Your search keyword '"disease freedom"' showing total 41 results

1. True prevalence and spatial distribution of antibodies to Brucella spp. in goat populations in Hubei Province, People’s Republic of China: Progress toward disease elimination

Author

Pei, Jie, Wang, Yu, Zhou, Yanjun, Huang, Tao, Xie, Jun, Guo, Aizhen, Chen, Yingyu, and Robertson, Ian D.

Published

2025

2. An Overview of Current Approaches and Challenges to the Control of Endemic Infectious Cattle Diseases in Albania

Author

Xhelil Koleci, Ali Lilo, Sotiraq Papa, Keti Margariti, Annika van Roon, Inge Santman-Berends, Gerdien van Schaik, Jaka Jakob Hodnik, Sam Strain, Maria Guelbenzu-Gonzalo, and Esa Karalliu

Subjects

cattle diseases, control programme, disease freedom, Standardizing Output-based surveillance to control Non-regulated Diseases of cattle in the EU, Albania, Veterinary medicine, SF600-1100

Abstract

Agriculture is an important production sector in Albania that makes a significant contribution to the gross domestic product (GDP) and employment. The livestock sector contributes more than half of the agricultural GDP. The Albanian cattle population represents 50% of the total livestock units and accounts for 85% of the national milk production, the rest being supplied by small ruminants. Cattle productivity, health and welfare are hindered by infectious diseases, some of which are also transmissible to humans (zoonosis). The aim of this manuscript is to provide an overview of the control of selected regulated and non-EU regulated cattle diseases in Albania and to highlight specific challenges for the Albanian cattle industry. The most important infectious cattle diseases in Albania for which national control and eradication strategies are in place are bovine brucellosis, bovine tuberculosis, and anthrax, which are all zoonotic. Additionally, lumpy skin disease recently emerged in the Balkan region and is currently subject to controls. Most of the available funds and European Union support are allocated to the control of EU regulated zoonotic diseases. For control of non-EU regulated cattle diseases, no funds are available resulting in the lack of national control programmes (CPs). Based on research, clinical investigations and laboratory results, several non-EU regulated cattle infectious diseases appear endemic in Albanian dairy farms. While no national CPs exist for any of them, regional initiatives are available on a voluntary basis to control infectious bovine rhinotracheitis and bovine viral diarrhea. In the voluntary CPs, there is no monitored requirement to prove disease freedom of purchased animals and to re-evaluate the herd's free status after the introduction of animals into a herd. Data on animal movements that are routinely collected could potentially be used to control the risk of purchase, but quality needs to be further improved to increase its usefulness in disease CPs. This overview aims to collate existing information on the CPs implemented in Albania and to evaluate these to highlight gaps and threats in disease control, as well as opportunities and strengths through a SWOT (Strengths, Weaknesses, Opportunities, and Threats) analysis, with the goal of providing a framework for the future implementation of animal disease control measures in Albania.

Published

2021

3. Classical swine fever in Victorian domestic pigs: evidence of disease freedom.

Author

Hunnam, JC, Moore, KM, Daniel, P, Stevenson, MA, and Salmon, SE

Subjects

*SWINE, *CLASSICAL swine fever, *AFRICAN swine fever, *COMMUNICABLE diseases, *EVIDENCE

Abstract

Objective: Australia is currently regarded as free of classical swine fever (CSF), a highly contagious disease of pigs caused by a pestivirus. This study aimed to provide additional evidence that the Victorian domestic pig population is free of CSF. Design: A structured representative sero‐prevalence survey of Victorian domestic pigs at slaughter. Method: Three‐hundred and ninety‐one pigs from 23 holdings were sampled at the time of slaughter between March 2016 and October 2017. Results: All samples were negative for CSF virus Ab on ELISA. Because of uncertainty in the sensitivity of the CSF Ab ELISA, estimates of the true prevalence of CSF were calculated using Bayesian methods. The median and upper bound of the 95% credible intervals for the true prevalence of CSF was zero when the diagnostic sensitivity of the CSF Ab ELISA was assumed to range from 0.75 to 0.95. Conclusion: These results provide evidence that the population of domestic pigs in Victoria in 2016‐2017 was free of CSF. [ABSTRACT FROM AUTHOR]

Published

2019

4. Estimating the herd and cow level prevalence of bovine digital dermatitis on New Zealand dairy farms: A Bayesian superpopulation approach.

Author

Yang, D.A., Johnson, W.O., Müller, K.R., Gates, M.C., and Laven, R.A.

Subjects

*DAIRY farming, *SKIN inflammation, *DISEASE prevalence, *BAYESIAN analysis, *LATENT class analysis (Statistics)

Abstract

Abstract A cross-sectional study of 127 dairy herds distributed across four regions of New Zealand (NZ) was conducted to estimate the regional herd-level prevalence of bovine digital dermatitis (BDD) and the prevalence of cows with BDD lesions within affected herds. Each herd was visited once during the 2016–2017 lactating season and the rear feet of all cows in the milking herd were examined to detect the presence of BDD lesions. Of the 127 herds examined, 63 had at least one cow with a detected BDD lesion. Of the 59 849 cows observed, 646 cows were observed with BDD lesions. All of the herds in which BBD was detected were located in three of the four regions (Waikato, Manawatu and South Canterbury). No convincing lesions were observed on the West Coast. The probability of BDD freedom on the West Coast was predicted to be 99.97% using a Bayesian latent class model. For the three regions where BDD lesions were observed, the true herd level and cow level prevalences were estimated using a Bayesian superpopulation approach which accounted for the imperfect diagnostic method. Based on priors obtained from previous research in another region of NZ (Taranaki), the true herd level prevalences in Waikato, Manawatu and South Canterbury were estimated to be 59.2% (95% probability interval [PI]: 44.3%–73.9%), 43.3% (95%PI: 29%–59%) and 65.9% (95%PI: 49.5%–79.9%), respectively, while the true median within-herd prevalences were estimated as 3.2% (95%PI: 2%–5%), 1.7% (95%PI: 0.9%–3.1%) and 3.7% (95%PI: 2.4%–5.5%), respectively. All of these estimates except for the true herd level prevalence in Manawatu were fairly robust to changes in the priors. For Manawatu region, changing from the prior obtained in Taranaki (the best estimate of the herd level prevalence = 60%, 95% sure > 40%) to one where the mode was 50% (95% sure < 80%) reduced the posterior from 43.3% to 35.2% (95%PI: 20.1%–53.5%). The marked variation in BDD prevalence between regions and between farms highlights the need for further exploration into risk factors for disease. [ABSTRACT FROM AUTHOR]

Published

2019

5. How to Demonstrate Freedom from African Swine Fever in Wild Boar—Estonia as an Example

Author

Katja Schulz, Christoph Staubach, Sandra Blome, Imbi Nurmoja, Arvo Viltrop, Franz J. Conraths, Maarja Kristian, and Carola Sauter-Louis

Subjects

African swine fever, disease freedom, wild boar, serology, surveillance, Medicine

Abstract

Estonia has been combatting African swine fever (ASF) for six years now. Since October 2017, the disease has only been detected in the wild boar population, but trade restrictions had to remain in place due to international regulations. Yet, the epidemiological course of the disease has changed within the last few years. The prevalence of ASF virus (ASFV)-positive wild boar decreased steadily towards 0%. In February 2019, the last ASFV-positive wild boar was detected. Since then, positive wild boar samples have exclusively been positive for ASFV-specific antibodies, suggesting the possible absence of circulating ASFV in the Estonian wild boar population. However, as the role of seropositive animals is controversially discussed and the presence of antibody-carriers is regarded as an indication of virus circulation at EU and OIE level, Estonia remains under trade restrictions. To make the disease status of a country reliable for trading partners and to facilitate the process of declaration of disease freedom, we suggest to monitor the prevalence of seropositive wild boar in absence of ASFV-positive animals. The possibility to include ASF in the list of diseases, for which an official pathway for recognition of disease status is defined by the OIE should be evaluated.

Published

2020

6. Roll-Back Eradication of Bovine Tuberculosis (TB) From Wildlife in New Zealand: Concepts, Evolving Approaches, and Progress

Author

Graham Nugent, Andrew M. Gormley, Dean P. Anderson, and Kevin Crews

Subjects

bovine tuberculosis, eradication, TB, possums, disease freedom, wildlife surveillance, Veterinary medicine, SF600-1100

Abstract

The New Zealand government and agricultural industries recently jointly adopted the goal of nationally eradicating bovine tuberculosis (TB) from livestock and wildlife reservoirs by 2055. Only Australia has eradicated TB from a wildlife maintenance host. Elsewhere the disease is often self-sustaining in a variety of wildlife hosts, usually making eradication an intractable problem. The New Zealand strategy for eradicating TB from wildlife is based on quantitative assessment using a Bayesian “Proof of Freedom” framework. This is used to assess the probability that TB has been locally eradicated from a given area. Here we describe the framework (the concepts, methods and tools used to assess TB freedom and how they are being applied and updated). We then summarize recent decision theory research aimed at optimizing the balance between the risk of falsely declaring areas free and the risk of overspending on disease management when the disease is already locally extinct. We explore potential new approaches for further optimizing the allocation of management resources, especially for places where existing methods are impractical or expensive, including using livestock as sentinels. We also describe how the progressive roll-back of locally eradicated areas scales up operationally and quantitatively to achieve and confirm eradication success over the entire country. Lastly, we review the progress made since the framework was first formally adopted in 2011. We conclude that eradication of TB from New Zealand is feasible, and that we are well on the way to achieving this outcome.

