History of Mass Transportation: The Diesel Multiple Unit 844.001 ČD in Cerhenice

 

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By PetrS. - Own work, CC BY-SA 3.0, https://commons.wikimedia.org/w/index.php?curid=19896613

Source: 

Link: https://en.wikipedia.org/wiki/List_of_Czech_locomotive_classes

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Cardsharps (I Bari), Caravaggio (c.1594)

 

{Click on Image to Enlarge}

Public Domain.

Source: 

Link: https://www.wikiart.org/en/caravaggio/cardsharps-1594-1

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History of Mass Transportation: The Romanian CFR 77-0913-2 Autorail at Pitești Station

 {Click on Image to Enlarge}

By Ștefan Pușcașu - http://cfr.stfp.net/?op=C&class=77, Public Domain, https://commons.wikimedia.org/w/index.php?curid=25390809

Source: 

Link: https://en.wikipedia.org/wiki/Rolling_stock_of_the_Romanian_Railways

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#Coronavirus Disease Research #References (AMEDEO, May 2 '26)

 

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    Science

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#Influenza and Other Respiratory Viruses Research #References (AMEDEO, May 2 '26)

 

Biochem Biophys Res Commun

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   Epidemiol Infect

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   J Immunol

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   J Infect Dis

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    Proc Natl Acad Sci U S A

30. RODRIGUEZ HERNANDEZ CJ, Cruz-Cruz A, Shrestha CL, Terekhova M, et al
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32. ZHANG Y, Wang C, Zheng Y, Chen F, et al
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    Vaccine

34. LIU Y, Jia M, Mu X, Jiang B, et al
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35. SILVA LL, Lopes VDS, da Silva DCB, Nemer CRB, et al
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36. JAMES E, Christie S, Boye B, Githieya D, et al
    How to leverage social media to build confidence in COVID-19 vaccines: findings and lessons learned from nationwide campaigns in four countries.
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37. MALDEN DE, Ackerson BK, Gee J, Peryer MA, et al
    Self-reported reactogenicity of RSV vaccines among older adults: a post-licensure study within a large integrated healthcare system in Southern California.
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38. FANTIN R, Das S, Loria V, Calderon A, et al
    Hybrid immunity provides stronger protection against SARS-CoV-2 infection than vaccination alone: Evidence from a population-based active monitoring study.
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39. DENG L, Barton B, Choi P, Clarke L, et al
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40. BRIGGS K, Gingerich MC, Gingerich A, Johnson SK, et al
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41. AZEEZ R, Ames SR, Lotoski LC, Winsor GL, et al
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42. ROOYAKKERS A, Ye L, Cahn PE, Ruiz-Palacios GM, et al
    Relative efficacy, safety, and immunogenicity analysis of two doses versus one dose of recombinant coronavirus vaccine (adenovirus type 5 vector) in adults 18 years and older: an international, multicentre, randomized, double blinded phase 3 trial.
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43. STRAUTINS K, Foong R, Carcione D, Spencer P, et al
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44. AIZAWA Y, Shobugawa Y, Tachikawa J, Ikuse T, et al
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45. LLOYD PC, Shah PB, Zhang HT, Shah N, et al
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46. MADNI SA, Olson CK, Zauche LH, Machefsky A, et al
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47. GIOVANATTI A, Shapiro AE
    Anticipating tuberculosis vaccine acceptability in Kenya and South Africa: a narrative review of behavioral and social drivers and strategies to optimize acceptability.
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48. GUARDALINI LGO, Martins IM, Bernardino TC, Quintilio W, et al
    Non-clinical analysis of virus-like particles (VLP) containing SARS-CoV-2 vaccine antigens.
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49. DURIER C, Benhamouda N, Besbes A, Lefebvre M, et al
    Ancestral Wuhan SARS-CoV-2 anti-spike CD4(+) T cells predict protection from symptomatic omicron breakthrough infection.
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50. VISKUPIC F, Wiltse DL, Liebl Z, Kinslow T, et al
    The prevalence and nature of anti-vaccination legislation in ten midwestern states: Implications for public health and policy.
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51. DRISLANE S, Lake J, Attwell K
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52. CABIESES B, Obach A, Madrid P, Blukacz A, et al
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53. LU PJ, Hung MC, Srivastav A, Kriss JL, et al
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58. MCEVOY R, Hervol JR, Zhang Y, Wagner EM, et al
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Rapid #risk #assessment: #Chikungunya virus disease, #Global (WHO, 24 April 2026, v2, summary)

