key: cord-1039385-6xoh95rh authors: Tsakok, M. T.; Watson, R. A.; Lumley, S. F.; Khan, F.; Qamhawi, Z.; Lodge, A.; Xie, C.; Shine, B.; Matthews, P.; Jeffery, K.; Eyre, D. W.; Benamore, R.; Gleeson, F.; Rodger, G.; Constantinides, B.; Sanderson, N.; Chau, K. K. title: Parenchymal involvement on CT pulmonary angiography in SARS-CoV-2 Alpha variant infection and correlation of COVID-19 CT severity score with clinical disease severity and short-term prognosis in a UK cohort date: 2021-11-23 journal: Clin Radiol DOI: 10.1016/j.crad.2021.11.002 sha: a7ad9212d26738c70960b067327ec061931b858f doc_id: 1039385 cord_uid: 6xoh95rh Aim To determine if there is a difference in radiological, biochemical, or clinical severity between patients infected with Alpha-variant SARS-CoV-2 compared with those infected with pre-existing strains, and to determine if the computed tomography (CT) severity score (CTSS) for COVID-19 pneumonitis correlates with clinical severity and can prognosticate outcomes. Materials And Methods Blinded CTSS scoring was applied to 137 hospital patients who had undergone both CT pulmonary angiography (CTPA) and whole-genome sequencing of SARS-CoV-2 within 14 days of CTPA between 1/12/20–5/1/21. Results There was no evidence of a difference in imaging severity on CTPA, viral load, clinical parameters of severity, or outcomes between Alpha and preceding variants. CTSS on CTPA strongly correlates with clinical and biochemical severity at the time of CTPA, and with patient outcomes. Classifying CTSS into a binary value of “high” and “low”, with a cut-off score of 14, patients with a high score have a significantly increased risk of deterioration, as defined by subsequent admission to critical care or death (multivariate hazard ratio [HR] 2.76, p<0.001), and hospital length of stay (17.4 versus 7.9 days, p<0.0001). Conclusion There was no evidence of a difference in radiological severity of Alpha variant infection compared with pre-existing strains. High CTSS applied to CTPA is associated with increased risk of COVID-19 severity and poorer clinical outcomes and may be of use particularly in settings where CT is not performed for diagnosis of COVID-19 but rather is used following clinical deterioration. A novel SARS-CoV-2 Alpha (B.1.1.7) variant, was identified in September 2020 in the UK 1 , and subsequently, demonstrated rapid spread, representing the dominant strain at Oxford University Hospitals NHS Trust by the end of December 2020 2 . The Alpha variant (B.1.1.7 lineage) is reported to be associated with increased disease severity and mortality in the community [3] [4] [5] , but there are few studies on the inhospital population 6, 7 , and none that have evaluated imaging findings. The Alpha variant is associated with increased viral load compared to pre-existing strains in the community 8 . Viral load is an important determinant of transmissibility 9 and has been associated with increased clinical disease severity and mortality 10, 11 ; however, the relationship of viral load and computed tomography severity score (CTSS) has not been well defined. Chest imaging has the potential to assist in stratifying COVID-19 severity, with multiple studies validating the use of visual semi-quantitative CTSS, which has been shown to correlate with clinical severity and short-term prognosis [12] [13] [14] [15] [16] ; however, no studies address a UK population, in which the majority of the COVID-19 CT imaging comprises CT pulmonary angiography (CTPA) to evaluate for thromboembolic disease rather than high-resolution computed tomography (HRCT) or unenhanced computed tomography (CT) as part of the diagnostic work-up 17 . The CTSS evaluating the lung parenchyma has not been well studied with this CTPA, in which contrast medium may confound interpretation of ground-glass opacities by increasing lung density, and which also images in arrested respiration resulting in inconsistency in the phase of the respiratory cycle. Furthermore, differential lineages affecting the UK COVID-19 patient population may limit the applicability of the findings of previous studies. The present retrospective analysis compared radiologically determined disease severity for initial CTPA of patients infected with the Alpha variant compared with those infected with pre-existing strains. In addition, the correlation of the CTSS with viral load, symptom duration, clinical disease severity, and biochemical parameters and prognostic markers was also evaluated. Data were collected retrospectively on 137 patients at a large tertiary-referral centre in the UK who had undergone CTPA within the study time window of 1 December 2020 to 5 January 2021 and also had a positive polymerase chain reaction (PCR) for SARS-CoV-2 within 14 days of CTPA with whole-genome sequencing (WGS) of the virus. The first CT pulmonary angiogram following patient presentation was performed using one of three CT systems. All examinations were performed with the standard CTPA protocol (100 kV where possible, with 70-100 ml at a speed of 4 ml/s