key: cord-1001935-tzq8ugxx
authors: Khanduri, Sachin; Chawla, Harleen; Khan, Asif; Ali, Iffat; Krishnam, Anvit; Malik, Saif; Khan, Nazia; Patel, Yunus D; ., Surbhi; Rehman, Mufidur
title: Spectrum of Chest Dual-Energy Computed Tomography Findings in COVID Patients in North India
date: 2021-01-04
journal: Cureus
DOI: 10.7759/cureus.12489
sha: da968389cfbe6222c5c31b84dfb0e067158cfc1d
doc_id: 1001935
cord_uid: tzq8ugxx

Purpose To study the spectrum of chest dual-energy computed tomography (DECT) imaging findings in severe acute respiratory syndrome coronavirus 2 (SARS-COV-2) or COVID-19 infected Indian patients and classify them on the basis of the Radiological Society of North America CT classification. Method A total of 110 reverse transcription-polymerase chain reaction (RT-PCR)-positive patients (subjects) in which noncontrast chest DECT was done in our COVID-19 care center (CCC) were enrolled in this study. The prevalence of various abnormalities of lung parenchyma due to SARS-COV-2 and their distribution with extent was recorded. Various types of lung parenchyma abnormalities due to COVID-19 were evaluated in all patients. Data were analyzed and various prevalent abnormalities were calculated as a percentage for each type. All the cases were also sorted into four major groups on the basis of the Radiological Society of North America CT classification of COVID patients. Result Among the total 110 patients that were enrolled in this study, 80 (72.7%) were males and 30 (27.3%) were females with a mean age of 40.5 ± 7 years (range 24-84). Out of this, we observed that 59 (53.6%) cases had abnormalities of lung parenchyma and were designated as DECT positive, whereas 51 (46.3%) cases had completely normal DECT. Only 14 (12.7%) of the patients (cases) presented with dyspnoea, 10 (9%) had hyperpnoea, whereas 12 (10.8%) had other associated comorbidities. Among the patients having abnormal DECT findings, multilobar (86%), bilateral lung field involvement (72.8%) with the ascendancy of peripheral and posterior distribution was most commonly noted. With respect to the different types of opacities noted in various patients, we found that ground-glass opacity (GGO) was the common abnormality found in almost all cases for the greatest part. Pure GGO was reported in 16 (28%), GGO admixed with a crazy-paving pattern were elicited in 17 (28.8%) and GGO mixed with consolidation was noted in 25 (42.3%) cases. Thirty-eight (64.4%) cases were having peri-lesional or intra-lesional segments or involving a small segment enlargement of the pulmonary vessel. Among the cases showing DECT positivity, the typical pattern on the basis of the Radiological Society of North America (RSNA) classification was noted in 71.2% of cases, whereas the atypical pattern was found in 1.2% percent of cases and the intermediate type was depicted in 25.4% percent of cases. Forty-six point three percent (46.3%) of the total cases that were enrolled in the study were grouped as the no pneumonia category. Conclusion The result of this study proved that the maximum number of RT-PCR-positive COVID-19 patients had mild symptoms and few comorbidities with normal chest DECT and fell under the no pneumonia category of the RSNA CT classification of COVID patients. However, out of the remaining patients, the majority of patients had GGO on DECT as a typical finding mixed with other patterns in a bilateral distribution and peripheral predominance. A preponderance of patients presented with the typical appearance of pneumonia followed by an intermediate type.