Published

2018

7. A new methodology to extrapolate disease freedom to an area using surveillance results from selected aquatic populations.

Author

Nérette, Pascale, Brown, Emily, Gautam, Raju, Paré, Julie, and Wagener, Annie

Subjects

*ANIMAL health, *LIBERTY, *AQUATIC animals, *FREE ports & zones

Abstract

According to Chapter 1.4 of the World Organisation for Animal Health (WOAH) Aquatic Animal Health Code, an entire country or zone can be classified as free of a disease only if there is compelling evidence that all susceptible populations within the country or zone are free. However, the methods for achieving freedom are not prescribed in the WOAH standards and guidelines. Within this context, this paper describes a novel methodology to determine if surveillance results can be extrapolated from a study population to a target population. A framework of six criteria was developed to standardize a method for extrapolating surveillance results to other susceptible populations that have not been sampled. Criteria 1 assesses the internal validity for the freedom claim on the source population. Criteria 2 assesses which other susceptible populations have a non-negligible probability of exposure. Criteria 3 assesses whether the risk of infection upon exposure of the source population is the same or greater than each of the other susceptible populations. Finally, Criteria 4, 5 and 6 assess if the other susceptible populations would transmit the infection to the source population or if they have the same exposure pathways as the source population. We illustrate the use of this novel methodology using two hypothetical case scenarios. The presented methodology has the advantage of being applicable either retrospectively or prospectively. When applied retrospectively, it can be used to assess if the surveillance results of the source population can be extrapolated to the target population. When applied prospectively it can be used to design a more efficient surveillance system by selecting source populations from which it is easier to extrapolate surveillance results to the rest of the target population. Conclusions drawn using this methodology depend on the validity of the assumptions made when working through the methodology. We therefore recommend cautious application of the criteria and thorough review of all assumptions. [ABSTRACT FROM AUTHOR]

Published

2023

8. Herd and within-herd BoHV-1 prevalence among irish beef herds submitting bulls for entry to a performance testing station

Author

O'Grady L, O'Neill R, Collins DM, Clegg TA, and More SJ

Subjects

beef herds, BoHV-1, bovine herpes virus 1, disease freedom, IBR, infectious bovine rhinotracheitis, Ireland, prevalence, Veterinary medicine, SF600-1100

Abstract

Abstract Infectious bovine rhinotracheitis (IBR), caused by bovine herpes virus 1 (BoHV-1), may result in various clinical consequences, including severe respiratory disease and conjunctivitis, venereal disease and reduced reproductive performance and abortion. This paper presents the serosurveillance findings from an intake of bulls into a performance testing station in Ireland during November 2007. The herd and within-herd BoHV-1 prevalence in 53 Irish beef herds and the risk factors for infection in these herds were determined, among bulls entering a beef performance testing station in Ireland. BoHV-1 status was determined for 41 herds, of which 30 (73.2%) herds were infected and the mean within-herd BoHV-1 prevalence was 28 (± 20)%. Multivariate exact logistic modelling revealed increasing numbers of contiguous herds and decreasing percentage of males within the herd as significant risk factors associated with infected herds. These findings highlight the high prevalence of BoHV-1 infection in those Irish beef herds that submitted bulls to this performance testing station, and raise concerns regarding IBR control nationally.

Published

2008

9. Analysis of German BSE Surveillance Data: Estimation of the Prevalence of Confirmed Cases versus the Number of Infected, but Non-Detected, Cattle to Assess Confidence in Freedom from Infection

Author

Anne Balkema-Buschmann, Thomas Selhorst, Franz Josef Conraths, Christine Müller-Graf, Wesley O. Johnson, and Matthias Greiner

Subjects

Freedom, Surveillance data, Response model, animal diseases, Health, Toxicology and Mutagenesis, prevalence, Poisson distribution, Risk Assessment, Article, BSE, symbols.namesake, disease freedom, Germany, Credible interval, Medicine, Animals, Point estimation, Estimation, business.industry, Public Health, Environmental and Occupational Health, Bayes Theorem, non-detects, Encephalopathy, Bovine Spongiform, Bayesian model, symbols, Cattle, Risk assessment, Birth cohort, business, Demography

Abstract

Quantitative risk assessments for Bovine spongiform encephalopathy (BSE) necessitate estimates for key parameters such as the prevalence of infection, the probability of absence of infection in defined birth cohorts, and the numbers of BSE-infected, but non-detected cattle entering the food chain. We estimated three key parameters with adjustment for misclassification using the German BSE surveillance data using a Gompertz model for latent (i.e., unobserved) age-dependent detection probabilities and a Poisson response model for the number of BSE cases for birth cohorts 1999 to 2015. The models were combined in a Bayesian framework. We estimated the median true BSE prevalence between 3.74 and 0.216 cases per 100,000 animals for the birth cohorts 1990 to 2001 and observed a peak for the 1996 birth cohort with a point estimate of 16.41 cases per 100,000 cattle. For birth cohorts ranging from 2002 to 2013, the estimated median prevalence was below one case per 100,000 heads. The calculated confidence in freedom from disease (design prevalence 1 in 100,000) was above 99.5% for the birth cohorts 2002 to 2006. In conclusion, BSE surveillance in the healthy slaughtered cattle chain was extremely sensitive at the time, when BSE repeatedly occurred in Germany (2000–2009), because the entry of BSE-infected cattle into the food chain could virtually be prevented by the extensive surveillance program during these years and until 2015 (estimated non-detected cases/100.000 [95% credible interval] in 2000, 2009, and 2015 are 0.64 [0.5,0.8], 0.05 [0.01,0.14], and 0.19 [0.05,0.61], respectively).

Published

2021

10. An Overview of Current Approaches and Challenges to the Control of Endemic Infectious Cattle Diseases in Albania

Author

Koleci, Xhelil, van Roon, Annika, Santman-Berends, Inge, van Schaik, Gerdien, Hodnik, Jaka Jakob, Strain, Sam, Guelbenzu-Gonzalo, Maria, Koleci, Xhelil, van Roon, Annika, Santman-Berends, Inge, van Schaik, Gerdien, Hodnik, Jaka Jakob, Strain, Sam, and Guelbenzu-Gonzalo, Maria

Abstract

Agriculture is an important production sector in Albania that makes a significant contribution to the gross domestic product (GDP) and employment. The livestock sector contributes more than half of the agricultural GDP. The Albanian cattle population represents 50% of the total livestock units and accounts for 85% of the national milk production, the rest being supplied by small ruminants. Cattle productivity, health and welfare are hindered by infectious diseases, some of which are also transmissible to humans (zoonosis). The aim of this manuscript is to provide an overview of the control of selected regulated and non-EU regulated cattle diseases in Albania and to highlight specific challenges for the Albanian cattle industry. The most important infectious cattle diseases in Albania for which national control and eradication strategies are in place are bovine brucellosis, bovine tuberculosis, and anthrax, which are all zoonotic. Additionally, lumpy skin disease recently emerged in the Balkan region and is currently subject to controls. Most of the available funds and European Union support are allocated to the control of EU regulated zoonotic diseases. For control of non-EU regulated cattle diseases, no funds are available resulting in the lack of national control programmes (CPs). Based on research, clinical investigations and laboratory results, several non-EU regulated cattle infectious diseases appear endemic in Albanian dairy farms. While no national CPs exist for any of them, regional initiatives are available on a voluntary basis to control infectious bovine rhinotracheitis and bovine viral diarrhea. In the voluntary CPs, there is no monitored requirement to prove disease freedom of purchased animals and to re-evaluate the herd's free status after the introduction of animals into a herd. Data on animal movements that are routinely collected could potentially be used to control the risk of purchase, but quality needs to be further improved to increase its

Published

2021

11. Routine clinical inspections in Norwegian marine salmonid sites: A key role in surveillance for freedom from pathogenic viral haemorrhagic septicaemia (VHS).

Author

Lyngstad, Trude Marie, Hellberg, Hege, Viljugrein, Hildegunn, Bang Jensen, Britt, Brun, Edgar, Sergeant, Evan, and Tavornpanich, Saraya

Subjects

*VIRAL hemorrhagic septicemia, *SALMONIDAE diseases, *AQUACULTURE, *FISHES, *BIOLOGISTS, *VETERINARY services, *ANIMAL health

Abstract

Since the mid-1980s, clinical inspections of aquaculture sites carried out on a regular basis by authorized veterinarians and fish health biologists (known as fish health services: FHS) have been an essential part of aquatic animal health surveillance in Norway. The aims of the present study were (1) to evaluate the performance of FHS routine clinical inspections for the detection of VHS and (2) to explore the effectiveness of risk-based prioritisation of FHS inspections for demonstrating freedom from VHS in marine salmonid sites in Norway. A stochastic simulation model was developed to estimate site sensitivity (SeS), population sensitivity (SeP), and probability of freedom (PFree). The estimation of SeS takes into consideration the probability that FHS submit samples if a site is infected, the probability that a sample is tested if submitted, the effective probability of infection in fish with clinical signs, laboratory test sensitivity, and the number of tested samples. SeP and PFree were estimated on a monthly basis over a 12 month period for six alternative surveillance scenarios and included the risk factors: region, species, area production density, and biosecurity level. Model results indicate that the current surveillance system, based on routine inspections by the FHS has a high capability for detecting VHS and that there is a high probability of freedom from VHS in Norwegian marine farmed salmonids (PFree >95%). Sensitivity analysis identified the probabilities that samples are submitted and submitted samples are tested, as the most influential input variables. The model provides a supporting tool for evaluation of potential changes in the surveillance strategy, and can be viewed as a platform for similar exotic viral infectious diseases in marine salmonid farming in Norway, if they share similar risk factors. [ABSTRACT FROM AUTHOR]

Published

2016

12. Bluetongue Virus RNA Detection by Real-Time RT- PCR in Post-Vaccination Samples from Cattle.

Author

De Leeuw, I., Garigliany, M., Bertels, G., Willems, T., Desmecht, D., and De Clercq, K.

