Joyce Odeke Akello scite author profile

Background: Human adenovirus (HAdV) is an important pathogen seen in clinical practice. Long-term studies may help better understand epidemiological trends and changes in circulating genotypes over time.Purpose: Using a large biobank of samples from hospitalized, adenovirus-positive patients over a 20-year period, we aimed to analyze long-term epidemiological trends and genotypic relatedness among circulating HAdV strains. Methods: Based on samples from hospitalized patients confirmed to be HAdV positive in Bern, Switzerland, from 1998 to 2017, and on their associated demographic and clinical data, we identified epidemiological trends and risk factors associated with HAdV infection. HAdV genotyping was performed by PCR amplification and sequencing of the hypervariable hexon gene. The obtained sequences were phylogenetically compared with sequences from international HAdV strains. Results: HAdV was identified in 1302 samples tested. Cases of HAdV infection were reported throughout the years with no clear seasonality. Upper respiratory tract samples, conjunctivitis swabs, and stool had the highest positivity rate (56.2%, 18.7%, and 14.2% of the cases, respectively). HAdV infection was highest among children ≤4 years old. Increased number of HAdV cases were observed in years 2009 (n = 110) and 2010 (n =112). HAdV8 was the predominant genotype among patients older than 20 years, and was mostly associated with ophthalmic infection. Predominant genotypes among children ≤4 years old were HAdV1, HAdV2, and HAdV3, which were mostly associated with respiratory tract infections. Recurring peaks of increased HAdV cases were evidenced every 4 years among children ≤4 years old. Conclusion: Our study gives novel insights on long-term epidemiological trends and phylogenetic relatedness among circulating HAdV strains in Switzerland, country in which little data on HAdV prevalence and diversity was so far available.

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Sustained detection of type 2 poliovirus in London sewage between February and July, 2022, by enhanced environmental surveillance

Klapsa

Wilton

Zealand³

et al. 2022

The Lancet

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Isolation of Vaccine-Like Poliovirus Strains in Sewage Samples From the United Kingdom

Majumdar

Klapsa

Wilton

et al. 2017

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Preparedness needs research: How fundamental science and international collaboration accelerated the response to COVID-19

et al. 2020

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The first cluster of patients suffering from coronavirus disease 2019 (COVID-19) was identified on December 21, 2019, and as of July 29, 2020, severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infections have been linked with 664,333 deaths and number at least 16,932,996 worldwide. Unprecedented in global societal impact, the COVID-19 pandemic has tested local, national, and international preparedness for viral outbreaks to the limits. Just as it will be vital to identify missed opportunities and improve contingency planning for future outbreaks, we must also highlight key successes and build on them. Concomitant to the emergence of a novel viral disease, there is a 'research and development gap' that poses a threat to the overall pace and quality of outbreak response during its most crucial early phase. Here, we outline key components of an adequate research response to novel viral outbreaks using the example of SARS-CoV-2. We highlight the exceptional recent progress made in fundamental science, resulting in the fastest scientific response to a major infectious disease outbreak or pandemic. We underline the vital role of the international research community, from the implementation of diagnostics and contact tracing procedures to the collective search for vaccines and antiviral therapies, sustained by unique information sharing efforts.

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Genomic analyses of human adenoviruses unravel novel recombinant genotypes associated with severe infections in pediatric patients