{Summary)

Overall Risk statement

-- This rapid risk assessment aims to assess the overall public health risk posed by chikungunya virus (CHIKV) transmission in 2026 at the global level. 

-- It considers the potential risk to human health, the likelihood of geographical spread, limitations in prevention and control capacities, and the influence of regional seasonal patterns that favour Aedes mosquito activity, which could drive outbreaks during the 2026 transmission season. 

-- Chikungunya virus poses a significant and growing global health risk due to large and widespread regional outbreaks in recent years, lack of specific treatment, limited use of vaccine, and climate- and conveyance-driven mosquito range expansion, with increasing international travel. 

-- While mortality remains relatively low, the CHIKV infection can cause prolonged arthritis with disability as well as severe illness in some patients.

-- In 2025, an overall of 502 264 CHIKV disease cases including 208 335 confirmed cases, and 186 deaths were reported globally from 41 countries and territories, including autochthonous and imported cases in travellers. 

-- From 1 January to 31 March 2026, Chikungunya transmission was reported by 18 countries, with the vast majority of cases occurring in the Region of the Americas. 

-- Brazil and Bolivia account for 87% of cases in the Region; together with Argentina, Suriname, and Cuba, these five countries represent approximately 99% of reported cases. 

-- The European Region reported the second-highest number of cases, predominantly reported from French overseas departments, particularly Mayotte and La Réunion. 

-- Global aggregation is limited due to incomplete reporting.

-- With the rainy season about to begin in many regions in the coming months, cases of CHIKV are expected to rise, as rainfall events create favourable conditions for Aedes mosquito breeding and increase the risk of CHIKV transmission, including in previously unaffected areas. 

-- Transmission dynamics will also be impacted by the population immunity acquired from outbreaks in recent years. 

-- Peak CHIKV transmission months in the respective WHO regions include:

• Southeast Asia & Western Pacific: May–October

• Americas: May–November (Northern hemisphere)/November–March (Southern hemisphere)

• Continental Europe: June–September (main season) (transmission in overseas departments aligns with climatic conditions within their geographic location/proximity)

• Africa & Eastern Mediterranean: During/after local rainy seasons (varies by country)

-- The global public health risk posed by CHIKV transmission is assessed as moderate. 

-- This takes into account the widespread transmission and outbreaks across multiple WHO regions in 2025, which continued into early 2026, including in areas with previously low or no transmission. 

-- Ongoing transmission in parts of the Indian Ocean region, such as Seychelles, Mauritius and Mayotte demonstrates continued regional activity. 

-- The resurgence and emergence of cases in new geographic areas are facilitated by the presence of competent Aedes mosquito vectors, limited population immunity, favorable environmental conditions, and increased human mobility coupled with under-performing/disrupted health systems, particularly in fragile, conflict-affected and vulnerable countries- leading to poor control measures.

-- The uneven distribution of cases across regions complicates the interpretation of a global trend but highlights significant localized transmission. 

-- Prevention and control capacities remain challenged by gaps in surveillance, equitable access to quality-assured diagnostics and laboratory confirmation, healthcare infrastructure, and sustained vector surveillance and control management.

(...)

Source: 

Link: https://www.who.int/publications/m/item/who-rapid-risk-assessment---chikungunya-virus-disease--global-v.2

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#Replication Efficiency of Contemporary Highly Pathogenic Avian #Influenza #H5N1 Virus Isolates in #Human #Nasal Epithelium Model

 

Abstract

Replication of influenza A virus in human nasal epithelium affects transmissibility and disease. We compared virus replication and immune responses in human nasal epithelium infected with seasonal and highly pathogenic avian influenza A(H5N1) viruses. Contemporary H5N1 viruses replicated better than the historical isolate; however, interferon response to B3.13 genotype viruses was dampened.