Subjects

*BLUETONGUE, *BLUETONGUE virus, *CATTLE diseases, *REVERSE transcriptase polymerase chain reaction, *SEROTYPES, *BLOOD circulation, *DIAGNOSIS, *VACCINATION

Abstract

Bluetongue virus serotype 8 ( BTV-8) was responsible for a large outbreak among European ruminant populations in 2006-2009. In spring 2008, a massive vaccination campaign was undertaken, leading to the progressive disappearance of the virus. During surveillance programmes in Western Europe in 2010-2011, a low but significant number of animals were found weakly positive using BTV-specific real-time RT- PCR, raising questions about a possible low level of virus circulation. An interference of the BTV-8 inactivated vaccine on the result of the real-time RT- PCR was also hypothesized. Several studies specifically addressed the potential association between a recent vaccination and BTV-8 RNA detection in the blood of sheep. Results were contradictory and cattles were not investigated. To enlighten this point, a large study was performed to determine the risks of detection of bluetongue vaccine-associated RNA in the blood and spleen of cattle using real-time RT- PCR. Overall, the results presented clearly demonstrate that vaccine viral RNA can reach the blood circulation in sufficient amounts to be detected by real-time RT- PCR in cattle. This BTV-8 vaccine RNA carriage appears as short lasting. [ABSTRACT FROM AUTHOR]

Published

2015

13. Model for ranking freshwater fish farms according to their risk of infection and illustration for viral haemorrhagic septicaemia.

Author

Oidtmann, Birgit C., Pearce, Fiona M., Thrush, Mark A., Peeler, Edmund J., Ceolin, Chiara, Stärk, Katharina D.C., Pozza, Manuela Dalla, Afonso, Ana, Diserens, Nicolas, Reese, R. Allan, and Cameron, Angus

Subjects

*VIRAL hemorrhagic septicemia, *INFECTIONS in fish, *INFECTION risk factors, *FISH pathogens, *FRESHWATER fishes, *FISH farming, *AQUACULTURE

Abstract

Abstract: We developed a model to calculate a quantitative risk score for individual aquaculture sites. The score indicates the risk of the site being infected with a specific fish pathogen (viral haemorrhagic septicaemia virus (VHSV); infectious haematopoietic necrosis virus, Koi herpes virus), and is intended to be used for risk ranking sites to support surveillance for demonstration of zone or member state freedom from these pathogens. The inputs to the model include a range of quantitative and qualitative estimates of risk factors organised into five risk themes (1) Live fish and egg movements; (2) Exposure via water; (3) On-site processing; (4) Short-distance mechanical transmission; (5) Distance-independent mechanical transmission. The calculated risk score for an individual aquaculture site is a value between zero and one and is intended to indicate the risk of a site relative to the risk of other sites (thereby allowing ranking). The model was applied to evaluate 76 rainbow trout farms in 3 countries (42 from England, 32 from Italy and 2 from Switzerland) with the aim to establish their risk of being infected with VHSV. Risk scores for farms in England and Italy showed great variation, clearly enabling ranking. Scores ranged from 0.002 to 0.254 (mean score 0.080) in England and 0.011 to 0.778 (mean of 0.130) for Italy, reflecting the diversity of infection status of farms in these countries. Requirements for broader application of the model are discussed. Cost efficient farm data collection is important to realise the benefits from a risk-based approach. [Copyright &y& Elsevier]

Published

2014

14. Viral hemorrhagic septicemia IVb status in the United States: Inferences from surveillance activities and regional context.

Author

Gustafson, L.L., Remmenga, M.D., Gardner, I.A., Hartman, K.H., Creekmore, L.H., Goodwin, A.E., Whaley, J.E., Warg, J.V., Gardner, S.L., and Scott, A.E.

Subjects

*VIRAL hemorrhagic septicemia, *VIRAL replication, *TEMPERATURE effect, *BAYESIAN analysis, *RISK assessment

Abstract

Abstract: The United States (U.S.) response to viral hemorrhagic septicemia virus (VHSV) IVb emergence in the Laurentian Great Lakes (GL) included risk-based surveillance for cost-effective decision support regarding the health of fish populations in open systems. All U.S. VHSV IVb isolations to date derive from free-ranging fish from GL States. Most originate in the region designated by US Geological Survey hydrologic unit code (HUC) 04, with the exception of two detections in neighboring Upper Mississippi (HUC 05) and Ohio (HUC 07) regions. For States outside the GL system, disease probability was assessed using multiple evidence sources. None substantiated VHSV IVb absence using surveillance alone, in part due to the limited temporal relevance of data in open systems. However, Bayesian odds risk-based analysis of surveillance and population context, coupled with exclusions where water temperatures likely preclude viral replication, achieved VHSV IVb freedom assurance for 14 non-GL States by the end of 2012, with partial evidence obtained for another 17 States. The non-GL region (defined as the aggregate of 4-digit HUCs located outside of GL States) met disease freedom targets for 2012 and is projected to maintain this status through 2016 without additional active surveillance. Projections hinge on continued basic biosecurity conditions such as movement restrictions and passive surveillance. Areas with navigable waterway connections to VHSV IVb-affected HUCs (and conducive water temperatures) should receive priority for resources in future surveillance or capacity building efforts. However, 6 years of absence of detections in non-GL States suggests that existing controls limit pathogen spread, and that even spread via natural pathways (e.g., water movement or migratory fish) appears contained to the Great Lakes system. This report exemplifies the cost-effective use of risk-based surveillance in decision support to assess and manage aquatic animal population health in open systems. [Copyright &y& Elsevier]

Published

2014

15. Adapting a scenario tree model for freedom from disease as surveillance progresses: The Canadian notifiable avian influenza model.

Author

Christensen, Jette, El Allaki, Farouk, and Vallières, André

Subjects

*AVIAN influenza, *ANIMAL diseases, *PROBABILITY theory, *PARAMETERS (Statistics), *PATHOGENIC microorganisms, *STOCHASTIC processes

Abstract

Abstract: Scenario tree models with temporal discounting have been applied in four continents to support claims of freedom from animal disease. Recently, a second (new) model was developed for the same population and disease. This is a natural development because surveillance is a dynamic process that needs to adapt to changing circumstances – the difficulty is the justification for, documentation of, presentation of and the acceptance of the changes. Our objective was to propose a systematic approach to present changes to an existing scenario tree model for freedom from disease. We used the example of how we adapted the deterministic Canadian Notifiable Avian Influenza scenario tree model published in 2011 to a stochastic scenario tree model where the definition of sub-populations and the estimation of probability of introduction of the pathogen were modified. We found that the standardized approach by Vanderstichel et al. (2013) with modifications provided a systematic approach to make and present changes to an existing scenario tree model. We believe that the new 2013 CanNAISS scenario tree model is a better model than the 2011 model because the 2013 model included more surveillance data. In particular, the new data on Notifiable Avian Influenza in Canada from the last 5 years were used to improve input parameters and model structure. [Copyright &y& Elsevier]

Published

2014

16. How to Demonstrate Freedom from African Swine Fever in Wild Boar-Estonia as an Example

Author

Christoph Staubach, Katja Schulz, Sandra Blome, Carola Sauter-Louis, Maarja Kristian, Arvo Viltrop, Imbi Nurmoja, and Franz Josef Conraths

Subjects

0301 basic medicine, Disease status, medicine.medical_specialty, endocrine system, 040301 veterinary sciences, Immunology, Population, Zoology, lcsh:Medicine, serology, Disease, Virus, Article, Serology, 0403 veterinary science, 03 medical and health sciences, Wild boar, disease freedom, biology.animal, Drug Discovery, Epidemiology, medicine, Pharmacology (medical), education, Pharmacology, education.field_of_study, biology, African swine fever, urogenital system, lcsh:R, 04 agricultural and veterinary sciences, 030104 developmental biology, Infectious Diseases, surveillance, wild boar

Abstract

Estonia has been combatting African swine fever (ASF) for six years now. Since October 2017, the disease has only been detected in the wild boar population, but trade restrictions had to remain in place due to international regulations. Yet, the epidemiological course of the disease has changed within the last few years. The prevalence of ASF virus (ASFV)-positive wild boar decreased steadily towards 0%. In February 2019, the last ASFV-positive wild boar was detected. Since then, positive wild boar samples have exclusively been positive for ASFV-specific antibodies, suggesting the possible absence of circulating ASFV in the Estonian wild boar population. However, as the role of seropositive animals is controversially discussed and the presence of antibody-carriers is regarded as an indication of virus circulation at EU and OIE level, Estonia remains under trade restrictions. To make the disease status of a country reliable for trading partners and to facilitate the process of declaration of disease freedom, we suggest to monitor the prevalence of seropositive wild boar in absence of ASFV-positive animals. The possibility to include ASF in the list of diseases, for which an official pathway for recognition of disease status is defined by the OIE should be evaluated.

