Early rise of West Nile fever in Israel, June 2024.

This report describes an unusual surge of West Nile fever in Israel in June 2024, during which 125 cases were diagnosed, compared with 4 cases on average during June in previous years (2014-23). Of the cases, 64 (62.1%) had neuroinvasive disease and 12 (9.6%) died; the 2024 case fatality rate was not significantly elevated vs the average rate in 2014-23. The early rise could be related to a temperature increase in spring and early summer of 2024.

West Nile virus in India: An update on its genetic lineages.

West Nile virus (WNV) is a rapidly spreading mosquito-transmitted zoonotic flavivirus. Mosquitoes belonging to the genus Culex are incriminated as the principal vectors of the virus, which causes West Nile fever (WNF) in humans. Manifestations of WNF include a mild, self-limiting, flu-like illness, which in severe cases (rare) may progress to encephalitis, resulting in life-threatening consequences. WNV is geographically distributed worldwide, covering Africa, the Americas, Europe, and Asia (except Antarctica). The virus exists in a bird-mosquito transmission cycle in nature, with humans and horses as incidental/accidental hosts. The virus can infect a large variety of hosts worldwide, i.e., about 300 birds and around 70 different mosquito species belonging to several genera. For a long time, it was believed that WNV was not highly virulent and caused only mild infection globally. However, the recent frequent and increasing incidence of clinically severe WNV infections, such as encephalitis in humans and horses with significant mortality, has been reported in the Americas, Europe, and several East Asian countries. The emergence of lineage 2 strains endemic to Africa, with epidemic potential in humans and horses in Europe, is considered a serious global health concern. Although WNV is known to circulate in India since 1952, its re-emergence with severe neuro-invasive pathogenic potential in humans in Assam, Kerala, West Bengal and Tamil Nadu states signals urgent efforts to understand the dynamics of circulating strains with regard to its vector, hosts, and environment. This could be done by prioritizing "One Health" approach for developing effective preventive and control strategies. In view of the global interest, we present an overview of the circulating genetic lineages of WNV in India in comparison with the global scenario. In addition, we stress on holistic approaches of "One Health" strategy as the current need of the hour for designing effective preventive and control strategies in the country.

Epidemiology of human West Nile virus infections in the European Union and European Union enlargement countries, 2010 to 2018.

BackgroundWest Nile virus (WNV) circulates in an enzootic cycle involving mosquitoes and birds; humans are accidental hosts.AimWe analysed human WNV infections reported between 2010 and 2018 to the European Centre for Disease Prevention and Control to better understand WNV epidemiology.MethodsWe describe probable and confirmed autochthonous human cases of WNV infection reported by European Union (EU) and EU enlargement countries. Cases with unknown clinical manifestation or with unknown place of infection at NUTS 3 or GAUL 1 level were excluded from analysis.ResultsFrom southern, eastern and western Europe, 3,849 WNV human infections and 379 deaths were reported. Most cases occurred between June and October. Two large outbreaks occurred, in 2010 (n = 391) and in 2018 (n = 1,993). The outbreak in 2018 was larger than in all previous years and the first cases were reported unusually early. The number of newly affected areas (n = 45) was higher in 2018 than in previous years suggesting wider spread of WNV.ConclusionReal-time surveillance of WNV infections is key to ensuring that clinicians and public health authorities receive early warning about the occurrence of cases and potential unusual seasonal patterns. Human cases may appear shortly after first detection of animal cases. Therefore, public health authorities should develop preparedness plans before the occurrence of human or animal WNV infections.

Unprecedented increase of West Nile virus neuroinvasive disease, Spain, summer 2020.

