Background
Severe fever with thrombocytopenia syndrome (SFTS) is a novel emerging infectious disease that was first discovered in rural areas of eastern and central China. In 2009, a novel bunyavirus was isolated from acute-phase patient serum samples and named as severe fever with thrombocytopenia syndrome virus (SFTSV), huaiyangshan virus (HYSV), or new bunyavirus (NBV) [
1‐
4]. It is now known as SFTSV. The disease has been reported in 23 Chinese provinces, more than 5000 cases were reported during 2009–2016, and Henan province had the highest case count, accounting for 45% of reported cases during 2011–2014 in China [
2,
5,
6]. SFTS patients have been found in Japan and Korea [
7,
8]. SFTSV is transmitted by tick bites, and human-to-human transmission has also been reported [
9‐
12]. A high case-fatality rate, ranging from 5 to 20%, has been reported for SFTSV-infected patients in the endemic areas [
13‐
15].
SFTS has been a serious public health concern; however, effective therapies or vaccines are not yet available, so understanding its features has important significance for the prevention and treatment of disease. In this article, we systemically searched and analysed the epidemiology, clinical signs, routine laboratory diagnosis, risk factors, and outcomes of SFTS.
Methods
Literature searching
We carefully performed a systematic search of the Chinese National Knowledge Infrastructure databases (CNKI), Wan Fang Data, PubMed, Embase, and Web of Science databases for all eligible papers (published from 2011 to 2018; English and Chinese publications) using the following search terms: “severe fever with thrombocytopenia syndrome” OR “SFTS” OR “SFTSV” OR “NBV”. We also manually included additional studies obtained from the references of the original articles and searches.
Inclusion and exclusion criteria
An initial screening of the titles and abstracts was performed by two authors independently. Thereafter, two independent authors screened the full texts of the selected articles. The inclusion criteria were as follows: the article had been accepted for publication; the study provided information on SFTS patients, or the SFTS patient mentioned in the selected studies was confirmed as meeting one or more of the following criteria: (1) the virus was isolated from the patient’s samples; (2) SFTSV RNA was detected in the patient’s serum; (3) a 4-fold or greater increase in antibody titers was detected between a paired patient serum samples collected from the acute and convalescent phases of infection.
The exclusion criteria included abstract-only articles, case reports (n < 5), letters, editorials, systematic reviews, duplicated publications, overlapping data sets (articles of the same region and year or articles containing another article were collected and carefully selected by two authors), in vitro studies, studies on animals, genotype analyses or treatments, and articles in which no data were extracted.
Data extraction and quality assessment
Data were independently extracted by two reviewers from the included articles. Disagreement was resolved through discussion or consensus. Subsequently, the following information was extracted from every eligible article: the first author; year of publication; region; year of admitted patients; the timing of the symptoms; number of patients; patient’s age; clinical information about SFTS patients, including symptoms (fever, myalgia, sputum, anorexia, abdominal pain, diarrhea vomiting, fatigue, gingival bleeding, headache, cough, nausea, petechiae and lymphadenopathy), routine laboratory parameters (lactic acid dehydrogenase (LDH), alanine aminotransferase (ALT), aspirate aminotransferase (AST), platelet count, albumin, creatine kinase (CK), creatinine, and white blood cell (WBC) count); interval between onset and admission; risk factors; outcomes; and the number of deaths. In addition, if there was no reliable data, we input “NA”, which means “not available”, during the extraction phases.
We evaluated the quality of primary studies using Study Quality Assessment Tools provided by the National Institute of Health [
16]. The criteria were divided into three grades: good, fair and poor. Based on the quality assessment for studies, we identified the articles’ quality ratings.
Statistical analysis
Means and standard deviation (SDs) were chosen to describe continuous variables with normal distributions. The medians and interquartile (IQ) ranges are shown for the interval between onset and admission, laboratory parameters and age. If the data showed medians and ranges or IQ ranges rather than the means and SDs, then the means and SDs were calculated as described by Hozo et al., Wan et al., and Luo et al. [
17‐
19]. Each study presenting the number of patients was included for calculation of the event rates and proportions with 95% confidence intervals (CIs) for clinical signs and outcomes. I-squared and Chi-square were chosen to reflect the heterogeneity among these studies [
20]. Heterogeneity was considered significant when
P < 0.05 and I
2 > 50%; then, a random effect model was applied. Otherwise, a fixed effect model was used. Furthermore, publication bias was assessed by visually using Begg’s funnel plot or Egger’s test [
21]. All of the statistical analyses were performed using Review Manager (RevMan version 5.3; Nordic Cochrane Centre, Copenhagen, Denmark) software and STATA software version 12.0 (STATA Corporation, College Station, Texas, USA).