Published

2020

17. Risk-based methods for fish and terrestrial animal disease surveillance.

Author

Oidtmann, Birgit, Peeler, Edmund, Lyngstad, Trude, Brun, Edgar, Bang Jensen, Britt, and Stärk, Katharina D.C.

Subjects

*ANIMAL diseases, *EARTH analogs, *FISH diseases, *AQUATIC animals, *FOLLOW-up studies (Medicine), *DISEASE prevalence, *DISEASE risk factors

Abstract

Abstract: Over recent years there have been considerable methodological developments in the field of animal disease surveillance. The principles of risk analysis were conceptually applied to surveillance in order to further develop approaches and tools (scenario tree modelling) to design risk-based surveillance (RBS) programmes. In the terrestrial animal context, examples of risk-based surveillance have demonstrated the substantial potential for cost saving, and a similar benefit is expected also for aquatic animals. RBS approaches are currently largely absent for aquatic animal diseases. A major constraint in developing RBS designs in the aquatic context is the lack of published data to assist in the design of RBS: this applies to data on (i) the relative risk of farm sites becoming infected due to the presence or absence of a given risk factor; (ii) the sensitivity of diagnostic tests (specificity is often addressed by follow-up investigation and re-testing and therefore less of a concern); (iii) data on the variability of prevalence of infection for fish within a holding unit, between holding units and at farm level. Another constraint is that some of the most basic data for planning surveillance are missing, e.g. data on farm location and animal movements. In Europe, registration or authorisation of fish farms has only recently become a requirement under EU Directive 2006/88. Additionally, the definition of the epidemiological unit (at site or area level) in the context of aquaculture is a challenge due to the often high level of connectedness (mainly via water) of aquaculture facilities with the aquatic environment. This paper provides a review of the principles, methods and examples of RBS in terrestrial, farmed and wild animals. It discusses the special challenges associated with surveillance for aquatic animal diseases (e.g. accessibility of animals for inspection and sampling, complexity of rearing systems) and provides an overview of current developments relevant for the design of RBS for fish diseases. Suggestions are provided on how the current constraints to applying RBS to fish diseases can be overcome. [Copyright &y& Elsevier]

Published

2013

18. Spring viraemia of carp (SVC) in the UK: The road to freedom.

Author

Taylor, N.G.H., Peeler, E.J., Denham, K.L., Crane, C.N., Thrush, M.A., Dixon, P.F., Stone, D.M., Way, K., and Oidtmann, B.C.

Subjects

*VIREMIA, *CARP, *FISH diseases, *LIBERTY, *CYPRINIDAE, *FISH mortality, *CYSTITIS

Abstract

Abstract: Spring viraemia of carp (SVC) is a disease of international importance that predominantly affects cyprinid fish and can cause significant mortality. In the United Kingdom (UK), SVC was first detected in 1977 with further cases occurring in fisheries, farms, wholesale and retail establishments throughout England and Wales (but not Scotland, where few cyprinid populations exist, nor Northern Ireland where SVC has never been detected) over the subsequent 30years. Following a control and eradication programme for the disease initiated in 2005, the UK was recognised free of the disease in 2010. This study compiles historic records of SVC cases in England and Wales with a view to understanding its routes of introduction and spread, and assessing the effectiveness of the control and eradication programme in order to improve contingency plans to prevent and control future disease incursions in the cyprinid fish sectors. Between 1977 and 2010 the presence of SVC was confirmed on 108 occasions, with 65 of the cases occurring in sport fisheries and the majority of the remainder occurring in the ornamental fish sector. The study found that throughout the history of SVC in the UK, though cases were widely distributed, their occurrence was sporadic and the virus did not become endemic. All evidence indicates that SVC was not able to persist under UK environmental conditions, suggesting that the majority of cases were a result of new introductions to the UK as opposed to within-country spread. The control and eradication programme adopted in 2005 was highly effective and two years after its implementation cases of SVC ceased. Given the non-persistent nature of the pathogen the most important aspect of the control programme focused on preventing re-introduction of the virus to the UK. Despite the effectiveness of these controls against SVC, this approach is likely to be less effective against more persistent pathogens such as koi herpesvirus, which are likely to require more stringent measures to prevent within-country spread. [Copyright &y& Elsevier]

Published

2013

19. Integrating expert judgment in veterinary epidemiology: Example guidance for disease freedom surveillance

Author

Gustafson, L.L., Gustafson, D.H., Antognoli, M.C., and Remmenga, M.D.

Subjects

*VETERINARY epidemiology, *MEDICAL decision making, *EPIDEMIOLOGY, *SYSTEM analysis, *INFECTIOUS disease transmission, *PUBLIC health, *QUALITY control

Abstract

Abstract: Expert opinions supplement empirical data in many epidemiologic assessments. For veterinary disease freedom surveillance, where the geographic scope of concern is often broad, populations subject to change, decisions eminent and empirical data, expert opinion can be a critical component of the decision making process. However, opinion is by definition subjective and the manner in which opinion is sought can impact the quality and reliability of estimates. Group interaction can hinder or improve the estimation process, depending on its facilitation. Further, whether and how validation is conducted can limit or increase acceptance of the resulting model. While the utility of expert opinion is widely recognized in many fields, and the impact of its use or misuse implicit, standards for application to veterinary assessments are not readily available. This paper aims to foster discussion on this influential component of epidemiology, with disease freedom application as a focus. Benefits and concerns attributed to expert judgment and guidelines for its structured elicitation are described, borrowing insights from its long history of use in decision science fields and examples from recent veterinary assessments. [Copyright &y& Elsevier]

Published

2013

20. A diagnostic study of Echinococcus multilocularis in red foxes (Vulpes vulpes) from Great Britain

Author

Learmount, J., Zimmer, I.A., Conyers, C., Boughtflower, V.D., Morgan, C.P., and Smith, G.C.

Subjects

*ECHINOCOCCUS multilocularis, *RED fox, *ECHINOCOCCUS granulosus, *DOMESTIC animal diseases, *TAPEWORMS

Abstract

Abstract: Alveolar echinococosis is caused by a parasitic tapeworm Echinococcus multilocularis and is a serious disease with high fatality in humans. The definitive primary host is the red fox (Vulpes vulpes) but domestic animals (dogs and to a lesser extent cats) as well as several genera of rodents can also be infected with the parasite. There is, to date, no evidence of indigenous cases of E. multilocularis in Great Britain (GB) but in most of continental Europe the parasite is considered to be endemic and/or slowly spreading. All pet dogs entering the United Kingdom (UK) under the pet travel scheme (PETS) are therefore currently treated with an anthelmintic effective against Echinococcus spp. Surveillance of red foxes is required to demonstrate disease freedom and maintain this regulation to prevent further geographical spread of the parasite to free areas within the EU. A study of 588 wild red foxes collected from across Great Britain (GB) between October 1999 and November 2000 found no Echinococcus spp. This report describes a further study of GB foxes collected predominately during 2005 and 2006. Fox faecal samples (n =384) were examined for both E. multilocularis and Echinococcus granulosus using an egg isolation procedure followed by PCR method, based on published primer sets. A non-specific primer set that amplifies Taenia spp. as well as Mesocestoides, Dipylidium and Diphyllobothrium was also included in the assay to validate the test procedure as these parasites are expected to be more common in wild fox populations. All faecal samples tested negative for both E. multilocularis and E. granulosus but results for approximately 35% of the samples indicated the presence of Taenia spp. or other closely related cestodes. This data contributes to the evidence that suggests that E. multilocularis is not present in mainland Britain and justifies the requirement for ongoing surveillance to demonstrate disease freedom. [Copyright &y& Elsevier]

Published

2012

21. A practical framework for conducting Foreign Animal Disease surveillance

Author

Christensen, Jette

Subjects

*ANIMAL diseases, *ANIMAL health, *PROJECT management, *STRUCTURAL frames, *DOCUMENTATION, *SCIENCE

Abstract

Abstract: This manuscript was written in honour of Dr. Preben Willeberg to illustrate some tools that may be useful to “make surveillance happen” and to build bridges between science and application in animal health surveillance. The paper illustrates how four elements (science, project management, communication and documentation) may be combined with some tools into a practical framework for Foreign Animal Disease surveillance. Specifically, I will show how the four elements are essential to make surveillance happen and provide a link between science and application in animal health surveillance. The Canadian Notifiable Avian Influenza Surveillance system is used as an example. In surveillance for Foreign Animal Diseases (FAD), with veterinary authorities as the lead and with many stakeholders, project management can support science in building evidence (documentation) that can be delivered (communicated) to trade negotiators and international trade partners. To bridge the gap between science and application in FAD surveillance I propose that we need people with skills in science, project management, communication and documentation. [Copyright &y& Elsevier]

Published

2012

22. Costs and benefits of freedom from shrimp diseases in the European Union

Author

Peeler, Edmund J.

