Sunday, July 5, 2026

Woman in an Interior with a Mirror, Carl Holsøe (c.1898)


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Public Domain.

Source: 


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Night, Edvard Munch (1890)

 


{Click on Image to Enlarge}

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Public Domain.

Source: 


Link: https://www.wikiart.org/en/edvard-munch/night-1890

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Cross-neutralization of #SARS-CoV-2 #BA322 #lineage by #JN1 #mRNA #vaccine-induced immunity

 


Highlights (for review)

    • JN.1 mRNA vaccination elicits cross-neutralizing antibodies against BA.3.2.2.

    • BA.3.2.2 is antigenically isolated from all circulating JN.1-descendant variants.

    • Retention of wild-type F456 in BA.3.2.2 preserves class 1/2 antibody epitopes.

    • AZD3152/sipavibart retains potent neutralization against BA.3.2.2.

    • VYD222/pemivibart maintains broad neutralization activity across all variants tested.


Abstract

The SARS-CoV-2 BA.3.2.2 sublineage has emerged globally as the dominant branch of BA.3.2 by late 2025, yet its antigenic relationship with JN.1 vaccine-induced immunity remains unclear. We evaluated neutralizing antibody responses in 25 JN.1 mRNA vaccinees against eight variants, stratified by anti-nucleocapsid antibody serostatus. Post-vaccination titers increased significantly against all variants in both N antibody-negative and -positive groups. Cross-neutralization against BA.3.2.2 was detected in both groups despite lower titers compared to JN.1. Antigenic cartography revealed that BA.3.2.2 was antigenically isolated from all JN.1-descendant variants. AZD3152/sipavibart retained potent neutralization against BA.3.2.2 but completely lost activity against all F456L-harboring JN.1-descendant variants, while VYD222/pemivibart and SA55 maintained broad activity. Retention of wild-type F456 in BA.3.2.2 preserves class 1/2 antibody epitopes, providing a mechanistic basis for cross-neutralization and suggesting a potential therapeutic window for sipavibart should BA.3.2.2 expand globally, pending clinical confirmation.

Source: 


Link: https://www.ijidonline.com/article/S1201-9712(26)00589-8/fulltext

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#Coronavirus Disease Research #References (AMEDEO, July 5 '26)

 


    Ann Intern Med

  1. XIE Y, Choi T, Al-Aly Z
    Adverse Events After Same-Day COVID-19 and Influenza Vaccination Versus Influenza Vaccination Alone : A Target Trial Emulation.
    Ann Intern Med. 2026 Jun 30. doi: 10.7326/ANNALS-26-00217.
    PubMed         Abstract available


  2. Summary for Patients: Adverse Events After Same-Day COVID-19 and Influenza Vaccination Versus Influenza Vaccination Alone.
    Ann Intern Med. 2026 Jun 30. doi: 10.7326/ANNALS-26-00217.
    PubMed        


    BMJ

  3. COZZOLINO A
    Covid-19 vaccine study pulled by US CDC is finally published.
    BMJ. 2026;394:e100157.
    PubMed        


    J Infect

  4. RAN J, Zhu L, Ning M, Zhang W, et al
    Age-associated impairment of humoral and cellular immune responses to SARS-CoV-2 in a large community cohort with hybrid immunity.
    J Infect. 2026 Jul 1:106803. doi: 10.1016/j.jinf.2026.106803.
    PubMed         Abstract available


    J Med Virol

  5. WIDANAGAMAACHCHI WN, Callahan AR, Willson TM, Barbeau B, et al
    How Many Veteran COVID-19 Cases Were There during the Pandemic?
    J Med Virol. 2026;98:e71040.
    PubMed         Abstract available


    J Travel Med

  6. KASSIANOS G, Goodyer L, Gomensoro EEB, Doobaree U, et al
    Assessment of the healthcare burden of dengue disease in England: a retrospective analysis (2010-2023).
    J Travel Med. 2026 Jul 2:taag059. doi: 10.1093.
    PubMed         Abstract available


    J Virol

  7. ZHOU X, Ivanov KI, Ge X, Guo X, et al
    Identification of GRP78 as a novel host factor that facilitates zoonotic porcine deltacoronavirus internalization and replication via clathrin-mediated endocytosis.
    J Virol. 2026 Jul 2:e0071726. doi: 10.1128/jvi.00717.
    PubMed         Abstract available

  8. TIWAREKAR V, Ebenig A, Predota Y, Schrauf S, et al
    Minor differences in the untranslated regions of measles vector additional transcription units are reflected by differential immunogenicity of encoded MERS-CoV Spike antigen.
    J Virol. 2026 Jul 1:e0064426. doi: 10.1128/jvi.00644.
    PubMed         Abstract available

  9. ZHANG L, Li Y, Zhao J, Liang R, et al
    Characterization of nucleolar localization signals in the avian infectious bronchitis virus nucleocapsid protein and their critical role in viral replication.
    J Virol. 2026;100:e0043326.
    PubMed         Abstract available


    JAMA

  10. LEUNG PB, Davis AM, Marks KM
    Antiviral Therapies for Adults With Mild to Moderate COVID-19 Infection.
    JAMA. 2026 Jun 30. doi: 10.1001/jama.2026.6918.
    PubMed        


    Lancet

  11. BLAKNEY AK, Top KA, Cowling BJ, Larson HJ, et al
    Safety and efficacy of mRNA vaccines: a mechanistic and public health perspective.
    Lancet. 2026 Jun 30:S0140-6736(26)00512-X. doi: 10.1016/S0140-6736(26)00512.
    PubMed         Abstract available

#Influenza and Other Respiratory Viruses Research #References (AMEDEO, July 5 '26)

 


    Ann Intern Med


  1. Summary for Patients: Adverse Events After Same-Day COVID-19 and Influenza Vaccination Versus Influenza Vaccination Alone.
    Ann Intern Med. 2026 Jun 30. doi: 10.7326/ANNALS-26-00217.
    PubMed        

