key: cord-033952-b9fxqnni
authors: Lu, Deng-Hui; Jiang, Hong; Lian, Jian-Qi
title: Hantavirus Infection during Pregnancy
date: 2020-10-19
journal: Virol Sin
DOI: 10.1007/s12250-020-00300-8
sha: 
doc_id: 33952
cord_uid: b9fxqnni

Hantavirus infection is a global health challenge, causing widespread public concern. In recent years, cases of hantavirus infection in pregnant women have been reported in many countries. The infected pregnant women and their fetuses appear to have more severe clinical symptoms and worse clinical outcomes. Hence, to study the prevalence of hantavirus infection in pregnant women, this study will focus on the epidemiological distribution of the virus, different virus species penetrating the placental barrier, and factors affecting the incidence and clinical outcome of the infection in pregnant women and their fetuses. In addition, this review will also discuss the diagnostic tools and treatments for pregnant patients and provide an overview of the relevant future research.

Hantaviruses are negative-sense, single-stranded, enveloped RNA viruses belonging to the family Hantaviridae. Since the first hantavirus was isolated in 1978, many countries and regions have reported a series of hantavirus infections continuously . Hantaviruses cause two clinical syndromes in humans; designated hemorrhagic fever with renal syndrome (HFRS), and hantavirus cardiopulmonary syndrome (HPS). HFRS mostly occur in Eurasian countries, caused by Hantaan virus (HTNV), Seoul virus (SEOV), Puumala virus (PUUV) and Dobrava virus (DOBV) (Avsic-Zupanc et al. 2019) . The clinical features of HFRS are severe systemic manifestations, including fever, hemorrhage and acute renal failure. HPS is mainly a group of syndromes with respiratory system involvement, caused by Sin Nombre virus (SNV), Andes virus, and other viruses. The leading cause of death in HPS is acute progressive non-cardiogenic pulmonary edema and respiratory failure .

Hantaviruses are zoonotic viruses that can be carried by small rodents. Approximately 20,000 cases of hantavirusrelated diseases occur worldwide each year (Jiang et al. 2017) . Furthermore, there is a clear indication that the incidence rate increases every year (Jiang et al. 2017; Watson et al. 2014 ). The mortality rates reported are 12% for HFRS and 60% for HPS (Zhang et al. 2010; Jonsson et al. 2010) . Pregnant women are afflicted by inhalation of host secretions and excretions carrying the virus, or by exposure to rodent carriers (Pedrosa and Cardoso 2011) . However, the cases of women infected with hantavirus during pregnancy are rarely reported even in areas where hantaviruses are concentrated, which poses certain difficulties for subsequent research and clinical management. Here, in order to contribute to the diagnosis, treatment, and prognosis prediction, we reviewed past cases of hantavirus infections in pregnant women. the rodent host distribution, and it is influenced by factors such as the climate, environment, and food availability, which can make up a unique rodent host-hantavirus system. The rodent hosts of principal disease-causing hantaviruses are Apodemus agrarius (HTNV) in Asia, Myodes glareolus (PUUV) in Europe, and Peromyscus maniculatus (SNV) in the Americas (Watson et al. 2014; Kariwa et al. 2007; Vaheri et al. 2013 ).

Cases of pregnant women infected by HTNV and SEOV hantaviruses are more than that infected by other hantavirus species (Fig. 1, Table 1 ). This is related to the high incidence rate and large population in the areas where these two virus species are primarily distributed. China and South Korea are the top two hantavirus infection areas (Kariwa 2017) , and this is consistent with the distribution of their rodent hosts, which is also in line with the final findings of this review.

