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REVIEW ARTICLE
Year : 2019  |  Volume : 149  |  Issue : 4  |  Page : 447-467

Emerging/re-emerging viral diseases & new viruses on the Indian horizon


1 ICMR-National Institute of Virology, Pune, India
2 Maximum Containment Laboratory, Pune, India
3 Influenza Department, Pune, India
4 Division of Epidemiology and Communicable Diseases, Indian Council of Medical Research, New Delhi, India
5 National Center for Disease Control, New Delhi, India

Date of Submission04-Jul-2018
Date of Web Publication16-Jul-2019

Correspondence Address:
Dr Devendra T Mourya
ICMR-National Institute of Virology, 20-A, Dr. Ambedkar Road, Pune 411 001, Maharashtra
India
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Source of Support: None, Conflict of Interest: None


DOI: 10.4103/ijmr.IJMR_1239_18

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   Abstract 

Infectious diseases remain as the major causes of human and animal morbidity and mortality leading to significant healthcare expenditure in India. The country has experienced the outbreaks and epidemics of many infectious diseases. However, enormous successes have been obtained against the control of major epidemic diseases, such as malaria, plague, leprosy and cholera, in the past. The country's vast terrains of extreme geo-climatic differences and uneven population distribution present unique patterns of distribution of viral diseases. Dynamic interplays of biological, socio-cultural and ecological factors, together with novel aspects of human-animal interphase, pose additional challenges with respect to the emergence of infectious diseases. The important challenges faced in the control and prevention of emerging and re-emerging infectious diseases range from understanding the impact of factors that are necessary for the emergence, to development of strengthened surveillance systems that can mitigate human suffering and death. In this article, the major emerging and re-emerging viral infections of public health importance have been reviewed that have already been included in the Integrated Disease Surveillance Programme.

Keywords: Avian influenza - CCHF - emerging - India - Nipah virus - re-emerging - respiratory viral infections - rotavirus - viral diseases


How to cite this article:
Mourya DT, Yadav PD, Ullas P T, Bhardwaj SD, Sahay RR, Chadha MS, Shete AM, Jadhav S, Gupta N, Gangakhedkar RR, Khasnobis P, Singh SK. Emerging/re-emerging viral diseases & new viruses on the Indian horizon. Indian J Med Res 2019;149:447-67

How to cite this URL:
Mourya DT, Yadav PD, Ullas P T, Bhardwaj SD, Sahay RR, Chadha MS, Shete AM, Jadhav S, Gupta N, Gangakhedkar RR, Khasnobis P, Singh SK. Emerging/re-emerging viral diseases & new viruses on the Indian horizon. Indian J Med Res [serial online] 2019 [cited 2019 Dec 7];149:447-67. Available from: http://www.ijmr.org.in/text.asp?2019/149/4/447/262871


   Introduction Top


The emergence of novel human pathogens and re-emergence of several diseases are of particular concerns in the current decade. At a basic level, emerging infections can be defined as those diseases whose incidence has been found to be increased within recent decades or which have threatened to increase in the future. Such emergences are often detection/spread of pathogen in newer areas, recognition of the presence of diseases that have been present in a population albeit as undetected entities, or due to the realization of an infectious aetiology in already established diseases [1]. Several factors underlie the emergence of such diseases, including increasing population, poverty and malnutrition, increased domestic and global connectivity, economic factors leading to population migration, social practices, prevalence of immunosuppressive diseases, unplanned urbanization, deforestation and change in agricultural practices such as mixed farming [2]. Genetic alterations in pathogens have also been responsible for such outbreaks, to a significant extent [3].

Estimates indicate that about 60 per cent of infectious diseases and 70 per cent of emerging infections of humans are zoonotic in origin, with two-thirds originating in wildlife [4]. Habitat destruction due to unplanned urbanization has placed humans at increasing contact with animal and arthropod vectors of viral infections. Such interactions have been one of the major causes for increased human susceptibility to infections by novel pathogens, in the absence of specific immunity in these populations.

Respiratory viral infections, arboviral infections and bat-borne viral infections represent three major categories of emerging viral infections in India. Infectious aerosols of the tracheobronchial tree represent efficient means for spread of viral pathogens affecting the respiratory tract. Pandemic influenza H1N1pdm09, highly pathogenic avian influenza (AI) infection (H5N1) and the Middle East respiratory syndrome coronaviruses (MERS-CoV) represent three pathogens posing severe threat in this category [5],[6]. Arthropod-borne viruses have consistently been the reason of emerging and re-emerging diseases in the Indian subcontinent, including Crimean-Congo haemorrhagic fever (CCHF), dengue, chikungunya, Japanese encephalitis and Kyasanur forest disease (KFD). The major arboviral pathogens of humans belong to the three genera of Flavivirus, Alphavirus and Nairovirus. Several bat-borne viruses have also come into prominent notice, best exemplified by Nipah viral disease, severe fever with thrombocytopenia virus (SFTV), as well as Ebola viral disease.

A consistent theme in the infectious disease landscape of the country has been the periods of quiescence of several pathogens following their initial discovery, only to be followed by their reappearance, often in more virulent forms. This is best exemplified by arboviral infections such as chikungunya and Zika. Several parts of the country have witnessed the re-emergence of chikungunya, an arboviral illness characterized by debilitating and prolonged arthralgia, since 2006[7]. Following the initial outbreaks during 1963 and 1973, the illness showed a long period of quiescence before making a re-appearance [8]. In contrast to the early outbreaks which were caused by Asian strains of the virus, the East African strains of chikungunya virus were responsible for the explosive outbreaks of chikungunya during 2006[7]. Most parts of the country abound with substantial populations of Aedes aegypti mosquitoes, which are competent vectors for dengue, chikungunya and Zika viruses, which remain as global threats [9],[10]. Although serological studies conducted in the 1960s showed the circulation of Zika virus in the country [11], a detailed understanding of the disease burden and its impact did not come forth till the explosive outbreaks began in Brazil in 2015[11]. Four cases of Zika viral infection were subsequently identified and reported from India (3 from Gujarat and 1 from Tamil Nadu), and no Zika-associated microcephaly cases have been identified in the country, till date (NIV, unpublished data).

There have also been cases of discovery of novel pathogens in the country. The examples include Chandipura virus (CHPV), CCHF virus and KFD virus (KFDV). These viruses were identified during the 1950s-1960s [12],[13],[14], but their pathogenic and public health significance remained unexplored for a long time. Several of these infections take a heavy toll on the animal husbandry and agricultural industry. The economic costs associated with such infections can be heavy as can be inferred from the high costs of medical and intensive care, days of productive work lost, impact on travel and tourism, ban on export of agricultural produce from affected regions, etc. The psychological impact of such outbreaks and their sequelae has also not been systematically evaluated in the country.

The Department of Health Research (DHR), Ministry of Health & Family Welfare, Government of India, made a vision in 2013 to establish and strengthen the network of laboratories across the country to create infrastructure for timely identification of viruses causing outbreaks or related to significant morbidity/mortality which are important at public health level. This network of Virus Research and Diagnostic Laboratory (VRDLN) is also intended to provide virological diagnosis to patients attending tertiary health facilities (medical colleges) and thereby help in generating surveillance data on common viral diseases from different parts of the country. The detailed list of VRDLN currently functional in India is available (http://112.133.207.124:82/vdln/vdls.php).

The situation of emerging public health infections in India was last reviewed by Dikid et al[1] in 2013. However, the country has witnessed many notable changes with regard to infectious diseases in the past 4-5 years, prompting a re-look into the scenario. The present review attempts to provide an updated review on the topic.


   Emerging Viral Infections Identified as Public Health Threats Top


Viral pathogens are known to cause outbreaks that have epidemic and pandemic potential. The Integrated Disease Surveillance Programme (IDSP) is a laboratory-based, IT-enabled system in the country for surveillance of epidemic-prone diseases [15]. During 2017, the IDSP network reported a total of 1683 outbreaks of such diseases. The analysis of data showed that 71 per cent of these outbreaks were caused by viral pathogens, while 29 per cent were due to non-viral pathogens. Nearly 72,000 individuals were affected in these outbreaks, and amongst them, 60 per cent had a viral aetiology. Data also revealed that febrile rash syndromes (including measles, rubella and chickenpox) contributed 30 per cent of the outbreaks, while gastroenteritis and arboviral diseases contributed 20 and 17 per cent, respectively [15] [Figure 1].
Figure 1: Disease-wise reported outbreaks in India. CCHF, Crimean-Congo hemorrhagic fever; KFD. Kyasanur forest disease; ARI, acute respiratory infection; JE, Japanese encephalitis; WN, West Nile; DHF, dengue hemorrhagic fever; DSS, Dengue Shock syndrome. Source: Ref. 15.

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Majority of the reported outbreaks occurred in the Western part of the country [Figure 2][15]. It is likely that the reported outbreaks represent only a part of the actual disease burden and only the symptomatic and/or geographically clustered cases identified by the health facility would have been covered in the reports. Subclinical and sporadic infections, as well as those not identified by the health facility, are often missed by the surveillance systems. The proportion of reported outbreaks is directly related to the public health infrastructure and surveillance network, with outbreak alerts originating most efficiently from those States with well-functioning public health infrastructure and disease surveillance systems.
Figure 2: Distribution of State and district-wise outbreaks of public health priority viral diseases. Abbreviations are as given in Fig. 1. Source: Ref. 15.

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The National Vector Borne Disease Control Programme (NVBDCP) undertakes the surveillance for the vector-borne diseases in the country. This Programme focusses on the prevention and control of diseases, which include malaria, dengue, chikungunya, Japanese encephalitis, kala-azar as well as lymphatic filariasis. The epidemiology of these diseases is known to vary with ecology, vector bionomics, as well as economic, socio-cultural and behavioural factors. Regular monitoring and evaluation would be critical to the overall success of the Programme. Arboviral infections, including dengue and chikungunya, have shown an upsurge in recent years, particularly in the urban community of the country [16]. Climatological factors and favourable environment conferring longevity of the vector mosquitoes, especially of Aedes species, are thought to underlie this. Concerted efforts toward the control of vectors, including mosquitoes with the help of community participation and by enhancing the community awareness, would be critical to curtail the disease transmission.