  2. XIE Y, Choi T, Al-Aly Z
    Adverse Events After Same-Day COVID-19 and Influenza Vaccination Versus Influenza Vaccination Alone : A Target Trial Emulation.
    Ann Intern Med. 2026 Jun 30. doi: 10.7326/ANNALS-26-00217.
    PubMed         Abstract available


    Antiviral Res

  3. YANG X, Wu L, Wan G, Chen R, et al
    The anti-respiratory syncytial virus activity of biochemicals from Pyrola incarnata.
    Antiviral Res. 2026;252:106473.
    PubMed         Abstract available


    Arch Virol

  4. ALVES MCS, Falcao RM, de Jesus Palmeira OF, de Sa Leitao Paiva-Junior S, et al
    Genomic and epidemiological characterization of SARS-CoV-2 in Northeastern Brazil: a comprehensive analysis (2020-2024).
    Arch Virol. 2025;171:1.
    PubMed         Abstract available

  5. NEHUL S, Nagaraj SK, Narayan R, Singh A, et al
    A novel molecule inhibits SARS-CoV-2 RBD binding to the ACE2 receptor, blocks viral entry and exhibits antiviral activity in a murine model.
    Arch Virol. 2026;171:98.
    PubMed         Abstract available

  6. MOYUE X, Liang S, Ying X, Yang Y, et al
    Research progress of nucleocapsid protein of novel coronavirus: structure, function and targeted therapy.
    Arch Virol. 2026;171:120.
    PubMed         Abstract available

  7. CHEPURNOV A, Miroshnichenko S, Ivanov M, Solomatina M, et al
    Specific features of the infection caused by SARS-CoV-2 variants in Vero cell culture.
    Arch Virol. 2026;171:133.
    PubMed         Abstract available

  8. JONES LR, D'Andrea JS, Levite J, Brito M, et al
    Viral genotype and the pace of epidemic waves: an assessment from SARS-CoV 2 genomics and wastewater surveillance data.
    Arch Virol. 2026;171:163.
    PubMed         Abstract available


    BMC Pediatr

  9. ASAFO-AGYEI SB, Ameyaw E, Nguah SB, Paintsil V, et al
    Immunisation status and clinical outcomes in children admitted to a Paediatric emergency unit in Ghana: a prospective cohort study.
    BMC Pediatr. 2025;25:981.
    PubMed         Abstract available

  10. PU F, Hao YQ
    Impact of COVID-19 epidemic prevention and control measures on the incidence of asthma in children.
    BMC Pediatr. 2026;26:8.
    PubMed         Abstract available

  11. AVSAR H, Bulbul A, Bas EK, Uslu HS, et al
    Maternal-infant vitamin D coupling and neonatal hypocalcemia: a six-year cohort integrating preterm risk, onset timing, and pandemic effects.
    BMC Pediatr. 2026 Jan 27. doi: 10.1186/s12887-026-06532.
    PubMed        

  12. MOHAMMADI R, Barzegar H, Zamani Z, Gorji M, et al
    Hospitalization outcomes and laboratory correlations in pediatric MIS-C patients: a retrospective cross-sectional study in Tehran, Iran.
    BMC Pediatr. 2026;26:205.
    PubMed         Abstract available

  13. MIYAGI Y, Morimoto Y, Satake E, Iwashima S, et al
    Identification of key clinical features for pediatric respiratory syncytial virus infection using machine learning.
    BMC Pediatr. 2026;26:266.
    PubMed         Abstract available

  14. COBAN Y, Evren G, Yildizdas D, Zengin N, et al
    Burden, risk factors, and outcomes respiratory syncytial virus (RSV) infection in pediatric intensive care units in Turkiye (RSVP Study 2020-2024).
    BMC Pediatr. 2026 Mar 5. doi: 10.1186/s12887-026-06562.
    PubMed        

  15. AKALIN H, Kilic A, Ozcetin M, Yildiz I, et al
    The effect of Covid 19 pandemic on childhood obesity in Turkey.
    BMC Pediatr. 2026;26:310.
    PubMed         Abstract available

  16. SCHMIDT L, Feddern S, Kossow A, Niessen J, et al
    Severe acute COVID-19 and early long COVID signals in paediatric cohorts: an analysis of real-world data from two health departments, Germany.
    BMC Pediatr. 2026;26:280.
    PubMed         Abstract available

  17. HANSEN G, Holt T
    RSV bronchiolitis versus COVID-19: could pediatric intensive care units have done more during the pandemic?
    BMC Pediatr. 2026 Apr 11. doi: 10.1186/s12887-026-06850.
    PubMed        


    J Gen Virol

  18. KUOK DIT, Ma APY, Ching RHH, Ng KC, et al
    Assessment of influenza virus and coronavirus tropism, replication competence and disease severity in ex vivo and in vitro cultures of the human respiratory tract.
    J Gen Virol. 2026;107:002281.
    PubMed         Abstract available


    J Virol

  19. LI P, Zheng Y-M, Liu S-L
    Altered infectivity, cell-cell fusion, and immune evasion of SARS-CoV-2 BA.3.2 and LP.8.1 variants.
    J Virol. 2026 May 12:e0001626. doi: 10.1128/jvi.00016.
    PubMed         Abstract available

  20. MCCABE M, Groves HE, Getty E, Campbell E, et al
    Age-dependent expression and antiviral activity of interferon epsilon in respiratory epithelium.
    J Virol. 2026 May 12:e0057825. doi: 10.1128/jvi.00578.
    PubMed         Abstract available

  21. SIVARAJAN R, Kirchgatterer PC, Lawrenz J, Tanner-Matiz E, et al
    Tonic and early interferons defend against respiratory viruses in primary human lung organoid-derived air-liquid interface cultures.
    J Virol. 2026 May 20:e0210425. doi: 10.1128/jvi.02104.
    PubMed         Abstract available

