key: cord-309517-yh4d414y authors: Yu, Chao; Zhou, Miao; Liu, Yang; Guo, Tinglin; Ou, Chongyang; Yang, Liye; Li, Yan; Li, Dongliang; Hu, Xinyu; Shuai, Li; Wang, Bin; Zou, Zui title: Characteristics of asymptomatic COVID-19 infection and progression: A multicenter, retrospective study date: 2020-08-12 journal: Virulence DOI: 10.1080/21505594.2020.1802194 sha: doc_id: 309517 cord_uid: yh4d414y Novel coronavirus disease 2019 (COVID-19), caused by novel coronavirus SARS-CoV-2, has spread globally since the end of 2019. Asymptomatic carriers are of great concern as they can undermine the interventions to stop the pandemic. However, there is limited information about the characteristics and outcomes of the asymptomatic patients. Therefore, we conducted this retrospective study and retrieved data of 79 asymptomatic COVID-19 patients at admission from three designated hospitals in Wuhan, China. The asymptomatic patients could happen at any age, ranged from 9 to 96 years. These patients also had lower levels of alanine aminotransferase and C-reactive protein. Patchy shadowing was the most common manifestation in computed tomography scan. Some asymptomatic carriers developed mild or moderate symptoms during hospitalization. Age and comorbidities, especially hypertension, may be predictive factors for symptom development in the initially asymptomatic carriers at admission. Early detection and treatment for these presymptomatic patients before symptom onset can shorten the communicable period for the coronavirus and reduce the occurrence of severe cases. Since December 2019, an outbreak of novel coronavirus disease 2019 , caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) has spread globally, affecting more than 200 countries and 3,000,000 individuals and causing over 200,000 deaths worldwide until April 30 [1] . Although the overall mortality rate of COVID-19 is low, the disease can be transmitted rapidly, and people are generally susceptible to its infection. The virus is primarily spread from person to person by respiratory droplets [2] . The COVID-19 incubation period ranges from 6 to 8 days, and patients can develop symptoms such as fever, cough, myalgia, pneumonia, and even respiratory failure after this period. However, a proportion of the patients are asymptomatic carriers, who are diagnosed based on positive viral nucleic acid test and show no COVID-19 symptoms. The transmission of the novel coronavirus from an asymptomatic carrier with normal chest computed tomography (CT) has been reported [3, 4] . A cohort study in China with 44,672 cases reported 1.2% asymptomatic carriers [5] , which is believed to be much underestimated. Recent reports suggested that 10-30% of patients infected with SARS-CoV-2 are asymptomatic. Thus, considering that the asymptomatic carriers are infectious, it's essential to identify them in order to effectively contain the spread of the virus. Till now, limited data are available for the prevalence and characteristics of the asymptomatic carriers [3] , especially the data about the recurrence of positive CONTACT Zui Zou zouzui1980@163.com; Bin Wang qcwangb@163.com; Li Shuai sli201575@163.com *These authors are contributed equally to this work. This study demonstrated the characteristics of asymptomatic COVID-19 carriers. Age and presence of hypertension may be predictive factors for symptom development in the initially asymptomatic carriers during hospitalization. Early detection and early treatment for these presymptomatic patients can help shorten the communicable period for the coronavirus and reduce the occurrence of severe cases. Supplemental data for this article can be accessed on the publisher's website. SARS-CoV2 RNA in these carriers. In addition, some asymptomatic patients can develop symptoms during hospitalization [6] , and the characteristics of these presymptomatic patients and their independent risk factors have not been addressed yet. Therefore, in the present study, we investigated 79 asymptomatic patients to analyze their clinical characteristics, disease progression, and recurrence of positive SARS-CoV2 RNA after discharge. We analyzed the demographic and clinical characteristics of the COVID-19 patients who were diagnosed according to the guidelines from the National Health Commission of the People's Republic of China and the interim guidance from World Health Organization interim guidance [7] . After excluding the non-COVID -19 patients, clinically diagnosed patients, unconscious patients, and mental patients, the remaining 1568 patients were divided into two groups based on their symptoms at admission ( Figure 1 ). All discharged COVID-19 patients were isolated and observed in a quarantine facility for two weeks continuously. Seventy-nine asymptomatic cases were recruited, and the final data of follow up was Mar 14 April 2020 or later. All