78 research outputs found
Rift Valley Fever Virus Circulating among Ruminants, Mosquitoes and Humans in the Central African Republic
Background
Rift Valley fever virus (RVFV) causes a viral zoonosis, with discontinuous epizootics and sporadic epidemics, essentially in East Africa. Infection with this virus causes severe illness and abortion in sheep, goats, and cattle as well as other domestic animals. Humans can also be exposed through close contact with infectious tissues or by bites from infected mosquitoes, primarily of the Aedes and Culex genuses. Although the cycle of RVFV infection in savannah regions is well documented, its distribution in forest areas in central Africa has been poorly investigated.
Methodology/Principal Findings
To evaluate current circulation of RVFV among livestock and humans living in the Central African Republic (CAR), blood samples were collected from sheep, cattle, and goats and from people at risk, such as stock breeders and workers in slaughterhouses and livestock markets. The samples were tested for anti-RVFV immunoglobulin M (IgM) and immunoglobulin G (IgG) antibodies. We also sequenced the complete genomes of two local strains, one isolated in 1969 from mosquitoes and one isolated in 1985 from humans living in forested areas. The 1271 animals sampled comprised 727 cattle, 325 sheep, and 219 goats at three sites. The overall seroprevalence of anti-RVFV IgM antibodies was 1.9% and that of IgG antibodies was 8.6%. IgM antibodies were found only during the rainy season, but the frequency of IgG antibodies did not differ significantly by season. No evidence of recent RVFV infection was found in 335 people considered at risk; however, 16.7% had evidence of past infection. Comparison of the nucleotide sequences of the strains isolated in the CAR with those isolated in other African countries showed that they belonged to the East/Central African cluster.
Conclusion and significance
This study confirms current circulation of RVFV in CAR. Further studies are needed to determine the potential vectors involved and the virus reservoirs
Challenges in clinical diagnosis of Clade I Mpox: Highlighting the need for enhanced diagnostic approaches
Background: Due to limited diagnostic capacity and availability of point-of-care tests, diagnosis of Clade I mpox in the geographical regions most affected is usually on clinical grounds. This may be complicated due to the similarity between mpox and varicella (chickenpox) lesions. Visual assessment of lesions is also used for determining clinical progress and to assess patient outcomes in clinical trials. However, there has been no investigation into whether clinicians can (i) identify Clade I mpox compared to other viral lesions (ii) differentiate between Clade I mpox lesion stages. Methodology/Principle findings: The objective of this study was to evaluate inter-rater reliability and agreement between clinicians assessing lesions in patients with Clade I mpox. We presented experienced clinicians with 17 images of Clade I mpox or varicella and asked them to independently indicate the most likely diagnosisâmpox or varicellaâand to categorise the lesions according to their stage. When selecting the most likely diagnosis, accuracy varied across all images, the inter-rater reliability was poor (Îș = 0.223; z = 10.1) and agreement was moderate (Po = 68%). When categorising lesions according to their type, if a single lesion type was present in the image, inter-rater reliability was moderate (Îș = 0.671, z = 40.6) and agreement was good (Po = 78%), but when multiple lesion types were shown in an image, both inter-rater reliability (Îș = 0.153, z = 10.5) and agreement (Po = 29%) decreased substantially. Conclusions: This study demonstrates that there are presently limitations in using visual assessment to diagnose Clade I mpox and evaluate lesion stage and treatment outcomes, which have an impact on clinical practice, public health and clinical trials. More robust indicators and tools are required to inform clinical, public-health, and research priorities, but these must be implementable in countries affected by mpox
First introduction of pandemic influenza A/H1N1 and detection of respiratory viruses in pediatric patients in Central African Republic
BACKGROUND: Acute viral respiratory illnesses in children in sub-Saharan Africa have received relatively little attention, although they are much more frequent causes of morbidity and mortality than in developed countries. Active surveillance is essential to identify the causative agents and to improve clinical management, especially in the context of possible circulation of pandemic viruses. FINDINGS: A prospective study was conducted in the Central African Republic (CAR) between January and December 2010 among infants and children aged 0â15 years attending sentinel sites for influenza-like illness or acute respiratory illness. Nasopharyngeal swabs were collected, and one-step real-time and multiplex reverse transcription-polymerase chain reaction were used to detect respiratory viruses. Respiratory viruses were detected in 49 of the 329 (14.9%) nasopharyngeal samples: 29 (8.8%) contained influenza viruses (5 (1.5%) had pandemic influenza A/H1N1 virus and 24 (7.3%) had influenza B viruses), 11 (3.3%) contained parainfluenza viruses types 1 and 3 and 9 (2.7%) contained human respiratory syncytial virus. Most cases were detected during the rainy season in the CAR. Analysis of the amplicon sequences confirmed the identity of each detected virus. CONCLUSIONS: The influenza surveillance system in the CAR has provided valuable data on the seasonality of influenza and the circulation of other respiratory viruses. Our network could therefore play a valuable role in the prevention and control of influenza epidemics in the CAR
Laboratory Diagnosis of Mpox, Central African Republic, 2016-2022.
