Comparative Insecticidal Effects of Dry Ocimum Gratissium (Scent Leaves) and Rambo™ Paper on Mosquitoes in Jos, Nigeria

Insecticides are chemicals or biological substances that are used to kill or disable insects. Blood feeding mosquitoes are responsible for the intolerable biting nuisance and transmission of large number of diseases such as malaria, yellow fever, dengue fever, filarias is amongst others, causing serious health problems to humans and obstacles to socioeconomic development of developing nations like Nigeria. The insecticidal effect of scent leaves (Ocimum gratissum) and Rambo™ paper on mosquitoes was investigated. The study is aimed at comparing the insecticidal effects of Ocimum gratissimum and Rambo™ paper on mosquitoes in Jos. 100 mosquitoes were exposed to dried Ocimum gratissum and Rambo™ paper at different time intervals of 5, 10 and 12 min. Results obtained showed a time dependent insecticidal effect on mosquitoes, which was 54.2%, 54.0% and 55.6% total mortality of mosquitoes at respective time intervals on exposures to both Rambo™ paper insecticide and Osimum gratissum, indicating that there was a significant difference in the lethal effect of Rambo™ paper insecticide and scent leave on mosquitoes at (p<0.05). In comparing the lethal effect of Rambo™ paper insecticide and Ocimum grasstisimum on mosquitoes at differnt locations in Jos, at Dogon Karfe, after 10 min of treatment, Rambo™ paper had the highest lethal effect of 21 (84.0%) compared to scent leaves 6 (24.0%) and at Abattoir Jos, after 12 min of treatment, Rambo™ paper had the highest lethal effect of 17 (94.4%) compared to Ocimum grasstisimum 3 (16.7%). These comparisons were significant at p 0.05. This study provides evidence that Ocimum grasstisimum has a mosquitocidal effect. However, the Rambo™ paper gave a better mosquitocidal effect than Ocimum grasstisimum. There is a need to discover better additive or extract options that could give Ocimum grasstisimum a better effect as a natural product available in Africa towards the malaria eradication programme.

Development and Evaluation of a Nested PCR for Improved Diagnosis and Genetic Analysis of Peste des Petits Ruminants Virus (PPRV) for Future Use in Nascent PPR Eradication Programme

Peste des petits ruminants (PPR) is a highly contagious viral disease of small ruminants caused by PPR virus (PPRV). PPR is endemic in Asia, the Middle East and across large areas of Africa and is currently targeted for global eradication by 2030. The virus exists as four different lineages that are usually limited to specific geographical areas. However, recent reports of spread of PPRV, in particular of lineage IV viruses to infection-free countries and previously PPR endemic areas are noteworthy. A rapid and accurate laboratory diagnosis and reports on its epidemiological linkage for virus spread play a major role in the effective control and eradication of the disease. Currently, molecular assays, including conventional reverse transcription-polymerase chain reaction (RT-PCR) and real-time RT-PCR (RT-qPCR) are usually used for diagnosis of PPR while the sequencing of part of the nucleocapsid gene is usually carried out for the viral lineage identification. However, it is difficult to diagnose and sequence the genetic material if the animal excreted a low level of virus at the initial stage of infection or if the PPRV is degraded during the long-distance transportation of samples to the reference laboratories. This study describes the development of a novel nested RT-PCR assay for the detection of the PPRV nucleic acid by targeting the N-protein gene, compares the performance of the assay with the existing conventional RT-PCR and also provides good-quality DNA suitable for sequencing in order to identify circulating lineages. The assay was evaluated using cell culture propagated PPRVs, field samples from clinically infected animals and samples from experimentally infected animals encompassing all four lineages (I–IV) of PPRV. This assay provides a solution with an easy, accurate, rapid and cost-effective PPR diagnostic and partial genome sequencing for use in resource-limited settings.

Measuring the Effective Dispersal of an Emerging Coastal Weed, Euphorbia Paralias (Sea Spurge), To Help Inform its Eradication.