Source: 

Link: https://wwwnc.cdc.gov/eid/article/32/5/26-0053_article

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Severe Respiratory Illness and Death Associated with #Outbreak of #Human #Rhinovirus B14 among Older Adults, #France, 2024

 

Abstract

We investigated an outbreak of unknown respiratory disease and 8 deaths among older adults in a long-term care facility in France. We identified human rhinovirus (HRV) by quantitative PCR and HRV-B14 by metagenomics. We obtained 5 HRV-B14 genomes that diverged from 5 publicly available genomes. Real-time metagenomics could enable rapid clinical diagnoses.

Source: 

Link: https://wwwnc.cdc.gov/eid/article/32/5/25-0981_article

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#Human #infections with avian #influenza #H5 viruses with potential #pandemic #risk: 1997–2025

 

ABSTRACT

Highly pathogenic avian influenza (HPAI) A(H5) viruses have caused sporadic human infections since 1997, with recent detections in the Americas and Asia. However, the evolutionary dynamics of different HPAI A(H5) viruses at the animal–human interface, along with their associated disease severity, propensity for animal-to-human (zoonotic) spillover, and human-to-human transmission potential, remain unclear. Here, we combine available genetic and epidemiological data with mechanistic models to better understand the global spread of HPAI A(H5) viruses that spilled over to humans in 1997–2025. Analysis of 7445 subsampled hemagglutinin gene sequences revealed frequent regional succession of HPAI A(H5) virus clades that varied by geographic location. The 1104 reported human HPAI A(H5) cases exhibited subtype- and clade-specific heterogeneity in age, gender, and exposure sources (p < 0.001). After adjusting for under-reporting, we estimated case-fatality risk to be low for HPAI A(H5N1) clade 2.3.4.4b (0.7%, 95%CI: 0.02%–3.9%) and for A(H5N6) clades 2.3.4x (0%, 0%–1.1%) and 2.3.4.4b (1.6%, 0.7%–3.2%), compared with other A(H5) clades (range: 4.7%–15.0%). We also show that, while the transmissibility of HPAI A(H5) viruses between humans remains very low to date (mean Rt: 0.10–0.23), zoonotic transmission has increased with the emergence of bovine-origin clade 2.3.4.4b (incidence: 7.85 per million people per year), relative to other avian-origin A(H5) clades (range: 1.54–5.04 per million people per year). Although other factors such as exposure sources, routes of transmission, immune function, underlying medical conditions, and clinical management can influence outcomes of case-patients, these findings highlight the ongoing pandemic threat posed by HPAI A(H5) viruses and the need for ongoing comprehensive surveillance, genotypic and phenotypic characterization, and preparedness.

Source: 

Link: https://academic.oup.com/nsr/article/13/7/nwaf471/8317928

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#USA, #Wastewater Data for Avian #Influenza #H5 (CDC, May 1 '26)

 

{Excerpt}

(...)

Time Period: April 19, 2026 - April 25, 2026

-- A(H5) Detection: 11 site(s) (2.6%)

-- No Detection: 414 site(s) (97.4%)

-- No samples: 117 site(s)

{Click on Image to Enlarge}

(...)

Source: 

Link: https://www.cdc.gov/wastewater/emerging-viruses/h5.html?

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Mechanistic #modelling of highly pathogenic avian #influenza: A scoping #review revealing critical gaps in cross-species #transmission models

 

Abstract

Background

Highly pathogenic avian influenza (HPAI) viruses, particularly subtypes such as H5N1 and H7N9, have caused widespread outbreaks in wild birds, poultry, livestock and occasionally humans, raising concerns about cross-species transmission and pandemic potential. Effective control and surveillance strategies require a thorough understanding of HPAI transmission dynamics, which can be supported by mathematical modelling.