   Impact of Mass Gatherings and Emerging Viral Infections Top


The World Health Organization (WHO) defines mass gatherings as occasions, which are organized or are spontaneous, that pulls large numbers of pool of people for straining the planning as well as response resources in the community, city or nation hosting that particular event. In addition to religious congregations, these events may be held in the sports, socio-cultural or political contexts [17]. The religious Kumbh Mela, held every 12 years in Uttar Pradesh in India, is considered as one of the biggest human mass gatherings on earth [18]. The other examples of religious mass gatherings in India include the Maha Pushkaram festival in Andhra Pradesh (last held in 2015 and attended by 48.1 million people in Andhra Pradesh and 57 million people in Telangana), annual pilgrimage to Sabarimala temple in Pathanamthitta district of Kerala (attended by 45-50 million devotees every year) and Velankanni, the biggest Catholic pilgrimage centre in India (visited by around 3 million people from late August to early September), Mahamaham in Kumbakonam in Tamil Nadu (last held on February 22, 2016, attended by one million people)[19]. Similar events of other religious denominations attended by comparatively lesser numbers of pilgrims are also observed in India with fervor. Such opportunities create situations for human proximity within very close distances and the challenges they present to the maintenance of sanitation. These gatherings create considerable public health concern. Transmission of respiratory and gastrointestinal infections remains major concerns during such large-scale assemblies. The outbreaks of infectious diseases have occurred during several of these events, best exemplified by the outbreak of cholera at the Kumbh Mela festival in 1817, which spawned the Asiatic cholera pandemic (1817-1824) through the returned, infected pilgrims [20]. These assume additional importance in the wake of the emerging and re-emerging infectious diseases, including that due to viruses. Large numbers of Muslim followers return from the Hajj and Umrah pilgrimage every year, there have been concerns that they might acquire infections with MERS-CoV during the event and subsequently lead to its introduction in India. However, no case of MERS-CoV infection has been detected in the country so far though reports have indicated the spread of influenza through infected, returning pilgrims [21]. It would seem likely that these large-scale gatherings may provide platforms for exchange of genomic material and thereby evolution of pathogens, including viruses.


   Nosocomial Transmission and Emerging Infections Top


Institutionalized care of vulnerable people with compromised immune systems (e.g. those receiving cancer chemotherapy or undergone the procedure of transplantation either of solid organ or hematopoietic stem cell, diabetics, elderly, pregnant women and pre-term babies) may present opportunities for transmission of viral infections. Use/sharing of contaminated instruments for injections and practices such as body piercing, tattooing and acupuncture may result in heightened risk for transmission of infections, including hepatitis-C virus (HCV), hepatitis-B virus (HBV) and human immunodeficiency virus (HIV). Appreciable risks also exist at dental clinics, haemodialysis units, etc. where sterilization/disinfection practices for patient care instruments are not followed stringently. Healthcare staff faces a real risk for the acquisition of several viral infections, including HBV, HCV, HIV, rubella, viral haemorrhagic fevers (CCHF), encephalitic infections such as rabies and Nipah. Hospital-associated transmission of infection was a prominent finding during the outbreaks of Nipah infection in West Bengal [22] and Kerala States, in which several healthcare staff fell victims to the infection. The details of emerging/re-emerging viral infections in India and new viruses are provided in [Table 1].
Table 1: Emerging/re-emerging viral infections in India and new viruses

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   Laboratory Accidents/lapses in Biosafety Practices Top


Neglect of laboratory biosafety requirements as well as laboratory accidents may also lead to the occurrences of emerging/re-emerging infections. Recently, there was a report on the development of buffalopox (BPX) lesions on the palm of a biomedical researcher following a shrapnel injury, warranting surgical treatment and leading to delayed healing [56]. Such reports, though infrequent, emphasize the need for stringent adherence to biosafety guidelines to be observed in research involving viral agents with human pathogenic potential.

Some viral pathogens that have gained particular attention in recent years are discussed below:

(i) Enteroviruses (EVs): The EVs are small, non-enveloped, positive-stranded RNA viruses of the family Picornaviridae, which remain as the neglected and re-emerging viral pathogens in our country. Originally classified into four groups based on pathogenetic properties (Coxsackie A viruses, Coxsackie B viruses, polioviruses and echoviruses), these are more accurately classified by molecular typing employing nucleotide sequencing of the VP1 region of their genome [21]. More than 300 EV types have been described [57]. The disease spectrum associated with these includes acute flaccid paralysis, meningitis, encephalitis, myocarditis, acute haemorrhagic conjunctivitis, myocarditis, pericarditis, type 1 diabetes mellitus, myositis, respiratory tract infections and exanthems such as the hand, foot and mouth disease (HFMD)[24]. Overlapping clinical presentations of enteroviral infections makes it difficult to arrive at an aetiological diagnosis without laboratory confirmation. Rao [24] reported a positivity of 35 per cent for non-polio EV (NPEV) infections amongst children with non-polio acute flaccid paralysis, with 66 serotypes of EVs detected in them. The author also observed that NPEVs, just like rotaviruses, had a significant association with diarrhoea. EVs have also been reported as aetiological agents of acute encephalitis in Uttar Pradesh [23],[58] and Karnataka States [59]. The infrequent reports of their detection in clinical cases may reflect a lower prevalence or more probably the inadequacy of the existing surveillance systems in the country. There have been reports of outbreaks of HFMD from several parts of the country [60]. Coxsackievirus A16 (CV-A16) and CV-A6 have been major and CV-A10, EV-A71 and E-9, infrequent causes of these outbreaks in the southern and eastern parts of India [61]. Saxena et al[62] reported the circulation of three genotypes of EV-A71 in India and also identified as a new genogroup (G) of the same. The authors observed that the genogroups D and G circulate widely in the country, while the sub-genogroup C1 was restricted to one focus in Western India. EV-A71 association has also been reported in cases of acute flaccid paralysis from Uttar Pradesh, Karnataka and Kerala [25],[26]. The exact disease burden associated with EV-A71 infections in India needs detailed investigations

A(ii) Reoviruses: Reoviridae includes viruses possessing linear double-stranded RNA genomes. Viruses of four genera, viz. Orbivirus, Rotavirus, Orthoreovirus and Coltivirus, affect animals and humans. Orbiviruses are known to infect humans, ruminants, horses, rodents, bats, marsupials, sloths and birds. These are transmitted by vectors which are included in Culicoides midges, mosquitoes, black flies, sand flies and ticks. Orbiviruses are widely distributed and contain 21 recognized species within multiple serotypes [63].

(iii) Herpesviruses including Varicella-Zoster virus (VZV): Herpesviruses are the important aetiological agents of vesicular exanthems and central nervous system (CNS) infections. Herpes simplex virus type 1 (HSV-1) is known to cause vesicular ulcerative lesions in the oral cavity and can also infect the genitalia, liver, lungs, eyes and CNS. A recent report indicated that HSV-1 was a significant pathogen in paediatric cases of acute viral encephalitis [64]. HSV-2 causes painful genital ulcers and high morbidity and mortality in neonates acquiring it from infected mothers [65]. VZV, one of the herpes viruses, is the causative agent for varicella (chickenpox), an acute febrile illness (AFI) with diffuse maculopapular vesicular rash and herpes zoster (shingles). Estimates indicate that more than 30 per cent of people over the age of 15 yr in India are susceptible to VZV [27]. Varicella seroprevalence was 16 per cent in children aged 1-4 yr, 54 per cent in those between the ages of 5 and 14 yr and 72 per cent amongst those aged 15-25 yr [66]. Varicella occurs in endemic and epidemic forms in the country and carries secondary attack rates of >85 per cent in the exposed individuals [67]. Conditions of overcrowding and low immunization coverage make ideal grounds for outbreaks of varicella. In southern India, varicella shows a seasonal peak from January to April [68]. After the recovery from chickenpox infection, the virus remains dormant and reactivation of the virus leads to shingles. It is mostly seen in immunocompromised person and is not transmitted from human to human [67].


   Current Scenario of Emerging Viral Infections Top


Respiratory viral infections

Acute respiratory diseases claim over four million deaths every year and cause millions of hospitalization in developing countries every year [69]. Over 200 viral pathogens, belonging to the families Orthomyxoviridae, Paramyxoviridae, Picornaviridae, Coronaviridae, Adenoviridae and Herpesviridae, cause respiratory infections in humans. Influenza, parainfluenza, respiratory syncytial virus (RSV) and adenoviruses remain important respiratory pathogens. Human metapneumovirus has also been recognized worldwide as a pathogen of significance [70].

(i) Influenza: Influenza viruses, belonging to Orthomyxoviridae family, are the frequent causes of epidemics and pandemics affecting humans. Influenza pandemics have occurred earlier in 1918 (Swine influenza), 1957 (Asian flu), 1968 (Hong Kong flu), 1977 (Russian flu) and the recent pandemic of 2009 (pandemic influenza A H1N1)[71]. Influenza virus type A is highly variable, shows continuous antigenic variation and is a major cause of epidemics and pandemics. The surface antigenic glycoproteins undergo two major types of antigenic variation, viz. antigenic shift and antigenic drift. Antigenic shift is the result of major changes in one or both the surface antigens [haemagglutinin (HA) and neuraminidase (NA)] and causes occasional pandemics. Three mechanisms might be operative in the antigenic shift, leading to emergence of pandemic influenza strains, viz. genetic re-assortment, direct transfer from avian/mammalian host to humans and virus recycling. Antigenic drift results due to minor changes in HA or NA and causes frequent epidemics [72]. Influenza viruses are continuously evolving and show ubiquitous distribution in the environment, animals and humans.

(ii) Severe acute respiratory syndrome-associated coronavirus (SARS-CoV): SARS was first reported in the Guangdong province of China in February 2003 showing human-to-human transmission. The disease caused an estimated 8000 cases and more than 750 deaths in more than 12 countries [73]. The WHO issued a global alert about the disease on March 13, 2003[74]. Although the cases mostly remained confined to China, a few cases were reported from North and South America, Europe and Asia. No case, however, has been reported fromIndia.

(iii) MERS-CoV: MERS-CoV is a zoonotic viral illness causing respiratory infection which was first reported in Saudi Arabia in 2012 and has since spread to 26 different countries. Over 2207 laboratory-confirmed cases and 787 deaths have occurred due to MERS-CoV infection globally, since 2012[75]. The clinical spectrum of illness associated with MERS-CoV ranges from asymptomatic infections to acute respiratory distress syndrome, resulting in multi-organ failure and death. The case-fatality rates (CFRs) have remained high at 3-4 per 10 cases [76]. Limited information currently exists about the transmission dynamics of this virus, and definitive treatment and a prophylactic vaccination remain unavailable till date. Evidence for secondary, tertiary and quaternary cases of MERS ensuing from a single infected patient also exists, even in the absence of mutations conferring hyper-virulence [77]. No case of infection with this virus has been detected in India so far. Bats are thought to be the natural reservoirs of this virus, and many patients developed the illness after contact with camels. India is home to a great diversity of bat species and has substantial camel population. The country also reports heavy passenger traffic from the Middle East, as part of pilgrimage, employment, tourism and trade. These facts call for preparedness and surveillance against this virus in the country.