During 2016-2022, PCR testing confirmed 100 mpox cases among 302 suspected cases in the Central African Republic. The highest detection rates were from active lesions (40%) and scabs (36%); cycle thresholds were lower (â18) than those for blood samples (â33). Results were consistent for generic primer- and clade I primer-specific PCR tests
Seroprevalence of Rift Valley fever virus in domestic ruminants of various origins in two markets of Yaoundé, Cameroon
Background: Rift Valley fever (RVF) is a mosquito-borne zoonosis endemic in Africa. With little known of the burden or epidemiology of RVF virus (RVFV) in Cameroon, this study aimed to determine the seroprevalence of RVFV in domestic ruminants of various origins in two markets of Yaoundé, Cameroon.
Methodology/Principal findings: The origin of animals randomly sampled at two livestock markets in YaoundĂ© were recorded and plasma samples collected for competitive and capture Enzyme-linked Immunosorbent Assay (ELISA) to determine the prevalence of Immunoglobulins G (IgG) and Immunoglobulins M (IgM) antibodies. Following ELISA IgM results, a real-time reverse transcription-polymerase chain reaction (qRT-PCR) was performed to detect RVFV RNA. In June-August 2019, February-March 2020, and March-April 2021, 756 plasma samples were collected from 441 cattle, 168 goats, and 147 sheep. RVFV IgG seroprevalence was 25.7% for all animals, 42.2% in cattle, 2.7% in sheep, and 2.4% in goats. However, IgM seroprevalence was low, at 0.9% in all animals, 1.1% in cattle, 1.4% in sheep, and 0% in goats. The seroprevalence rates varied according to the animalâs origin with the highest rate (52.6%) in cattle from Sudan. In Cameroon, IgG and IgM rates respectively were 45.1% and 2.8% in the North, 44.8% and 0% in the Adamawa, 38.6% and 1.7% in the Far-North. All IgM positive samples were from Cameroon. In cattle, 2/5 IgM positive samples were also IgG positive, but both IgM positive samples in sheep were IgG negative. Three (42.9%) IgM positive samples were positive for viral RVFV RNA using qRT-PCR but given the high ct values, no amplicon was obtained.