Objective

This scoping review aimed to identify mechanistic models used to study HPAI transmission. Specifically, we sought to categorize model types, describe their application contexts (e.g., wild birds, poultry, livestock, and humans), and highlight modelling gaps relevant to understanding and mitigating the risks of HPAI spread.

Methods

Following PRISMA guidelines and the PRISMA extension for scoping reviews (PRISMA-ScR), we conducted systematic searches of PubMed and Web of Science to identify peer-reviewed studies employing deterministic and stochastic models to analyze HPAI transmission. Eligible articles published between January 2023 and June 2025 were screened and grouped by model structure, host populations, transmission pathways, and modelling objectives.

Results

After screening, 30 studies published after 2023 were included in this scoping review. Compartmental models were the most common (26 studies), with 16 deterministic and 10 stochastic approaches. These models were primarily used to describe transmission among wild birds, poultry, livestock, and humans and to evaluate interventions such as culling, vaccination, and movement restrictions. Agent-based models (2 studies) captured individual-level interactions and spatial heterogeneity, while network models (2 studies) represented contact structures and transmission pathways between farms or species.

Conclusions

Currently, mechanistic modelling of HPAI is dominated by compartmental approaches, including both deterministic and stochastic formulations, whereas agent-based and network models remain relatively underused. Although most studies focus on transmission in wild birds and poultry, and in some cases spillover infections to humans, few explicitly examine infection dynamics in livestock or in transmission between livestock and humans, despite the importance of livestock (e.g., cattle) as potential intermediaries in human infection. Key gaps persist in the integration of empirical data, representation of multi-host interactions, and evaluation of realistic intervention strategies. Addressing these limitations is essential to improve predictive accuracy and to strengthen the role of modelling in informing HPAI surveillance and control.

Source: 

Link: https://journals.plos.org/plosone/article?id=10.1371/journal.pone.0347929

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Prior #immunity to seasonal #influenza #H3N2 virus confers varying levels of cross - #protection against challenge with clade 2.3.4.4b #H5N1, #H7N9, or #H9N2 virus in a #ferret model

 

ABSTRACT

Evaluating how prior immunity to seasonal influenza viruses influences subsequent zoonotic influenza A virus (IAV) infection in animal models is critical for pandemic preparedness. In this study, we investigated the cross-protective effect of pre-existing A(H3N2) immunity in ferrets challenged with three distinct subtypes of zoonotic IAVs: low pathogenic A(H7N9) and A(H9N2) viruses, and highly pathogenic clade 2.3.4.4b A(H5N1) virus. Our results show that A(H3N2) preimmunity conferred some protection against A(H5N1) and A(H9N2) virus infection, as evidenced by more rapid viral clearance in the upper respiratory tract, reduced virus shedding in the nasal wash on select days post-inoculation, and a lowered frequency of viral detection in specific tissues compared with naive animals. In contrast, A(H3N2) preimmunity provided minimal cross-protection against A(H7N9) infection, as weight loss and viral dissemination in tissues were not significantly reduced in A(H3N2) preimmune ferrets relative to naive animals. These findings highlight the variable breadth and magnitude of cross-protection elicited by prior seasonal IAV immunity against zoonotic influenza virus challenges in the ferret model. Seasonal influenza A(H3N2) preimmunity provided differing levels of cross-protection against zoonotic influenza A virus infections in ferrets.

Source: 

Link: https://journals.asm.org/doi/10.1128/spectrum.03974-25

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#France - High pathogenicity avian #influenza #H5N1 viruses (Inf. with) (#poultry) - Immediate notification

 

{Tarn-et-GaronneRegion} Gallus gallus and vaccinated ducks. Clinical signs on Gallus gallus.

{Dordogne} A poultry farm.