Cases of West Nile neuroinvasive disease (WNND) in Spain increased in summer 2020. Here we report on this increase and the local, regional and national public health measures taken in response. We analysed data from regional surveillance networks and the National Epidemiological Surveillance Network, both for human and animal West Nile virus (WNV) infection. During the 2020 season, a total of 77 human cases of WNV infection (median age 65 years; 60% males) were detected in the south-west of Spain; 72 (94%) of these cases developed WNND, presenting as meningoencephalitis, seven of which were fatal. In the previous two decades, only six human cases of WNND were detected in Spain. Reduced activities for vector control this season, together with other factors, might have contributed to the massive increase. Public health measures including vector control, campaigns to raise awareness among physicians and the general population, and interventions to ensure the safety of donations of blood products, organs, cells and tissues were effective to reduce transmission. Going forward, maintenance of vector control activities and an update of the vector-borne diseases response plan in Spain is needed.

West Nile Virus in Farmed Crocodiles, Zambia, 2019.

We detected West Nile virus (WNV) nucleic acid in crocodiles (Crocodylus niloticus) in Zambia. Phylogenetically, the virus belonged to lineage 1a, which is predominant in the Northern Hemisphere. These data provide evidence that WNV is circulating in crocodiles in Africa and increases the risk for animal and human transmission.

Autochthonous West Nile virus infection outbreak in humans, Leipzig, Germany, August to September 2020.

Following a distinct summer heat wave, nine autochthonous cases of West Nile fever and West Nile neuroinvasive disease, including one fatality, were observed in Leipzig, Germany, in August and September 2020. Phylogenetic analysis demonstrated close relationships in viruses from humans, animals and mosquitos in eastern Germany, obtained during the preceding 2 years. The described large cluster of autochthonous West Nile virus infections in Germany indicates endemic seasonal circulation of lineage 2 viruses in the area.

Detection of West Nile virus in a common whitethroat (Curruca communis) and Culex mosquitoes in the Netherlands, 2020.

On 22 August, a common whitethroat in the Netherlands tested positive for West Nile virus lineage 2. The same bird had tested negative in spring. Subsequent testing of Culex mosquitoes collected in August and early September in the same location generated two of 44 positive mosquito pools, providing first evidence for enzootic transmission in the Netherlands. Sequences generated from the positive mosquito pools clustered with sequences that originate from Germany, Austria and the Czech Republic.

Arthropod-Borne Disease Control at a Glance: What's New on Drug Development?

Discovering and validating effective drugs to manage arthropod-borne diseases (ABD) is a timely and important research challenge with major impacts on real-world control programs at the time of quick resistance development in the targeted pathogens. This editorial highlights major research advances in the development of drugs for the control of vector-borne diseases, with a significant focus on malaria, Chagas disease, dengue, human African trypanosomiasis, leishmaniasis, and Zika. Broad reviews providing new insights on ABD recently published in Molecules have also been covered in "The Editors' pick" section.

West Nile Virus Infection in Travelers Returning to United Kingdom from South Africa.

West Nile virus (WNV) is an arthropod-transmitted flavivirus that causes West Nile fever and may infrequently cause neuroinvasive disease in humans. We present 2 cases of confirmed WNV infection, 1 of severe encephalitis and 1 of mild febrile illness, in a couple returning to the United Kingdom from South Africa.

Economic Burden of West Nile Virus Disease, Quebec, Canada, 2012-2013.

The economic burden of West Nile virus (WNV) infection is not known for Canada. We sought to describe the direct and indirect costs of WNV infection in the province of Quebec, Canada, up to 2 years after onset of signs and symptoms. We conducted a retrospective cohort study that included WNV cases reported during 2012 and 2013. For 90 persons infected with WNV, persons with encephalitis accounted for the largest proportion of total cost: a median cost of $21,332 per patient compared with $8,124 for West Nile meningitis (p = 0.0004) and $192 for West Nile fever (p<0.0001). When results were extrapolated to all reported WNV patients, the estimated total cost for 124 symptomatic cases was ≈$1.7 million for 2012 and that for 31 symptomatic cases was ≈$430,000 for 2013. Our study provides information for the government to make informed decisions regarding public health policies and infectious diseases prevention and control programs.