(iv) Avian influenza (AI): Humans are susceptible to infection with AI and swine influenza viruses, including the AI virus subtypes - A(H5N1), A(H7N9) and A(H9N2). Exposure to infected birds or contaminated environment is thought to underlie human infection with these viruses [78]. Human cases of AI might occur in future, in view of the ongoing circulation of AI viruses in birds. There have been sporadic reports of human infections with AI and other zoonotic influenza viruses, but sustained human-to-human infection and transmission have been lacking. Although the public health risk from the currently known influenza viruses at the human-animal interface remains the same, the sustained human-to-human transmission of this virus is low.

(v) RSV: RSV is an important pathogen causing acute lower respiratory tract infection (ALRTI) in young children. It can also affect older adults and immunocompromised individuals [79]. Estimates indicate an annual incidence of approximately 34 million episodes of ALRTI associated with RSV infection in children aged five years or less [80]. RSV infections also lead to about three million cases of hospitalization and about 66,000-199,000 deaths, with more than 99 per cent of the deaths reported from developing country [80]. In view of the public health significance, the WHO has started a pilot project for RSV surveillance in its six regions, utilizing the well-established platform of Global Influenza Surveillance and Response Network [81]. The exact burden and impact of RSV infections in the country need to be studied in depth.

Viral haemorrhagic fevers

(i) CCHF: CCHF was first recognized in 1944 from the West Crimean region, former Soviet Union as a huge outbreak, and the virus was subsequently isolated in 1956 from a human CCHF-positive case [82]. CCHF virus belongs to the genus Orthonairovirus of the family Nairoviridae. This virus had been detected from almost 30 countries in Africa, South-Eastern Europe, the Middle East and Western Asia. The CCHF viruses clustering is seen in 6-7 different groups (Group I - West African strains; Group II - Central African strains; Group III - South Africa and West Africa, Group IV - the Middle East and Asian strains; Group V - European strains; Group VI - Greek strains). Group IV involves Asia 1 and Asia 2 subgroups [83]. Phylogenetic analysis based on the S gene segment of CCHF virus had shown that the Indian CCHF virus strains formed a distinct cluster in the Asian-Middle East group IV [84]. Humans are normally infected by bites from ticks or close contacts with bodily fluids of acute viraemic CCHF-positive cases (showing potential for human to human transmission) and also from blood or tissue from viraemic livestock during handling or slaughtering. The high-risk groups are those who either get exposed to ticks (e.g. farmers, shepherds and veterinarians) and persons (mainly healthcare workers/family members) who come in close contact with the CCHF patients [85].

Since its first detection in the country in 2011[86], many nosocomial and sporadic outbreaks of CCHF have been investigated in Gujarat and the adjoining Rajasthan State [28],[87]. A nation-wide survey by the ICMR-National Institute of Virology (ICMR-NIV), Pune, revealed wide seropositivity amongst sheep, goat and cattle population across the country [88]. Since 2011 till December 2018, almost 81 cases have been diagnosed positive for CCHF (NIV, unpublished data).

The clinical manifestations typically develop after incubation period of 1-3 (maximum 9) days after exposure to tick bite; while in infections acquired through direct contact with viraemic livestock or CCHF-positive patients, it may extend to 5-6 (maximum 13) days. The clinical features include abrupt onset of high-grade fever, severe headache, malaise, nausea, vomiting, diarrhoea and sore throat. The disease typically progresses through the stages of incubation period, pre-haemorrhagic, haemorrhagic period and then convalescence [89]. Molecular assays such as conventional reverse-transcription polymerase chain reaction (RT-PCR) and qualitative real-time RT-PCR (qRT-PCR) have been used to detect CCHF RNA and for laboratory diagnosis. Several serological tests including enzyme-linked immunosorbent assay (ELISA) have also been developed to detect CCHF-specific IgM and IgG antibodies. The isolation and propagation of CCHF virus require a high-containment [biosafety level (BSL)-4] laboratory. No specific treatment is available for CCHF disease and treatment includes supportive medications and maintenance of fluid-electrolyte balance, timely monitoring and replacement of platelets in case of severe thrombocytopenia along with administration of fresh-frozen plasma and erythrocyte preparations to maintain the blood volume in case of circulatory failure. The antiviral drug ribavirin has shown promise in some studies [89]; however, its use remains controversial. The WHO has recently declared CCHF as the highest priority disease globally, needing urgent research and development [90]. Serious alertness and cohesive work under the 'One Health Programme' is required to cope up with the threat of this dreadful zoonotic disease.

(ii) KFDV: The KFDV belongs to genus Flavivirus and family Flaviviridae. The virus was identified for the first time in 1957, during investigations of a febrile illness affecting monkeys (including the species Semnopithecus entellus and Macaca radiata) and also humans [14]. KFDV is usually maintained in nature by enzootic cycles which occur between small mammals and ticks. Monkeys acquire the infection through bites of infected Haemaphysalis spinigera ticks, develop disease and pass on the infection to ticks that feed on them subsequently. In monkeys, the illness manifests as a severe febrile illness. Ticks dropping off from the bodies of monkeys that die of the illness create hotspots of infection which further spread the virus. Since 1957, the disease has occurred in sporadic and epidemic form in many parts of Karnataka State in India. However, since 2012, KFD infections (involving monkeys and humans) have also been reported from States of Kerala, Tamil Nadu, Goa and Maharashtra [29]. With widespread distribution across the Western Ghats, KFDV has emerged as an important disease of public health importance in the past few years [91],[92] [Figure 3]. After an incubation period of 3-8 days following the tick bite, the illness manifests with high-grade fever with or without chills, frontal headache and body ache, lasting for 5-12 days. The CFR is generally around 3-5 per cent and the convalescence is often prolonged. In some infected individuals, the illness is biphasic, starting after a febrile period of 1-2 wk. The fever mostly lasts from 2 to 12 days and is mainly started with headache and CNS manifestations are usually apparent. Neck stiffness, psychological disturbances, coarse tremors, giddiness and abnormalities in reflexes are often noted.
Figure 3: Kyasanur forest disease positivity in human, ticks and monkeys recorded in different States of India during recent past. Source: Ref. 92.

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Laboratory diagnosis generally relies on the detection of KFDV RNA in serum/blood samples by conventional RT-PCR or qRT-PCR. ELISA tests are also used to diagnose KFDV-specific IgM and IgG antibodies. Isolation and propagation of KFDV require a BSL-4 laboratory. A formalin-inactivated, chick embryo fibroblast-derived KFD vaccine is currently employed for prophylaxis in the affected areas. The vaccine was found to be immunogenic, safe and potent. However, no specific treatment is available for KFD till date and management is mostly supportive [93].

(iii) Rift valley fever (RVF) virus: RVF belongs to genus Phlebovirus. First time, this virus was identified in 1931 during an investigation of an epidemic amongst the sheep farm in the Rift Valley of Kenya [94]. Since then, many outbreaks have been reported in Sub-Saharan Africa. RVF is primarily a disease for animals with zoonotic potential to cause infection in humans. It is transmitted to humans either through contact of blood or fluids of infected animals as well as bite from infected mosquitoes (Aedes or Culex species). Till date, human is considered as dead end and no human-to-human transmission is reported in RVF. This disease is known in two forms: mild and severe. Incubation period is 2-6 days. Milder form generally presents with flu-like symptoms, fever, myalgia, arthralgia, vomiting, malaise, etc[95].

Majority of cases are relatively mild; still a small percentage of patients develop severe forms of disease including: ocular (eye) disease (in 0.5-2%) with blurred vision, lesions in eyes involving macula leading to loss of vision. These symptoms start after 1-3 wk of initial mild symptoms; meningoencephalitis form (in less than 1%) that usually occurs after 1-4 wk of onset of initial RFV symptoms presenting with severe headache, memory loss, disorientation, lethargy, convulsions, hallucinations leading to coma and neurological complications; and haemorrhagic fever form (in <1%) in whom haemorrhagic symptoms generally appear 2-4 days after disease onset. Bleeding manifestation includes haematemesis, melaena, purpuric rash or ecchymosis, bleeding in gums, epistaxis, menorrhagia and bleeding from venepuncture site. CFR in bleeding cases is almost 50 per cent [95].

Laboratory diagnosis is mainly through qRT-PCR and IgM ELISA assay. Till date, there is no specific vaccine or drug available for RVF treatment.

(iv) Yellow fever (YF) virus: YF is a viral haemorrhagic fever disease transmitted by infected Aedes mosquitoes and the virus belongs to family Filoviridae. This disease is endemic in tropical areas of Africa and Central and South America. YF presents with acute-onset jaundice with constitutional symptoms such as fever, headache, myalgia, nausea, vomiting and fatigue. The cases with severe symptoms may land up in liver and multi-organ failure and CFR may be up to 50 per cent in such cases [96].

Laboratory diagnosis is mainly through qRT-PCR and IgM ELISA assay. Plaque reduction neutralization test (PRNT) may be needed due to cross-reactivity with other flaviviruses. An extremely effective vaccine is available against YF. A single dose of YF vaccine is sufficient to provide life-long immunity within 10 days after vaccination (80-100% effective) while 99 per cent immunity within 30 days. A booster dose of the vaccine is not needed. There is currently no specific anti-viral drug available for the treatment of YF, and hence, vaccination against YF is mainstay of prevention [96].

Gastroenteritis viruses

(i) Rotavirus: Rotavirus is double-stranded RNA virus belonging to the family Reoviridae. It is one of the major causes of severe and dehydrating diarrhoea amongst children aged less than five years. In India, rotavirus is responsible for almost 22 per cent deaths, 30 per cent hospitalizations and 8.3 per cent outpatient visits each year [30]. Two rotavirus vaccines, namely Rotarix and RotaTeq, have been licensed for prophylaxis of rotavirus diarrhoea. The WHO has recommended both these vaccines to be included in childhood immunization programmes [97]. A study conducted in Pune highlighted the burden of rotavirus disease and changing profile of circulating rotavirus strains, highlighting the emergence of G9P(4) re-assortant strains [98]. Surveillance of rotaviral infections will help in early identification of the rare and emerging strains of rotaviruses. Thus, monitoring of rotavirus disease and strains is essential to assess the impact of rotavirus vaccines and circulating rotavirus strains in the country.

(ii) Sapovirus: Sapovirus is responsible for acute gastroenteritis (AGE) in humans as well as animals. These are of public health importance due to sporadic outbreaks reported in people of all age groups worldwide. In 1976, in the United Kingdom (UK), sapovirus particles were discovered in human stool samples for the first time [99] and eventually identified as a new gastroenteritis pathogen due to its worldwide distribution [100]. Sapovirus belongs to the genus Sapovirus of family Caliciviridae. There are 14 genogroups of sapoviruses. The four genogroups of human sapovirus infection are GI, GII, GIV and GV. GIV1 strains are detected and reported from Canada, Japan, United States, Europe in 2007[31]. The first detection of sapovirus in India was in 2000 from Vellore [101]. During the investigation of a food-borne outbreak in Delhi, Norovirus (NoV) belonging to GII genogroup was identified [102]. During a paediatric gastroenteritis outbreak investigation in Vellore in south India in 2007, sapovirus infections accounted for 16.7 per cent of cases [103]. In India, sapovirus has also been detected in asymptomatic children. It seems probable that sapovirus infections might contribute significantly to the burden of diarrhoeal diseases in India. Limited information exists on the sequence diversity of sapoviruses in India, and molecular epidemiological studies need to be performed to understand the dynamics of sapovirus infections in the country.

