mRMR scores. Figure 1 shows the correlation matrix heatmap of the thirty-eight significant features. Figure 2 shows the feature selection process with LASSO algorithm. Figure 3 shows the contribution of the seven features to the model. Figure 4 shows the signatures of all patients, as well as ROC. Figure 5 shows the PRC for the model. Non-survivors and discharged patients differed significantly in the signature derived from the model (P < 0.0001). The AUC was 0.997 [95% CI 0.99, 1.00]. The sensitivity and specificity in predicting outcome of SARS-CoV-2 pneumonia were 98% [93%, 100%] and 91% [84%, 99%] respectively. The area under precision recall curve (AUPRC) was 0.996. Hosmer-Lemeshow test showed good calibration (P = 0.95) for the model.

The seven features included in the prediction model were as follows: PTA, urea, white blood cell (WBC), interleukin-2 receptor (IL-2r), indirect bilirubin (IB), myoglobin, and fibrinogen degradation products (FgDP). All features had coefficients of positive number except PTA. PTA and FgDP are from coagulation profile. Urea and IB are from renal and liver function respectively. WBC is from blood routine test. Myoglobin is a marker of myocardial injury. IL-2r is related to immune response. The signatures derived from the model could be positive or negative numbers. www.nature.com/scientificreports/ Non-survivors and discharged patients did not differ in age or gender (median age 67 vs. 66, P = 0.75; percentage of males, 66% vs. 64%, P = 0.66). The comparisons of laboratory findings between non-survivors and discharged patients are shown in Table 2 .

Blood routine test. WBC and neutrophils were significantly higher in non-survivor group versus discharge group. Lymphocyte, platelets and red blood cells were significantly lower in non-survivors. AUC for them were 0.646-0.910. Table 1 . The fifteen features with higher mRMR scores were selected for the step of LASSO logistic regression. Some candidate features coefficients were shrunk to zero and the remaining variables with non-zero coefficients were selected. mRMR maximum relevance minimum redundancy, LASSO least absolute shrinkage and selection operator, PTA prothrombin activity, WBC white blood cell, IL-2r interleukin-2 receptor, IB indirect bilirubin, TB total bilirubin, FgDP fibrinogen degradation products, hs-CRP hypersensitive C-reactive protein, LDH lactate dehydrogenase, eGFR estimated glomerular filtration rate. Cytokine. IL-2r and IL-6 were significantly higher in non-survivor group versus discharge group. AUC for them were 0.689-0.909.

Procalcitonin, high sensitive C-reactive protein, ferritin and N-terminal pro-brain natriuretic peptide (NT-proBNP) were significantly higher in non- 

Non-survivors and discharged patients with SARS-CoV-2 pneumonia differed significantly in thirty-eight laboratory findings. By using machine learning method, we established a prediction model involving seven laboratory features. The model was found highly accurate in distinguishing non-survivors from discharged patients. The seven features selected by artificial intelligence also indicated that dysfunction of multiple organs or systems correlated with the prognosis of SARS-CoV-2 pneumonia. The SARS-CoV-2 triggers a series of immune responses and induces cytokine storm, resulting in changes in immune components 5, 18 . When immune response is dysregulated, it will result in an excessive inflammation, even cause death 7, 19 . Excessive neutrophils may contribute to acute lung damage, and are associated with fatality 20 . Higher serum level of IL-2r was found in non-survivors, indicating excessive immune response. In addition, high leukocyte count in SARS-CoV-2 patients may be also due to secondary bacterial infection 21, 22 .

Liver injury has been reported to occur during the course of the disease 23, 24 , and is associated with the severity of diseases. Increased serum bilirubin level was observed in fatal cases. Acute kidney injury could have been related to direct effects of the virus, hypoxia, or shock 25, 26 . Blood urea level continued to increase in some cases. Non-survivors had higher blood urea compared to survivors. Myocardial injury was seen in non-survivors, which was suggested by elevated level of myoglobin. The mechanism of multiple organ dysfunction or failure may be associated with the death of patients with SARS-CoV-2 pneumonia. Some patients with SARS-CoV-2 infection progressed rapidly with sepsis shock, which is well established as one of the most common causes of disseminated intravascular coagulation (DIC) 27 . The non-survivors in our cohort revealed significantly lower PTA compared to survivors. At the late stages of SARS-CoV-2 infection, level of fibrin-related markers (FgDP) markedly elevated in most cases, suggesting a secondary hyperfibrinolysis condition.