these carriers received anti-viral therapy, traditional Chinese medicine (TCM), and symptomatic treatment during hospitalization. These initially asymptomatic carriers were then further grouped into presymptomatic patients and completely asymptomatic patients according to their disease progression during Variables were eligible for entry into a multiple logistic regression model if there were intergroup differences (P < 0.05). Logistic regression analysis and the area under the receiver operator characteristic (ROC) curve were used to predict discrimination accuracy. P value less than 0.05 indicated a statistically significant difference. Asymptomatic infection can occur at any age, but had a higher prevalence in patients aged <45 compared with the symptomatic group (Table 1) . Hypertension and diabetes were the most common comorbidities, and incidence rate of diabetes was higher in the asymptomatic group than in the symptomatic group (20.25% vs. 11.69%). The two groups did not differ in the incidence rates of comorbidities including respiratory disease, hypertension, coronary heart disease, chronic renal disease. The asymptomatic group also had more patients without abnormalities in radiographic presentations at admission than the symptomatic group (8.86% vs. 3.83%). No intergroup differences were observed in other radiographic characteristics, and patchy shadowing was the most common abnormality Meanwhile, the asymptomatic carriers had normal levels of other markers related to liver damage, renal dysfunction, inflammation, and coagulation, which were comparable with those of the symptomatic patients. Though some asymptomatic patients at admission developed symptoms during hospitalization, most of the symptoms were mild or moderate (Table 1) . Only 2.53% of asymptomatic carriers developed severe disease, but not critical disease, and all of these patients were discharged from the hospitals. However, 14.57% of the symptomatic patients presented severe or critical disease with a mortality of 3.29%. Of the 79 initially asymptomatic patients at admission, 34(43.03%) of them developed symptoms during hospitalization. The median age in these presymptomatic patients was higher than that of the completely asymptomatic patients (68.50 years(IQR 49.00, 80.50) vs. 55.00 years (IQR 37.50,64.00)) ( Table 3 ). The symptoms developed about 8.00 days (median, IQR [5.00,12.00 days], 95%CI 4.36-11.64 days) post positive nucleic acid test. The minimum and maximum incubation period were 2 and 28 days, respectively. Fever (28/ 34, 82.35%) was the main symptom in these presymptomatic patients (Supplementary Table 1 ). Most of their body temperatures were under 38°C, and only two presented high fever (>38°C). Compared with the symptomatic patients, the presymptomatic patients had less symptoms including lower incidences of cough, fatigue, and chest distress. Compared with the completely asymptomatic patients, the presymptomatic patients had more comorbidities (52.94% vs. 22.22%), especially hypertension (44.12% vs. 4.44%), and higher incidence of having over two coexisting disorders (32.35% vs. 6.67%). The radiographic characteristics of the presymptomatic patients were similar to those of the asymptomatic patients. The completely asymptomatic patients also had bilateral abnormalities (77.78%), and patchy shadowing (53.33%) was their most common abnormality. They also had lower level of albumin and higher serum creatinine than the presymptomatic patients. The levels of ALT and CRP also differed between these two groups. As comorbidity may be an important risk factor of presymptomatic patients, we then focused on the subgroup of the asymptomatic patients with or without comorbidities (Supplementary Table 2 ). Of the asymptomatic patients, those with comorbidities were older (68.50 years vs. 51.00 years) and were more likely to develop symptoms during hospitalization compared with those without comorbidities (64.29% vs. 31.37%). The patients with comorbidities also had higher percentage of bilateral patchy shadowing in chest CT scan, higher levels of blood urea nitrogen and CRP, and lower levels of albumin than the asymptomatic patients without comorbidities. Hypertension and diabetes were the two most common comorbidities. Furthermore, of the 17 asymptomatic patients with hypertension, 11 (64.70%) suffered from two or more comorbidities, and 15 (88.23%) developed symptoms during hospitalization. To identify the independent risk factors associated with the presymptomatic COVID-19 patients at admission, multivariate logistic regression analysis on laboratory variables and demographic data was conducted (Table 4 ). At baseline, age and hypertension were independent discriminatory variables and risk factors for presymptomatic patients. A mode (AUC 0.751, 95%CI 0.636-0.866) combining age>69.5 years with