  22. FAN L, Gao X, Feng W, Huang Q, et al
    SARS-CoV-2 ORF3a suppresses host antiviral interferon responses by promoting STUB1-mediated PTEN proteasomal degradation.
    J Virol. 2026 Jun 2:e0018626. doi: 10.1128/jvi.00186.
    PubMed         Abstract available

  23. SUSMA B, Spronken M, van Nieuwkoop S, Kalverda B, et al
    Increased or decreased numbers of CpG dinucleotide motifs in the genome of influenza A virus do not affect in vitro virus phenotype.
    J Virol. 2026 Jun 22:e0004726. doi: 10.1128/jvi.00047.
    PubMed         Abstract available

  24. ZHANG Q, Zhang Y, Sun H, Li H, et al
    Single-cell and spatial transcriptomic profiling reveals distinct immune landscapes in murine lungs infected with H1N1 versus H5N1 influenza viruses.
    J Virol. 2026 Jun 29:e0074626. doi: 10.1128/jvi.00746.
    PubMed         Abstract available

  25. KATO K, Okamura K, Nakamura Y, Iwata M, et al
    Influenza A virus infection induces initial proliferation of commensal Streptococcus pneumoniae in the larynx leading to dissemination into the lower respiratory tract.
    J Virol. 2026 Jun 29:e0055526. doi: 10.1128/jvi.00555.
    PubMed         Abstract available


    Pediatrics

  26. GERHART J, Leister-Tebbe H, Chan PLS, McComsey GA, et al
    Nirmatrelvir/Ritonavir for the Treatment of COVID-19 in Children Aged 6 Years and Older.
    Pediatrics. 2026 Jun 25:e2025073999. doi: 10.1542/peds.2025-073999.
    PubMed         Abstract available

  27. ZMUDA E, Hannon TS, Valentic J
    The Role of the Pediatrician to Promote Effective Approaches for Child and Adolescent Nutrition in Schools: Policy Statement.
    Pediatrics. 2026 Jun 15:e2026077404. doi: 10.1542/peds.2026-077404.
    PubMed         Abstract available

  28. MEHROTRA-VARMA S, Nguyen HQ, Henry S, Collins J, et al
    Long-Term Outcomes of Multisystem Inflammatory Syndrome in Children up to 4.5 Years After COVID-19.
    Pediatrics. 2026;158:e2025075578.
    PubMed         Abstract available


    PLoS One

  29. HUANG L, Wang TM, Sugimoto JD, Heberer KR, et al
    Association of SARS-CoV-2 infection with incident diabetes among U.S. Veterans in a prospective longitudinal cohort.
    PLoS One. 2026;21:e0351992.
    PubMed         Abstract available

  30. ALLARDET-SERVENT J, Hezard N, Pissier C, Bardin N, et al
    Circulating biomarkers of bronchoalveolar injury help predict the need for mechanical ventilation in patients with moderate to severe COVID-19 pneumonia: A prospective cohort study.
    PLoS One. 2026;21:e0337792.
    PubMed         Abstract available

  31. NAZIR A, Shorfuzzaman M, Lotfi ML, Kamalov F, et al
    Forecasting COVID-19 new cases using NBEATS deep learning and mobility data.
    PLoS One. 2026;21:e0350264.
    PubMed         Abstract available

  32. WERTZ E, Babinska M, Batorski D, Louison-Lavoy D, et al
    Ad-based social media interventions increase belief accuracy and generate pro-social opinions among non-news readers.
    PLoS One. 2026;21:e0352588.
    PubMed         Abstract available

  33. HERNANDEZ-ORTIZ BA, Dos Santos TA, Appolinario CM, Arcila-Cardona AM, et al
    Spatial association of seabirds and aquatic birds with highly pathogenic avian influenza (H5N1) outbreaks in Brazil: A nationwide ecological and statistical modelling approach.
    PLoS One. 2026;21:e0350505.
    PubMed         Abstract available

  34. KEARNEY GD, Obi ON, Maddipati V, Levitin G, et al
    Social vulnerability and spatial patterns of COVID-19 mortality: Global implications for respiratory health equity.
    PLoS One. 2026;21:e0352270.
    PubMed         Abstract available

  35. KATUSIIME L, Agbola FW
    Determinants of mobile money loan disbursements: Evidence from Uganda's post pandemic digital credit boom.
    PLoS One. 2026;21:e0338535.
    PubMed         Abstract available

  36. KIERNAN EA, Guzman JD
    Paying in public: Peer effects, impression management, and willingness to pay on digital payment platforms.
    PLoS One. 2026;21:e0340550.
    PubMed         Abstract available


    Proc Natl Acad Sci U S A

  37. CAO J, Liu S, Su C, Wang L, et al
    Genomic and structural evidence of SARS-CoV-2 and MERS-CoV in migratory birds.
    Proc Natl Acad Sci U S A. 2026;123:e2400023123.
    PubMed         Abstract available

  38. METZGER SM, Jones TC, Meier JIJ, Richter A, et al
    Evaluation of a proposed link between the SARS-CoV-2 furin cleavage site and mouse-adapted MERS-coronavirus MA30.
    Proc Natl Acad Sci U S A. 2026;123:e2601806123.
    PubMed         Abstract available

  39. TYLLIS TS, Norton TS, Abbott C, McPeake DJ, et al
    B cell-intrinsic CXCR3 drives efficient generation of ectopic pulmonary germinal center responses to influenza A virus infection.
    Proc Natl Acad Sci U S A. 2026;123:e2535787123.
    PubMed         Abstract available

  40. SOEWONGSONO AC, Thompson A, Landis MJ
    Inferring epidemiological parameters under an infectious phylogeography model with visitor dynamics.
    Proc Natl Acad Sci U S A. 2026;123:e2535042123.
    PubMed         Abstract available


    Vaccine

  41. YADEGARYNIA D, Keyvanfar A, Keyvani H, Tehrani S, et al
    Corrigendum to "Immunogenicity and safety of a quadrivalent recombinant influenza vaccine manufactured in Iran (FluGuard) in volunteers aged 18-60 years: A double-blind, non-inferiority, randomized controlled trial" [Vaccine 42(9) (2024) 2254-2259].
    Vaccine. 2026;88:128881.
    PubMed        