Coronavirus disease (COVID-19) has been declared a pandemic and public health emergency of international concern since March 11, 2020 [1] . Severe acute respiratory syndrome coronavirus 2 (SARS COV 2, which is an encapsulated single-stranded ribonucleic acid (RNA) [1] [2] emerged at the end of 2019 in Wuhan, a city in China. The clinical scenario of this disease has a broad spectrum, ranging from being 1 1 1 1 1 1 1 asymptomatic to mild symptomatic to severely ill [1, [3] [4] . Image finding also depicts a wide spectrum and mainly includes ground-glass opacification with a basal and peripheral predominance as an initial manifestation to gradually transforming to consolidations [1, [4] [5] at later stages. The majority of COVID-19 sufferers have the complaint of disturbance of smell and taste, including dysgeusia, ageusia, hyposmia, and anosmia. A few also develop conjunctivitis and even have a positive viral polymerase chain reaction (PCR) in their conjunctival fluid. Cutaneous lesions can also develop, similar to any other viral infection; the most common one is an erythematous rash [5] [6] . Dual-energy computed tomography (DECT) has been introduced so as to provide better imaging possibilities in reverse transcription (RT)-PCR positive COVID patients. DECT has an edge over CT in the creation of Iodine maps, which can be further used to quantify perfusion disorders within the lung parenchyma, e.g. in pulmonary hypertension or pulmonary embolism [7] . In this study, we aim to gain insight into the spectrum of various findings on color-coded, noncontrast DECT images in the general population so as to create a database that can help further study in this direction. We also aim to assess the spectrum of findings elicited on the different energy scale of noncontrast DECT, so as to decide whether it is beneficial for those patients who cannot be subjected to contrast DECT either due to allergy to iodine-based contrast or any other reason.

This is a monocentric, retrospective study conducted in our tertiary care center, which is a designated COVID-19 care center, between the months of May and July 2020. It has the facility of separate inpatient, quarantine, and intensive care units, and patients were admitted as per the patient's health condition and severity of symptoms. Informed patient consent was waived by the institutional ethical committee, as no individual data were included. All the examinations were carried out in accordance with ethical standards, as enacted in the Declaration of Helsinki, 1964, and its amendments that occurred in due course of time. In this study, chest DECT was accomplished over symptomatic patients who were referred to our hospital from other district hospitals after being confirmed RT-PCR positive for SARS-COV-2. All symptomatic patients who presented with a variable degree of fever, cough, and dyspnea and fulfilled the inclusion, as well as exclusion criteria, were enrolled in this study.

Symptomatic patients with fever, cough, and dyspnea who are proven COVID-19 with positive RT-PCR and have undergone noncontrast DECT chest scans at a maximum of 28 days after the positive RT-PCR test.

All asymptomatic patients with positive RT-PCR-confirmed SARS-COV-2 infection.

On all the patients who fulfilled the above criteria, DECT scans were performed on the 384-slice dual-energy CT scanner (Somatom Force, Siemens Healthcare, Erlangen, Germany). After scout acquisition, imaging was conducted in a supine position and craniocaudal scanning direction. All the DECT images were acquired in a single shot where patients were asked to hold the breath in the inspiratory phase. Images were later reconstructed over the software using an increment of 0.7 mm into 1 mm slice thickness. As per guidelines, decontamination of the DECT suit, which was worn by the patient, was required and was performed using either 70% ethanol or 0.1% sodium hypochlorite as per the availability at the stance. After each DECT examination, there was passive air exchange allowed in the gantry area for a duration of 60 minutes.

Two radiologists (more than five years experience) reviewed the DECT images independently on an Osirix MD Workstation (Apple Mac; Apple Inc., Cupertino, California) [8] . Both the radiologists who were involved in the study were purposedly blinded to clinical data so as to avoid any bias. A detailed evaluation of the images was done and changes were identified, ranging from ground-glass opacity (GGO), consolidation, crazy-paving pattern, to various other parenchymal abnormalities. The location of lesions was assessed carefully and they were divided into different categories involving one lung (right or left) or both lungs. The number of lobes involved was calculated. Distribution of all the opacities in different zones of the bilateral lung field was done, and they were further classified as central, which is the inner two-third of the lung tissue, and peripheral, which extends as the outer one-third of the lung tissue. The distribution of lung abnormalities was further sub-segmented based on their location into anterior and posterior locations with respect to an imaginary line. This division is made as the parenchyma of the bilateral lung field anterior to a line drawn midway on axial DECT (imaginary line) was considered anterior and the remaining portion of the lung parenchyma was considered posterior. Lesions of lung parenchyma were also categorized into different entities using the Fleischner society glossary of terms for thoracic imaging [9] . GGO is established as an abnormal increase in lung density with non-obscuration of bronchial as well as vascular structures, whereas consolidation is explicated as lung parenchyma with increased density through which vascular and bronchial structures cannot be visualized. Furthermore, we evaluated for other associated abnormalities such as airway, vascular, pleural, and mediastinal abnormalities. A semi-quantitative scoring system has been used to quantitatively estimate the involvement of lung parenchyma by visually calculating the percentage of the total lung involved by dividing the right lung into three lobes and the left lung into two lobes [10] .