hypertension may discriminate presymptomatic patients from completely asymptomatic patients at admission, with a sensitivity of 56.7% and specificity of 87.2% (Supplementary Table 3, and Supplementary Figure 1) . All the asymptomatic patients received antiviral therapy, traditional Chinese medicine, and symptomatic treatment during hospitalization. Although the presymptomatic patients developed symptoms during hospitalization, these patients had similar viral RNA shedding duration compared with the asymptomatic carriers (14 days [IQR 7-25 days] vs. 12 days [IQR 5-24 days])( Table 3) . The viral shedding duration in the presymptomatic cases may even be 8 days [IQR 6-15.25 days] since the symptom onset. Surprisingly, the completely asymptomatic patients also had recurrence of positive SARS-CoV-2 RNA after discharge, which was similar to the presymptomatic patients (11.11% vs. 8.82%). Asymptomatic COVID-19 carriers are estimated to comprise 10-30% of SARS-CoV-2 infected patients. As viral RNA sheds in the upper respiratory tract, it has been proven that both asymptomatic and presymptomatic patients are contagious. Recently, one report revealed that the rates of virus infection through close contact with symptomatic patients and with asymptomatic patients were 6.30% and 4.11%, respectively [8] . Since the asymptomatic patients are more difficult to be identified and isolated than the symptomatic carriers, they might be one of the major drivers of the COVID-19 pandemic [9] . In this study, we reported 79 laboratory-confirmed asymptomaticCOVID-19 cases. We found that younger carriers were more prone to be symptom-free. However, diabetes and cancer were more common in the asymptomatic patients, which was different from the previous reports that comorbidities were mainly the risk factors for severe COVID-19. After analyzing these asymptomatic patients, we found that 11 cases in the asymptomatic group were from the same nursing home coronavirus cluster. Elevated occurrence of diabetes and cancer in these elder patients caused increased incidence of diabetes and cancer in the asymptomatic group. In addition, most of these patients (7/11, 63.64%) were actually presymptomatic patients who developed symptoms during hospitalization. Other comorbidities were not correlated with the development of symptomatic or asymptomatic cases, indicating common comorbidities may have no significant relevance in distinguishing those asymptomatic carriers at admission. The radiographic abnormalities of the asymptomatic patients were almost similar to those of the symptomatic patients in our study, except for the fact that the asymptomatic group had slightly more patients without abnormalities (8.86% vs. 3.83%), indicating CT scan can not identify the asymptomatic carriers. However, a recent paper reported nearly half (43.2%) asymptomatic patients without radiographic abnormalities [10] . In addition, they also found most of the abnormalities were unilateral, which is inconsistent with our findings. Thus, the exact radiographic characteristics of asymptomatic patients needs further investigation. Though some of the asymptomatic cases developed symptoms during hospitalization, most of these cases were mild or moderate. The lower levels of ALT and CRP in the asymptomatic patients compared with symptomatic patients indicated these patients had less liver damage and inflammation. Some studies demonstrated a substantial decrease in the total number of lymphocytes in COVID-19 patients. However, no marked reduction of lymphocytes were observed in both asymptomatic and symptomatic patients in our study. Reduced lymphocytes may indicate a more severe phenotype of the disease. The severely diseased COVID-19 patients comprised a less percent in the symptomatic group, and some of their conditions were even moderate or mild at admission. Thus, the decreased lymphocytes may be observed with further detailed classification of the symptomatic patients. Although most of the presymptomatic patients developed mild or moderate disease, two patients developed severe disease and required oxygen therapy or other interventions. Therefore, identifying these severe diseased presymptomatic patients can have great clinical value and more studies need to be carried out in this area. The presymptomatic patients developed symptoms 8 days post positive nucleic acid test, indicating an incubation period of about 8 days, or even longer considering the interval between SARS-CoV-2 exposure and nucleic acid test. However, previous reports declared a 5-6 day median incubation period from virus exposure [11, 12] . Studies also found that the elders had a longer incubation period and a larger variance than the youngers [12] . Thus, the prolonged incubation period found in our study may be due to the higher percentage of the elderly patients and the medical treatment