(iii) Novovirus: NoV is RNA virus of the family Caliciviridae. Human NoV, erst Norwalk virus, was first detected in the stool specimen of a gastroenteritis outbreak in Norwalk. It was the first viral agent reported as a cause of AGE [104]. These are the leading cause for AGE outbreaks reported amongst all the age groups worldwide after rotavirus [32],[105]. There are five genotypes of NoV (GI-GV), of which GI, GII and GIV are responsible for human AGE cases. NoV was reported amongst AGE cases in western India [106]. NoV positivity was found to be 6.3-12.6 per cent with a prominence of GII genotype (96.6%)[107], suggesting it to be the second most common cause of non-bacterial gastroenteritis after rotavirus in western India. Of the 59 human Caliciviridae strains from India, 61 per cent were NoV with predominance of GII genotype (15%), which were detected using two-step multiplex RT-PCR [108]. In India, NoV infections are common cause of childhood AGE cases. The replacement of strains had made a cautionary and pointed out the need for strain-specific vaccines.

Acute febrile illness (AFI) and acute-undifferentiated fever (AUF)

Increasing number of cases of febrile illnesses, in which a definitive aetiology is not detectable, leading to their classification as fever of unknown origin (FUO), has been a concern in the tropical countries. Locally endemic infections such as malaria, dengue, leptospirosis, rickettsial infections, Japanese encephalitis [33] and influenza could probably be responsible for AUF cases. Unavailability of diagnostic facilities, challenges in collection, transport and testing of the right type of specimen(s) at the right time often impact accurate laboratory diagnosis of these conditions. Bacteriological tests often reveal infections with  Salmonella More Details sp., Leptospira sp.,  Escherichia More Details coli and Staphylococcus aureus also as the underlying cause of FUO. Despite a battery of tests for a variety of pathogens, an aetiological agent is often not detected in as much as one-third to one-fourth of patients with FUO [109].

Acute encephalitis syndrome (AES) and acute encephalopathy

(i) Nipah virus (NiV) disease: For the first time, NiV was identified during an outbreak of acute febrile encephalitis cases amongst pig handlers that occurred in Kampung Sungai Nipah, Malaysia, in 1998[110]. NiV, along with Hendra virus, belongs to the Henipavirus and is a pathogenic paramyxovirus which causes acute-onset encephalitis, leading to deaths in humans. The reservoir for NiV is known to be Pteropus bats (flying foxes) and transmission to humans usually occurs through contact of positive NiV cases through their infectious secretions or an intermediate animal host such as pigs. Human-to-human spread of the virus has also been described [110]. Outbreaks of NiV in pigs have been reported from Malaysia and Singapore. Subsequently, human disease has been reported from Malaysia, Singapore, India and Bangladesh [110]. Evidence of the virus without clinical disease has also been found in fruit bats in Cambodia, Thailand and Madagascar. The outbreaks of human cases of NiV have been reported in Siliguri (2001) and Nadia (2007) districts of West Bengal [111]. A focal outbreak that led to 18 laboratory-confirmed cases and amongst them 16 deaths in Kozhikode and Malappuram districts of Kerala State in south India in May 2018 has been the latest report of this deadly disease [112].

NiV disease in human has average incubation period of 4-14 days with maximum incubation period of 21 days. The virus causes multi-organ vasculitis and the pathology is seen mostly in the CNS and the respiratory system. The virus causes acute febrile encephalitis with symptoms including fever, headache, drowsiness, dizziness and coma. Thrombocytopenia, leucopenia and elevated aspartate aminotransferase and alanine transaminase levels have also been reported from NiV-infected cases. NiV infection in pigs is known as porcine respiratory and encephalitis syndrome and barking pig syndrome. Infections by NiV in humans and animals are confirmed by virus isolation, RNA as well as anti-Nipah IgM and IgG antibodies detection. BSL-4 facilities are mandatory for isolation as well as virus propagation. There are no vaccines available for NiV for human use. Studies in small-animal models of NiV infection suggest that monoclonal antibodies therapy may be promising [113].

The circulation of NiV has been confirmed in Pteropus giganteus bat populations of West Bengal and Assam States of India [34] [Figure 4]. Large colonies/roosts of this bat species were observed in proximity of human settlements. This indicated that the north-eastern region of India could be one of the hot spots for spillover of NiV infection from bat to human population.
Figure 4: Geographic location of bat collection (indicated by arrows) and Tioman virus positivity in Pteropus giganteus bat (indicated by black dot), North-East India. Source: Adapted from Ref. 34.

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(ii) Thottapalayam virus (TPMV): In India, TPMV was isolated for the first time from the Asian house shrew (Suncus murinus) from Vellore, in 1964[114]. TPMV belongs to the family Hantaviridae and the genus Orthohantavirus. Serological and electron microscopic studies confirmed its resemblance to Hantaviruses (HTNV). The house shrew naturally harbours this virus. It is known to cause transient viraemia with shedding of virus from oropharyngeal secretions of the house shrew. Delayed excretion and presence of virus in urine, faeces and persistence in tissues, particularly lung, have also been recorded.

(iii) Lymphocytic choriomeningitis virus (LCMV): LCMV is a rodent-borne disease that causes a wide range of human infections from meningoencephalitis to congenital birth defects. It is also known to cause severe disseminated illness reported from organ transplant immunocompromised patients [35]. Isolation of this virus was done from cerebrospinal fluid (CSF) of a menigoencephalitis case in 1933 for the first time [115]. In 1955, first congenital LCMV was reported in England following which multiple cases were reported throughout Europe and the United States [116]. In pregnancy, LCMV may cause foetal death or induce/spontaneous abortion and the surviving foetuses can be visually impaired or with brain dysfunction [117]. Rodents, especially house mouse, are the main reservoirs of LCMV and exposure to their secretions, and excreta leads to transmission to humans. Congenital LCMV does not occur unless pregnant women contracts with primary LCMV infection during pregnancy [35].

In India, the incidence of LCMV was observed to be 0.76 per cent in mice. The presence of LCMV in rat and mice of southern and north India was analyzed and found to be 2.85 per cent [117],[118]. Extensive surveys need to be done in the areas of the country, showing abundance of rodents to understand circulation of LCMV and to assess its epidemic potential.

(iv) Human parvovirus-4 (PARV4): It is a single-stranded DNA virus, first identified in 2005 from a hepatitis-B-positive patient who was intravenous drug user (IDU)[119]. PARV4 belongs to family Parvoviridae. The other viruses of significance in this family are parvovirus B19, human bocaviruses 1-4 and adeno-associated viruses 1-5[36]. There are three genotypes of PARV4. Among these, genotypes 1 and 2 are predominantly found in Europe, North America as well as Asia, while genotype 3 is found mainly in Africa. PARV4 infection and its widespread presence in diverse tissue samples have been recently detected [120]. Transmission of PARV4 to humans occurs amongst IDU and is strongly linked to acquisition of both HCV and HIV infection as reported in Europe and North America [36]. The presence of PARV4 in two per cent plasma samples from voluntary blood donors has been reported from North America [121]. These viruses were found resistant to traditional methods for viral inactivation employed mainly for plasma-derived products. A high prevalence of PARV4 infection (35%) among those with HIV infection (with or without HCV co-infection) has been reported from Iran [122]. High PARV4 levels were observed in CSF in children suspected to have encephalitis from southern India suggesting an acute infection [123]. The incidence of PARV4 in humans in India is limited, thus, the clinical significance of PARV4 remains unclear.

(v) Human cytomegalovirus (CMV): CMV, also known as human herpesvirus-5, is a highly host-specific virus belonging to Herpesviridae family [37]. In 1956, CMV was isolated by Smith [124] from submaxillary gland of a dead infant for the first time. The virus is of public health importance as it is known to responsible for high morbidity and mortality in new-borns as well as immunocompromised patients. It is probably one of the most common infections amongst healthy individual characterized by a self-limiting infection. Besides contact with seropositive mothers (passage through genital tract, breast milk, etc.), blood transfusion is also known as one of the most important mode of perinatal/post-natal spread of CMV to neonates. Distribution of CMV is seen globally and predominantly in developing countries [125].

Foetus can be infected after a primary or a recurrent infection in pregnant women. Infections in utero are associated with intrauterine death or congenital foetal abnormalities and intrauterine growth retardation along with developmental delays, blindness and deafness as sequelae [126],[127]. Infections are usually subclinical and can be confirmed only by laboratory testing. CMV is a common congenital infection worldwide with estimated incidence of 0.2-2.2 per cent and seroprevalence of 45-100 per cent [128]. Seroprevalence in India is about 80-90 per cent [129]. In a recent seroprevalence study in western India, 83 per cent seropositivity for CMV IgG and 9.46 per cent seropositivity for CMV IgM have been observed in antenatal women [129]. In India, due to scarcity of data regarding birth defects, it is difficult to extrapolate the true incidence of recurrent CMV.

(vi) CHPV: CHPV is a single-stranded, negative sense, RNA arbovirus of the genus Vesiculovirus and family Rhabdoviridae. CHPV was first discovered by Bhatt and Rodrigues [130] in 1966 during investigations of febrile illness in Chandipura region of Maharashtra. Epidemics of CHPV-associated AES were reported in young children from Andhra Pradesh, Gujarat and Nagpur [38]. Apart from India, CHPV is prevalent in West Africa since 1975, which had been isolated from hedgehog and phlebotomine sand flies [131]. Phlebotomine sand flies are the main vectors for CHPV transmission. CHPV is also known to infect mosquitoes, mainly Ae. aegypti; it survives in the salivary gland of the mosquito for 4-5 days and is then transmitted to other vertebrates. Adults are unaffected by CHPV, while CFRs in infected children can range from 56 to 75 per cent. Despite the progress made in understanding the virus and development of diagnostics, antivirals and control strategies, CHPV is a known public health problem in certain parts of Maharashtra and in Andhra Pradesh [132]. Although the case fatality rates could be reduced, a substantial section of population in these regions remains at risk. The factors responsible for the amplification of this virus in natural reservoirs need to be investigated in detail.