Hantavirus infection with different species during pregnancy also has different results for pregnant women. As observed from our statistical review, the mortality rate of pregnant women infected with HTNV/SEOV was 10.5% (27/256) (Table 1), and that of those infected with SNV was 25.0% (2/8) (Table 1) . From the data we collected, the mortality rate of pregnant women infected with HTNV was The sequelae mainly include menstrual disorders, amenorrhea, no milk secretion after delivery, sexual dysfunction, hair loss, autonomic dysfunction, and chronic renal insufficiency (Hofmann et al. 2012; Ji et al. 2017; Howard et al. 1999; Partanen et al. 1990; Silberberg et al. 1993; Prebensen 1997; Tiilikainen and Jouppila 1989; Jing and Jing 1994; Wang et al. 1992; Sha et al. 2000; Mace et al. 2013; Dai 2004; Liu et al. 2013; Georges et al. 2008; Schneider et al. 2009; Gilson et al. 1994; Murthy et al. 2016; Wang 2014; Zhang 1995; Duan et al. 1996; Kim and Choi 2006; Zheng 1985; Cui 2005; Liu et al. 2017; Todorovic et al. 2010; Chen 2008; Xie 1994; Hao 1997; Ying 1984; Gao 2013; Chen 1994; Lu et al. 2018; Li 2019; Ma et al. 2003; Latus et al. 2013 ).

not significantly different from that of the general population, while that of those infected with SNV was lower than that of the general population (Zhang et al. 2010; Jonsson et al. 2010) . We speculate that the sample size may primarily limit this. Moreover, after being infected by a hantavirus, the residual sequelae, which mainly consist of menstrual disorders, amenorrhea, no milk secretion after delivery, sexual dysfunction, hair loss, autonomic dysfunction and chronic renal insufficiency, were only seen with HTNV/SEOV infections (Table 1) . Furthermore, no deaths have been reported in pregnant women infected with PUUV or DOBV (Hofmann et al. 2012; Ji et al. 2017; Partanen et al. 1993 ). However, PUUV and DOBV cannot be ruled out due to the limited number of cases ( Table 1) . The clinical outcome for fetuses is also significantly different. Since the death of the mother causes the death of the fetus in most cases, this review will only discuss the cases where the mother survived the hantavirus infection. According to the available data, fetal deaths were only reported in HTNV/SEOV and SNV infections ( Table 2 ). The mortality rate of fetuses delivered by pregnant women with HTNV/SEOV infections was 31.8% (71/223) (Table 2), and that of those delivered by pregnant women with SNV was 33.3% (2/6) ( Table 2) . Also, several sequelae, including congenital heart disease, necrotizing enteritis, restricted growth and development, as well as hydrocephalus, troubled these babies ( Table 2 ). The incidence rate of sequelae in the babies, whose mothers had been infected with HTNV/SEOV and SNV was 3.6% (8/223) and 16.7% (1/6), respectively (Table 2) .

There were no reports of fetal malformations in pregnant women with a hantavirus infection, though many vertically transmitted viral infections are likely to cause fetal malformations (Seferovic et al. 2018; Silasi et al. 2015) .

Currently, there is no evidence that PUUV, DOBV and SNV can be transmitted through the placenta (Hofmann et al. 2012; Partanen et al. 1993; Howard et al. 1999) . Partanen et al. (1990) presented a case, where a 29 yearold woman at 17 weeks gestation had suffered from acute abdominal pain with high fever and myalgia. As a result, she had been diagnosed with PUUV infection. After treatment, the woman had recovered within 4 weeks and delivered a healthy boy naturally. Besides, the postoperative serological testing showed no evidence of placental transmission. However, few cases of fetal death caused by PUUV infection were also reported (Partanen et al. 1993; Silberberg et al. 1993; Prebensen 1997; Tiilikainen and Jouppila 1989) . Hofmann et al. (2012) conducted an immunological and molecular analysis of hantaviruses in the cord blood of four pregnant women, who had been infected with PUUV or DOBV. The results also showed no evidence of virus transmission through the placenta. Howard et al. (1999) reviewed five cases of HPS during pregnancy, and as expected, there was no evidence of vertical transmission, though SNV infections mostly had severe consequences, even death, in pregnant women and fetuses.