A number of laboratory features were compared between non-survivors and discharged patients with SARS-CoV-2 pneumonia. The two groups differed significantly in as many as thirty-eight lab features. However, none of the futures provided adequate accuracy in predicting the outcome of SARS-CoV-2 pneumonia. Thus, a novel prediction model involving multiple features was established in the study. With machine learning methods previously used in radiomics, a prediction model combining seven out of thirty-eight laboratory features was built for predicting the outcome of SARS-CoV-2 pneumonia.

The mRMR algorithm was used for assessing significant features to avoid redundancy between features. The mRMR score of a feature is defined as the mutual information between the status of the patients and this feature minus the average mutual information of previously selected features and this feature 17, 28, 29 . The top fifteen features with high mRMR scores were selected for the next step of modeling. The least absolute shrinkage and selection operator logistic regression model was used to processing the features selected by mRMR algorithm. LASSO is actually a regression analysis method that improves the model prediction accuracy and interpretability 30 . The signature calculated with the model can be positive or negative number, corresponding with poor and good prognosis respectively. Our results showed that the AUC of the signature was 10-40% higher than that of a single feature.

The modeling process is a black box; however, the choice of variables seems reasonable. PTA can more accurately reflect the coagulation function compared to prothrombin time, and can also reflect the degree of liver injury. Urea is a good index to reflect the degree of renal function damage. WBC can not only reflect immune www.nature.com/scientificreports/ It is suitable to start to use this model after three repeated laboratory tests (about 2 weeks after admission), because doctors may have enough data at that time. Lots of laboratory findings are generated in hospitalization. Which are most important for predicting outcome? Our study at least answered such a problem. Seven laboratory features could be used to construct a new signature with the model. The new signature seems more useful than any single feature. We encourage such a simple-to-use model widely used in clinical practice.

Most of clinical factors are not continuous variables (such as underlying disease). We used a machine learning method similar to radiomics, which mainly deals with continuous features. Our study focused on continuous laboratory variables. We had to exclude non-continuous clinical factor with the current machine learning method. By using other methods, a model that involves both continuous variables and category variables can be established. Thus clinical factors raised as significant predictive factors (such as respiratory status or radiological features) could be included in the models. However, there are more than forty laboratory findings in our study, making establishment of model difficult. We felt it necessary to simplify laboratory features. Thus we establish a sub-model based on lab findings. A new lab signature is thus created, and is proved highly valuable. In future study, the signature may be combined with clinical factors to establish a more complex model.

Our study has some limitations. First, this is a single-center retrospective study. Multi-center large-sample studies are required to validate our prediction model. Second, our model may not be directly used in other centers. However, they could easily establish a prediction model using their own data with machine learning method. Third, some patients who did not have all the lab findings were excluded. Selection bias must be present due to patients exclusion. Other studies with more strict design were thus required to reveal the bias. Fourth, statistical approach conducted in this study is not perfect. As LASSO was used for 15 variables, 150 or more patients were needed. More patients should be collected in future study.

In conclusion, it is feasible to establish a accurate prediction model of outcome of SARS-CoV-2 pneumonia based on laboratory findings. Injury of liver, kidney and myocardium, coagulation disorder and excess immune response all correlate with the outcome of SARS-CoV-2 pneumonia.

After publication, the data will be made available to others on reasonable requests to the corresponding author.

Received: 26 March 2020; Accepted: 10 August 2020

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We thank all patients and their families involved in the study.

G.W., S.Z. and Y.W. collected the epidemiological and clinical data. T.W., W.L. and S.W. summarized all data. G.W., X.L. drafted the manuscript. T.W. and X.L. revised the final manuscript.

The authors declare no competing interests.

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