using pump injection, dependent upon body habitus). Images were reconstructed using sharp reconstruction kernel for parenchyma and viewed at window setting optimised for assessment of the lung parenchyma. One radiologist with >15 years of thoracic imaging experience and one radiologist with 3.5 years of imaging experience evaluated the severity of images blinded to J o u r n a l P r e -p r o o f lineage, other radiologist scoring, and clinical information using the semi-quantitative CTSS proposed by Pan et al. 18 . CTSS was determined by scoring each of the five lobes considering the extent of anatomical involvement as follows: 0, no involvement; 1, <5% involvement; 2, 5-25% involvement; 3, 26-50% involvement; 4, 51-75% involvement; and 5, >75% involvement. The resulting global CTSS was the sum of each individual lobar score and (0 to 25). The mean score from two CTSS raters was used for the analysis. The electronic patient records were used to establish the date of symptom onset and to determine outcome measures. Oxygen saturation and requirements were used to calculate the World Health Organization (WHO) ordinal progression score 19 (Table 1 ). For the purposes of this study, severity of illness of patients admitted to hospital was derived by recording the highest point reached on this ordinal scale within 30 days of admission or from the first positive swab date if asymptomatic. The WHO score was also recorded on the day of CTPA. Patients with severe disease were defined as those patients reaching point 6 or higher during the assessment period. Mortality data were defined by death by day 30 after the first positive swab. Admission to critical care was defined as an admission to either a high-dependency unit (HDU) or intensive-care unit (ICU) within 30 days of the positive PCR swab. Participants were defined as having a comorbidity if they had at least one of the following: diabetes mellitus, chronic obstructive pulmonary disease (COPD), asthma, ischaemic heart disease, hypertension. Biochemical data including C-reactive protein (CRP) and lymphocytes, both at time of CTPA and maximum level during admission was collected. Significance was set at p<0.05. There was no evidence of difference in severity of lung involvement between variants (p=0.79; Fig. 1a ). A small but statistically significance difference in maximum CRP between the Alpha and non-Alpha groups was demonstrated (134 versus 172 respectively; p=0.08); however, there was no evidence of a difference in the WHO Ordinal Score, hospital length of stay (LOS), critical care admission, or death within 30 days of positive swab (see Fig. 1 ). Lastly, a difference in viral load as determined by cycle threshold between variants was not observed ( Table 2) . There was excellent correlation between reporters in the blinded evaluation of CT imaging using the 25 point scoring system (Spearman's rho=0.93, p<0.0001, Fig. 2; ICC 0.943, 0.919-0.960, p<0.0001). The association between CTSS score and viral load was assessed and no correlation was found between viral load (PCR cycle threshold ORF) and CTSS, CTSS was associated with clinical outcomes. There was also a moderate correlation between CTSS and hospital LOS (Fig. 5a, rho=0.42, p<0.0001) . Patients with subsequent admission to critical care (between 1 and 30 days post-CTPA) had a mean CTSS of 16 versus 12.6 for those who were not admitted (Fig. 5b, p<0.0001 ). Those who died had a mean score of 15.4 versus 13.3; however, this was not statistically significant (Fig. 5c, p=0.083) . To explore the association with clinical outcome further, a logistic regression model was performed controlling for age, gender, comorbidities, and variant. A strongly significant association was found between CTSS score and both admission to critical 1.034-1.3, p<0.01) . CTSS was then classified into a binary outcome of "high" and "low" and used a receiver operating characteristic (ROC) curve to define an optimal cut-off for CTSS on CTPA. Using a composite J o u r n a l P r e -p r o o f outcome of admission to critical care or death, a cut-off of 13.5 was obtained (sensitivity=0.69, specificity=0.65, AUC=0.72). Taking a threshold score of ≥14 to be "high", Kaplan-Meier survival analysis was performed and demonstrated significant divergence in the composite outcome of critical care admission or death (log rank p<0.0001; Fig. 6a ). Using Cox proportional hazards analysis, controlling for age, sex, and comorbidities demonstrated a significant hazard ratio (HR) for the composite outcome (HR=2.76 [1.53-4.96], p<0.001) . Finally, using this cut-off of 14, hospital LOS was also prolonged significantly at a mean stay of 17.4 days for those with a high score versus 7.9 days for those with a low score (Fig. 6b) . The present retrospective study compares the severity of lung disease, rates of pulmonary embolism, and viral load between patients hospitalised with the Alpha variant and pre-existing variants of SARS-CoV-2 in a UK tertiary-referral centre. There was no evidence of a difference between variants