in the presymptomatic group. To discriminate the presymptomatic patients from the asymptomatic carriers, we also compared them with the completely asymptomatic carriers. Those who were older and had hypertension or combined comorbidities were more likely develop symptoms during hospitalization. Hypertension has been identified previously as a risk factor for severe COVID-19 disease and can cause higher mortality [13, 14] . Angiotensin-converting enzyme inhibitor (ACEIs) and angiotensin II receptor blockers (ARBs) have been used in the first-line treatment for hypertension. ACEIs and ARBs can increase the expression level of ACE2, the main cellular entry receptor for SARS-CoV-2 virus. However, a recent retrospective, multicenter study revealed that the hospitalized patients who received ACEI/ARB had lower mortality rate compared with ACEI/ARB nonusers [15] . Thus, presence of hypertension and no usage of ACEI/ARB may be correlated with the disease progression in the asymptomatic carriers. Albumin and creatinine levels can reflect the function of the liver and kidney. All the asymptomatic patients possessed normal range albumin and creatinine, and the presymptomatic patients had lower level of albumin and higher level of serum creatinine compared with completely asymptomatic patients, suggesting slight liver and kidney injury. This result aligned with the previous reports that the SARS-CoV-2 virus can invade liver and kidney and have significant cytotoxicity toward these cells [16] [17] [18] . These correlations also suggested the association between symptoms and organ injury. The viral shedding duration of the completely asymptomatic patients were 12 days (median), which was comparable to that in the presymptomatic patients. The viral shedding duration of the asymptomatic patients was shorter than that of the symptomatic patients, which was 17 days or even longer [19] [20] [21] [22] . In this study, the viral shedding duration was calculated from the first day when a patient had a positive nucleic acid test, which may be underestimated compared with those in symptomatic patients starts from the symptom onset. However, the viral shedding duration of the presymptomatic patients in our study started before symptom onset and was overestimated compared with previous reports. By receiving antiviral therapy and traditional Chinese medicine treatment before the symptom onset, the patients could have a shorter communicable period compared with those symptomatic patients in the previous studies [22] . This finding strongly indicated that early detection and early treatment of the presymptomatic patients can not only stop the rapid transmission but also reduce the viral communicable period. Another study also demonstrated that delayed admission to hospital after illness onset is associated with prolonged viral shedding duration [22] . In addition, early treatment may also reduce the severe disease ratio, as relatively fewer presymptomatic patients in our study developed severe or critical disease compared with the symptomatic patients who started treatment after symptom onset. However, a recent paper reported a median duration of viral shedding in the asymptomatic group as 19 days [10] . These may be caused by the resource of the patients, as their patients were from active screening close contacts under quarantine, but ours were from those who came to hospital by themselves. The asymptomatic carriers may also be redetected positive for SARS-CoV-2 RNA after discharge, even only had mild disease and no abnormalities in the laboratory parameters. This finding was consistent with the report that mild diseased patients are more prone to be redetected positive after discharge [23, 24] . In our study, the recurrence rate of positive SARS-CoV-2 nucleic acid in the asymptomatic carriers after discharge was lower than that in the symptomatic patients (10.12% vs. 14.5%) [24] . Although the exact reasons for this recurrence remain unclear, false negativity, residual virus, and age distribution may be potential factors [25, 26] . Recently, postmortem pathological evidence revealed the presence of residual virus in the pulmonary tissues of patient who had a sudden death when ready for discharge [27] . These explanations for symptomatic patients may also apply to the asymptomatic carriers. Therefore, in addition to the asymptomatic coronavirus transmission, the recurrence in the asymptomatic carriers should also be taken into concern to control the spread of the virus. The characteristics of these asymptomatic patients with recurrence of positive SARS-CoV-2 RNA require further investigation with a mass of samples. There were still limitations to this study. First, only 79 asymptomatic inpatient cases were included, and most of the asymptomatic patients were under medical observation in mobile cabin hospitals