Cumulative Incidence of West Nile Virus Infection, Continental United States, 1999-2016.

Using reported case data from ArboNET and previous seroprevalence data stratified by age and sex, we conservatively estimate that ≈7 million persons in the United States have been infected with West Nile virus since its introduction in 1999. Our data support the need for public health interventions and improved surveillance.

Backbone modifications in peptidic inhibitors of flaviviral proteases.

The NS2B-NS3 protease is a promising target for the development of drugs against dengue virus (DENV), West Nile virus (WNV) and related flaviviruses. We report the systematic variation of the peptide backbone of the two lead compounds Bz-Arg-Lys-d-Phg-NH2 and Bz-Arg-Lys-d-Phg(OBn)-NH2. While inhibitory activity against WNV protease was generally decreased, the inhibitory potency against DENV protease could be conserved and increased in several peptidomimetics, particularly in those containing a (NMe)arginine fragment or an N-terminal α-keto amide. Methylation at the α-position of the C-terminal phenylglycine led to a 6-fold higher potency against DENV protease. Peptidomimetics with modified backbone showed increased resistance against hydrolytic attack by trypsin and α-chymotrypsin.

One Health approach for West Nile virus surveillance in the European Union: relevance of equine data for blood safety.

West Nile virus (WNV) infection is notifiable in humans and equids in the European Union (EU). An area where a human case is detected is considered affected until the end of the mosquito transmission season (week 48) and blood safety measures have to be implemented. We used human and equine case notifications between 2013 and 2017 to define the WNV distribution in the EU and to investigate the relevance of using equine cases as a complementary trigger for blood safety measures. Adding areas with equine cases to the definition of an affected area would have a major impact on blood safety measures. Adding areas with equine cases where human cases have been reported in the past would increase the timeliness of blood safety measures with only a limited impact. Although the occurrence of human and/or equine cases confirms virus circulation in the EU, no evidence was found that occurrence of equine cases leads to human cases and vice versa. We conclude that information about equine data should contribute to raising awareness among public health experts and trigger enhanced surveillance. Further studies are required before extending the definition of affected areas to areas with human and/or equine cases.

Epidemiologic and phylogenetic analysis of the 2018 West Nile virus (WNV) outbreak in Israel demonstrates human infection of WNV lineage I.

As at 12 November 2018, an outbreak of West Nile virus (WNV) was responsible for 139 WNV infection cases in Israel. Here, we characterise the epidemiology of the outbreak and demonstrate that only WNV lineage I was circulating in mosquitoes and responsible for WNV infection in humans. This suggests that the concurrence of the outbreak in Israel with WNV outbreaks in several European countries is not due to a common, more virulent WNV genotype.

West Nile fever - autochthonous human cases in South Moravia in 2018 from the epidemiological perspective.

AIM: To analyse repeated detection of West Nile virus (WNV) in mosquitoes in South Moravia in correlation with the first documented autochthonous human cases of West Nile fever (WNF), focusing on epidemiological and environmental investigation. MATERIALS AND METHODS: Here we report case studies of five patients with autochthonous WNF without any travel history diagnosed in South Moravia in 2018, along with in-depth epidemiological and environmental investigation. The cases were classified as confirmed based on the case definition criteria established in Commission Implementing Decision (EU) 2018/945. RESULTS: Between July and September 2018, a total of five human cases of West Nile virus infection were suspected and subsequently confirmed by the National Reference Laboratory for Arboviruses in Ostrava. All mosquito suspensions from the area where the first case of WNV infection was diagnosed tested WNV negative. CONCLUSIONS: WNV circulation in South Moravia has been known since 1997 when the first human cases (probably caused by WNV lineage 1) were confirmed after floods. The presence of more serious neuroinvasive lineage 2 (WNV-2), now circulating in central and eastern Europe, was detected repeatedly in 2013, 2015, and 2016 in Cx. modestus and Cx. pipiens mosquitoes within the scope of targeted entomological surveillance. These findings were published in 2016-2018 in both the professional press and mass media. It was only a matter of time and of making the correct differential diagnosis in patients with non-specific neuroinfections before there were confirmed autochthonous human cases of WNF caused by WNV-2. These presumptions were corroborated by epidemiological investigations performed by the staff of the Regional Public Health Authority of the South Moravian Region and Academy of Sciences.