in disease severity, either radiologically on clinical outcomes or on viral load. The cause for apparent low but significant higher CRP in patients infected with non-Alpha variants is unclear. CTSS performed during CTPA can effectively stratify patients into those that are at increased risk of deterioration (leading to critical care admission or death) with a cutoff score of 14 giving a significant HR (2.76, p<0.001) for this outcome. The present findings are consistent with published work 6 that describes no difference in severity or death between variants in a hospitalised cohort, despite larger community-based studies detecting a difference in mortality outcome 5 . The present study is believed to be the first to compare lineage of hospital presenters undergoing CTPA and report no evidence of a difference in radiological severity on CTPA J o u r n a l P r e -p r o o f between the Alpha variant and non-Alpha variant infection; however, the study was not able to replicate the finding of a difference in viral load 6 . Furthermore, the present study did not find an association between PCR cycle threshold and CT determined severity of COVID-19. Cycle threshold is used as a marker of viral load, with lower cycle threshold suggesting higher viral load. Only one study to date has correlated cycle threshold with CT findings, and demonstrated that high CTSS were associated with lower viral load 20 , a finding that was not replicated in the present study. No difference was demonstrated in CTSS between early and late-phase disease as determined by date from symptom onset. Although many studies have demonstrated increased CTSS with later phase disease 13, 21, 22 , other studies have demonstrated severity of COVID-19 to be variable at different temporal windows of the epidemic curve 23 . The relationship between CTSS and duration of symptoms is therefore complex. The finding that CTSS evaluated on CTPA can provide insight into likelihood of subsequent deterioration or prolonged hospital stay is of particular value in settings where CT does not perform part of the diagnostic pathway for COVID-19, such as the UK. Here, CT is performed due to clinical deterioration and evaluation for pulmonary embolism, for which there is very limited validation of the CTSS. The present study demonstrates that these CTPA can be used to predict likely deterioration. CTPA may lead to more challenging interpretation of ground-glass opacities due to COVID-19, as there may be ground-glass opacities due to expiration and contrast medium. The present study shows a higher mean score than previous studies, which has been most widely used, and is likely to be more acceptable in clinical practice than the 40 point scale proposed by Feng et al. 14 . Demonstration that CTSS on CTPA may help risk stratify and is associated with increased risk of HDU/ITU admission and LOS and may help further define its role. The present study is limited by its retrospective design, small sample size, and lack of an external validation cohort. Furthermore, CTSS is a semi-quantitative scoring system, which is not necessarily an accurate surrogate for percentage lung involvement, as scoring of all lobes are equally weighted despite not comprising equal proportion of ventilatory capacity. A strength of this study is full genome sequencing to establish B.1.1.7 lineage, rather than the SGTF status as proxy. It is also the first to perform blinded comparison of severity on imaging between the groups. Future studies may assess if radiological patterns, including features such as ground-glass or crazy-paving are similar between emerging variants as well as if the longer-term sequelae, for example, of fibrosis, is similar between the two groups. Validation of the CTSS cut-off described on a separate cohort would also substantially build on these current findings. Software analysis of percentage lung involvement may also allow more quantitative evaluation. This study is only the second such study to compare in-hospital disease severity in the Alpha variant to wild-type viruses, and it is the first work to correlate lineage with imaging findings. CTSS on CTPA was also correlated with clinical and biochemical markers of severity and short-term prognosis in a UK population, whereby demonstrating higher scores are associated critical care admission and death. 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The role of CT in patients suspected with COVID-19 infection Time course of lung changes at chest CT during recovery from coronavirus disease 2019 (COVID-19) A minimal common outcome measure set for COVID-19 clinical research Relationship of the cycle threshold values of SARS-CoV-2 polymerase chain reaction and total severity score of computerized tomography in patients with COVID 19 Chest CT findings of COVID-19 pneumonia by duration of symptoms Chest CT in COVID-19 pneumonia: a correlation of lung abnormalities with duration and severity of symptoms The authors thank Avneet Gill, Oxford University Hospitals NHS Trust, Oxford, UK.