  42. BARBAROUX A, Serati I, Milhabet I
    Effectiveness and acceptability of an opt-out nudge to promote influenza vaccination among medical residents: A randomized controlled trial.
    Vaccine. 2026;89:128894.
    PubMed         Abstract available

  43. MORRIS SE, O'Halloran A, Sundaresan D, Olson SM, et al
    Public health benefits of maternal influenza vaccination among pregnant women and infants <6 months in the United States, 2011-2020.
    Vaccine. 2026;89:128895.
    PubMed         Abstract available

  44. HALWE NJ, Krammer F
    Vaccine strategies and development before and during the 1968 H3N2 influenza pandemic.
    Vaccine. 2026;89:128877.
    PubMed         Abstract available

Saturday, July 4, 2026

History of Mass Transportation: A Class 84 Diesel Shunter at Bucarest Nord Station

 


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By The original uploader was Dr2005 at Romanian Wikipedia. - Transferred from ro.wikipedia to Commons., CC BY 2.5, https://commons.wikimedia.org/w/index.php?curid=8459430

Source: 


Link: https://en.wikipedia.org/wiki/Rolling_stock_of_the_Romanian_Railways#/media/File:84-0002-0-BucN-001.jpg

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Clade 2.3.4.4b #H5N1 #influenza virus and #SARS-CoV-2 #seroprevalence among owned and feral #cats in #Philadelphia and surrounding communities

 


Abstract

Clade 2.3.4.4b H5NX influenza viruses have spread widely in birds since 2020. In addition to causing disease in birds, these viruses have infected a variety of mammals, including humans. Clade 2.3.4.4b H5N1 viruses are currently causing an outbreak among dairy cattle in the United States, and it is important to determine if other mammals have been exposed to H5NX viruses. Cats, specifically outdoor and feral cats, frequently predate wild birds. Recent studies have shown that cats living on dairy cattle farms can be infected with H5N1. Here, we completed serological studies to determine if owned and feral cats living in an urban environment in the United States have evidence of past H5N1 exposures. We used multianalyte bead-based assays to measure clade 2.3.4.4b hemagglutinin (HA) antibody levels in serum samples collected in July 2023 to June 2025 from 417 feral and 228 owned cats from the greater Philadelphia area. We also measured antibody levels against a panel of HAs from other human and non-human influenza viruses, and the receptor binding domain (RBD) of the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). We completed additional H5N1 and SARS-CoV-2 neutralization assays using samples that had detectable antibodies in the multianalyte bead-based assays. One cat (0.16%) was positive for H5 antibodies and twenty cats (3.1%) were positive for SARS-CoV-2 antibodies in both binding and neutralization assays. These data suggest that cats in the Philadelphia area have not been routinely exposed to clade 2.3.4.4b H5N1 viruses but have been more commonly exposed to SARS-CoV-2.

Source: 


Link: https://www.biorxiv.org/content/10.64898/2026.07.03.736283v1

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Seasonal #surveillance in #humans in 2026 for #WNV - Weekly Report (ECDC, Week 27, 2026, July 4 '26): Six cases reportes so far in total {#Italy, #Romania, N. #Macedonia}

 


Week 27, 2026

Produced on 2 July 2026 at 12:00 based on data submitted up to 1 July 2026


Epidemiological summary

    Since the beginning of 2026, and as of 1 July, three countries in Europe reported six human cases{1} of West Nile virus (WNV) infection: Italy (three cases), Romania (two cases) and North Macedonia (one case).

    The current report in Table 1 includes the number of probable and confirmed cases of WNV infections per NUTS3 region. However, these figures are preliminary and should be interpreted with caution as they may be revised by the countries as more information becomes available. 

    For further details on case numbers, please refer to the joint monthly report, which offers a more detailed analysis.

    Please note: The table and map in this report contain countries and areas where human West Nile virus infection cases were reported to EpiPulse Cases.

(...)


Overview of West Nile virus cases in EU/EEA and EU-neighbouring countries

Table 1. Countries and regions with locally acquired human cases of West Nile virus infections in 2026 as of 1 July.


{Click on Image to Enlarge}

* An ‘affected area’ or ‘risk area’ is defined as ‘a risk area with ongoing transmission of WNV to humans’. This means that at least one autochthonous human case of WNV has been reported as a result of local transmission in the area according to the agreed, standardised and disease-specific case definition. In exceptional circumstances, a probable case can be used to determine transmission, however, this should only apply in specific and agreed situations when a case cannot be confirmed within a reasonable time.


** Compared to the previous weekly report.

(...)

Source: 


Link: https://www.ecdc.europa.eu/en/west-nile-fever/surveillance-and-disease-data/disease-data-ecdc

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Friday, July 3, 2026

#Assessment of #influenza virus and #coronavirus #tropism, #replication competence and disease severity in ex vivo and in vitro cultures of the #human respiratory tract



ABSTRACT

The emergence of animal influenza viruses circulating in poultry and human populations poses a significant public health threat, yet current risk assessment tools that connect surveillance data to human transmission risk and disease severity are lacking. To address this, we employed a semi-quantitative approach to analyze virus tropism and replication competence, conducting risk assessments of influenza and coronavirus adaptation to human transmission in an ex vivo model, and evaluating virus-induced impairment of alveolar fluid clearance (AFC) in vitro as a correlation of disease severity. Our results showed that seasonal influenza A H1N1, H3N2, influenza B, MERS-CoV, and SARS-CoV exhibited productive viral replication and tissue infection in bronchial tissues, whereas wild bird surveillance isolates such as H5N3 and H7N1 showed minimal replication when compared to pandemic H1N1 and highly pathogenic avian influenza (HPAI) H5N1. Notably, differential lung viral replication and tissue tropism were detected for H5N6 and H9N2. HPAI H5N1, H7N9, MERS-CoV, and SARS-CoV caused more severe AFC impairment than seasonal H1N1, H3N2, and influenza B viruses, correlating with their clinical severity. Overall, these findings revealed an important association between viral tropism and human transmissibility in ex vivo explants, as well as the impairment of AFC in vitro, which aligns with the clinical manifestations of disease severity across different viral strains.