Subjects

*AQUACULTURE, *SHRIMP diseases, *PENAEIDAE

Abstract

Abstract: The growth in penaeid shrimp aquaculture has been mirrored by the emergence of a number of serious diseases, some of which (e.g. white spot syndrome virus – WSSV) spread rapidly across the globe through movement of infected stock. The World Organisation for Animal Health (OIE) lists six penaeid shrimp pathogens of which three are notifiable in the EU: WSSV (listed as non-exotic to the EU), Taura syndrome virus (TSV) and yellow head disease (YHD) (both listed as exotic). EU Member States (MS) must determine a status for non-exotic diseases (e.g. disease free, unknown, infected). In developing a policy for WSSV, import risk analysis (IRA) can be used to systematically assess the risks of introduction and justify risk mitigation to maintain freedom. OIE guidelines recommend that countries assess the risk of disease introduction via commodities, not listed by the OIE as safe, and apply sanitary measures if necessary. The sanitary measures necessary to maintain freedom from WSSV may not be compatible with current EU animal health legislation. The recent revision by OIE of products listed as safe for international trade strengthens the case for the risks of TSV and YHD introduction into the EU to be assessed. Freedom from WSSV is an important criterion for the development of shrimp aquaculture in the EU. However, in developing disease control policy, governments need to balance the potentially competing interests of all stakeholders, including consumers. Thus economic modelling of the impact of possible sanitary measures on consumer prices of imported products is needed to support decision making. The creation of disease free compartments and post-import risk mitigation for commodities may create the conditions conducive to the development of shrimp aquaculture whilst minimising the costs of maintaining disease freedom. [Copyright &y& Elsevier]

Published

2012

23. Crustacean diseases in European legislation: Implications for importing and exporting nations

Author

Stentiford, G.D., Oidtmann, B., Scott, A., and Peeler, E.J.

Subjects

*CRUSTACEAN diseases, *SEAFOOD industry, *BIOSECURITY, *MOLLUSKS, *VIRUS diseases, *LAW

Abstract

Abstract: EC Council Directive 2006/88/EC, adopted during 2008, has for the first time introduced controls for crustacean diseases to be applied across all Member States of the European Union. It lists three crustacean diseases, all of which are caused by viral pathogens and primarily associated with the production of marine penaeid shrimp: White Spot Disease (WSD) caused by the White Spot Syndrome Virus (WSSV), Yellowhead disease (YHD) caused by Yellowhead Virus (YHV) and Taura syndrome (TS) caused by Taura syndrome Virus (TSV). Under Directive 2006/88/EC, WSD is listed as ‘non-exotic’ to the EU while YHD and TS are listed as exotic. The listing of crustacean diseases in the Directive recognises the global potential for the transboundary movement of economically and ecologically significant pathogens with live animals and with aquatic animal products and in essence, aligns approaches to biosecurity of farmed and wild crustacean populations of Europe with measures in place for molluscan shellfish and for finfish. Here, we discuss the implications of Directive 2006/88/EC for European Union Member States (net importers) and for producer nations wishing to export live crustaceans and associated products into the European Union. These implications are further compared to recommendations from the World Organisation for Animal Health (OIE) for trading of live crustaceans and products arising from them. [Copyright &y& Elsevier]

Published

2010

24. Methodological approach for substantiating disease freedom in a heterogeneous small population. Application to ovine scrapie, a disease with a strong genetic susceptibility

Author

Martinez, Marie-José, Durand, Benoit, Calavas, Didier, and Ducrot, Christian

Subjects

*SCRAPIE, *GENETICS of disease susceptibility, *COMMUNICABLE diseases in animals, *DISEASE prevalence, *HYPERGEOMETRIC distribution, *DISEASE risk factors, *ANIMAL populations

Abstract

Abstract: Demonstrating disease freedom is becoming important in different fields including animal disease control. Most methods consider sampling only from a homogeneous population in which each animal has the same probability of becoming infected. In this paper, we propose a new methodology to calculate the probability of detecting the disease if it is present in a heterogeneous population of small size with potentially different risk groups, differences in risk being defined using relative risks. To calculate this probability, for each possible arrangement of the infected animals in the different groups, the probability that all the animals tested are test-negative given this arrangement is multiplied by the probability that this arrangement occurs. The probability formula is developed using the assumption of a perfect test and hypergeometric sampling for finite small size populations. The methodology is applied to scrapie, a disease affecting small ruminants and characterized in sheep by a strong genetic susceptibility defining different risk groups. It illustrates that the genotypes of the tested animals influence heavily the confidence level of detecting scrapie. The results present the statistical power for substantiating disease freedom in a small heterogeneous population as a function of the design prevalence, the structure of the sample tested, the structure of the herd and the associated relative risks. [Copyright &y& Elsevier]

Published

2010

25. Combining surveillance and expert evidence of viral hemorrhagic septicemia freedom: A decision science approach

Author

Gustafson, L., Klotins, K., Tomlinson, S., Karreman, G., Cameron, A., Wagner, B., Remmenga, M., Bruneau, N., and Scott, A.

Subjects

*VIRAL hemorrhagic septicemia, *VIRUS disease transmission, *VIRUS diseases, *DECISION support systems, *BAYESIAN analysis, *INFORMATION resources, *DISEASE risk factors

Abstract

Abstract: The ability to combine evidence streams to establish disease freedom or prioritize surveillance is important for the evaluation of emerging diseases, such as viral hemorrhagic septicemia virus (VHSV) IVb in freshwater systems of the United States and Canada. Waterways provide a relatively unconstrained pathway for the spread of VHSV; and structured surveillance for emerging disease in open systems has many challenges. We introduce a decision framework for estimating VHSV infection probability that draws from multiple evidence streams and addresses challenges associated with the assessment of emerging disease. Using this approach, historical and risk-based evidence, whether empirical or expert-derived, supplement surveillance data to estimate disease probability. Surveillance-based estimates of VHSV prevalence were described using beta distributions. Subjective likelihood ratios (LRs), representing contextual risk, were elicited by asking experts to estimate the predicted occurrence of risk factors among VHSV-affected vs. VHSV-unaffected watersheds. We used the odds form of Bayes’ theorem to aggregate expert and surveillance evidence to predict the risk-adjusted posterior probability of VHSV-infection for given watersheds. We also used LRs representing contextual risk to quantify the time value of past surveillance data. This evidence aggregation model predicts disease probability from the combined assessment of multiple sources of information. The method also provides a flexible framework for iterative revision of disease freedom status as knowledge and data evolve. [Copyright &y& Elsevier]

Published

2010

26. Alternative Methods for Computing the Sensitivity of Complex Surveillance Systems.

Author

Hood, G. M., Barry, S. C., and Martin, P. A. J.

Subjects

ELECTRONIC surveillance, BAYESIAN analysis, STOCHASTIC analysis, TREE diseases & pests, TREE care, TREE injuries

Abstract

Stochastic scenario trees are a new and popular method by which surveillance systems can be analyzed to demonstrate freedom from pests and disease. For multiple component systems—such as a combination of a serological survey and systematically collected observations—it can be difficult to represent the complete system in a tree because many branches are required to represent complex conditional relationships. Here we show that many of the branches of some scenario trees have identical outcomes and are therefore redundant. We demonstrate how to prune branches and derive compact representations of scenario trees using matrix algebra and Bayesian belief networks. The Bayesian network representation is particularly useful for calculation and exposition. It therefore provides a firm basis for arguing disease freedom in international forums. [ABSTRACT FROM AUTHOR]

Published

2009

27. Probability of freedom from disease after the first detection and eradication of PRRS in Sweden: Scenario-tree modelling of the surveillance system

Author

Frössling, Jenny, Ågren, Estelle Carina Constance, Eliasson-Selling, Lena, and Lewerin, Susanna Sternberg

Subjects

*PORCINE reproductive & respiratory syndrome, *COMMUNICABLE diseases in animals, *VETERINARY medicine, *ANIMAL health, *MATHEMATICAL models in medicine, *SERODIAGNOSIS, *SENSITIVITY analysis

Abstract

Abstract: In July 2007, PRRS was detected for the first time in Sweden. A total of eight positive herds were identified and various measures were taken to eradicate the disease, including restrictions and slaughter of infected herds. Subsequently, both active and passive surveillance activities were undertaken. This study describes stochastic scenario-tree modelling of all the various surveillance system components, to estimate the current probability that Sweden is free from PRRS. The model includes all actions taken after the first positive herd was detected. The surveillance system components included in the model were as follows: investigations undertaken in association with the outbreak, a serological study based on samples collected at slaughter, samples collected in the national PRRS surveillance programme and passive clinical surveillance. The probability of freedom was estimated in time steps of 1 month, from July to December 2007. After each time step, the calculated posterior probability of freedom from the previous month, combined with the probability of introduction, was used as a prior probability for the next month. The result from the model showed a 99.8% probability that Sweden was free from PRRS at the end of December 2007. The estimated total sensitivity of the surveillance system varied between 81.2% and 94.3% and was highest during the first months after the outbreak. For sensitivity analysis purposes, the model was also applied using higher risks of introduction. However, this did not make considerable difference to the final estimates. [Copyright &y& Elsevier]

Published

2009

28. Estimating population sensitivity and confidence of freedom from highly pathogenic avian influenza in the Victorian poultry industry using passive surveillance.