WEST NILE VIRUS INFECTION WITH NEUROLOGICAL DISORDERS: A CASE REPORT AND A BRIEF REVIEW OF THE SITUATION IN BULGARIA.

A case of a 66-year-old man with West Nile neuroinvassive disease manifested with fever, weakness, fatigue, consciousness disorders and underlying diabetes mellitus type 2 and cardiovascular diseases is presented. Laboratory data showed elevated erythrocyte sedimentation rate and fibrinogen. Serological tests revealed West Nile virus specific antibodies of class IgM and IgG in serum. West Nile virus RNA was detected in urine sample. Supportive therapy was applied.

Early start of the West Nile fever transmission season 2018 in Europe.

In Europe, surveillance indicates that the 2018 West Nile fever transmission season started earlier than in previous years and with a steeper increase of locally-acquired human infections. Between 2014 and 2017, European Union/European Economic Area (EU/EEA) and EU enlargement countries notified five to 25 cases in weeks 25 to 31 compared with 168 cases in 2018. Clinicians and public health authorities should be alerted to ensure timely implementation of prevention measures including blood safety measures.

West Nile virus outbreak in humans and epidemiological surveillance, west Andalusia, Spain, 2016.

In Andalusia, Spain, West Nile virus (WNV) surveillance takes place from April to November, during the active vector period. Within this area seroconversion to this virus was evidenced in wild birds in 2004, affecting horses and two humans for the first time in 2010. Since 2010, the virus has been isolated every year in horses, and national and regional surveillance plans have been updated with the epidemiological changes found. WNV is spreading rapidly throughout southern Europe and has caused outbreaks in humans. Here we describe the second WNV outbreak in humans in Andalusia, with three confirmed cases, which occurred between August and September 2016, and the measures carried out to control it. Surveillance during the transmission season is essential to monitor and ensure prompt identification of any outbreaks.

Increase in human West Nile and Usutu virus infections, Austria, 2018.

Between 28 June and 17 September 2018, 27 cases of human West Nile virus infections were recorded in Austria; four cases of West Nile neuroinvasive disease, 11 cases of West Nile fever, six infections detected by blood donation screening and six imported cases. In addition, 18 cases of human Usutu virus infections (all blood donors) were recorded. This is the highest number of annual infections recorded in Austria since the introduction of both viruses.

West Nile virus surveillance in Europe: moving towards an integrated animal-human-vector approach.

This article uses the experience of five European countries to review the integrated approaches (human, animal and vector) for surveillance and monitoring of West Nile virus (WNV) at national and European levels. The epidemiological situation of West Nile fever in Europe is heterogeneous. No model of surveillance and monitoring fits all, hence this article merely encourages countries to implement the integrated approach that meets their needs. Integration of surveillance and monitoring activities conducted by the public health authorities, the animal health authorities and the authorities in charge of vector surveillance and control should improve efficiency and save resources by implementing targeted measures. The creation of a formal interagency working group is identified as a crucial step towards integration. Blood safety is a key incentive for public health authorities to allocate sufficient resources for WNV surveillance, while the facts that an effective vaccine is available for horses and that most infected animals remain asymptomatic make the disease a lesser priority for animal health authorities. The examples described here can support other European countries wishing to strengthen their WNV surveillance or preparedness, and also serve as a model for surveillance and monitoring of other (vector-borne) zoonotic infections.