Other emerging and re-emerging viruses

(i) Severe fever with thrombocytopenia syndrome virus (SFTSV): SFTSV is a tick-borne virus and belongs to the genus Phlebovirus and family Bunyaviridae [Figure 5] reported from China, Japan and South Korea [133],[134]. The clinical spectrum of illness associated with this virus includes fever, thrombocytopenia, leucocytopenia, gastrointestinal and muscular symptoms, neurological abnormalities, coagulopathy and haemophagocytic syndrome. SFTSV has been detected in Haemaphysalis ticks [134]; however, this virus has also been detected in bats [135]; hence, it is difficult to comment upon the likely vectors for its transmission to humans or other animals. The seroprevalence of SFTV is reported from domesticated animals, including sheep, goats, cattle, pigs, dogs and chickens [136].
Figure 5: Place of first isolation of Bunyaviruses in India. Source: Adapted from Ref. 46.

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(ii) Malsoor virus: Malsoor virus is a novel phlebovirus, belonging to family Phenuiviridae. It was isolated from bats in India and found phylogenetically related to SFTSV [135]. The potential of Malsoor virus to cause disease in humans remains unknown. In India, bats often live near human habitats and the potential spillover of viral pathogens from them to humans is a matter of concern.

(iii) Chobar Gorge virus (CGV): The tick-borne Orbivirus species which includes Chenuda virus, CGV, Wad Medani virus and Great Island virus [39]. CGV was isolated from Ornithodoros spp [136]. CGV is divided into two serotypes: serotype-1 from ticks collected from a limestone cave in Nepal while Fomede virus (FV) was isolated from bat species in caves in Guinea in 1978. Serological evidence was found in horses, sheep, cattle, buffalo and humans [137]. The virus has a genomic structure similar to the other tick-borne orbiviruses and consists of seven structural and three non-structural proteins. However, no human disease has been attributed to it so far [39].

(iv) Equine encephalosis virus (EEV): EEV is an arthropod-borne Orbivirus (Family Reoviridae) and causes febrile non-contagious disease in equids [138]. In 1967, EEV was isolated from horses in South Africa for the first time. The infection presents as an acute illness involving lack of appetite and oedema [40]. The disease results in 60-70 per cent morbidity in equids, but deaths are rare [139]. Two species of the midges belonging to Culicoides species are known to be the vectors for EEV [138]. Recently, complete genome of EEV has been obtained from a dead horse from India with next-generation sequencing methods, thus confirming its presence in the country [41].

(v) Buffalopox virus (BPXV) from human and buffaloes in India: Poxviruses are the largest and complex viruses belonging to genus Orthopoxvirus (OPXV) under the subfamily Chordopoxvirinae (infecting vertebrates) of poxviruses [140]. The OPXVs include variola virus (VARV), vaccinia virus (VACV), monkeypox virus, cowpox virus (CPXV), camelpox virus (CMLV), horse pox virus, rabbitpox virus, buffalopox virus, Cantagalo virus and Aracatuba viruses. OPXV genomes typically measure about 200 Kb and contain conserved coding regions in centre essential for viral replication as well as for virus assembly with variable terminal ends which determine host range and pathogenicity [141]. All OPXVs are immunologically related to each other, causing cross-reactivity and cross-protection [142]. The practice of vaccination with VACV began in the 20th century, and in 1979, human smallpox (VARV) was successfully eradicated [143].

BPXV is a double-stranded, enveloped DNA virus in the genus OPXV and family Poxviridae[42]. BPX is a highly contagious and one of the known and important zoonotic viral disease [144] affecting humans and livestock species such as buffaloes and cow. This disease causes considerable financial loss to the dairy industry in terms of reduction in milk production and draught capacity [145]. In buffaloes and cows, this disease affects udder, teats, inguinal region, ears and eyes, and in the generalized form, it affects the hindquarters [146]. In humans, the disease is characterized by erythematous pocks on arms, face and neck, along with fever, axillary lymphadenopathy and malaise [147]. Till date, BPX has been reported frequently from different States of India as well as in Pakistan, Bangladesh, Nepal, Indonesia and Egypt [147]. The first report of a zoonotic human case of BPX was reported in 1934[148]. Nosocomial infection of BPXV in human beings has also been reported in Pakistan [149].

Despite the successful smallpox eradication programme, a possibility exists that VARV and VACV-related viruses may re-emerge in human and animal population, posing a public health threat. Hence, a deeper understanding of the evolutionary biology and host specificity of OPXVs becomes important. Measures for prevention of BPX warrant high priority, considering its increasing incidence, the potential economic loss to the dairy sector as well as the zoonotic impact on humans.


   Conclusion Top


India, being a country of extreme geo-climatic diversity, faces a constant threat of emerging and re-emerging viral infections of public health importance [Table 1] and [Table 2]. There is a need for strengthening disease surveillance in the country focusing on the epidemiology and disease burden. There is also a pressing need to gain detailed insights into disease biomics, including vector biology and environmental factors influencing the diseases. It is also important to strengthen the emergency preparedness for these diseases and response by focusing on 'one health' approach.
Table 2: Known future threat of emerging viral infections in India

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Acknowledgment: Authors acknowledge the encouragement and support given by Dr Balram Bhargava, Secretary, Department of Health Research and Director General, Indian Council of Medical Research, New Delhi. We also acknowledge Dr Prachi Pardeshi from BSL-4 facility, ICMR-National Institute of Virology, Pune, for help she extended for this review.

Financial support & sponsorship: None.

Conflicts of Interest: None.[155]



 
   References Top

1.
Dikid T, Jain SK, Sharma A, Kumar A, Narain JP. Emerging & re-emerging infections in India: An overview. Indian J Med Res 2013; 138 : 19-31.  Back to cited text no. 1
    
2.
Mani RS, Ravi V, Desai A, Madhusudana SN. Emerging viral infections in India. Proc Natl Acad Sci India Sect B Biol Sci 2012; 82 : 5-21.  Back to cited text no. 2
    
3.
Sarma N. Emerging and re-emerging infectious diseases in South East Asia. Indian J Dermatol 2017; 62 : 451-5.  Back to cited text no. 3
    
4.
World Health Organization, South-East Asia Region, Western Pacific Region. Asia Pacific strategy for emerging diseases: 2010. New Delhi, Manila: WHO, South-East Asia Region, Western Pacific Region; 2011.  Back to cited text no. 4
    
5.
Tran TH, Nguyen TL, Nguyen TD, Luong TS, Pham PM, Nguyen V, et al. Avian Influenza A (H5N1) in 10 patients in Vietnam N Engl J Med, 2004; 350 : 1179-88.   Back to cited text no. 5
    
6.
Gopalakrishnan R, Sureshkumar D, Thirunarayan MA, Ramasubramanian V. Melioidosis: An emerging infection in India. J Assoc Physicians India 2013; 61 : 612-4.  Back to cited text no. 6
    
7.
Arankalle VA, Shrivastava S, Cherian S, Gunjikar RS, Walimbe AM, Jadhav SM. Genetic divergence of Chikungunya viruses in India (1963-2006) with special reference to the 2005-2006 explosive epidemic. J Gen Virol 2007; 88 (Pt 7) : 1967-76.  Back to cited text no. 7
    
8.
Jupp P, McIntosh B. Chikungunya virus disease. In: Monath TP, editor. The arboviruses: epidemiology and ecology. Boca Raton, Florida: CRC Press, Inc.; 1988. pp. 137-57.  Back to cited text no. 8
    
9.
Halstead SB. Dengue. Lancet 2007; 370 : 1644-52.  Back to cited text no. 9
    
10.
Paixão ES, Teixeira MG, Rodrigues LC. Zika, chikungunya and dengue: The causes and threats of new and re-emerging arboviral diseases. BMJ Glob Health 2018; 3 : e000530.  Back to cited text no. 10
    
11.
Bhardwaj S, Gokhale MD, Mourya DT. Zika virus: Current concerns in India. Indian J Med Res 2017; 146 : 572-5.  Back to cited text no. 11
    
12.
Bhatt PN, Rodrigues FM. Chandipura: A new arbovirus isolated in India from patients with febrile illness. Indian J Med Res 1967; 55 : 1295-305.  Back to cited text no. 12
    
13.
Casals J. Antigenic similarity between the virus causing Crimean hemorrhagic fever and Congo virus. Proc Soc Exp Biol Med 1969; 131 : 233-6.  Back to cited text no. 13
    
14.
Nichter M. Kyasanur forest disease: An ethnography of a disease of development. Med Anthropol 1987; 1 : 406-23.  Back to cited text no. 14
    
15.
Integrated Disease Surveillance Programme, Ministry of Health & Family Welfare, Government of India. Available from: http://idsp.nic.in/index4.php?lang=1&level=0&linkid=406&lid=3689, accessed on June 5, 2018.  Back to cited text no. 15
    
16.
Cecilia D. Current status of dengue and chikungunya in India. WHO South East Asia J Public Health 2014; 3 : 22-6.  Back to cited text no. 16
    
17.
World Health Organization. Communicable disease alert and response for mass gatherings. Key considerations. Geneva: WHO; 2008.   Back to cited text no. 17
    
18.
David S, Roy N. Public health perspectives from the biggest human mass gathering on earth: Kumbh Mela, India. Int J Infect Dis 2016; 47 : 42-5.  Back to cited text no. 18
    
19.
Meena V. Temples of South India. Kanyakumari: Hari Kumari Arts; 1976.  Back to cited text no. 19
    
20.
Hays JN. Epidemics and Pandemics:Their Impacts on Human History. Santa Barbara, CA and Oxford: ABC-CLIO; 2005. p. 527.  Back to cited text no. 20
    
21.
Koul PA, Mir H, Saha S, Chadha MS, Potdar V, Widdowson MA, et al. Respiratory viruses in returning Hajj & Umrah pilgrims with acute respiratory illness Kashmir, north India in 2014-2015. Indian J Med Res 2018; 148 : 329-33.  Back to cited text no. 21
    
22.
Harit AK, Ichhpujani RL, Gupta S, Gill KS, Lal S, Ganguly NK, et al. Nipah/Hendra virus outbreak in Siliguri, West Bengal, India in 2001. Indian J Med Res 2006; 123 : 553-60.  Back to cited text no. 22
    
23.
Kumar A, Shukla D, Kumar R, Idris MZ, Misra UK, Dhole TN. Molecular epidemiological study of enteroviruses associated with encephalitis in children from India. J Clin Microbiol 2012; 50 : 3509-12.  Back to cited text no. 23
    
24.
Rao CD. Non-polio enteroviruses, the neglected and emerging human pathogens: Are we waiting for the sizzling enterovirus volcano to erupt? Proc Indian Natn Sci Acad 2015; 81 : 447-62.  Back to cited text no. 24
    