Therefore, it could be speculated that HTNV and SEOV pass through the placental barrier. Liu et al. (1987) suggested that there is a phenomenon of vertical transmission between the mother and the baby. Nonetheless, no evidence directly proves it. Lee (1989) detected the presence of IgM antibody against HTNV in the blood of fetuses, whose mothers had a HTNV infection, confirming the possibility of placental transmission. Kim et al. (1978) studied a pregnant woman, who had had a miscarriage due to hypotension after SEOV infection. After the autopsy of the fetus, researchers found bleeding throughout the body, including lungs, kidneys, and adrenal glands. This is in line with the symptoms of SEOV infection, but unfortunately, they did not perform further serological testing of the fetus The sequelae mainly include congenital heart disease, necrotizing enteritis, restricted growth and development, and hydrocephalus (Hofmann et al. 2012; Ji et al. 2017; Howard et al. 1999; Partanen et al. 1990; Silberberg et al. 1993; Prebensen 1997; Tiilikainen and Jouppila 1989; Jing and Jing 1994; Wang et al. 1992; Sha et al. 2000; Mace et al. 2013; Schneider et al. 2009; Gilson et al. 1994; Wang 2014; Zhang 1995; Duan et al. 1996; Kim and Choi 2006; Todorovic et al. 2010; Chen 2008; Xie 1994; Hao 1997; Ying 1984; Chen 1994; Lu et al. 2018; Li 2019; Ma et al. 2003; Latus et al. 2013 ). (Kim et al. 1978) . In addition Jing PT and Jing H (1994) , isolated hantaviruses from fetal brain tissues of an aborted fetus. Unexpectedly, the results indicated that hantaviruses could pass not only the placental barrier but also the bloodbrain barrier. However, it is a pity that the study failed to identify the species. Instead, it was based on the epidemiological analysis of the target area, which indicated that the virus was most likely SEOV. Most of the abortion and stillbirth cases in patients with HFRS occur when they have a fever, so further research is needed to clarify the specific mechanism (Chen 1994; Wang et al. 1992; Sha et al. 2000) .

The clinical outcomes of pregnant women with a hantavirus infection are also related to their age. The mortality rate of women aged 30 or older and infected with hantaviruses during pregnancy is 45.5% (5/11) (Table 3) , while for women under 30, it is only 2.5% (1/40) (Table 3) . Hjertqvist et al. (2010) found, in a study with 5,282 patients, that there is a significant correlation between mortality and the age of the hantavirus-infected patients. The mortality rates of pregnant women and others increase with age, and the trend remains consistent.

The incidence of hantavirus infection in pregnant women varies in different gestational periods. By reviewing the literature, we conducted a statistical analysis of the gestational age of women with a hantavirus infection during pregnancy. Among the reported cases of hantavirus-infected pregnant women, the incidence rate in the first trimester (\ 13 weeks) was 7.7% (4/52) ( Table 3 ), whereas that in the second trimester (C 13 weeks, \ 28 weeks) and the third trimester (C 28 weeks) was 92.3% (48/52) (Table 3) . Coincidentally, this phenomenon was also found in other placenta-transmissible viruses. Zhao (2017) conducted a controlled observation, including 288 cases of HPV-infected pregnant women at different stages of pregnancy, and found that the incidence of viral infection was the highest at the third stage. Moreover, having researched Epstein-Barr virus infection in pregnant women at different stages of pregnancy, Ming (2017) also reached the same conclusion.

Different mode of delivery may exert various influences on the transmission of the virus from mother to child. Lee (1989) detected hantaviruses in the serum of a vaginally delivered fetus. The fetus died within 12 h of delivery.

However, there were no similar cases reported in fetuses born via cesarean section.