or even in the open. A more extensive study on these cases need to be conducted to describe their characteristics and find independent risk factors for the disease progression. Furthermore, since only two asymptomatic cases progressed to severe disease during hospitalization, no clues were found on how to distinguish these asymptomatic patients who may develop severe disease. In addition, since we did not have adequate information about the levels of inflammatory cytokines in these cases, we could not analyze whether the inflammatory state of the asymptomatic carriers was correlated with the progression and severity of the disease in these asymptomatic patients. Therefore, large-scale retrospective or prospective studies with more detailed information are needed to expand and validate our study. In sum, our study has been the largest multicenter retrospective study on asymptomatic COVID-19 carriers to describe their clinical characteristics and their disease progression. Patients under 45 years old are more likely to develop asymptomatic infection. Age and presence of hypertension may be predictive factors for the symptomatic progression of asymptomatic carriers at admission. Recurrence of positive SARS-CoV-2 nucleic acid may also happen in asymptomatic carriers. Early detection and treatment of these asymptomatic patients can shorten the communicable period and reduce the chances to develop severe disease. As a result, a more scientific control strategy with more focus on these asymptomatic patients need to be developed to control the COVID-19 pandemic. COVID-19) Situation Report -101; 2020. Epub COVID-19-new insights on a rapidly changing epidemic Presumed asymptomatic carrier transmission of COVID-19 Transmission of 2019-nCoV infection from an asymptomatic contact in Germany Novel Coronavirus Pneumonia Emergency Response Epidemiology T. [The epidemiological characteristics of an outbreak of Follow-up of asymptomatic patients with SARS-CoV-2 infection Clinical management of severe acute respiratory infection when novel coronavirus (2019-nCoV) infection is suspected: interim guidance Asymptomatic and presymptomatic infectors: hidden sources of COVID-19 disease Gutierrez investigating the impact of asymptomatic carriers on COVID-19 transmission. medRxiv Clinical and immunological assessment of asymptomatic SARS-CoV-2 infections The incubation period of coronavirus disease 2019 (COVID-19) from publicly reported confirmed cases: estimation and application Estimate the incubation period of coronavirus 2019 (COVID-19) Clinical characteristics of 138 hospitalized patients with 2019 novel coronavirus-infected Pneumonia in Wuhan Clinical course and risk factors for mortality of adult inpatients with COVID-19 in Wuhan, China: a retrospective cohort study Association of inpatient use of angiotensin converting enzyme inhibitors and angiotensin ii receptor blockers with mortality among patients with hypertension hospitalized with COVID-19 Identification of a potential mechanism of acute kidney injury during the covid-19 outbreak: a study based on single-cell transcriptome analysis Liver injury in COVID-19: management and challenges ACE2 expression in kidney and testis may cause kidney and testis damage after 2019-nCoV infection. medRxiv Temporal dynamics in viral shedding and transmissibility of COVID-19 sars-cov-2 viral load in upper respiratory specimens of infected patients Prolonged SARS-CoV-2 RNA shedding: not a rare phenomenon Factors associated with prolonged viral RNA shedding in patients with COVID-19 Positive RT-PCR Test Results in Patients Recovered From COVID-19 Clinical characteristics of the recovered COVID-19 patients with re-detectable positive RNA test. medRxiv Prolonged presence of SARS-CoV-2 in feces of pediatric patients during the convalescent phase False-negative of RT-PCR and prolonged nucleic acid conversion in COVID-19: rather than recurrence Pathological evidence for residual SARS-CoV-2 in pulmonary tissues of a ready-for-discharge patient We thank Ning Ma (Department of Laboratory Medicine, Changzheng hospital, Second Military Medical University, Shanghai) for helpful discussion and review of the manuscript. The datasets generated during the current study are available from the corresponding author on reasonable request. ZZ and CY conceived and designed the study. CY, MZ, and YL analyzed the data and wrote the first draft of the manuscript. YL, TG, CO, LY, YL, DL, and XH recruited patients, gathered data, and did statistical analysis. LS, BW, and ZZ supervised the study and reviewed the manuscript. All authors had approved the decision to submit the manuscript. All of the authors declare that they have no conflict of interest. We are grateful for the financial support from the Shanghai Science and Technology Committee (18411951300, 18411951301, 18411951302, 18411951303)