Akello

Kamgang

Barbani

et al. 2021

Sci Rep

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Human adenoviruses (HAdVs) are highly contagious pathogens of clinical importance, especially among the pediatric population. Studies on comparative viral genomic analysis of cases associated with severe and mild infections due to HAdV are limited. Using whole-genome sequencing (WGS), we investigated whether there were any differences between circulating HAdV strains associated with severe infections (meningitis, sepsis, convulsion, sudden infant death syndrome, death, and hospitalization) and mild clinical presentations in pediatric patients hospitalized between the years 1998 and 2017 in a tertiary care hospital group in Bern, Switzerland covering a population base of approx. 2 million inhabitants. The HAdV species implicated in causing severe infections in this study included HAdV species C genotypes (HAdV1, HAdV2, and HAdV5). Clustering of the HAdV whole-genome sequences of the severe and mild cases did not show any differences except for one sample (isolated from a patient presenting with sepsis, meningitis, and hospitalization) that formed its own cluster with HAdV species C genotypes. This isolate showed intertypic recombination events involving four genotypes, had the highest homology to HAdV89 at complete genome level, but possessed the fiber gene of HAdV1, thereby representing a novel genotype of HAdV species C. The incidence of potential recombination events was higher in severe cases than in mild cases. Our findings confirm that recombination among HAdVs is important for molecular evolution and emergence of new strains. Therefore, further research on HAdVs, particularly among susceptible groups, is needed and continuous surveillance is required for public health preparedness including outbreak investigations.

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Nested VP1 PCR and Nanopore Sequencing from Stool and ES Samples v1.11 v2

Shaw¹,

Majumdar²,

Troman³

et al. 2022

Preprint

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This protocol is updated from the protocol described in the paper "Rapid and sensitive direct detection and identification of poliovirus from stool and environmental surveillance samples using nanopore sequencing" by Shaw et al in the Journal of Clinical Microbiology (2020), DOI: 10.1128/JCM.00920-20. The protocol aims to amplify the VP1 region of poliovirus through a nested PCR using panEV primers followed by amplification of the VP1 sequence using the Q8/Y7 primer set. We advise the use of barcoded primers where possible as this greatly simplifies the subsequent library preparation process. Additional steps have however been included in the case that the second PCR step is performed either with standard Q8/Y7 primers or using Q8/Y7 with the barcode adaptors (BCA) attached. Primer sequences for the panEV primers, Q8/Y7 primers and modified Q8/Y7 primers are found in Dataset S1 of the publication. Sequencing of the panEV product is also possible through the removal of the VP1 nested PCR steps and the preparation of the panEV product for sequencing. Version updates: v1.1 – Updated to LSK-109 v1.2 – Minor formatting edits v1.3 – Streamlining and minor alterations v1.4 – Written inclusion of negative control in PCR v1.5 – Updated to dreamtaq and Y7R primers v1.6 – Updated MinKNOW instructions & minor edits v1.7 – Changed back to Y7 primers v1.10 – Updated to LSK-110, removed cleaning and quantification prior to pooling, updated taq volume in rtPCR, altered nested VP1 to use neat panEV product. V1.11 – Updated RNA extraction to include Proteinase K, removed DNA CS addition, added pooling of Y7/Q8 primers.

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Comparison of Eleven RNA Extraction Methods for Poliovirus Direct Molecular Detection in Stool Samples

et al. 2023

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Norovirus attribution study: Detection of norovirus from the commercial food preparation environment in outbreak and non-outbreak premises

Elviss¹,

Allen

Kelly

et al. 2022

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Aims Norovirus remains the most significant virological risk that is transmitted via food and the environment to cause acute gastroenteritis. This study aimed to investigate the hypothesis that the contamination of the commercial food production environment with norovirus will be higher in premises that have recently reported a foodborne norovirus outbreak than those that have not. Methods Sampling of commercial food production environments was carried out across a 16‐month period between January 2015 and April 2016 in the South East and the North West of England by local authority environmental health departments as part of routine surveillance visits to premises. A total of 2982 samples, 2038 virological and 944 bacteriological, were collected from 256 premises. Sixteen of these premises, six from South East and ten from North West England, were sampled as part of a public health outbreak investigation. Results & Conclusions Overall, 2038 swabs were submitted for norovirus testing, with an average of eight swabs per premises (range 4 to 23) and a median of seven. Of the premises sampled, 11.7% (30/256) yielded at least one norovirus‐positive sample (environmental, and/or food handler hand swab), and 2.5% of the swabs were positive for norovirus. A peak in the positivity rate was seen in the South East in April 2016. No associations were found between norovirus positivity and bacteriology indicators, or between bacteriology indicators and hygiene ratings. Significance and impact of study This study demonstrates that food premises and food handlers remain a potential source of norovirus transmission and outbreaks.

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