Early diagnosis is vital for pregnant women with a hantavirus infection since it leads to early and more effective treatment, as well as a better clinical outcome. Accurate diagnosis usually relies on clinical manifestations and laboratory tests. Exploring the history of exposure in the epidemic area is also essential for a precise diagnosis. The typical clinical manifestations of HFRS are fever, hemorrhage, hyperemia, hypotensive shock and kidney damage accompanied by clinical symptoms, such as hematuria, proteinuria, and disseminated intravascular coagulation (DIC) (Lazzerini et al. 2017 ). Similar to the general population, the typical clinical course of HFRS in pregnant women is divided into the following: Fever period (3-7 days), hypotensive period (hours to 2 days), oliguria (3-7 days), polyuria (several days to weeks), and recovery period (2-3 months) (Vaheri et al. 2013; Latus et al. 2015; Connolly-Andersen et al. 2014) . The clinical symptoms of HPS include flu-like symptoms in the prodromal stage (5 days), subsequent acute respiratory distress syndrome (ARDS), bilateral diffuse interstitial pulmonary edema, respiratory failure, as well as non-cardiogenic shock (Duchin et al. 1994; Khan et al. 1996; Hallin et al. 1996; Macneil et al. 2011) . Molecular, immunochemical, and serological examination contribute to routine laboratory tests (Zou et al. 2016) . IgM/IgG antibodies against the Gn and Gc of hantaviruses are often used to aid the diagnosis (Hedman et al. 1991 ). However, early diagnosis is not that simple and straightforward, although diagnostic criteria are clear. Misdiagnosis often happens because of inexperienced nonspecialist clinicians, a limited number of cases, and atypical clinical manifestations. Misdiagnosis rate of pregnant patients with HFRS infection is as high as 50% according to several reports (Xia 2009; Yun 2007) . Patients with HFRS that have mild or atypical presentations are most likely to be misdiagnosed, especially in the early period (Xia 2009; Yun 2007) . Pregnant women with a hantavirus infection are often misdiagnosed with acute fatty liver of pregnancy (AFLP), hemolysis, and elevated liver enzymes and low platelets (HELLP), as they have similar clinical manifestations (Mace et al. 2013; Haram et al. 2009 ). Thus, accurate differential diagnosis is vital. A substantial reduction in non-selective proteinuria in a short period is conspicuous for HFRS, but rare for AFLP and HELLP (Clement et al. 2013) .

Currently, there is no safe and effective treatment for pregnant women with hemorrhagic fever. Recently, new Virologica Sinica (Chen 1994) . Furthermore, continuous renal replacement therapy (CRRT) plays a leading role, especially if hantavirus-infected pregnant patients display high blood volume and pulmonary edema (Ji et al. 2017) . Last but not the least, glucocorticoids have strong anti-inflammatory effects and are widely used in patients with stubborn and unresolved renal failure. However, the question that needs to be studied further is whether glucocorticoids can improve the health of the patients (Kruger et al. 2015; Martinuč Bergoč et al. 2013) . Sequelae: It refers to the remaining symptoms in pregnant women infected with hantavirus after their condition improves, which are mentioned in Tables 1 and 2. CS cesarean section, VD vaginal delivery.

In areas with high hantavirus prevalence, vaccination of women before pregnancy can effectively alleviate hantavirus infections (Dai 2004; Liu et al. 2013 ). However, for those who are already pregnant, the safety and effectiveness of vaccination have not been insightfully studied (Dai 2004; Liu et al. 2013) .

Although there are not many cases of hantavirus infection reported in pregnant women, even in the endemic areas, clinicians are expected to thoroughly consider severe consequences when they receive patients with similar symptoms. Specific immune status of pregnant women might increase their susceptibility to hantavirus infection. Pregnant women have unique immunology and physiology, and their immune system can develop a particular immunosuppressive state by suppressing cellular immunity to tolerate fetal antigens of paternal origin (Beigi 2017; Jamieson et al. 2006) . However, maintenance of this specific immune state during pregnancy has not been thoroughly explored. Gaunt and Ramin (2001) believe that this immunosuppressive state might be closely related to factors such as the absence of MHC-I antigens, the presence of unique HLA surface molecules, and nonspecific reduction of systemic immunoreactivity. Moreover, the blocking antibody, expressions of complement regulatory proteins, and reduced immunoreactivity might contribute to the formation of this unique immune state. These changes are likely to influence a systemic immune response to infections and lead to increased susceptibility to hantavirus infection.