Source: 

Link: https://wahis.woah.org/#/in-review/7521

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Emergence and #Evolution of Triple #Reassortant Highly Pathogenic Avian #Influenza #H5N1 Virus, #Argentina, 2025

 

Abstract

The H5N1 subtype of highly pathogenic avian influenza (HPAI) poses a major zoonotic threat due to its high fatality rate and capacity for cross species transmission. In early 2025, Argentina detected a novel triple reassortant A(H5N1) virus in Chaco Province, combining Eurasian, North American, and South American lineage segments. Genomic analyses of subsequent outbreaks in Buenos Aires and Entre Ríos confirmed persistence of this reassortant and additional HA substitutions (T204K, P251S) potentially linked to increased mammalian receptor affinity. Although PB2 sequences lacked canonical mammalian-adaptive markers (E627K, Q591K, D701N), all contained I292M, a mutation associated with human adaptation. Phylogenetic analyses revealed distinct genotypes and increasing divergence. These findings indicate ongoing viral evolution and adaptation within Argentina, emphasizing the urgent need for sustained genomic surveillance, timely data sharing, and integrated One Health strategies to mitigate zoonotic and socioeconomic risks associated with H5N1 spread in South America.

Source: 

Link: https://www.mdpi.com/1999-4915/18/5/525

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Characterizing #viral #clearance kinetics in acute #influenza

 

Abstract

Pharmacometric assessment of antiviral efficacy in acute influenza informs treatment decisions and pandemic preparedness. We characterized natural viral clearance in acute influenza to guide phase II trial design using simulations based upon observed data. Standardized duplicate oropharyngeal swabs were collected daily over 14 days from 80 untreated low-risk Thai adults, with viral densities measured using quantitative polymerase chain reaction. We evaluated three models to describe viral clearance: exponential, bi-exponential and growth-and-decay. The growth-and-decay model provided the best fit, but the exponential decay model was the most parsimonious. The median viral clearance half-life was 10.3 h (interquartile range (IQR): 6.8–15.4h), varying by influenza type: 9.6 h (IQR: 6.2–13.0 h) for influenza A and 14.0 h (IQR: 10.3–19.3 h) for influenza B. Simulated trials using parameters from the exponential decay model showed that 148 patients per arm provide over 90% power to detect treatments accelerating viral clearance by 40%. Variation in clearance rates strongly impacted the power; doubling this variation would require 232 patients per arm for an antiviral with a 60% effect size. A sampling strategy with four swabs per day reduces the required sample size to 81 per arm while maintaining over 80% power. We recommend this approach to assess and compare current anti-influenza drugs.

This article is part of the Theo Murphy meeting issue ‘Evaluating anti-infective drugs’.

Source: 

Link: https://royalsocietypublishing.org/rstb/article/381/1949/20240351/481559/Characterizing-viral-clearance-kinetics-in-acute

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#Antiviral treatment for #influenza

 

Abstract

Seasonal influenza is a widespread acute respiratory infection that causes significant illness and death worldwide. Two major antiviral classes are neuraminidase inhibitors (NAIs) and polymerase inhibitors. NAIs, including oseltamivir, zanamivir, peramivir and laninamivir, block viral release, while polymerase inhibitors such as baloxavir disrupt viral RNA replication. Early administration within 48 h of symptom onset reduces illness duration, severity and complications, particularly in high-risk groups. Oseltamivir is the most widely studied NAI, demonstrating reduced viral shedding, faster symptom resolution and lower complication rates, though gastrointestinal side effects are common. Higher doses generally do not improve outcomes compared to standard dosing. Zanamivir is more effective against influenza B and is inhibitory for most influenza A viruses resistant to oseltamivir, but the inhaled formulation is less suitable for patients with severe illness or airway disease. Intravenous (IV) zanamivir is approved for hospitalized influenza patients in some countries. Peramivir offers IV treatment options, while laninamivir is mainly used in Japan. Baloxavir shows superior viral load reduction and comparable symptom relief to oseltamivir in outpatients, though resistance variants can emerge. Favipiravir and newer polymerase inhibitors are under investigation. Combination therapies may enhance recovery, with limited evidence. Overall, timely antiviral use is critical to reducing influenza’s burden.

This article is part of the Theo Murphy meeting issue ‘Evaluating anti-infective drugs’.