Source: 


Link: https://www.microbiologyresearch.org/content/journal/jgv/10.1099/jgv.0.002281

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#Ebola disease caused by #Bundibugyo virus, #DRC & #Uganda (WHO D.O.N., July 3 '26): 1460 cases and 452 deaths in DRC

 


Situation at a glance

    The Bundibugyo virus disease (BVD) outbreak in the Democratic Republic of the Congo continues to evolve rapidly, with sustained transmission and increasing numbers of reported cases

    As of 1 July, a cumulative of 1460 confirmed cases, including 452 deaths, have been reported from the Democratic Republic of the Congo

    As of 2 July, Uganda has reported 20 confirmed cases including two deaths, as well as one probable case who has died. 

    In addition, on 24 June 2026, French authorities notified WHO of a laboratory-confirmed case of Ebola disease caused by Bundibugyo virus in a medical doctor returning from the Democratic Republic of the Congo. 

    In Uganda, the outbreak remains epidemiologically linked to transmission originating in the Democratic Republic of the Congo, with evidence of both imported infections and secondary transmission among contacts and healthcare workers. 

    Uganda has not reported any new cases since 21 June 2026

    National authorities in the two affected countries, in collaboration with WHO and partners, are implementing an extensive set of response measures. 

    A regional preparedness and prioritization framework continues to guide readiness activities across the African Region.


Description of the situation

    Since the last Disease Outbreak News was published on 19 June 2026, the number of confirmed cases and deaths have increased rapidly in the Democratic Republic of the Congo. 

    In total, 1481 confirmed cases; 1460 from the Democratic Republic of the Congo, 20 from Uganda and one from France (linked to DRC); and 454 deaths including two from Uganda, have been reported.  

    At least 229 patients have recovered from the disease; 213 patients from the Democratic Republic of the Congo and 16 patients from Uganda.

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(...)

Democratic Republic of the Congo

    Since 19 June when the last Disease Outbreak News was published, an additional 564 confirmed cases, including 220 confirmed deaths, have been reported from the Democratic Republic of the Congo. 

    The increase is in part due to the scale up of surveillance activities, testing and diagnostic capacities.

    As of 1 July 2026, a total of 1460 confirmed cases including 452 deaths (crude case fatality ratio [CFR] 30.9%) have been reported from the Democratic Republic of Congo. 

    So far, 213 patients have recovered

    Cases have been reported from 36 health zones (HZ) from Ituri (24/36 HZ), North Kivu (11/35 HZ) and South Kivu provinces (1/34 HZ).[1] 

    To date, 102 confirmed cases including 25 deaths have been reported among health and care workers.

    Of the 36 affected health zones, the outbreak remains active in 21 health zones from where cases have been reported in the past 21 days. The remaining health zones have not reported any new cases during this period. In the past 21 days, 838 confirmed cases, including 314 confirmed deaths, have been reported.

    Ituri Province remains the most affected, accounting for 91.3% (1333/1460) of all confirmed cases and 84% (380/452) of all reported deaths nationwide. Within the province, the highest number of confirmed cases have been reported from Bunia (416 cases), Rwampara (308 cases), Mongbwalu (270 cases), Nyankunde (95 cases), and Nizi (65 cases) health zones. 

    As of 1 July, the outbreak has spread to three additional health zones in the province. Following epidemiological investigations, three confirmed cases with travel history from Nia Nia health zone in Ituri province have been reported on 30 June in Wamba health zone in Haut Uele Province and Kisangani in Tshopo province. These cases have been reported under Nia Nia health zone. Response activities, including contact tracing and follow-up, are ongoing in both provinces. Of the total confirmed cases, 17 are yet to be assigned to a specific health zone.

    As of 1 July, 10 821 contacts have been identified and are under follow-up across Ituri (8376), and North Kivu (2445). Of these, 8954 contacts have been followed up, corresponding to follow-up rates of 83.2% in Ituri, and 81% in North Kivu. Previously listed contacts from South Kivu province have completed 21 days of follow up.  

    In addition, 107 contacts of the case reported in France have been listed and are under follow up in Kinshasa.

    The outbreak is unfolding in a complex humanitarian and conflict-affected environment, characterized by highly mobile and often displaced populations, often lacking access to basic services, including food, clean water, shelter, healthcare and protection which poses an increased risk of transmission to the populations living in overcrowded internally displaced camps. These dynamics, combined with increasing security-related incidents affecting health facilities, have posed additional operational challenges in affected provinces, such as constrained access for response teams, disrupted surveillance and response activities, and heightened risk of undetected transmission. These conditions underscore the need for response efforts to be led by local leaders and anchored in communities.

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Figure 2: Number of confirmed cases (n = 1460), in the Democratic Republic of the Congo, by date of reporting, as of 1 July 2026  Confirmed cases in DRC


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Figure 3: Number of deaths among confirmed cases (n = 452), in the Democratic Republic of the Congo, by date of reporting, as of 1 July 2026. Deaths in DRC


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NB: Newly reported confirmed cases/deaths may be part of the backlog of samples and therefore not necessarily newly acquired infections. 

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Uganda

    The last confirmed case was reported to be identified on 21 June 2026.  

    As of 2 July 2026, a cumulative of 20 confirmed cases including two deaths in imported cases (reported on 15 May and 5 June), and one probable case who has died, have been reported. 

    Of the confirmed cases, 15 are imported cases, while five are secondary cases among contacts and health workers with links to imported cases from the Democratic Republic of the Congo. 

    The cases have been reported in two districts, Kampala and Wakiso, both part of the Kampala Metropolitan Area. 

    To date, there has been no documented community transmission in Uganda. 

    Exposure risks are associated with healthcare settings and cross-border movements. 