After being infected with hantavirus, pregnant women and their fetuses seem to have worse clinical symptoms and outcomes (Sha et al. 2000; Liu et al. 2003) Nevertheless, currently, no theory can entirely explain the mechanism behind this phenomenon. In similar research of other viruses, this phenomenon is attributed to the unique immunological and physiological characteristics of pregnant women (Beigi 2017; Beigh 2012) . However, patients' immune response to a hantavirus infection, such as cytokine storms, is likely to harm the body (Schönrich et al. 2008) . Pregnant women are in a specific state of immunosuppression, and their immune damage is much smaller than that of other people, which is inconsistent with the findings of this literature review. Therefore, it can be speculated that the cause for this difference might come from two aspects. Primarily, pregnancy increases the organ burden of patients with a hantavirus infection, worsens the health, and increases the risk of death (Guimarães et al. 2019) . Additionally, the flow dynamics of patients might change during pregnancy. Consequently, the synthesis of clotting factors increases, and the placenta synthesizes a large number of thrombogenic substances (Avsic-Zupanc et al. 2019).

Early and timely diagnosis, comprehensive symptomatic treatment based on liquid therapy, and accurate judgments improve the patient's life (Dai 2004) . Moreover, the cooperation between emergency room physicians, infectious disease specialists, and obstetricians is also helpful for timely diagnosis and treatment. These measures are expected to improve the health of pregnant women and fetuses to a great extent.

Hantavirus infections

Influenza during pregnancy: a case of serious infection in obstetrics

Emerging infections and pregnancy

A case of pregnancy with epidemic hemorrhagic fever

Clinical analysis of 17 cases of epidemic hemorrhagic fever with pregnancy

A case of hantavirus pulmonary syndrome complicating pregnancy

Two cases of Korean hemorrhagic fever complicated with pregnancy

Letter to the editor: distinguishing between hantavirus-induced haemorrhagic fever with renal syndrome and pregnancy-induced liver pathologies (aflp and hellp syndromes)

Increased risk of acute myocardial infarction and stroke during hemorrhagic fever with renal syndrome: a self-controlled case series study

Nursing for pregnant women with epidemic hemorrhagic fever

A case of late pregnancy with epidemic hemorrhagic fever

Clinical and serological analysis of 48 patients with epidemic hemorrhagic fever during pregnancy

Hantavirus pulmonary syndrome: a clinical description of 17 patients with a newly recognized disease. The hantavirus study group

A case of pregnancy with epidemic hemorrhagic fever

Immunological tolerance of the human fetus

Nephropathia epidemica as the result of a Puumala virus infection in a pregnant patient

Hantavirus pulmonary syndrome complicating pregnancy

Heart disease and pregnancy: state of the art

Cardiopulmonary manifestations of hantavirus pulmonary syndrome

A case of severe epidemic hemorrhagic fever in pregnancy

The hellp syndrome: clinical issues and management

Hantavirus infections by Puumala or Dobrava-Belgrade virus in pregnant women

Hantavirus pulmonary syndrome in pregnancy

Rapid diagnosis of hantavirus disease with an IgG-avidity assay

Mortality rate patterns for hemorrhagic fever with renal syndrome caused by Puumala virus

Emerging infections and pregnancy

Hantavirus infection: a global zoonotic challenge

Hemorrhagic fever with renal syndrome caused by Hantaan virus infection in four pregnant Chinese women

Impact of pregnancy infection EHF virus on pregnant women, fetuses, newborns, infants