The finding of this study was evaluated using the Statistical Package for Sciences (SPSS version 21.0; IBM Corp., Armonk, NY). In this, we have used categorical variables, which were specified as counts and percentages while continuous variables were directed as mean, range, and standard deviation. The conformity between two interpreting radiologists as required for DECT findings was conceived using the Kappa method. According to Landis and Koch, the following statistics are used: 0 elicited poor agreement; 0.01-0.20 showed slight agreement; 0.21-0.40 elicited fair agreement; 0.41-0.60 showed moderate agreement; 0.61-0.80 directs substantial agreement; whereas 0.81-1.0 depicts almost perfect agreement [1] .

A total of 110 patients were enrolled in the study, of which 80 were males and 30 were females with a mean age of 40.5 +/-seven years. (range 24-84 years). Out of 110 patients, 76 patients had a history of travel to high-risk zones within or outside the country or a history of close contact with a positive patient. Fever was the most frequently observed symptom seen in 60 patients followed by fatigue or malaise in 60 patients (54.5%), sore throat in 35 (31.8%) patients, and cough in 52 (47.3%) patients. Only 14 (12.7%) patients were dyspnoeic, 10 (9.1%) patients complained of tachypnea, and six (5.4%) patients had desaturation. Lymphopenia was documented in 50 patients (34%), whereas lymphocytosis was seen in 14 (9.5%). Creactive protein was above the maximum limit of the standard normal range in 77 (52.4%). All these findings regarding patient demographics, clinical features, and laboratory investigations are summarized in Table 1 . 

It was observed that there was almost perfect agreement (Cohen's Kappa of 0.83) in reading noncontrast DECT images between the two primary radiologists. Lung parenchyma showed a wide spectrum of changes in RT-PCR-positive cases, from being completely normal to showing various findings in multiple lobes of bilateral lung fields (Figure 1 ). Multiple lobe involvement was seen more frequently (see Figures 1-6) . Twenty-six (44.1%) had involvement of all five lobes, whereas two-lobe and single lobe involvement was seen in seven (11.8%) patients each. In axial sections, we observed distribution in peripheral areas is the most common, seen in 57 (96%) cases, among which 40 (67.8%) had solely peripheral distribution, whereas 17 (28.8%) has peripheral as well as central distribution and neither of the patients showed purely central distribution. In consideration of the anterior-posterior sections, 0% of cases have shown solely anterior distribution, whereas 29 (49.2%) cases have shown solely posterior distribution, whereas 26 (44.1%) cases have shown combined anterior and posterior distribution. Reticulations were seen in 17 (28.8%) cases, whereas pure GGO (Figure 2 ) was observed in 16 (28%). A crazy-paving pattern (Figure 4) is produced when GGO combines with interlobular septal thickening and intralobular lines. A relatively less number of cases showed subpleural curvilinear lines, i.e. in 11 patients (18.6%). The reverse halo sign ( Figure 5) , also known as the atoll sign, was seen in 11 (18.6%) and the air bronchogram sign (Figure 3 ) was seen in 14 (23.7%) cases, respectively. Eight patients (13.6%) show bronchial wall thickening, whereas three patients (5.1%) show bronchodilatation. None of the patients showed the halo sign, cavitation, pleural effusion, or mediastinal lymphadenopathy. Patchy GGO is also observed in a few patients ( Figure 6 ). These findings are cumulated below in the form of Table 2 and Table 3 . Figure 3A is the section in grayscale, Figure 3B in 40 keV energy, Figure 3C in 190 keV, Figure 3D as a colorcoded image based on atomic number. year-old male shows patchy GGO in the lower basal segment of the right and left (marked with arrows) lung fields Figure 6A is the section in grayscale, Figure 6B in 40 keV energy, Figure 6C in 190 keV energy, and Figure  6D as a color-coded image based on atomic number. 