    Following case reclassification, the number of affected healthcare workers was revised from five to four. In total, 16 recoveries have been reported to date.

    Of the 831 contacts listed as of 28 June, 821 contacts have completed their 21-day follow-up period as of 2 July.

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Figure 4: Number of confirmed cases (n = 20), in Uganda by date of reporting, as of 2 July 2026 


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France:

    On 24 June 2026, French authorities notified WHO of a laboratory-confirmed case of Ebola disease caused by Bundibugyo virus in a middle-aged male medical doctor returning from the Democratic Republic of the Congo. 

    The patient had been deployed for five weeks in Ituri Province, where he was involved in the care of patients with BVD. 

    Upon arrival at Charles de Gaulle Airport on 23 June 2026, the patient self-reported symptoms to airport health authorities, prompting immediate isolation and referral to a designated high-containment healthcare facility.

    At the time of reporting, the patient was clinically stable and had no fever, with no reported vomiting, diarrhoea, or haemorrhagic manifestations during travel. PCR testing detected Bundibugyo virus. Comprehensive contact tracing has been initiated in the Democratic Republic of the Congo and in France.


Epidemiology

    Bundibugyo virus disease (BVD) is a severe Ebola disease caused by the Bundibugyo virus, one of the Orthoebolavirus species. It is a zoonotic disease, with fruit bats suspected to be the natural reservoir. Human infection is thought to occur through close contact with the blood or secretions of infected wildlife, such as bats or non-human primates, and it subsequently spreads from person to person through direct contact with the blood, secretions, organs, or other bodily fluids of infected individuals or contaminated surfaces or items. Transmission is particularly amplified in health-care settings when infection prevention and control (IPC) measures are inadequate, and during unsafe burial practices involving direct contact with the deceased.

    The incubation period for BVD ranges from two to 21 days, and individuals are not infectious until symptom onset. Early symptoms such as fever, fatigue, muscle pain, headache, and sore throat, are non-specific, which complicates clinical diagnosis and can delay detection. These symptoms then progress to gastrointestinal symptoms, organ dysfunction, and in some cases haemorrhagic manifestations. CFRs in the past two BVD outbreaks, reported in Uganda and in the Democratic Republic of the Congo in 2007 and 2012 were 30% and 50%, respectively.

    Differentiating BVD from other endemic febrile illnesses such as malaria is challenging without laboratory confirmation using PCR or antigen/antibody-based assays. Outbreak control relies on rapid case identification, isolation and care, contact tracing, safe burials, and strong community engagement, as no approved vaccines or specific treatments currently exist for BVD.


Public health response

    Health authorities in the Democratic Republic of the Congo and Uganda, in collaboration with WHO and partners, are implementing extensive public health measures including implementing the continental response plan, engaging donors and mobilizing additional resources to address critical funding gaps and sustain response operations across affected and at-risk areas.

(...)


WHO risk assessment

    On 6 June 2026, WHO reassessed the risk of the outbreak of BVD to incorporate newly available information and align with the WHO Temporary Recommendations. 

    The risk for countries sharing land borders with countries with documented Bundibugyo virus (BVDV) detection, currently the Democratic Republic of the Congo and Uganda, has been separated out from the risk for other countries in the African Region.

    The risk in the Democratic Republic of the Congo remains assessed as very high due to ongoing transmission and the continued expansion of the outbreak into new health zones, increasing the potential for further national and regional spread.

    The risk in Uganda is assessed as high due to confirmed cross-border spread through imported cases and ongoing epidemiological links along the eastern Democratic Republic of the Congo–western Uganda corridor, historically affected by Ebola outbreaks, including Bundibugyo and Sudan virus disease outbreaks.

    The risk for countries with land borders adjoining countries with documented BDBV detection is assessed as high due to sustained population mobility linked to cross-border trade and mining activities, variation in capacities and experience of BVD response, and variable levels of readiness.

    The risk for the rest of the Africa region and at the global level is assessed as low.

(...)


WHO advice

    WHO advises against any restriction of travel to, or trade with, the Democratic Republic of the Congo or Uganda based on the currently available information. WHO continues to closely monitor and, where necessary, verify travel and trade measures in relation to this event.

    For further information on the considerations for implementing border health and international travel-related temporary recommendations, please see the relevant technical note issued on 26 May 2026.

    The Temporary Recommendations issued to State Parties on 22 May 2026 underscore the importance of coordinated outbreak control, enhanced cross‑border collaboration, and sustained surveillance and preparedness to prevent further regional spread and ensure an effective public health response.

    WHO has convened several technical advisory groups, including the Strategic Advisory Group of Experts on Immunization (SAGE) to assess candidate vaccines and therapeutics for BVD. Key recommendations made are available in the news release published on 28 May 2026.


(...)

Citable reference: World Health Organization (3 July 2026). Disease Outbreak News; Bundibugyo Virus Disease, Democratic Republic of the Congo and Uganda. Available at https://www/who.int/emergencies/disease-outbreak/news/item/2026-DON612


 [1] #Data source: Centre des opérations d'urgences de sante publique (COUSP-DRC) 

Source: 


Link: https://www.who.int/emergencies/disease-outbreak-news/item/2026-DON612

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#Influenza at the #human - #animal #interface - Summary and #risk #assessment, from 9 May to 12 June 2026 (WHO, July 3 '26): 4 new human #H9N2 cases in #China

 


Influenza at the human-animal interface -  Summary and risk assessment, from 9 May to 12 June 2026 {1} 

    New human cases {2}: 

        ° From 9 May to 12 June 2026, based on reporting date, detections of influenza A(H9N2) in four humans were reported officially. 

    Circulation of influenza viruses with zoonotic potential in animals

        ° High pathogenicity avian influenza (HPAI) events in poultry and non-poultry animal species continue to be reported to the World Organisation for Animal Health (WOAH).{3} 

        ° The Food and Agriculture Organization of the United Nations (FAO) also provides a global update on avian influenza viruses with pandemic potential.{4} 

    ° Additionally, low pathogenicity avian influenza viruses as well as swine influenza viruses continue to circulate in animal populations. 