A global perspective on hantavirus ecology, epidemiology, and disease

Hantavirus infection in east Asia

Rodent associated hantaviruses and hantavirus infections

Hantavirus pulmonary syndrome: the first 100 us cases

A case of pregnancy complicated with Korean hemorrhagic fever

Hemorrhagic fever with renal syndrome complicated with pregnancy: a case report

A case of fetal death after maternal infection of Korean hemorrhagic fever

Hantaviruses-globally emerging pathogens

The case: fever, myalgia, visual disorders, and acute kidney failure in a pregnant woman. Diagnosis: severe acute hantavirus infection

Clinical course and long-term outcome of hantavirus-associated nephropathia epidemica

Clinical features, imaging characteristics, and long-term outcome of dogs with cranial meningocele or meningoencephalocele

Isolation of the etiologic agent of Korean hemorrhagic fever

Hemorrhagic fever with renal syndrome in Korea

A case of pregnancy with epidemic hemorrhagic fever

Intrauterine infection of epidemic hemorrhagic fever (ehf) via placenta

Epidemic hemorrhagic fever in pregnancy: a case report and literature review

Epidemic hemorrhagic fever complicated with late pregnancy: a case report

The 2263 cases of hemorrhagic fever with renal syndrome

Clinical analysis of 18 cases of hemorrhagic fever with renal syndrome during pregnancy

Hemorrhagic fever with renal syndrome presenting with intrauterine fetal death a case report

Severe Seoul hantavirus infection in a pregnant woman

Hantavirus pulmonary syndrome

Successful treatment of severe hantavirus nephritis with Virologica Sinica corticosteroids: a case report and literature review

Observation of EB virus infection and pregnancy outcome in pregnant women and newborns at different gestational weeks

Hantavirus pulmonary syndrome in a postpartum woman

The first established focus of hantavirus infection in Poland

A case of Korean hemorrhagic fever complicated with pregnancy

Infection with the Puumala virus in pregnancy. Case report

Lack of evidence of Puumala virus infection in patients with spontaneous abortion

Viral infections in workers in hospital and research biosafety aspects

Nephropathia epidemica infection during first trimester of pregnancy-normal fetal outcome

Spectrum of hantavirus infection: hemorrhagic fever with renal syndrome and hantavirus pulmonary syndrome

The first French hemorrhagic fever with renal syndrome in pregnant woman

Hantavirus-induced immunity in rodent reservoirs and humans

Experimental Zika virus infection in the pregnant common marmoset induces spontaneous fetal loss and neurodevelopmental abnormalities

Clinical analysis of 21 cases of hemorrhagic fever with pregnancy renal syndrome

Haemorrhagic fever with renal syndrome and pregnancy: a case report

Viral infections during pregnancy

Epidemic hemorrhagic fever during pregnancy

Hemorrhagic fever with renal syndrome during pregnancy: case report

Study on the influence of epidemic hemorrhagic fever on pregnancy outcome and childbirth

Epidemic hemorrhagic fever in pregnancy: report of 7 cases

Epidemiology of hantavirus infections in humans: a comprehensive, global overview

Hantavirus infections in Europe and their impact on public health

Discussion on emergency screening for hemorrhagic fever with renal syndrome

Two cases of pregnancy with epidemic hemorrhagic fever

Epidemic hemorrhagic fever and pregnancy (1 case of stillbirth with autopsy)

Analysis of 5 cases of atypical epidemic hemorrhagic fever

Pregnancy combined with epidemic hemorrhagic fever clinical features and treatment

Hantavirus infections in humans and animals

Human papillomavirus infection in pregnant women and its effect on maternal and infant outcomes

A case report of death from epidemic hemorrhagic fever in late pregnancy

Haemorrhagic fever with renal syndrome: literature review and distribution analysis in China

Acknowledgements We would like to thank Editage (www.editage. cn) for their assistance with English language editing and Jiamin Wang from Beijing Foreign Studies University, for improving the English writing. This work was supported by the National Scientific Research Program of China: New technology and project on intervention and elimination of cytokine storm and secondary infection in acute severe respiratory infectious diseases (2017ZX10204401-002-005).