The Radiological Society of North America (RSNA) has recently released a consensus statement, which has been endorsed by the Society of Thoracic Radiology and the American College of Radiology, which has classified the various CT appearances of COVID-19 into four major categories, so as to establish a standardized reporting language that can be used by any doctor in any part of the world. This will ease the sharing of information among different parts of the world, and more conclusive data can be accumulated [11] . It has four major groups as typical appearance, intermediate appearance, atypical appearance, and negative for pneumonia. Typical appearance involves peripheral bilateral GGO with the presence or absence of consolidation. The atoll sign also signified the typical appearance. In our study, 42 (71.2%) cases showed typical appearance [7] . The intermediate appearance had a major absence of typical findings, and the presence of diffuse, multifocal, perihilar, or unilateral GGO, with or without consolidation, lacking a specific distribution, and are non-rounded or non-peripheral were present in 15 cases (25.4%) [7] . In our study, two (1.2%) cases showed the atypical appearance, which covers the absence of both typical and intermediate appearance with a predominant presence of isolated lobar or segmental consolidation without GGO, along with the presence of small nodules in discrete distribution and lung cavitation. The negative for pneumonia finding is given to patients where the CT chest is devoid of any finding that is suggestive of pneumonia, which is seen in 51 (46.3%) cases. In other words, there is in particular absence of GGO or consolidation [7] .

We have conducted this retrospective study at our COVID-19 care center (CCC) to gain a wider view of the chest on non-contrast DECT of COVID-19 RT-PCR-positive patients in our population so as to gather more information about the various spectrums of COVID findings. Li K et al. conducted a study with positive COVID-19 cases that presented with a wide range of clinical symptoms and found that 71.8% had a CT positivity rate, of which 30.8% were mild cases, 59% common, and 10.2% severe cases, respectively [12] . Caruso D et al. observed various pulmonary findings in 96.6% of symptomatic COVID-positive patients on chest CT [13] . Yu M et al. reported a CT positivity rate of 100% in their cohort study [14] . In our study, we have concluded that among COVID RT-PCR-positive patients who have lung parenchymal abnormalities, bilateral and multilobar distribution of pulmonary opacities with a peripheral predilection was observed. Our study has been successful in collecting data that fairly collaborate the distribution and type of pulmonary opacities observed in various COVID-positive patients. These patterns are cumulated in Table 4 . [13] [14] . Bai HX et al. observed that enlargement in vessel size has been frequently associated with COVID-19 pneumonia in comparison to non-COVID-19 pneumonia with a significant pP-value (<0.001) [15] . In severe cases, the percentage of diseased lung parenchyma was relatively higher than the cases with a mild form of the disease.

In conclusion, we found a high proportion of cases of normal chest DECT in mildly symptomatic, laboratoryconfirmed SARS-CoV-2 patients, which fell under the no pneumonia category of the RSNA CT Classification system. Patients with a positive DECT series elicited a predominance of bilateral and multilobar distributions of GGO with a posterior and peripheral predilection, which was similar to the findings reported in other studies. The majority of patients who were DECT positive presented with typical appearances of pneumonia followed by the intermediate type.

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Human subjects: Consent was obtained by all participants in this study. Animal subjects: All authors have confirmed that this study did not involve animal subjects or tissue. Conflicts of interest: In compliance with the ICMJE uniform disclosure form, all authors declare the following: Payment/services info: All authors have declared that no financial support was received from any organization for the submitted work. Financial relationships: All authors have declared that they have no financial relationships at present or within the previous three years with any organizations that might have an interest in the submitted work. Other relationships: All authors have declared that there are no other relationships or activities that could appear to have influenced the submitted work.