    Risk assessment {5}: 

        ° Sustained human to human transmission has not been reported associated with the above-mentioned human infection events. 

        ° Based on information available at the time of this risk assessment update, the overall public health risk from currently known influenza A viruses detected at the human-animal interface has not changed and remains low

        ° At present, these viruses are not thought to be capable of sustained human-to-human transmission, although this could change as they evolve.  

        ° Although human infections with viruses of animal origin are infrequent, they are not unexpected at the human-animal interface.  

    IHR compliance {6}: 

        ° This includes any influenza A virus that has demonstrated the capacity to infect a human and its haemagglutinin (HA) gene (or protein) is not a mutated form of those, i.e. A(H1) or A(H3), circulating widely in the human population. 

        ° Information from these notifications is critical to inform risk assessments for influenza at the human-animal interface.  


Avian influenza viruses in humans 

A(H9N2), China  

    ° Between 13 May and 11 June 2026, China notified WHO of four laboratory-confirmed cases of A(H9N2) virus infection detected through influenza-like illness surveillance. 

    ° All cases recovered from illness. 

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    ° The child with onset in April was admitted to hospital with pneumonia

    ° The adult case had comorbidities and was hospitalized

    ° All the cases had exposure to live bird markets or household poultry. 

    ° Samples from environments associated with the likely area of exposure of all but one of these cases tested positive for A(H9) viruses. 

    ° No further cases were detected among contacts of these cases.   


Risk assessment for avian influenza A(H9N2):  

  1. What is the global public health risk of additional human cases of infection with avian influenza A(H9N2) viruses?  
    • Most human cases follow exposure to the A(H9N2) virus through contact with infected poultry or contaminated environments
    • Most human infections of A(H9N2) to date have resulted in mild clinical illness
    • Since the virus is endemic in poultry in multiple countries in Africa and Asia, additional human cases associated with exposure to infected poultry or contaminated environments are expected but remain unusual. 
    • The impact to public health if additional sporadic cases are detected is minimal
    • The overall global public health risk is low.  
  2. What is the likelihood of sustained human-to-human transmission of avian influenza A(H9N2) viruses related to these events?  
    • At the present time, no sustained human-to-human transmission has been identified associated with the recently reported human infections with A(H9N2) viruses. 
    • Current evidence suggests that A(H9N2) viruses from these cases did not acquire the ability of sustained transmission among humans.  
  3. What is the likelihood of international spread of avian influenza A(H9N2) virus by travellers?  
    • Should infected individuals from affected areas travel internationally, their infection may be detected in another country during travel or after arrival. 
    • If this were to occur, further community level spread is considered unlikely as current evidence suggests the A(H9N2) virus subtype has not acquired the ability to transmit easily among humans.  

Overall risk management recommendations
    
    ° Surveillance and investigations 
    
        Due to the constantly evolving nature of influenza viruses, WHO continues to stress the importance of global strategic surveillance in animals and humans to detect virologic, epidemiologic and clinical changes associated with circulating influenza viruses that may affect human (or animal) health. 
        
            Continued vigilance is needed within affected and neighbouring areas to detect infections in animals and humans. 
        
            Close collaboration with the animal health and environment sectors is essential to understand the extent of the risk of human exposure and to prevent and control the spread of animal influenza. 
    
            WHO has published guidance on surveillance for human infections with avian influenza A(H5) viruses. 

        As the extent of influenza virus circulation in animals is not clear, epidemiologic and virologic surveillance and the follow-up of suspected human cases should continue systematically. 
            
            Guidance on investigation of non-seasonal influenza and other emerging acute respiratory diseases has been published on the WHO website. 

            Countries should: 
            
                - increase avian influenza surveillance in domestic and wild birds, enhance surveillance for early detection in cattle populations in countries where HPAI is known to be circulating, include HPAI as a differential diagnosis in non-avian species, including cattle and other livestock populations, with high risk of exposure to HPAI viruses; 
                
                - monitor and investigate cases in non-avian species, including livestock, report cases of HPAI in all animal species, including unusual hosts, to WOAH and other international organizations, 

                - share genetic sequences of avian influenza viruses in publicly available databases, 

                - implement preventive and early response measures to break the HPAI transmission cycle among animals through movement restrictions of infected livestock holdings and strict biosecurity measures in all holdings, 

                - employ good production and hygiene practices when handing animal products, and 

                - protect persons in contact with suspected/infected animals.{7} 

            More guidance can be found from WOAH and FAO. 

        • When there has been human exposure to a known outbreak of an influenza A virus in domestic poultry, wild birds or other animals – or when there has been an identified human case of infection with such a virus – enhanced surveillance in potentially exposed human populations becomes necessary. 

            - Enhanced surveillance should consider the health care seeking behaviour of the population, and could include a range of active and passive health care and/or communitybased approaches, including: enhanced surveillance in local influenza-like illness (ILI)/SARI systems, active screening in hospitals and of groups that may be at higher occupational risk of exposure, and inclusion of other sources such as traditional healers, private practitioners and private diagnostic laboratories. 

        Vigilance for the emergence of novel influenza viruses with pandemic potential should be maintained at all times including during a non-influenza emergency. In the context of the cocirculation of SARS-CoV-2 and influenza viruses, WHO has updated and published practical guidance for integrated surveillance. 


    ° Notifying WHO 

        All human infections caused by a new subtype of influenza virus are notifiable under the International Health Regulations (IHR, 2005).{8,9} State Parties to the IHR (2005) are required to immediately notify WHO of any laboratory-confirmed {10} case of a recent human infection caused by an influenza A virus with the potential to cause a pandemic {11}. Evidence of illness is not required for this report. Evidence of illness is not required for this report. 