Understanding dispersal and establishment patterns of invasive plant species is critical information to help control and eradicate their populations. Euphorbia paralias, sea spurge, is a highly invasive weed that can be a serious threat to coastal environments. Two recent incursions of E. paralias on New Zealand’s coastline consisted of one reproductive adult surrounded by several hundred juveniles, providing the opportunity to gather effective dispersal distance data for this species. Using these two separate populations effective dispersal distances curves were created for E. paralias. It was found one adult led to the establishment of 213 healthy plants at NZ’s southern-most incursion and 484 healthy plants at the northern-most incursion. All plants were subsequently removed from the site. The maximum effective dispersal distance of 15.8m on land for E. paralias was larger than would be predicted by the majority of trait-based dispersal distance models and the estimate of ~ 2m in the literature. These results show that E. paralias can establish large healthy populations, making it a considerable threat to coastal environments. However, populations around an adult plant are fairly concentrated at the very early stages of invasion (90% of offspring < 5.5m from the adult) providing opportunities to remove the seed bank at incursion sites. Early detection of E. paralias populations using comprehensive surveillance and removal of any new populations (seed and establishing plants) will be essential components for the success in any eradication programme for sea spurge.

The Northern Ireland Control Programmes for Infectious Cattle Diseases Not Regulated by the EU

The disease control programmes for Bovine Viral Diarrhoea (BVD), Infectious Bovine Rhinotracheitis (IBR), Johne's Disease (JD), Leptospirosis and Neosporosis are described including the approved diagnostic tools, diagnostic quality systems, and the role of vaccination (where appropriate). This paper describes the control programmes within NI, the challenges relating them, as well as assessing their impact and effectiveness, taking into consideration the quality of data available and number of herds participating. With the NI agricultural industry experiencing increasing financial pressures and post Brexit changes, the necessity of working to maximise the performance of bovine disease control programmes at the individual farm level as well as at the regional level is increasingly important. The programmes described fall into two categories with two distinct aims. Two managed by Animal Health &amp; Welfare NI (AHWNI), the BVD eradication and JD Dairy Control programmes seek to eradicate or control infection at the regional level. A further 5 programmes, covering BVD, JD, IBR, Leptospirosis and Neosporosis, are managed by the Agri-Food and Biosciences Institute (AFBI) and focus on facilitating eradication or control at the individual herd level. These latter programmes conform to the Cattle Health Certification Standards (UK) (CHeCS) which is a UK self-regulatory body set up to ensure consistency between different disease control schemes across herds. The largest of all the programmes described is the AHWNI BVD Eradication Programme which has led to significant reductions in infection incidence. Compliance with it has been high with more than 97% of all cattle alive at the end of 2020 having a BVD test status. The rolling annual incidence of BVD virus positive calves has fallen by 56% since the start of the compulsory programme in 2016. This decrease has occurred largely through industry initiatives to deal with BVD positives, including the voluntary culling of persistently infected (PI) animals by herd owners, a voluntary abattoir ban on the slaughter of BVD virus (BVDv) positive animals, and the inclusion of retention of a BVDv positive animal as a non-conformance in the industry-run Farm Quality Assurance Scheme.

A Herd Investigation Tool in Support of the Irish Bovine Viral Diarrhoea Eradication Programme

Bovine viral diarrhoea (BVD) is an important endemic disease of cattle. In Ireland, an industry-led compulsory eradication programme began in January 2013. The main elements of this programme are the identification and elimination of persistently infected (PI) calves by testing all new-borns, the implementation of biosecurity to prevent re-introduction of disease and continuous surveillance. In 2016, a standardised framework was developed to investigate herds with positive results. This is delivered by trained private veterinary practitioners (PVP). The investigation's aims are 3-fold: firstly, to identify plausible sources of infection; secondly, to ensure that no virus-positive animals remain on farm by resolving the BVD status of all animals in the herd; and thirdly, agreeing up to three biosecurity measures with the herd owner to prevent the re-introduction of the virus. Each investigation follows a common approach comprising four steps based on information from the programme database and collected on-farm: firstly, identifying the time period when each virus-positive calf was exposed in utero (window of susceptibility, taken as 30–120 days of gestation); secondly, determining the location of the dam of each positive calf during this period; thirdly, to investigate potential sources of exposure, either within the herd or external to it; and finally, based on the findings, the PVP and herdowner agree to implement up to three biosecurity measures to minimise the risk of reintroduction. Between 2016 and 2020, 4,105 investigations were completed. The biosecurity recommendations issued more frequently related to the risks of introduction of virus associated with contact with neighbouring cattle at pasture, personnel (including the farmer), the purchase of cattle and vaccination. Although each investigation generates farm-specific outcomes and advice, the aggregated results also provide an insight into the most commonly identified transmission pathways for these herds which inform overall programme communications on biosecurity. The most widely identified plausible sources of infection over these years included retained BVD-positive animals, Trojan births, contact at boundaries and indirect contact through herd owner and other personnel in the absence of appropriate hygiene measures. While generated in the context of BVD herd investigations, the findings also provide an insight into biosecurity practises more generally on Irish farms.