Source: 

Link: https://royalsocietypublishing.org/rstb/article/381/1949/20240344/481548/Antiviral-treatment-for-influenza

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#Cambodia - High pathogenicity avian #influenza #H5N1 viruses (Inf. with) (#poultry) - Immediate notification

 

On 22 April 2026, an outbreak investigation team visited a backyard poultry farm following reports of illness and mortality suspected to be caused by Avian Influenza (AI). A total of four chicken samples were collected and submitted to NAHPRI/GDAHP for testing of Avian Influenza (H5N1). And on 23 April 2026, laboratory results confirmed that all four chicken samples tested positive for Avian Influenza (H5N1). Additionally, in the same area, one human case of Avian Influenza (H5N1) was confirmed by the Ministry of Health on 22 April 2026.

Source: 

Link: https://wahis.woah.org/#/in-review/7520

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#Orthopoxvirus #Antibodies in Feral #Mammals in #Mpox #Outbreak Areas, #Nigeria, 2021–2022

 

Abstract

We analyzed tissue and serum samples from 124 wild animals from communities with confirmed mpox cases in Nigeria. Tissue samples were PCR-negative, but serum samples from 8 animals (6.45%)—3 feral cats, 4 giant pouched rats, and 1 shrew—revealed Orthopoxvirus antibodies, suggesting these species as probable reservoirs.

Source: 

Link: https://wwwnc.cdc.gov/eid/article/32/5/25-1565_article

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#qRTPCR #Detection of Inactivated #H5 Avian #Influenza Virus in Raw #Milk Samples by Miniaturized Instruments Designed for On-Site Testing

 

Abstract

Highly pathogenic avian influenza virus (HPAIV) of H5 and H7 subtypes has emerged as one of the most important zoonotic pathogens in the 21st century with significant economic consequences. The recent outbreak of H5N1 avian influenza (AI) in dairy cattle highlighted the importance of early detection in managing and mitigating HPAIV outbreaks. A successful high-speed diagnostic response requires rapid site and specimen access, minimal time for test protocols, and prompt communication of the diagnostic results to government officials. A new diagnostic paradigm that consists of miniaturized extractor and qPCR instruments (EZextractor and EZcycler MiniQ), designed for mobile, on-site testing has been compared with a platform of benchtop instruments (QIAGEN RNeasy and QuantStudio 5) for detecting inactivated H5 avian influenza virus (AIV) spiked in raw milk samples. Two sets of experiments were performed: 1) 15 raw milk samples, obtained from 15 different farms, diluted with phosphate-buffered saline and spiked with the virus to reach approximately 10 copies/mcL virus concentration, and 2) raw milk samples from two farms, each spiked with the inactivated AIV H5 followed by 5 series of dilution to reach AIV concentrations of 1000, 100, 10, 1 and 0.1 copies/mcL. Results show that despite the inhibitors in raw milk, AIV in all samples can be detected by both platforms. The MT platform showed higher sensitivity than the benchtop platform: the Ct values from the MT were ~2 units lower than the benchtop Ct values. Our findings demonstrate the robustness of the MT platform for diagnosing AIV H5 in raw milk samples and support its use as an on-site diagnostic for rapid surveillance and response.

Competing Interest Statement

The authors have declared no competing interest.

Funder Information Declared

DiaVac Biotech Co.

Schweitzer Biotech Co.

Source: 

Link: https://www.biorxiv.org/content/10.1101/2025.06.02.657307v3

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Highly Pathogenic Avian #Influenza #H5N1 Clade 2.3.4.4b Virus and Mass #Mortality in Eurasian #Cranes, #Germany, 2025

 

Abstract

In autumn 2025, highly pathogenic avian influenza A(H5N1) clade 2.3.4.4b virus, genotype EA-2024-DI.2.1, caused systemic infections leading to a mass mortality event among the western migrating subpopulation of Eurasian cranes (Grus grus) in Germany. Gregarious behavior at feeding and resting sites likely promoted rapid viral spread within the population.

Source: 

Link: https://wwwnc.cdc.gov/eid/article/32/5/26-0170_article

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