25.
Deshpande JM, Nadkarni SS, Francis PP. Enterovirus 71 isolated from a case of acute flaccid paralysis in India represents a new genotype. Curr Sci 2003; 84 : 1350-3.  Back to cited text no. 25
    
26.
Rao CD, Yergolkar P, Shankarappa KS. Antigenic diversity of enteroviruses associated with nonpolio acute flaccid paralysis, India, 2007-2009. Emerg Infect Dis 2012; 18 : 1833-40.  Back to cited text no. 26
    
27.
Arunkumar G, Vandana KE, Sathiakumar N. Prevalence of measles, mumps, rubella, and varicella susceptibility among health science students in a university in India. Am J Ind Med 2013; 56 : 58-64.  Back to cited text no. 27
    
28.
Yadav PD, Patil DY, Shete AM, Kokate P, Goyal P, Jadhav S, et al. Nosocomial infection of CCHF among health care workers in Rajasthan, India. BMC Infect Dis 2016; 16 : 624.  Back to cited text no. 28
    
29.
Awate P, Yadav P, Patil D, Aich A, Kumar V, Kore P, et al. Outbreak of Kyasanur forest disease (Monkey fever) in Sindhudurg, Maharashtra state, India, 2016. J Infect 2016; 72 : 759-61.  Back to cited text no. 29
    
30.
Tate JE, Chitambar S, Esposito DH, Sarkar R, Gladstone B, Ramani S, et al. Disease and economic burden of rotavirus diarrhoea in India. Vaccine 2009; 27 (Suppl 5) : F18-24.  Back to cited text no. 30
    
31.
Svraka S, Vennema H, van der Veer B, Hedlund KO, Thorhagen M, Siebenga J, et al. Epidemiology and genotype analysis of emerging Sapovirus-associated infections across Europe. J Clin Microbiol 2010; 48 : 2191-8.  Back to cited text no. 31
    
32.
Cheng WX, Ye XH, Yang XM, Li YN, Jin M, Jin Y, et al. Epidemiological study of human calicivirus infection in children with gastroenteritis in Lanzhou from 2001 to 2007. Arch Virol 2010; 155 : 553-5.  Back to cited text no. 32
    
33.
Kulkarni R, Sapkal GN, Kaushal H, Mourya DT. Japanese encephalitis: A brief review on Indian perspectives. Open Virol J 2018; 12 : 121-30.  Back to cited text no. 33
    
34.
Yadav P, Sudeep A, Gokhale M, Pawar S, Shete A, Patil D, et al. Circulation of Nipah virus in Pteropus giganteus bats in northeast region of India, 2015. Indian J Med Res 2018; 147 : 318-20.  Back to cited text no. 34
    
35.
Bonthius DJ. Lymphocytic choriomeningitis virus: A prenatal and postnatal threat. Adv Pediatr 2009; 56 : 75-86.  Back to cited text no. 35
    
36.
Matthews PC, Malik A, Simmons R, Sharp C, Simmonds P, Klenerman P. PARV4: An emerging tetraparvovirus. PLoS Pathog 2014; 10 : e1004036.  Back to cited text no. 36
    
37.
Chakravarti A, Kashyap B, Matlani M. Cytomegalovirus infection: An Indian perspective. Indian J Med Microbiol 2009; 27 : 3-11.  Back to cited text no. 37
    
38.
Gurav YK, Tandale BV, Jadi RS, Gunjikar RS, Tikute SS, Jamgaonkar AV, et al. Chandipura virus encephalitis outbreak among children in Nagpur division, Maharashtra, 2007. Indian J Med Res 2010; 132 : 395-9.  Back to cited text no. 38
    
39.
Belaganahalli MN, Maan S, Maan NS, Brownlie J, Tesh R, Attoui H, et al. Genetic characterization of the tick-borne orbiviruses. Viruses 2015; 7 : 2185-209.  Back to cited text no. 39
    
40.
Howell PG, Guthrie AJ, Coetzer JAW. Equine encephalosis. In: Coetzer JAW, Tustin R, editors. Infectious diseases of livestock. Cape Town: Oxford University Press; 2004. p. 1247-51.  Back to cited text no. 40
    
41.
Yadav PD, Albariño CG, Nyayanit DA, Guerrero L, Jenks MH, Sarkale P, et al. Equine encephalosis virus in India, 2008. Emerg Infect Dis 2018; 24 : 898-901.  Back to cited text no. 41
    
42.
Singh RK, Hosamani M, Balamurugan V, Satheesh CC, Shingal KR, Tatwarti SB, et al. An outbreak of Buffalopox in buffalo (Bubalus bubalis) dairy herds in Aurangabad, India. Rev Sci Tech 2006; 25 : 981-7.  Back to cited text no. 42
    
43.
Sudeep AB, Jadi RS, Mishra AC. Ganjam virus. Indian J Med Res 2009; 130 : 514-9.  Back to cited text no. 43
    
44.
Matsuno K, Weisend C, Travassos da Rosa APA, Anzick SL, Dahlstrom E, Porcella SF, et al. Characterization of the Bhanja serogroup viruses (Bunyaviridae): A novel species of the genus Phlebovirus and its relationship with other emerging tick-borne phleboviruses. J Virol 2013; 87 : 3719-28.  Back to cited text no. 44
    
45.
Yadav PD, Nyayanit DA, Shete AM, Jain S, Majumdar TP, Chaubal GY, et al. Complete genome sequencing of Kaisodi virus isolated from ticks in India belonging to Phlebovirus genus, family phenuiviridae. Ticks Tick Borne Dis 2019; 10 : 23-33.  Back to cited text no. 45
    
46.
Yadav PD, Chaubal GY, Shete AM, Mourya DT. A mini-review of bunyaviruses recorded in India. Indian J Med Res 2017; 145 : 601-10.  Back to cited text no. 46
    
47.
Rogers DJ, Wilson AJ, Hay SI, Graham AJ. The global distribution of yellow fever and dengue. Adv Parasitol 2006; 62 : 181-220.  Back to cited text no. 47
    
48.
Sudeep AB, Bondre VP, Mavale MS, Ghodke YS, George RP, Aher RV, et al. Preliminary findings on Bagaza virus (Flavivirus: Flaviviridae) growth kinetics, transmission potential & transovarial transmission in three species of mosquitoes. Indian J Med Res 2013; 138 : 257-61.  Back to cited text no. 48
    
49.
Karron RA, Black RE. Determining the burden of respiratory syncytial virus disease: The known and the unknown. Rancet 2017; 390 : 917-8.  Back to cited text no. 49
    
50.
Presti RM, Zhao G, Beatty WL, Mihindukulasuriya KA, da Rosa APAT, Popov VL, et al. Quaranfil, Johnston Atoll, and Lake Chad viruses are novel members of the family Orthomyxoviridae. J Virol 2009; 83 : 11599-606.  Back to cited text no. 50
    
51.
Rao S, Messacar K, Torok MR, Rick AM, Holzberg J, Montano A, et al. Enterovirus D68 in critically ill children: A comparison with pandemic H1N1 influenza. Pediatr Crit Care Med 2016; 17 : 1023-31.  Back to cited text no. 51
    
52.
Briese T, Renwick N, Venter M, Jarman RG, Ghosh D, Köndgen S, et al. Global distribution of novel rhinovirus genotype. Emerg Infect Dis 2008; 14 : 944-7.  Back to cited text no. 52
    
53.
Munivenkatappa A, Yadav PD, Nyayanit DA, Majumdar TD, Sangal L, Jain S, et al. Molecular diversity of coxsackievirus A10 circulating in the Southern and Northern region of India [2009-17]. Infect Genet Evol 2018; 66 : 101-10.  Back to cited text no. 53
    
54.
Purdy MA. Hepatitis B virus S gene escape mutants. Asian J Transfus Sci 2007; 1 : 62-70.  Back to cited text no. 54
    
55.
Yadav PD, Shete AM, Nyayanit DA, Albarino CG, Jain S, Guerrero LW, et al. Identification and characterization of novel mosquito-borne (Kammavanpettai virus) and tick-borne (Wad Medani) reoviruses isolated in India. J Gen Virol 2018; 99 : 991-1000.  Back to cited text no. 55
    
56.
Riyesh T, Karuppusamy S, Bera BC, Barua S, Virmani N, Yadav S, et al. Laboratory-acquired Buffalopox virus infection, India. Emerg Infect Dis 2014; 20 : 324-6.  Back to cited text no. 56
    
57.
International Committee on Taxonomy of Viruses. ICTV Virus Taxonomy: The online (10th) report of the International Committee on Taxonomy of Viruses. Genus Enterovirus. Available from: https://talk.ictvonline.org/ictv-reports/ictv_online_report/positive-sense-rna-viruses/picornavirales/w/picornaviridae/681/genus-enterovirus, accessed on June 23, 2018.  Back to cited text no. 57
    
58.
Sapkal GN, Bondre VP, Fulmali PV, Patil P, Gopalkrishna V, Dadhania V, et al. Enteroviruses in patients with acute encephalitis, Uttar Pradesh, India. Emerg Infect Dis 2009; 15 : 295-8.  Back to cited text no. 58
    
59.
Lewthwaite P, Perera D, Ooi MH, Last A, Kumar R, Desai A, et al. Enterovirus 75 encephalitis in children, Southern India. Emerg Infect Dis 2010; 16 : 1780-2.  Back to cited text no. 59
    
60.
Sarma N. Hand, foot, and mouth disease: Current scenario and Indian perspective. Indian J Dermatol Venereol Leprol 2013; 79 : 165-75.  Back to cited text no. 60
    
61.
Gopalkrishna V, Patil PR, Patil GP, Chitambar SD. Circulation of multiple enterovirus serotypes causing hand, foot and mouth disease in India. J Med Microbiol 2012; 61 : 420-5.  Back to cited text no. 61
    
62.
Saxena VK, Sane S, Nadkarni SS, Sharma DK, Deshpande JM. Genetic diversity of enterovirus A71, India. Emerg Infect Dis 2015; 21 : 123-6.  Back to cited text no. 62
    
63.
Attoui H, Mohd Jaafar F. Zoonotic and emerging orbivirus infections. Rev Sci Tech 2015; 34 : 353-61.  Back to cited text no. 63
    
64.
Kumar R, Kumar P, Singh MK, Agarwal D, Jamir B, Khare S, et al. Epidemiological profile of acute viral encephalitis. Indian J Pediatr 2018; 85 : 358-63.  Back to cited text no. 64
    
65.
Looker KJ, Magaret AS, Turner KM, Vickerman P, Gottlieb SL, Newman LM. Global estimates of prevalent and incident herpes simplex virus type 2 infections in 2012. PLoS One 2015; 10 : e114989.  Back to cited text no. 65
    
66.
Lee BW. Review of varicella zoster seroepidemiology in India and Southeast Asia. Trop Med Int Health 1998; 3 : 886-90.  Back to cited text no. 66
    