Author

Sergeant, Evan S.G., Dries, Leanna R., Moore, Karen M., and Salmon, Sally E.

Subjects

*AVIAN influenza, *POULTRY industry, *POULTRY farms, *CONFIDENCE, *LIBERTY, *DISTRIBUTION (Probability theory), *SHEEP farming

Abstract

Highly pathogenic avian influenza (HPAI) is a serious disease affecting multiple organ systems and resulting in high levels of mortality in domestic poultry and may also be a serious zoonotic condition. In July-August 2020, HPAI was confirmed on 3 egg-laying chicken farms in Victoria, Australia, while a further two turkey farms and one emu farm were diagnosed with low pathogenicity viruses. All six farms were depopulated and decontaminated by 26 November 2020 and Australia declared regained freedom from HPAI on 26 February 2021. As part of the follow-up surveillance in support of claiming HPAI freedom, a scenario-tree model was developed to estimate the population sensitivity of passive surveillance for the detection of HPAI in the Victorian commercial poultry industry, and to also estimate the confidence of freedom from HPAI provided by passive surveillance, predicted over a 2-year period. Risk factors included in the model were industry sector (breeder, broiler, layer and other), flock size: small commercial (50 ≤ 5000 birds) or large commercial (> 5000 birds) and housing type (cage, barn or free-range). A detection cascade was also modelled, with probabilities allocated, to estimate the flock sensitivity for flocks in each risk stratum. System sensitivity and confidence of freedom were then estimated across all flocks in the industry. Design prevalence was set at 1, 2, 5 or 10 infected flocks and prior confidence of freedom at 0.5. Other model inputs were entered as probability distributions and the model was simulated for 10,000 iterations. Outputs were expressed as median and 95% probability intervals (PI), with the time period for analysis set at 1 month. Median system sensitivity was 0.58 (95% PI: 0.47–0.69) per time period for a single infected flock, increasing to 0.81, 0.985 and 0.9998 for 2, 5 and 10 infected flocks respectively. Median confidence of freedom was > 0.7 (95% PI: 0.65–0.76) after one time period and exceeded 0.95 and 0.99 after 4 and 7 months, respectively for one infected flock and 2 and 3 months respectively for 2 infected flocks. These results support the conclusion that passive surveillance is a highly effective tool for the detection of HPAI in commercial poultry and add further weight to evidence that HPAI has been successfully eradicated from the Victorian poultry industry and that the industry has regained HPAI free status. • Passive surveillance is effective for detecting HPAI in commercial poultry. • The Victorian commercial poultry industry is free of HPAI. • Confidence of freedom from HPAI rapidly approaches 100%. • HPAI detection relies on farmers recognising and investigating possible cases. [ABSTRACT FROM AUTHOR]

Published

2022

29. Application of non-structural protein antibody tests in substantiating freedom from foot-and-mouth disease virus infection after emergency vaccination of cattle

Author

Paton, David J., de Clercq, Kris, Greiner, Matthias, Dekker, Aldo, Brocchi, Emiliana, Bergmann, Ingrid, Sammin, Donal J., Gubbins, Simon, and Parida, Satya

Subjects

*VACCINATION, *FOOT & mouth disease, *IMMUNIZATION, *VIRUS diseases

Abstract

Abstract: There has been much debate about the use of the so-called “vaccinate-to-live” policy for the control of foot-and-mouth disease (FMD) in Europe, according to which, spread of the FMD virus (FMDV) from future outbreaks could be controlled by a short period of “emergency” vaccination of surrounding herds, reducing the need for large-scale pre-emptive culling of at-risk animals. Since vaccinated animals may become subclinically infected with FMDV following challenge exposure, it is necessary to either remove all vaccinates (vaccinate-to-kill) or to detect and remove vaccinates in which virus is circulating or has established persistent infections (vaccinate-to-live), in order to rapidly regain the most favoured trading status of FMD-free without vaccination. The latter approach can be supported by testing vaccinated animals for the presence of antibodies to certain non-structural proteins (NSP) of FMDV, which are induced by infection with the virus, but not by vaccination with purified FMD vaccines. Using test sensitivity and specificity data established at a recent workshop on NSP assays [Brocchi E, Bergmann I, Dekker A, Paton DJ, Sammin DJ, Greiner M, et al. Comparative performance of six ELISAs for antibodies to the non-structural proteins of foot-and-mouth disease. Vaccine, in press], this paper examines the ways in which serological testing with NSP ELISAs can be used and interpreted and the effect that this will have on the confidence with which freedom from infection can be demonstrated within guidelines specified by the World Animal Health Organisation and the European Commission. [Copyright &y& Elsevier]

Published

2006

30. On the surveillance for animal diseases in small herds

Author

Greiner, Matthias and Dekker, Aldo

Subjects

*ANIMAL diseases, *COMMUNICABLE diseases, *INFECTION, *MEDICAL microbiology

Abstract

Abstract: Small herds may present a problem in surveillance for infectious animal diseases because typical levels of a within-herd design prevalence are not directly applicable. We suggest a definition of small herds as those smaller than 2/(within-herd design prevalence) on the basis that such herds would be expected to have less than two (i.e. only one) infected animals. Consequently, the probability of detecting small herds cannot be improved by choosing a larger sample size within the herd. We derive necessary sample sizes of herds and the probability (“confidence”) of detecting disease within a stratum of small herds, given the among-herd design prevalence and test diagnostic sensitivity. Both a binomial model and a Poisson model can be used to establish the confidence for a given sample size of herds (and vice versa). The results of a simulation study suggest that the Poisson model provides more conservative (lower) estimates of the confidence for a given sample size and should therefore be preferred. [Copyright &y& Elsevier]

Published

2005

31. Hierarchical Bayesian model for prevalence inferences and determination of a country’s status for an animal pathogen

Author

Suess, E.A., Gardner, I.A., and Johnson, W.O.

Subjects

*DISEASE management, *BAYESIAN analysis, *ANIMAL products

Abstract

Certification that a country, region or state is “free” from a pathogen or has a prevalence less than a threshold value has implications for trade in animals and animal products. We develop a Bayesian model for assessment of (i) the probability that a country is “free” of or has an animal pathogen, (ii) the proportion of infected herds in an infected country, and (iii) the within-herd prevalence in infected herds. The model uses test results from animals sampled in a two-stage cluster sample of herds within a country. Model parameters are estimated using modern Markov-chain Monte Carlo methods. We demonstrate our approach using published data from surveys of Newcastle disease and porcine reproductive and respiratory syndrome in Switzerland, and for three simulated data sets. [Copyright &y& Elsevier]

Published

2002

32. Demonstrating disease freedom—combining confidence levels

Author

Cannon, R.M.

Subjects

*DISEASES, *DIAGNOSIS

Abstract

Part of the requirements for demonstrating disease freedom usually will be that sufficient testing be done to give a specified confidence of detecting the disease if it were present at a specified level. Often, this requirement is translated into a fixed testing regime that must be followed (an inflexible approach that might not be the most economic or practical solution).A more flexible approach is to specify the capabilities of the various tests that can be used to detect the disease, and let the party hoping to demonstrate disease freedom decide upon the testing regime. The question then arises as to how to combine information that can come from a variety of sources over a period of time to give an overall level of confidence.Two methods are given. The first, an exact method based on multiplying probabilities, would be more appropriate for a survey of an area in which no disease is thought to be present. The second method (more appropriate for a herd-assurance program within an infected area) is a point-based system that takes into account the different sensitivities of the methods used to detect disease and the change in prevalence over time. It allocates points for each test done proportional to the sensitivity of the test and the prevalence at the time of testing. [Copyright &y& Elsevier]

Published

2002

33. Development and evaluation of a new method to combine clinical impression survey data with existing laboratory data for veterinary syndromic surveillance with the Canada West Swine Health Intelligence Network (CWSHIN).

Author

Christensen, Jette, Byra, Chris, Keenliside, Julia, Huang, Yanyun, Harding, John C.S., Duizer, Glen, and Detmer, Susan E.