        WHO published the case definition for human infections with avian influenza A(H5) virus requiring notification under IHR (2005): https://www.who.int/teams/global-influenzaprogramme/avian-influenza/case-definitions


    ° Virus sharing and risk assessment 

        It is critical that these influenza viruses from animals or from humans are fully characterized in appropriate animal or human health influenza reference laboratories. Under WHO’s Pandemic Influenza Preparedness (PIP) Framework, Member States are expected to share influenza viruses with pandemic potential on a timely basis {12} with a WHO Collaborating Centre for influenza of GISRS. The viruses are used by the public health laboratories to assess the risk of pandemic influenza and to develop candidate vaccine viruses.  

        The Tool for Influenza Pandemic Risk Assessment (TIPRA) provides an in-depth assessment of risk associated with some zoonotic influenza viruses – notably the likelihood of the virus gaining human-to-human transmissibility, and the impact should the virus gain such transmissibility. TIPRA maps relative risk amongst viruses assessed using multiple risk elements. The results of TIPRA complement those of the risk assessment provided here, and those of prior TIPRA risk assessments are published at http://www.who.int/teams/global-influenza-programme/avianinfluenza/tool-for-influenza-pandemic-risk-assessment-(tipra).  


    ° Risk reduction 

        Given the observed extent and frequency of avian influenza in poultry, wild birds and some wild and domestic mammals, the public should avoid contact with animals that are sick or dead from unknown causes, including wild animals, and should report dead birds and mammals or request their removal by contacting local wildlife or veterinary authorities.  

        Eggs, poultry meat and other poultry food products should be properly cooked and properly handled during food preparation. Due to the potential health risks to consumers, raw milk should be avoided. WHO advises consuming pasteurized milk. If pasteurized milk isn’t available, heating raw milk until it boils makes it safer for consumption. 

        WHO has published practical interim guidance to reduce the risk of infection in people exposed to avian influenza viruses. 


    ° Trade and travellers 

        WHO advises that travellers to countries with known outbreaks of animal influenza should avoid farms, contact with animals in live animal markets, entering areas where animals may be slaughtered, or contact with any surfaces that appear to be contaminated with animal excreta. Travelers should also wash their hands often with soap and water. All individuals should follow good food safety and hygiene practices.  

        WHO does not advise special traveller screening at points of entry or restrictions with regards to the current situation of influenza viruses at the human-animal interface. For recommendations on safe trade in animals and related products from countries affected by these influenza viruses, refer to WOAH guidance.  


Links:  


    WHO Influenza (Avian and other zoonotic) fact sheet https://www.who.int/news-room/fact-sheets/detail/influenza-(avian-and-other-zoonotic) 

    WHO Protocol to investigate non-seasonal influenza and other emerging acute respiratory diseases https://www.who.int/publications/i/item/WHO-WHE-IHM-GIP-2018.2 

    WHO Public health resource pack for countries experiencing outbreaks of influenza in animals:  https://www.who.int/publications/i/item/9789240076884 

    Cumulative Number of Confirmed Human Cases of Avian Influenza A(H5N1) Reported to WHO  https://www.who.int/teams/global-influenza-programme/avian-influenza/avian-a-h5n1-virus 


    World Organisation of Animal Health (WOAH) web page: Avian Influenza  https://www.woah.org/en/home/ 

    Food and Agriculture Organization of the United Nations (FAO) webpage: Avian Influenza https://www.fao.org/animal-health/avian-flu-qa/en/ 

    WOAH/FAO Network of Expertise on Animal Influenza (OFFLU) http://www.offlu.org/

___ 

{1} This summary and assessment covers information confirmed during this period and may include information received outside of this period. 

{2} For epidemiological and virological features of human infections with animal influenza viruses not reported in this assessment, see the reports on human cases of influenza at the human-animal interface published in the Weekly Epidemiological Record here.  

{3} World Organisation for Animal Health (WOAH). Avian influenza. Global situation. Available at: https://www.woah.org/en/disease/avian-influenza/#ui-id-2

{4} Food and Agriculture Organization of the United Nations (FAO). Global Avian Influenza Viruses with Zoonotic Potential situation update. Available at: https://www.fao.org/animal-health/situation-updates/global-aiv-withzoonotic-potential

{5} World Health Organization (2012). Rapid risk assessment of acute public health events. World Health Organization. Available at: https://iris.who.int/handle/10665/70810

{6} World Health Organization. Case definitions for the four diseases requiring notification in all circumstances under the International Health Regulations (2005). Available at: https://www.who.int/publications/m/item/case-definitions-for-the-four-diseases-requiring-notification-towho-in-all-circumstances-under-the-ihr-(2005).  

{7} World Organisation for Animal Health. Statement on High Pathogenicity Avian Influenza in Cattle, 6 December 2024 (https://www.woah.org/en/high-pathogenicity-avian-influenza-hpai-in-cattle/). 

{8} World Health Organization. International Health Regulations (2005), as amended through resolutions WHA67.13 (2014), WHA75.12 (2022), and WHA77.17 (2024) (https://apps.who.int/gb/bd/pdf_files/IHR_20142022-2024-en.pdf). 

{9} World Health Organization. Case definitions for the four diseases requiring notification in all circumstances under the International Health Regulations (2005) (https://www.who.int/publications/m/item/casedefinitions-for-the-four-diseases-requiring-notification-to-who-in-all-circumstances-under-the-ihr-(2005)). 

{10} World Health Organization. Manual for the laboratory diagnosis and virological surveillance of influenza (2011) (https://apps.who.int/iris/handle/10665/44518). 

{11} World Health Organization. Pandemic influenza preparedness framework for the sharing of influenza viruses and access to vaccines and other benefits, 2nd edition (https://iris.who.int/handle/10665/341850). 

{12} World Health Organization. Operational guidance on sharing influenza viruses with human pandemic potential (IVPP) under the Pandemic Influenza Preparedness (PIP) Framework (2017) (https://apps.who.int/iris/handle/10665/259402). 


Source: 


Link: https://www.who.int/publications/m/item/influenza-at-the-human-animal-interface-summary-and-assessment--12-june-2026

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