key: cord-1004540-vos01ero authors: Cho, Eun Been; Choi, Seong‐Ho; Chung, Jin‐Won; Lee, Mi‐Kyung title: Usefulness of national respiratory virus surveillance data for clinicians who manage adult patients date: 2018-04-26 journal: J Med Virol DOI: 10.1002/jmv.25199 sha: 84fd5a7a33ce032d94daebe73f835baa1f51cb01 doc_id: 1004540 cord_uid: vos01ero The Korean Centers for Disease Control and Prevention (KCDC) provides weekly respiratory virus (RV) surveillance reports on its website (the KCDC data). Clinicians in clinical settings wherein the use of PCR for RVs is not a routine laboratory test for adult patients with acute respiratory illness (ARI) may question the clinical utility of such a national RV surveillance dataset in predicting RV outbreaks among their adult patients. We compared the KCDC data to the RV PCR data of adult patients who visited a tertiary care center. During a period of 108 weeks, a total of 6955 (5598 pediatric and 1257 adult) patients underwent RV PCR tests for ARI; most of these tests were administered while the patients were admitted (n = 6,920; 99.5%). From the KCDC website, we collected the RV PCR test results of 22 540 patients. Three graphs of weekly positivity rates were made for adults, children, and the KCDC data per each RV, and these graphs were then compared with one another. Whereas RV outbreaks were coincident between the KCDC and the adult graph with respect to influenza virus, respiratory syncytial virus, human metapneumovirus, and human coronavirus, the same was not true for human bocavirus, parainfluenza virus, rhinovirus, and adenovirus. However, a negative predictive value of the KCDC data in the prediction of the occurrence of an outbreak in the adult graph was high for the respective eight RVs (85‐100%). A national RV surveillance dataset may be useful in identifying RV outbreaks in adult patients with severe ARI. Polymerase chain reaction (PCR) tests for common respiratory viruses (RVs) are rarely included as a part of routine diagnostic tests performed in the majority of adult patients with acute respiratory illnesses (ARIs) other than the influenza virus (IFV) because the clinical significance of these RVs has been stressed more so in pediatric patients and effective antiviral treatments remain underdeveloped. 1, 2 However, considering that recent studies have shown their serious adverse impacts in adults, [3] [4] [5] it may be necessary for clinicians who manage adult patients with ARI caused by one of these RVs to suspect the cause early; identify it quickly; and prevent it from spreading within the community or hospital through education, vaccination, or other methods of infection control. In current clinical practice, without the routine performance of RV PCR tests for adult patients with ARI, a national or regional laboratory RV surveillance database may be a useful adjunct to that end. The use of such datasets in clinical practice is already well-accepted for IFV, which causes massive outbreaks in both children and adults throughout the community, leading to serious symptoms in some. 6 Based on a national surveillance influenza dataset, the Korean The system was organized by the KCDC nearly two decades ago. 7 After several revisions, the system now includes 200 sentinel sites throughout the country, including data on primary care clinics for pediatrics (n = 100), internal medicine (n = 71), and family medicine (n = 29). Each sentinel site provides weekly reports of the number of patients who present with influenza-like illnesses (ILIs) among those evaluated at KCDC sentinel sites. Of these, 36 also provide respiratory specimens from patients with ARI (laboratory sentinel site). The KCDC posts the data, including the rate of ILI prevalence among examined patients and the prevalence for the eight RVs among the tested specimens, on its website every week. 8 Relevant KCDC data were retrieved from the KCDC website during the present study's period. For each RV, we developed three graphs of weekly positivity rates representing the adult rates, the pediatric rates, and the KCDC rates. Although this study focused on adult patients, the pediatric data of the study hospital were also included because the KCDC data included those from all age groups and the pediatric data were thought to be helpful in addressing some differences between the KCDC data and the adult data. We compared the KCDC graph to the adult graph in three ways. First, we compared them based on the timing of outbreaks and seasonal peaks for each RV. Second, we examined whether the occurrence of an outbreak in the KCDC graph in a given week could predict that in the adult graph in the same week. An outbreak of any RV was regarded to occur at a given week if the detection rate of the RV was >3% during that week. The detection rate of 3% was selected because most of the RV outbreaks in our data began just after the weekly detection rate went up over the value. The predictability of the KCDC data for the occurrence of an outbreak in the adult data was presented as a positive predictive value (PPV), a negative predictive value (NPV), sensitivity (SN), and specificity (SP). Third, a statistical correlation between the KCDC graph and the adult/pediatric graph was assessed using Pearson's correlation coefficients with 95% confidence intervals using Fisher transformation. For coding purposes, we labeled each week with a four-digit number, with the first two digits denoting the year and the last two denoting the week (eg, 1411 indicates the 11th week of 2014). Using this method, each season of the study period was defined as follows: spring (from 1408 to 1422, from 1510 to 1522, and from 1610 to 1614), summer (from 1423 to 1435, and from 1523 to 1535), fall (from 1436 to 1448, and from 1536 to 1548), and winter (from 1449 to 1509, and from 1549 to 1609). During the 108-week study period (from the 8th week of 2014 to the 14th week of 2016), a total