Kala-azar Burden in Bangladesh- An Overview

Kala-azar is one of the major public health problems in Bangladesh and the disease is endemic for many decades. In SEA Region, VL is reported from 109 contiguous districts bordering Bangladesh, India and Nepal. Approx. 147 million people at risk in these three countries with an estimated 50,000 new cases each year. Kala-azar or Leishmaniasis is a disease caused by protozoan parasites of the Leishmania genus. It is transmitted by the sand fly named Phlebotomus argentipes and affects largely the socially marginalized and the poorest communities. The parasite migrates to the internal organs such as liver, spleen and bone marrow and if left untreated, will almost always result in the death of the host. Signs and symptoms include fever, weight loss, fatigue, anemia, and substantial swelling of the spleen and occasionally liver. In Bangladesh, kala-azar cases were reported from 45 of 64 districts, >90% of cases were reported from just 10 districts. Mymensingh accounted for more than 50% of the total kala-azar cases reported in Bangladesh. Research in recent years has demonstrated the utility of non-invasive diagnostic modalities such as the direct agglutination test and rapid tests based on the immune response to the rK39 antigen. Primary kala-azar now can be easily recognized and effective treatment is available. Clinical trials in Bangladesh have reported encouraging results with amphotericin B (recommended as a third-line drug by the National Malaria Eradication Programme). Until a safe and effective vaccine is developed, a combination of sandfly control, detection and treatment of patients and prevention of drug resistance is the best approach for controlling kala-azar. CBMJ 2020 January: Vol. 09 No. 01 P: 43-50

Genetic Variability of PRRSV Vaccine Strains Used in the National Eradication Programme, Hungary

Porcine reproductive and respiratory syndrome (PRRS) is a globally spread, highly infectious viral disease. Live, attenuated vaccines against PRRS virus (PRRSV) decrease virus excretion and evoke protective immunity reducing the economic damage caused by the disease. In a longitudinal molecular epidemiological study accompanying ongoing national eradication programme we evaluated the suitability of PRRSV ORF5 and ORF7 sequences to identify possible field strains of vaccine-origin. In total, 2342 ORF5 sequences and 478 ORF7 sequences were analysed. Vaccine strains were identified by sequence identity values and phylogenetic network analysis. Strains that shared greater than 98% nucleotide identity within ORF5 and/or ORF7 were considered to have originated from vaccine. A total of 882 (37.6%) ORF5 and 88 (18.4%) ORF7 sequences met these criteria. In detail, 618, 179 and 35 ORF5 and 51, 29 and 8 ORF7 sequences were related to Porcilis PRRS vaccine, Unistrain PRRS vaccine, and ReproCyc PRRS EU vaccine, respectively. Data showed that the Porcilis vaccine was genetically more stable. Whereas, the variability of the Unistrain and the ReproCyc strains was significantly higher. Given that ORF7 shares, in some instances, complete identity between a particular vaccine strain and some historic variants of field PRRSV strains, care must be taken when evaluating vaccine relatedness of a field isolate based on the ORF7. On the contrary, ORF5 sequences were more suitable to predict the vaccine origin making a distinction more robustly between field and vaccine strains. We conclude that ORF5 based molecular epidemiological studies support more efficiently the ongoing PRRS eradication programmes. The conclusions presented in this large-scale PRRS molecular epidemiological study provides a framework for future eradication programmes planned in other countries.

Quantifying conflict zones as a challenge to certification of Guinea worm eradication in Africa: a new analytical approach