Conclusion/Significance: These findings confirm the circulation of RVFV in livestock in Cameroon with prevalence rates varying by location. Despite low IgM seroprevalence rates, RVF outbreaks can occur without being noticed. Further epidemiological studies are needed to have a broad understanding of RVFV transmission in Cameroon
Results from the second WHO external quality assessment for the molecular detection of respiratory syncytial virus, 2019-2020
BACKGROUND: External quality assessments (EQAs) for the molecular detection of human respiratory syncytial virus (RSV) are necessary to ensure the standardisation of reliable results. The Phase II, 2019-2020 World Health Organization (WHO) RSV EQA included 28 laboratories in 26 countries. The EQA panel evaluated performance in the molecular detection and subtyping of RSV-A and RSV-B. This manuscript describes the preparation, distribution, and analysis of the 2019-2020 WHO RSV EQA. METHODS: Panel isolates underwent whole genome sequencing and in silico primer matching. The final panel included nine contemporary, one historical virus and two negative controls. The EQA panel was manufactured and distributed by the UK National External Quality Assessment Service (UK NEQAS). National laboratories used WHO reference assays developed by the United States Centers for Disease Control and Prevention, an RSV subtyping assay developed by the Victorian Infectious Diseases Reference Laboratory (Australia), or other in-house or commercial assays already in use at their laboratories. RESULTS: An in silico analysis of isolates showed a good match to assay primer/probes. The panel was distributed to 28 laboratories. Isolates were correctly identified in 98% of samples for detection and 99.6% for subtyping. CONCLUSIONS: The WHO RSV EQA 2019-2020 showed that laboratories performed at high standards. Updating the composition of RSV molecular EQAs with contemporary strains to ensure representation of circulating strains, and ensuring primer matching with EQA panel viruses, is advantageous in assessing diagnostic competencies of laboratories. Ongoing EQAs are recommended because of continued evolution of mismatches between current circulating strains and existing primer sets
Orthobunyavirus de la République Centrafricaine : détection, séquençage et analyse phylogénétique
The Orthobunyavirus genus is composed of segmented negative sense RNA viruses that are responsible for mild to severe human diseases. To date, no molecular studies of Bunyaviridae of the genus Orthobunyavirus from Central Africa have been reported, and their classification relies on serological testing. We have designed and evaluated four new primer pairs for amplification by RT -PCR and sequencing of the complete genomic small (S) RNA segments often Orthobunyavirus viruses isolated from Central African Republic (CAR) and pertaining to 5 different serogroups. Phylogenetic analysis showed that these 10 viroses belong to the Bunyamwera serogroup. The S segment sequences differ from those of the Bunyamwera virus reference strain by 5-15 % at the nucleotide level, and both overlapping reading frames encoding nucleocapsid (N) and non-structural (NS) protein were evident in sequenced genomes. Partial sequencing of M segment was also performed and inversely to the S fragment, the obtained phylogenetic p-ee was not monophyletic as M'Poko strain was highly divergent. This study should improve diagnosis and surveillance of African bunyaviruses.La famille des Bunyaviridae regroupe plus de 350 virus transmis par des arthropodes, classés en cinq genres. La prévalence de ces virus en République Centrafricaine est mal connue et mérite des études moléculaires afin mettre en place un diagnostic fiable, de mieux caractériser les vecteurs et d'identifier les réservoirs qui sont le plus souvent inconnus. Etant donnée la diversité de ces virus, seuls les virus du genre Orthobunyavirus ont été caractérisés dans cette étude. La caractérisation génomique de Bunyaviridae a été réalisée par le séquençage de segments encadrés par des amorces consensus pour un diagnostic d'espÚce. Parmi les orthobunyavirus isolés à l'Institut Pasteur de Bangui (RCA), 12 souches classées dans six sérogroupes ont été incluses dans cette étude. Des couples d'amorces définies dans notre laboratoire ont permis d'amplifier et d'obtenir une séquence complÚte du segment S de dix souches virales. Une séquence partielle de la glycoprotéine G2 (segment M) de ces souches a également été obtenue. L'organisation génétique du segment S de ces souches de RCA recoupe celle des sérogroupes Bunyamwera, California et Simbu. Leur génome est constitué de deux cadres ouverts et chevauchants de lecture qui codent une protéine de la nucléocapside et une protéine non structurale. La comparaison des séquences nucléiques du segment S et de la protéine G2 des souches de RCA à celle de la souche de référence Bunyamwera NC_001927 montre une différence de 5 % à 15 % et 3,3 % à 42,2 % respectivement. Les séquences des protéines N et G2 de la souche M'Poko ArB365 ont été les plus divergentes (15 % et 42,2 % de différence respectivement). L'arbre phylogénétique construit avec les séquences de la protéine N est monophylétique tandis que celui obtenu avec les séquences de la protéine G2 ne l'est pas
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