Subjects

*FOOT & mouth disease, *SWINE, *HEALTH care networks, *ROUTINE diagnostic tests, *EVALUATION methodology

Abstract

• Existing data from multiple divergent sources can be useful in monitoring temporal trends. • Clinical syndromic surveillance should be coupled with a good intelligence network to interpret and disseminate the results. • Clinical impression survey data can be used in stochastic scenario tree models for disease freedom. The Canada West Swine Health Intelligence Network (CWSHIN) is a surveillance system imbedded in an intelligence network. It has been conducting syndromic surveillance in the four western provinces of Canada since 2012. The quarterly activities include repeated clinical impression surveys, compilation of laboratory data, discussion of trends with an expert group (practitioners, laboratory diagnosticians) and swine health reports for producers and swine practitioners. However, due to the lack of standardized population identifiers across data sources usual methods of combining data could not be applied and the collated data were not being fully utilized and analysed. Therefore in 2019, CWSHIN underwent a substantial review resulting in the "Next Generation CWSHIN". The objectives of this study were to develop and evaluate a new data merging method to combine CWSHIN's clinical impression survey and laboratory data; and to provide examples of analyses and modeling based on these data. The data for analysis were restricted to repeated clinical impression surveys (2019–2020) from veterinary practitioners and laboratory diagnostic data (2016–2020). Merging surveillance data from existing sources can be challenging. Therefore, as an alternative to merge data using a hierarchy of population identifiers, we developed a Disease Map to link surveillance data from all our data-sources. The resulting Data Repository allowed monitoring of temporal trends of syndromes, clinical diseases, and laboratory identified organisms, but it cannot provide estimates of disease occurrence. Two main reasons were the lack of denominators and using existing data on routine diagnostic tests. Therefore, discussion in the expert group (veterinary practitioners, laboratory diagnosticians, swine health experts) was critical to the system's success. Based on repeated clinical impression surveys a stochastic scenario tree model for freedom from Foot and Mouth Disease (CWSHIN Blister model) was also developed. In conclusion, the method to link existing data systems from multiple divergent sources by means of a Disease Map improved CWSHIN's veterinary syndromic surveillance. Together the Data Repository and Disease map provided flexibility to monitor temporal trends, define populations and diseases, and allow analysis. However, it is critical that the surveillance is coupled with a good intelligence network that can help interpret the results and disseminate knowledge to veterinarians and producers. [ABSTRACT FROM AUTHOR]

Published

2021

34. An innovative Surveillance analysis Tool for Outcome-based Comparison of FREEdom from infection in heterogeneous control programs

Author

Santmann, Inge, Fourichon, Christine, Madouasse, Aurélien, Mercat, Mathilde, Moré, S, Graham, David, Gethmann, Jörn, Sauter-Louis, Carola, Frössling, Jenny, Lindberg, Ann, Gomes, Carla, Gunn, George, Henry, Madeleine, Nielen, Mirjam, van Roon, Annika, van Duijn, Linda, van Schaik, Gierdien, Department of Farm Animal Health, Faculty of Veterinary Medicine, Utrecht University [Utrecht], Biologie, Epidémiologie et analyse de risque en Santé Animale (BIOEPAR), Institut National de la Recherche Agronomique (INRA), University College Dublin [Dublin] (UCD), Ireland, Friedrich-Loeffler-Institut (FLI), Clinic for Ruminants with Ambulatory and Herd Health Services at the Centre for Clinical Veterinary Medicine, Ludwig Maximilians University of Munich, Veterinary Epidemiology, Economics & Public Health Group, Royal Veterinary College - University of London, National Veterinary Institute, Technical University of Denmark [Lyngby] (DTU), Scotland's Rural College (SRUC), GD - Animal Health Service, and ProdInra, Migration

Subjects

[SDV] Life Sciences [q-bio], Surveillance, Control programmes, Endemic diseases, [SDV]Life Sciences [q-bio], Disease freedom

Abstract

International audience; Countries differ in existence, stage of eradication and design of control programs for non-regulated diseases. When freedom from infection is achieved, safe trade is essential to protect that status. The aim of STOC free, a collaboration between six countries, is to develop and validate a framework that enables transparent and standardized comparison of confidence of disease freedom for control programs across herds, regions or countries. The framework consists of a model (STOC free MODEL) combined with a tool to facilitate the collection of the necessary parameters (STOC free DATA). All actions taken in a control program will be included in a Bayesian model, which needs prior distributions for most parameters. Data for the distributions can be obtained from databases of control programs, demographic data and contact structures between herds. In addition, frequency of occurrence and risk estimates for factors that influence either the probability of introduction or delayed detection of the infection will be included in the model. Bovine viral diarrhea virus (BVDV) is used as an example disease. Many countries have control programs in place for this complex and detrimental disease with wide differences between application of vaccinations, combinations of diagnostic tests applied, frequency of testing and target groups. Although BVDV will be a thorough test of the initial developed framework, it should be generic enough to be adaptable to control programs for other diseases. With the introduction of the new Animal Health Law (AHL), it is anticipated that assessments of the performance of control programmes will progressively change towards output-based measures. The STOC free framework will support the AHL by providing a single general framework, adaptable to multiple diseases, which aims to enhance the safety of trade.

Published

2018

35. Qualitative comparison of BVDV control programmes in Europe to substantiate freedom from infection

Author

van Roon, Annika, Santmann, Inge, Graham, David, Moré, S, Nielen, Mirjam, van Duijn, Linda, Mercat, Mathilde, Fourichon, Christine, Madouasse, Aurélien, Gethmann, Jörn, Sauter-Louis, Carola, Frössling, Jenny, Lindberg, Ann, Gomes, Carla, Gunn, George, Henry, Madeleine, van Schaik, Gierdien, Department of Farm Animal Health, Faculty of Veterinary Medicine, Utrecht University [Utrecht], Ireland, University College Dublin [Dublin] (UCD), Biologie, Epidémiologie et analyse de risque en Santé Animale (BIOEPAR), Institut National de la Recherche Agronomique (INRA), Friedrich-Loeffler-Institut (FLI), Clinic for Ruminants with Ambulatory and Herd Health Services at the Centre for Clinical Veterinary Medicine, Ludwig Maximilians University of Munich, Veterinary Epidemiology, Economics & Public Health Group, Royal Veterinary College - University of London, National Veterinary Institute, Technical University of Denmark [Lyngby] (DTU), Scotland's Rural College (SRUC), GD - Animal Health Service, and ProdInra, Migration

Subjects

[SDV] Life Sciences [q-bio], Non-regulated diseases, Surveillance, Control programmes, animal diseases, viruses, [SDV]Life Sciences [q-bio], virus diseases, Disease freedom, complex mixtures, BVDV

Abstract

International audience; Objective: Several European countries have implemented control or eradication programmes for non-regulated diseases such as bovine viral diarrhoea virus (BVDV). However, the diversity in such control programmes (CP) creates difficulties for intra-community trade given that the probability of freedom from e.g. BVDV will differ between countries. This poses a risk of potential movement of BVDV into free regions. An understanding of equivalence with respect to disease freedom is important when seeking to facilitate interstate animal movements,whilst also managing the risk of infection. In this project, six European countries collaborate to develop an output-based approach to assess and compare confidence of freedom resulting from different CPs. The aim was to qualitatively compare the confidence of freedom resulting from different BVDV CPs. Materials and methods: An existing tool for harmonized description of surveillance programmes (the RISKSUR tool) was used to collect information from each participating country about BVDV status, demographic information and surveillance activities for BVDV, and expanded to also include control measures of the BVDV CPs. Results: The design of BVDV CPs differed considerably as well as country demographics (Table 1). The aspects of the different CPs were grouped in three main topics: context (i.e. BVDV status, occurrence of risk factors), actions to obtain a BVDV free status and measures to monitor the free status. Conclusions: The variation in context was larger than the variation in control programmes, resulting in different risk classifications for territories. The context of a country or territory is crucial information for an outcomebased comparison of BVDV CPs.

Published

2018

36. Analysis of German BSE Surveillance Data: Estimation of the Prevalence of Confirmed Cases versus the Number of Infected, but Non-Detected, Cattle to Assess Confidence in Freedom from Infection.

Author

Greiner M, Selhorst T, Balkema-Buschmann A, Johnson WO, Müller-Graf C, and Conraths FJ

Subjects

Animals, Bayes Theorem, Cattle, Freedom, Prevalence, Risk Assessment, Encephalopathy, Bovine Spongiform diagnosis, Encephalopathy, Bovine Spongiform epidemiology

Abstract

Quantitative risk assessments for Bovine spongiform encephalopathy (BSE) necessitate estimates for key parameters such as the prevalence of infection, the probability of absence of infection in defined birth cohorts, and the numbers of BSE-infected, but non-detected cattle entering the food chain. We estimated three key parameters with adjustment for misclassification using the German BSE surveillance data using a Gompertz model for latent (i.e., unobserved) age-dependent detection probabilities and a Poisson response model for the number of BSE cases for birth cohorts 1999 to 2015. The models were combined in a Bayesian framework. We estimated the median true BSE prevalence between 3.74 and 0.216 cases per 100,000 animals for the birth cohorts 1990 to 2001 and observed a peak for the 1996 birth cohort with a point estimate of 16.41 cases per 100,000 cattle. For birth cohorts ranging from 2002 to 2013, the estimated median prevalence was below one case per 100,000 heads. The calculated confidence in freedom from disease (design prevalence 1 in 100,000) was above 99.5% for the birth cohorts 2002 to 2006. In conclusion, BSE surveillance in the healthy slaughtered cattle chain was extremely sensitive at the time, when BSE repeatedly occurred in Germany (2000-2009), because the entry of BSE-infected cattle into the food chain could virtually be prevented by the extensive surveillance program during these years and until 2015 (estimated non-detected cases/100.000 [95% credible interval] in 2000, 2009, and 2015 are 0.64 [0.5,0.8], 0.05 [0.01,0.14], and 0.19 [0.05,0.61], respectively).