67.
Centers for Disease Control and Prevention. Epidemiology and Prevention of Vaccine Preventable Diseases: Varicella. Available from: https://www.cdc.gov/vaccines/pubs/pinkbook/varicella.html, accessed on January 15, 2019.  Back to cited text no. 67
    
68.
Lopez A, Marin M. Strategies for the control and investigation of Varicella Outbreaks manual; 2008. Available from: https://www.cdc.gov/chickenpox/outbreaks/manual.html, accessed on June 12, 2018.  Back to cited text no. 68
    
69.
Rao BL. Epidemiology and control of influenza. Natl Med J India 2003; 16 : 143-9.  Back to cited text no. 69
    
70.
National Institute of Virology Commemorative Compendium. Respiratory viral diseases. Golden Jubilee Publication; 2004. p. 201.  Back to cited text no. 70
    
71.
Paules C, Subbarao K. Influenza. Lancet 2017; 390 : 697-708.  Back to cited text no. 71
    
72.
Moghadami M. A narrative review of influenza: A seasonal and pandemic disease. Iran J Med Sci 2017; 42 : 2-13.  Back to cited text no. 72
    
73.
World Health Organization. Summary of probable SARS cases with onset of illness from 1 November 2002 to 31 July 2003. Available from: http://www.who.int/csr/sars/country/table2004_04_21/en/, accessed on June 12, 2018.  Back to cited text no. 73
    
74.
World Health Organization. The operational response to SARS. Available from: https://www.who.int/csr/sars/goarn2003_4_16/en/, accessed on April 11, 2019.  Back to cited text no. 74
    
75.
World Health Organization. Middle East respiratory syndrome coronavirus (MERS-CoV). Available from: http://www.who.int/emergencies/mers-cov/en/, accessed on June 12, 2018.  Back to cited text no. 75
    
76.
World Health Organization. Middle East respiratory syndrome coronavirus (MERS-CoV). Available from: https://www.who.int/emergencies/mers-cov/en/, accessed on April 11, 2019.  Back to cited text no. 76
    
77.
Cowling BJ, Park M, Fang VJ, Wu P, Leung GM, Wu JT. Preliminary epidemiological assessment of MERS-CoV outbreak in South Korea, May to June 2015. Euro Surveill Bull Eur Sur Mal Transm Eur Commun Dis Bull 2015; 20 : 7-13.  Back to cited text no. 77
    
78.
World Health Organization. Influenza (Avian and other zoonotic). Available from: https://www.who.int/news-room/fact-sheets/detail/influenza-(avian-and-other-zoonotic), accessed on April 11, 2019.  Back to cited text no. 78
    
79.
Karron RA, Black RE. Determining the burden of respiratory syncytial virus disease: The known and the unknown. Lancet 2017; 390 : 917-8.  Back to cited text no. 79
    
80.
Nair H, Nokes DJ, Gessner BD, Dherani M, Madhi SA, Singleton RJ, et al. Global burden of acute lower respiratory infections due to respiratory syncytial virus in young children: A systematic review and meta-analysis. Lancet 2010; 375 : 1545-55.  Back to cited text no. 80
    
81.
World Health Organization. Influenza: WHO Global RSV surveillance pilot - objectives. Available from: https://www.who.int/influenza/rsv/rsv_objectives/en/, accessed on April 11, 2019.  Back to cited text no. 81
    
82.
Jauréguiberry S, Tattevin P, Tarantola A, Legay F, Tall A, Nabeth P, et al. Imported Crimean-Congo hemorrhagic fever. J Clin Microbiol 2005; 43 : 4905-7.  Back to cited text no. 82
    
83.
Chamberlain J, Cook N, Lloyd G, Mioulet V, Tolley H, Hewson R. Co-evolutionary patterns of variation in small and large RNA segments of Crimean-Congo hemorrhagic fever virus. J Gen Virol 2005; 86 : 3337-41.  Back to cited text no. 83
    
84.
Anagnostou V, Papa A. Evolution of Crimean-Congo hemorrhagic fever virus. Infect Genet Evol 2009; 9 : 948-54.  Back to cited text no. 84
    
85.
Centers for Disease Control. Management of patients with suspected viral hemorrhagic fever. MMWR Suppl 1988; 37 : 1-6.  Back to cited text no. 85
    
86.
Mishra AC, Mehta M, Mourya DT, Gandhi S. Crimean-Congo haemorrhagic fever in India. Lancet 2011; 378 : 372.  Back to cited text no. 86
    
87.
Yadav PD, Gurav YK, Mistry M, Shete AM, Sarkale P, Deoshatwar AR, et al. Emergence of Crimean-Congo hemorrhagic fever in Amreli district of Gujarat state, India, June to July 2013. Int J Infect Dis 2014; 18 : 97-100.  Back to cited text no. 87
    
88.
Mourya DT, Yadav PD, Shete AM, Sathe PS, Sarkale PC, Pattnaik B, et al. Cross-sectional serosurvey of Crimean-Congo hemorrhagic fever virus IgG in livestock, India, 2013-2014. Emerg Infect Dis 2015; 21 : 1837-9.  Back to cited text no. 88
    
89.
Appannanavar SB, Mishra B. An update on crimean congo hemorrhagic fever. J Glob Infect Dis 2011; 3 : 285-92.  Back to cited text no. 89
    
90.
World Research and Development Blueprint. 2018 Annual review of diseases prioritized under the Research and Development Blueprint: Informal Consultation. Geneva: WHO; 2018. Available from: http://www.who.int/emergencies/diseases/2018prioritization-report.pdf?ua=1, accessed on April 11, 2019.  Back to cited text no. 90
    
91.
Munivenkatappa A, Sahay RR, Yadav PD, Viswanathan R, Mourya DT. Clinical & epidemiological significance of Kyasanur forest disease. Indian J Med Res 2018; 148 : 145-50.  Back to cited text no. 91
    
92.
Mourya D, Yadav P, Patil D. Highly infectious tick-borne viral diseases: Kyasanur forest disease and Crimean-Congo hemorrh agic fev er in India. WHO South East Asia J Public Health 2014; 3 : 8-21.  Back to cited text no. 92
    
93.
Kiran SK, Pasi A, Kumar S, Kasabi GS, Gujjarappa P, Shrivastava A, et al. Kyasanur forest disease outbreak and vaccination strategy, Shimoga district, India, 2013-2014. Emerg Infect Dis 2015; 21 : 146-9.  Back to cited text no. 93
    
94.
World Health Organization. Rift Valley fever. Available from: https://www.who.int/news-room/fact-sheets/detail/rift-valley-fever, accessed on April 11, 2019.  Back to cited text no. 94
    
95.
Rift valley fever. Available from: https://web.gideononline.com/web/microbiology/identify_index.php?type=bacteria, accessed on January 15, 2019.  Back to cited text no. 95
    
96.
97.
World Health Organization. Meeting of the immunization strategic advisory group of experts, April 2009 – Conclusions and recommendations. Wkly Epidemiol Rec 2009; 84 : 220-36.  Back to cited text no. 97
    
98.
Chitambar SD, Ranshing SS, Pradhan GN, Kalrao VR, Dhongde RK, Bavdekar AR. Changing trends in circulating rotavirus strains in Pune, Western India in 2009-2012: Emergence of a rare G9P[4] rotavirus strain. Vaccine 2014; 32 (Suppl 1) : A29-32.  Back to cited text no. 98
    
99.
Madeley CR, Cosgrove BP. Caliciviruses in man. Lancet 1976; 307 : 199-200.  Back to cited text no. 99
    
100.
Chiba S, Nakata S, Numata-Kinoshita K, Honma S. Sapporo virus: History and recent findings. J Infect Dis 2000; 181 : S303-8.  Back to cited text no. 100
    
101.
Kang G, Hale AD, Richards AF, Jesudason MV, Estes MK, Brown DWG. Detection of 'Norwalk-like viruses' in Vellore, Southern India. Trans R Soc Trop Med Hyg 2000; 94 : 681-3.  Back to cited text no. 101
    
102.
Girish R, Broor S, Dar L, Ghosh D. Foodborne outbreak caused by a Norwalk-like virus in India. J Med Virol 2002; 67 : 603-7.  Back to cited text no. 102
    
103.
Romani S, Azimzadeh P, Mohebbi SR, Bozorgi SM, Zali N, Jadali F. Prevalence of sapovirus infection among infant and adult patients with acute gastroenteritis in Tehran, Iran. Gastroenterol Hepatol Bed Bench 2012; 5 : 43-8.  Back to cited text no. 103
    
104.
Kapikian AZ, Wyatt RG, Dolin R, Thornhill TS, Kalica AR, Chanock RM. Visualization by immune electron microscopy of a 27-nm particle associated with acute infectious nonbacterial gastroenteritis. J Virol 1972; 10 : 1075-81.  Back to cited text no. 104
    
105.
Hall AJ, Lopman BA, Payne DC, Patel MM, Gastañaduy PA, Vinjé J, et al. Norovirus disease in the United States. Emerg Infect Dis 2013; 19 : 1198-205.  Back to cited text no. 105
    
106.
Chhabra P, Dhongade RK, Kalrao VR, Bavdekar AR, Chitambar SD. Epidemiological, clinical, and molecular features of norovirus infections in Western India. J Med Virol 2009; 81 : 922-32.  Back to cited text no. 106
    
107.
Chhabra P, Chitambar SD. Norovirus genotype IIb associated acute gastroenteritis in India. J Clin Virol 2008; 42 : 429-32.  Back to cited text no. 107
    
108.
Rachakonda G, Choudekar A, Parveen S, Bhatnagar S, Patwari A, Broor S. Genetic diversity of noroviruses and sapoviruses in children with acute sporadic gastroenteritis in New Delhi, India. J Clin Virol 2008; 43 : 42-8.  Back to cited text no. 108
    
109.
Susilawati TN, McBride WJ. Acute undifferentiated fever in Asia: A review of the literature. Southeast Asian J Trop Med Public Health 2014; 45 : 719-26.  Back to cited text no. 109
    
110.
Kulkarni DD, Tosh C, Venkatesh G, Senthil Kumar D. Nipah virus infection: current scenario. Indian J Virol 2013; 24 : 398-408.  Back to cited text no. 110
    
111.
Ang BSP, Lim TCC, Wang L. Nipah virus infection. J Clin Microbiol 2018; 56. pii: e01875-17.  Back to cited text no. 111
    
112.
World Health Organization South-East Asia. Nipah virus outbreaks in the WHO South-East Asia Region. Available from: http://www.searo.who.int/entity/emerging_diseases/links/nipah_virus_outbreaks_sear/en/, accessed on July 21, 2018.  Back to cited text no. 112
    