of 6955 patients underwent RV Table 1 summarizes the characteristic features presented in Figure 2 . IFV was the virus most commonly detected in the adult patients, followed by RHV, RSV, and hMPV. RHV was the virus most commonly detected in the pediatric patients, followed by RSV, ADV, and PIV. RHV was the most common virus in the KCDC data, followed by IFV, PIV, and ADV. Of the three dataset, the mean weekly positivity rate was highest among pediatric patients for most of the RVs, with the exception of IFV, which was highest in the KCDC data (Table 1) . Regarding IFV, RSV, hMPV, and hCoV, the outbreaks represented in the three graphs were consistent with one another. However, in the graphs representing outbreak trends for RHV and ADV, the temporal trends were not as consistent across the datasets as they were for the other RVs ( Figure 2 ). The numbers of hBoV-positive and PIV-positive tests were very small among adult patients (Table 1 ) and positive cases occurred only sporadically ( Figure 2 ). Thus, for these two RVs, comparison among the three graphs was difficult. Table 2 presents the relationship between the KCDC graph and the adult or pediatric graph as well as the predictabilities of the KCDC data for the occurrence of an outbreak in the adult or pediatric data. A statistically significant correlation between the KCDC data and adult data was observed with respect to IFV, RSV, hMPV, and hCoV. For all eight RVs, the relationship between the KCDC data and the pediatric data was observed to be statistically significant. Predictabilities of the KCDC data for the occurrence of an outbreak in the adult data were the best for IFV. NPVs of the KCDC data for the occurrence of an outbreak in the adult data were generally high regarding the eight RVs (85-100%), whereas PPVs were high for such in the pediatric data (72.3-100%). Outbreaks of IFV, RSV, hMPV, and hCoV among the adult patients who underwent an RV PCR test for ARI at a tertiary care center in this study coincided with outbreaks observed in the KCDC data. For these four RVs, statistically significant correlations were also found between the KCDC data and the adult data. Our study results strongly support the clinical use of the national laboratory surveillance data during the outbreak of IFV, regarding that the correlation Table 1 ), a similar correlation would likely be observed for these two RVs. Furthermore, we should pay attention to the fact that the NPVs of the KCDC data for the occurrence of an outbreak in the adult data were high regarding all eight RVs. In other words, for each of the eight RVs, an occurrence of no outbreak in the KCDC data may be predictive of an occurrence of no outbreak of the respective RV among adult hospitalized patients. If one of these RVs was frequently detected in a hospital or any locale in a manner not consistent with its prevalence in the KCDC data, we might suspect that hospital or local RV outbreaks were ongoing separate from community outbreaks. All of these findings suggest that the KCDC data may be a helpful adjunct in uncovering outbreaks of RVs in adult hospitalized patients with ARI, especially in those clinical practices that currently do not perform RV PCR tests in ARI patients routinely. Importantly, prior to the clinical utilization of the national data, we should call to mention some characteristic features of the data. For example, the KCDC data include all age groups. Regarding the fact that RV PCR tests are usually more frequently performed in children than in adults and more frequently have positive results among children than among adults, it is well-understood that the values of the weekly positive rates in the KCDC data are mostly positioned between higher rates from the pediatric data and lower ones from the adult data (Table 1 ). In other words, the pediatric graph may be an inflated form of the KCDC graph, whereas the adult graph may represent a deflated form of the KCDC graph. This may be responsible for the fact that, with regard to the predictability of the KCDC data for the occurrence of an outbreak in the other two datasets, PPVs were high for the pediatric data and NPVs were high for the adult data, generally for all 8 RVs. Considering that RVs have some differences in their impacts on adults and children, we suggest that the KCDC data should be classified according to age group. This study has two important limitations. First, it did not provide important characteristics of the study patients such as types or severity of their illnesses, except for age and sex. Second, the KCDC data were compared to data from only one tertiary care center in Seoul. Comparisons of the KCDC data with data from other centers in various geographic regions may yield different results. In conclusion, national RV surveillance data may provide clinicians who manage adult patients with ARI with some assistance in predicting an RV outbreak among their patients. None to report. Seong-Ho Choi http://orcid.org/0000-0001-8108-2412 Viruses associated with pneumonia in adults Utilization of the respiratory virus multiplex reverse transcription-polymerase chain reaction test for adult patients at a Korean tertiary care center Community-acquired pneumonia requiring hospitalization among U.S. adults Lower respiratory tract virus findings in mechanically ventilated patients with severe community-acquired pneumonia Viral infection in patients with severe pneumonia requiring intensive care unit admission NPV, negative predictive value; PPV, positive predictive value; SN, sensitivity; SP, specificity. *P-value <0 Seasonal influenza in adults and children-diagnosis, treatment, chemoprophylaxis, and institutional outbreak management: clinical practice guidelines of the Infectious Diseases Society of America Korea influenza and respiratory surveillance report Usefulness of national respiratory virus surveillance data for clinicians who manage adult patients