ObjectivesTo quantify conflict events and access across countries that remain to be certified free of transmission of Dracunculus medinensis (Guinea worm disease) or require postcertification surveillance as part of the Guinea Worm Eradication Programme (GWEP).Setting and participantsPopulations living in Guinea worm affected areas across seven precertification countries and 13 postcertification sub-Saharan African countries.Outcome measuresThe number of conflict events and rates per 100 000 population, the main types of conflict and actors reported to be responsible for events were summarised and mapped across all countries. Chad and Mali were presented as case studies. Guinea worm information was based on GWEP reports. Conflict data were obtained from the Armed Conflict Location and Event Data Project. Maps were created using ArcGIS V.10.7 and access was measured as regional distance and time to cities.ResultsMore than 980 000 conflict events were reported between 2000 and 2020, with a significant increase since 2018. The highest number and rates were reported in precertification Mali (n=2556; 13.0 per 100 000), South Sudan (n=2143; 19.4), Democratic Republic of Congo (n=7016; 8.1) and postcertification Nigeria (n=6903; 3.4), Central Africa Republic (n=1251; 26.4), Burkina Faso (n=2004; 9.7). Violence against civilians, protests and battles were most frequently reported with several different actors involved including Unidentified Armed Groups and Boko Haram. Chad and Mali had contracting epidemiological and conflict situations with affected regions up to 700 km from the capital or 10 hours to the nearest city.ConclusionsUnderstanding the spatial–temporal patterns of conflict events, identifying hotspots, the actors responsible and their sphere of influence is critical for the GWEP and other public health programmes to develop practical risk assessments, deliver essential health interventions, implement innovative surveillance, determine certification and meet the goals of eradication.

Social welfare program and poverty eradication in sub-saharan region of Eket Senatorial district, Akwa Ibom State, Nigeria

The study investigated development gap in social policy and social problem interaction by examining impact of National Poverty Eradication Programme (NAPEP) on rural communities in Akwa Ibom State, Nigeria. The specific objectives were to examine the relationship between non-participation of beneficiary communities in NAPEP project design at community level, corruption and policy implementation strategy on rural poverty reduction. The Ex-post facto research design was adopted to study communities in Oron and Udung Uko local government areas in Akwa Ibom State. Using a multistage sampling procedure, data were obtained from 400 respondents using Taro Yamene sample size determination formula. Data were analysed using Chi-square (X2) statistical technique. Main findings indicated that significant relationship exists between non-participation of beneficiary communities in NAPEP project design, corruption, policy implementation and poverty reduction in rural communities. The findings imply that NAPEP has not significantly achieved its goal of poverty reduction in rural communities. It has failed to elicit economic wellbeing priorities directly from target communities. Poverty can be reduced through accommodative and humanistic arrangements by allowing communities to identify welfare projects and eligible recipients. Rural dwellers have not experienced poverty reduction because of NAPEP development strategy gap.

Elimination of PRRS Using An Inactivated Vaccine in Combination With A Roll-Over Method in A Hungarian Large-Scale Pig Herd

Background:Four countries are free from the porcine reproductive and respiratory syndrome virus (PRRSV) in Europe, a virus that causes severe economic losses worldwide. A number of countries have initiated eradication programmes against the disease. Among the applied methods, complete depopulation-repopulation is the safest and fastest but at the same time the most expensive process. Another possible way of heard eradication is to replace the infected breading stock by gilts reared PRRSV free on the infected farm. This way maintaining continued farm production. In this paper, the authors present a successful complex method of eradication (including the application of an inactivated vaccine and segregated rearing of offspring) in a Hungarian large scale pig farm. Case presentation:A farm of 1475 sows (Farm A) was infected with PRRSV and the clinical signs of reproductive failure were eliminated by using an inactivated vaccine (Progressis®, Ceva). At the beginning of eradication, gilts selected for breeding were vaccinated at 60 and 90–100 days of age, respectively. The subsequent vaccinations of breeding animals were applied at 6 months of age, on the 60–70th day of pregnancy and at weaning. The 7weeks-old piglets of the vaccinated sows, approximately 1200 piglets were transported in groups of 300 animals to a closed, empty farm (Farm B) after a testing negative with PCR, and they were reared here until 14 weeks of age. These seronegative gilts were subsequently transported to a third, closed, empty farm (Farm C), and (having reached the breeding age) they were inseminated here after a negative serological test (ELISA). At the same time, Farm A was depopulated, cleaned and disinfected. All pregnant gilts were transported from Farm C to Farm A after being tested negative with ELISA, where follow-up was performed after farrowing by two serological tests with an interval of six months. Based on the subsequent negative test results, the competent authority declared the herd PRRSV free. Conclusions:The farm presented in this study was the first in the course of the National PRRS Eradication Programme to eradicate PRRSV successfully by vaccinating the sows with an inactivated vaccine and performing segregated rearing of the offspring. Production was almost continuous during the whole process of the population replacement. Testing for monitoring purposes was also cheaper and simpler because of the use of an inactivated vaccine.