113.
Broder CC, Xu K, Nikolov DB, Zhu Z, Dimitrov DS, Middleton D, et al. A treatment for and vaccine against the deadly Hendra and Nipah viruses. Antiviral Res 2013; 100 : 8-13.  Back to cited text no. 113
    
114.
Carey DE, Reuben R, Panicker KN, Shope RE, Myers RM. Thottapalayam virus: A presumptive arbovirus isolated from a shrew in India. Indian J Med Res 1971; 59 : 1758-60.  Back to cited text no. 114
    
115.
Armstrong C, Lillie RD. Experimental lymphocytic choriomeningitis of monkeys and mice produced by a virus encountered in studies of the 1933 St. Louis encephalitis epidemic. Public Health Rep 1896-1970 1934; 49 : 1019-27.  Back to cited text no. 115
    
116.
Barton LL, Budd SC, Morfitt WS, Peters CJ, Ksiazek TG, Schindler RF, et al. Congenital lymphocytic choriomeningitis virus infection in twins. Pediatr Infect Dis J 1993; 12 : 942-6.  Back to cited text no. 116
    
117.
Biggar RJ, Woodall JP, Walter PD, Haughie GE. Lymphocytic choriomeningitis outbreak associated with pet hamsters. Fifty-seven cases from New York state. JAMA 1975; 232 : 494-500.  Back to cited text no. 117
    
118.
Manjunath S, Kulkarni PG, Nagavelu K, Samuel RJ, Srinivasan S, Ramasamy N, et al. Seroprevalence of rodent pathogens in India. PLoS One 2015; 10 : e0131706.  Back to cited text no. 118
    
119.
Yu X, Zhang J, Hong L, Wang J, Yuan Z, Zhang X, et al. High prevalence of human parvovirus 4 infection in HBV and HCV infected individuals in Shanghai. PLoS One 2012; 7 : e29474.  Back to cited text no. 119
    
120.
Fryer JF, Delwart E, Hecht FM, Bernardin F, Jones MS, Shah N, et al. Frequent detection of the parvoviruses, PARV4 and PARV5, in plasma from blood donors and symptomatic individuals. Transfusion 2007; 47 : 1054-61.  Back to cited text no. 120
    
121.
Asiyabi S, Nejati A, Shoja Z, Shahmahmoodi S, Jalilvand S, Farahmand M, et al. First report of human parvovirus 4 detection in Iran. J Med Virol 2016; 88 : 1314-8.  Back to cited text no. 121
    
122.
Benjamin LA, Lewthwaite P, Vasanthapuram R, Zhao G, Sharp C, Simmonds P, et al. Human parvovirus 4 as potential cause of encephalitis in children, India. Emerg Infect Dis 2011; 17 : 1484-7.  Back to cited text no. 122
    
123.
Chakravarty A, Kashyap B, Rathi K. The seroepidemiological study on cytomegalovirus in women of child-bearing age with special reference to pregnancy and maternal-fetal transmission. Indian J Pathol Microbiol 2005; 48 : 518-21.  Back to cited text no. 123
    
124.
Riley HD Jr. History of the cytomegalovirus. South Med J 1997; 90 : 184-90.   Back to cited text no. 124
    
125.
Mustakangas P, Sarna S, Ammälä P, Muttilainen M, Koskela P, Koskiniemi M. Human cytomegalovirus seroprevalence in three socioeconomically different urban areas during the first trimester: A population-based cohort study. Int J Epidemiol 2000; 29 : 587-91.  Back to cited text no. 125
    
126.
Brown HL, Abernathy MP. Cytomegalovirus infection. Semin Perinatol 1998; 22 : 260-6.  Back to cited text no. 126
    
127.
Ross DS, Dollard SC, Victor M, Sumartojo E, Cannon MJ. The epidemiology and prevention of congenital cytomegalovirus infection and disease: Activities of the Centers for Disease Control and Prevention Workgroup. J Womens Health 2006; 15 : 224-9.  Back to cited text no. 127
    
128.
Mathur A, Jindal I, Chaturvedi UC. A serological study of cytomegalovirus infection at Lucknow. Indian J Med Res 1981; 73 : 678-81.  Back to cited text no. 128
    
129.
Kumar M, Nizam MB, Hugunthan M. Seroprevalence of cytomegalovirus infection in antenatal women in a Tertiary Care Center in Western India. J Marine Med Society 2017; 19 : 51-4.  Back to cited text no. 129
    
130.
Bhatt PN, Rodrigues FM. Chandipura: A new arbovirus isolated in India from patients with febrile illness. Indian J Med Res 1967; 55 : 1295-305.  Back to cited text no. 130
    
131.
Ba Y, Trouillet J, Thonnon J, Fontenille D. Phlebotomus of Senegal: Survey of the fauna in the region of Kedougou. Isolation of arbovirus. Bull Soc Pathol Exot 1999; 92 : 131-5.  Back to cited text no. 131
    
132.
Sudeep AB, Gurav YK, Bondre VP. Changing clinical scenario in Chandipura virus infection. Indian J Med Res 2016; 143 : 712-21.  Back to cited text no. 132
    
133.
Xu B, Liu L, Huang X, Ma H, Zhang Y, Du Y, et al. Metagenomic analysis of fever, thrombocytopenia and leukopenia syndrome (FTLS) in Henan province, China: Discovery of a new bunyavirus. PLoS Pathog 2011; 7 : e1002369.  Back to cited text no. 133
    
134.
Takahashi T. Severe fever with thrombocytopenia syndrome (SFTS) and SFTS virus. Uirusu 2015; 65 : 7-16.  Back to cited text no. 134
    
135.
Mourya DT, Yadav PD, Basu A, Shete A, Patil DY, Zawar D, et al. Malsoor virus, a novel bat Phlebovirus, is closely related to severe fever with thrombocytopenia syndrome virus and heartland virus. J Virol 2014; 88 : 3605-9.  Back to cited text no. 135
    
136.
Beran GW, editor. Zoonoses caused by Reoviridae. In: Handbook of zoonoses, 2nd ed. Boca Raton, Florida: CRC Press; 1994.  Back to cited text no. 136
    
137.
Karabatsos N. International catalogue of arboviruses including certain other viruses of vertebrates, 3rd ed. San Antonio, TX, USA: American Society of Tropical Medicine and Hygiene; 1985.  Back to cited text no. 137
    
138.
Dhama K, Pawaiya RVS, Karthik K, Chakraborty S, Tiwari R, Verma AK. Equine encephalosis virus (EEV): A review. Asian J Animal Vet Adv 2014; 9 : 123-33.  Back to cited text no. 138
    
139.
Paweska JT, Gerdes GH, Woods PS, Williams R. Equine encephalosis in Southern Africa: Current situation. In: Wernery U, Wade JF, Mumford JA, Kaaden OR, editors. Equine infectious diseases. Newmarket, UK: R and W Publication; 1999. p. 303-5.  Back to cited text no. 139
    
140.
Hughes AL, Irausquin S, Friedman R. The evolutionary biology of poxviruses. Infect Genet Evol 2010; 10 : 50-9.  Back to cited text no. 140
    
141.
Moss B. Poxviridae: The viruses and their replication. In: Knipe DM, Howley PM. Field's virology, 4th ed. Philadelphia: Lippincott Raven; 2001. p. 2849-83.  Back to cited text no. 141
    
142.
Haller SL, Peng C, McFadden G, Rothenburg S. Poxviruses and the evolution of host range and virulence. Infect Genet Evol 2014; 21 : 15-40.  Back to cited text no. 142
    
143.
Fang Q, Yang L, Zhu W, Liu L, Wang H, Yu W, et al. Host range, growth property, and virulence of the smallpox vaccine: Vaccinia virus Tian Tan strain. Virology 2005; 335 : 242-51.  Back to cited text no. 143
    
144.
Food and Agricultural Organization/World Health Organization. Third report. WHO technical report series. Geneva: World Health Organization; 1967. p. 378.  Back to cited text no. 144
    
145.
Singh RK, Hosamani M, Balamurugan V, Bhanuprakash V, Rasool TJ, Yadav MP. Buffalopox: An emerging and re-emerging zoonosis. Anim Health Res Rev 2007; 8 : 105-14.  Back to cited text no. 145
    
146.
Prabhu M, Yogisharadhya R, Pavulraj S, Suresh C, Sathish G, Singh RK. Camelpox and Buffalopox: Two emerging and re-emerging orthopox viral diseases of India. Adv Anim Vet Sci 2015; 3 : 527-41.  Back to cited text no. 146
    
147.
Bhanuprakash V, Venkatesan G, Balamurugan V, Hosamani M, Yogisharadhya R, Gandhale P, et al. Zoonotic infections of Buffalopox in India. Zoonoses Public Health 2010; 57 : e149-55.  Back to cited text no. 147
    
148.
Gurav YK, Raut CG, Yadav PD, Tandale BV, Sivaram A, Pore MD, et al. Buffalopox outbreak in humans and animals in Western Maharashtra, India. Prev Vet Med 2011; 100 : 242-7.  Back to cited text no. 148
    
149.
Zafar A, Swanepoel R, Hewson R, Nizam M, Ahmed A, Husain A, et al. Nosocomial Buffalopoxvirus infection, Karachi, Pakistan. Emerg Infect Dis 2007; 13 : 902-4.  Back to cited text no. 149
    
150.
Claude KM, Underschultz J, Hawkes MT. Ebola virus epidemic in war-torn eastern DR Congo. Lancet 2018; 392 : 1399-401.  Back to cited text no. 150
    
151.
Yu X, Jin T, Cui Y, Pu X, Li J, Xu J, et al. Influenza H7N9 and H9N2 viruses: Coexistence in poultry linked to human H7N9 infection and genome characteristics. J Virol 2014; 88 : 3423-31.  Back to cited text no. 151
    
152.
Jöst H, Bialonski A, Maus D, Sambri V, Eiden M, Groschup MH, et al. Isolation of Usutu virus in Germany. Am J Trop Med Hyg 2011; 85 : 551-3.  Back to cited text no. 152
    
153.
Eyngor M, Zamostiano R, Kembou Tsofack JE, Berkowitz A, Bercovier H, Tinman S, et al. Identification of a novel RNA virus lethal to tilapia. J Clin Microbiol 2014; 52 : 4137-46.  Back to cited text no. 153
    
154.
Garigliany MM, Hagen RM, Frickmann H, May J, Schwarz NG, Perse A, et al. Cyclovirus cyCV-VN species distribution is not limited to Vietnam and extends to Africa. Sci Rep 2014; 4 : 7552.  Back to cited text no. 154
    
155.
Reuter G, Boros A, Delwart E, Pankovics P. Novel seadornavirus (family reoviridae) related to banna virus in Europe. Arch Virol 2013; 158 : 2163-7.  Back to cited text no. 155
    


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