Discussion
Our review identified a total of 4143 SFTS cases from 25 articles in SFTS- endemic regions including China, Korea and Japan. The main clinical and laboratory characteristics of SFTS were fever, gastrointestinal and neurological symptoms as well as thrombocytopenia and leukopenia. Fever was the most common symptom of SFTS patients, suggesting that it is an important indicator of the early stage of disease. The gastrointestinal and neurological symptoms included anorexia, nausea, vomiting, headache and other signs, but these symptoms were not very specific and were not associated with the progression of the disease; Further, some viral hemorrhagic fevers could cause these common symptoms, such as Rift Valley, Dengue fever and haemorrhagic fever with renal syndrome (HFRS) [
47‐
49]. The clinical signs of fatal and non-fatal SFTS patients were studied, and the results showed that diarrhea and vomiting on admission were associated with fatal outcomes. Diarrhea and vomiting were obvious symptoms for patients, and most patients had these clinical symptoms. Clinicians could take appropriate treatment measures quickly on admission. The clinical signs, such as diarrhea and vomiting, had no differences during hospitalization. The reason might be that patients with clinical symptoms would be treated in time during hospitalization, while most of the patients had clinical symptoms before admission, so the treatment was delayed and the condition aggravated. In the intensive care unit (ICU) or ward, clinicians should pay special attention to patients with diarrhea and vomiting and timely treatment to prevent the disease from aggravating. We extracted the numbers of positive symptoms and total cases on admission to calculate the pooled positive rates of clinical symptoms. Meta-analysis showed that most clinical signs had significant heterogeneity, and the random effect model was used. Subgroup analysis explored the source of heterogeneity, and the results suggested that different provinces had impacts on heterogeneity. China has a vast territory and the incidence of SFTS was widespread. Although we issued diagnostic guidelines [
50], there was a lack of diagnostic indicators and training work, suggesting that we must improve the unified criteria. According to the results, the pooled positive rates of clinical signs were observed to provide symptomatic diagnoses and treatment for SFTS patients.
The SFTS patients were classified into mild, severe or mild, common, severe and critical by clinical features and laboratory parameters in previous studies [
26,
51]. In our study, routine laboratory parameters of mild and severe cases were analysed. Compared to patients with mild symptoms, the LDH, ALT, AST, and CK levels of patients with severe symptoms were elevated, but albumin and platelet levels were reduced. Leukocytopenia was an important characteristic for SFTS. Data for WBC counts were extracted and analysed, but the scarceness of the literature resulted in no differences between the patients with severe and mild symptoms. Because fever, fatigue, nausea, anorexia, and myalgia were the most frequent symptoms, they could represent the majority of patient conditions. Laboratory parameters and clinical symptoms could serve as references for disease classification and suspected patients.
The risk factors of SFTS patients were evaluated, including the risk factors of poor prognosis and the risk factor of contracting SFTS. Age was an important factor associated with SFTS disease and was a critical risk factor or determinant of morbidity and mortality in SFTS. Farmers accounted for the overwhelming majority of SFTS cases, and farming was a risk factors for SFTS. The transmission of SFTS occurs via tick bites, farmers often work in fields; thus, it is possible that the probability of tick bites was greatly increased for farmers. Further analysis indicated that the occurrence of SFTS was related to tick bites but there was no association between tick bites and fatal outcomes. The reason for the strong heterogeneity might be that the distribution of ticks was different country to country. The six studies originated from 3 countries, including Japan (1 study), Korea (2 studies), and China (3 studies). Tick bites were a risk factor for the occurrence of SFTS, but the deaths of the patients were related to personal conditions and the severity of the disease.
The case-fatality rate of SFTS has varied widely among endemic areas. The case fatality rates in Japan and Korea were apparently higher than that in China [
14,
15,
33]. The reasons for this discrepancy might include different notification systems and monitoring durations among the three countries, but the high case fatality from Japan or Korea, the most severe cases reported, just as China at an early stage of SFTS outbreak. We conducted subgroup analysis by region in the three countries. The significant heterogeneity derived from Korea. Because too little literature regarding Korea was included, we could not perform further analysis.
Compared to the previous articles, our meta-analysis had two different levels [
52‐
54]. We summarized the distribution of clinical symptoms, and it was important to distinguish whether the clinical symptoms of each report occurred at the time of hospital visits, at the time of hospitalization or during hospitalization. Fatal and non-fatal patients on clinical symptoms and risk factors, and patients with severe and mild symptoms on routine laboratory parameters, were analysed; thus, we could draw more comprehensive conclusions.
This meta-analysis had some limitations. First, significant heterogeneity brought into question the suitability of performing this meta-analysis, however, the sensitivity analysis showed that the pooled rates were stable and no publication bias was found in our meta-analysis. Second, we could not analyse some indicators in these studies due to lacking data for clinical signs of patients with severe and mild symptoms. Third, the quality of the primary studies might have an impact on the results.
Conclusions
In conclusion, China was the country with the highest incidence of SFTS. May to July was peak of the epidemic, and farmers were a high-risk group. The risk factor of SFTS included age (poor prognosis) and tick bites (contracting SFTS). Patients with diarrhea and vomiting symptoms on admission should be noted to prevent the disease from aggravating. Clinicians could use the routine laboratory parameters (AST, ALT, LDH, CK, albumin, platelet count) and clinical symptoms (fever, fatigue, nausea, anorexia, myalgia) as references for clinically suspected cases, classification of SFTS and timely treatment, especially in basic hospitals. In addition, epidemiological (population distribution, regional distribution, and time distribution) and clinical characteristics should be combined and then developed public-health interventions for the control and prevention of SFTS.
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