Published

2021

37. How to Demonstrate Freedom from African Swine Fever in Wild Boar—Estonia as an Example.

Author

Schulz, Katja, Staubach, Christoph, Blome, Sandra, Nurmoja, Imbi, Viltrop, Arvo, Conraths, Franz J., Kristian, Maarja, and Sauter-Louis, Carola

Subjects

AFRICAN swine fever, WILD boar, FERAL swine, TRADE regulation

Abstract

Estonia has been combatting African swine fever (ASF) for six years now. Since October 2017, the disease has only been detected in the wild boar population, but trade restrictions had to remain in place due to international regulations. Yet, the epidemiological course of the disease has changed within the last few years. The prevalence of ASF virus (ASFV)-positive wild boar decreased steadily towards 0%. In February 2019, the last ASFV-positive wild boar was detected. Since then, positive wild boar samples have exclusively been positive for ASFV-specific antibodies, suggesting the possible absence of circulating ASFV in the Estonian wild boar population. However, as the role of seropositive animals is controversially discussed and the presence of antibody-carriers is regarded as an indication of virus circulation at EU and OIE level, Estonia remains under trade restrictions. To make the disease status of a country reliable for trading partners and to facilitate the process of declaration of disease freedom, we suggest to monitor the prevalence of seropositive wild boar in absence of ASFV-positive animals. The possibility to include ASF in the list of diseases, for which an official pathway for recognition of disease status is defined by the OIE should be evaluated. [ABSTRACT FROM AUTHOR]

Published

2020

38. Compartmentalisation: an example of a national official assurance system.

Author

Maja M, Janse Van Rensburg L, and Gerstenberg C

Subjects

Animal Husbandry, Animals, Global Health, Poultry, Swine, African Swine Fever, Animal Diseases, Swine Diseases

Abstract

In South Africa's experience, compartmentalisation has been extremely effective in maintaining an animal subpopulation of a specific health status, based on segregation and biosecurity management. Compartmentalisation promotes animal disease control and underwrites a national official assurance system that provides zoosanitary trade guarantees for animals and animal products. South Africa started to develop the concept of compartmentalisation during the 1950s for the pig sector, due to African swine fever being endemic in wildlife in the north of the country, where certain biosecurity measures were used to protect domestic pigs. Compartmentalisation protocols were formalised and officially published from 2001 as voluntary systems, first for the pig industry and later for the poultry (chicken and ostrich) industry. South Africa uses five basic principles for animal health compartmentalisation, namely, segregation, biosecurity, record-keeping, surveillance and official inspection. These are applied in line with the World Organisation for Animal Health Terrestrial Animal Health Code guidelines. Industry and the farmer bear the costs of compartmentalisation and, in turn, obtain not only animal disease protection but also trade advantages due to health assurances. Compartmentalisation ensures optimal use of government resources as the expenses for animal disease control are shared with private industries. International acceptance and standardisation of compartments is advocated as a measure to provide assurances for disease freedom, based on risk-specific mitigation measures.

Published

2020

39. Routine clinical inspections in Norwegian marine salmonid sites: A key role in surveillance for freedom from pathogenic viral haemorrhagic septicaemia (VHS)

Author

Hildegunn Viljugrein, Trude Marie Lyngstad, Evan S.G. Sergeant, Britt Bang Jensen, Edgar Brun, Saraya Tavornpanich, and Hege Hellberg

Subjects

0301 basic medicine, Atlantic salmon, Operations research, 040301 veterinary sciences, Population, Biosecurity, Salmo salar, Sample (statistics), Norwegian, Aquaculture, 0403 veterinary science, Novirhabdovirus, 03 medical and health sciences, Health surveillance, Food Animals, Risk Factors, Environmental health, Hemorrhagic Septicemia, Viral, Risk-based surveillance, Animals, Disease freedom, education, education.field_of_study, business.industry, Norway, 04 agricultural and veterinary sciences, 030108 mycology & parasitology, Fish health service, language.human_language, Viral haemorrhagic septicaemia, Laboratory test, Rainbow trout, Geography, Oncorhynchus mykiss, Epidemiological Monitoring, language, Viral Haemorrhagic Septicaemia, Animal Science and Zoology, business

Abstract

Since the mid-1980s, clinical inspections of aquaculture sites carried out on a regular basis by authorized veterinarians and fish health biologists (known as fish health services: FHS) have been an essential part of aquatic animal health surveillance in Norway. The aims of the present study were (1) to evaluate the performance of FHS routine clinical inspections for the detection of VHS and (2) to explore the effectiveness of risk-based prioritisation of FHS inspections for demonstrating freedom from VHS in marine salmonid sites in Norway. A stochastic simulation model was developed to estimate site sensitivity (SeS), population sensitivity (SeP), and probability of freedom (PFree). The estimation of SeS takes into consideration the probability that FHS submit samples if a site is infected, the probability that a sample is tested if submitted, the effective probability of infection in fish with clinical signs, laboratory test sensitivity, and the number of tested samples. SeP and PFree were estimated on a monthly basis over a 12 month period for six alternative surveillance scenarios and included the risk factors: region, species, area production density, and biosecurity level. Model results indicate that the current surveillance system, based on routine inspections by the FHS has a high capability for detecting VHS and that there is a high probability of freedom from VHS in Norwegian marine farmed salmonids (PFree >95%). Sensitivity analysis identified the probabilities that samples are submitted and submitted samples are tested, as the most influential input variables. The model provides a supporting tool for evaluation of potential changes in the surveillance strategy, and can be viewed as a platform for similar exotic viral infectious diseases in marine salmonid farming in Norway, if they share similar risk factors.

Published

2015

40. Risk-based methods for fish and terrestrial animal disease surveillance

Author

Britt Bang Jensen, E.J. Peeler, Edgar Brun, Trude Marie Lyngstad, Birgit Oidtmann, and Katharina D.C. Stärk

Subjects

Risk analysis, Context (language use), Animals, Wild, Aquaculture, Terrestrial animal, Risk Assessment, Animal Diseases, Fish Diseases, Food Animals, Risk Factors, media_common.cataloged_instance, Risk-based surveillance, Animals, Disease freedom, European union, Environmental planning, Constraint (mathematics), media_common, Disease surveillance, biology, business.industry, Animal, Fishes, Risk factor (computing), biology.organism_classification, Fish, Animals, Domestic, Population Surveillance, Animal Science and Zoology, Risk factor, business, Sentinel Surveillance

Abstract

Over recent years there have been considerable methodological developments in the field of animal disease surveillance. The principles of risk analysis were conceptually applied to surveillance in order to further develop approaches and tools (scenario tree modelling) to design risk-based surveillance (RBS) programmes. In the terrestrial animal context, examples of risk-based surveillance have demonstrated the substantial potential for cost saving, and a similar benefit is expected also for aquatic animals. RBS approaches are currently largely absent for aquatic animal diseases. A major constraint in developing RBS designs in the aquatic context is the lack of published data to assist in the design of RBS: this applies to data on (i) the relative risk of farm sites becoming infected due to the presence or absence of a given risk factor; (ii) the sensitivity of diagnostic tests (specificity is often addressed by follow-up investigation and re-testing and therefore less of a concern); (iii) data on the variability of prevalence of infection for fish within a holding unit, between holding units and at farm level. Another constraint is that some of the most basic data for planning surveillance are missing, e.g. data on farm location and animal movements. In Europe, registration or authorisation of fish farms has only recently become a requirement under EU Directive 2006/88. Additionally, the definition of the epidemiological unit (at site or area level) in the context of aquaculture is a challenge due to the often high level of connectedness (mainly via water) of aquaculture facilities with the aquatic environment. This paper provides a review of the principles, methods and examples of RBS in terrestrial, farmed and wild animals. It discusses the special challenges associated with surveillance for aquatic animal diseases (e.g. accessibility of animals for inspection and sampling, complexity of rearing systems) and provides an overview of current developments relevant for the design of RBS for fish diseases. Suggestions are provided on how the current constraints to applying RBS to fish diseases can be overcome.

Published

2013

41. Methodological approach for substantiating disease freedom in a heterogeneous small population. Application to ovine scrapie, a disease with a strong genetic susceptibility

Author

Didier Calavas, Christian Ducrot, Marie-José Martinez, Benoit Durand, Unité de recherche d'Épidémiologie Animale (UEA), Institut National de la Recherche Agronomique (INRA), Modelling and Inference of Complex and Structured Stochastic Systems (MISTIS), Inria Grenoble - Rhône-Alpes, Institut National de Recherche en Informatique et en Automatique (Inria)-Institut National de Recherche en Informatique et en Automatique (Inria)-Laboratoire Jean Kuntzmann (LJK), Université Pierre Mendès France - Grenoble 2 (UPMF)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut Polytechnique de Grenoble - Grenoble Institute of Technology-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA)-Université Pierre Mendès France - Grenoble 2 (UPMF)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut Polytechnique de Grenoble - Grenoble Institute of Technology-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA)-Institut National Polytechnique de Grenoble (INPG), Laboratoire de Lyon, Agence nationale de sécurité sanitaire de l'alimentation, de l'environnement et du travail (ANSES), Unité de Recherche d'Épidémiologie Animale (UR EpiA), Université Pierre Mendès France - Grenoble 2 (UPMF)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Centre National de la Recherche Scientifique (CNRS)-Université Pierre Mendès France - Grenoble 2 (UPMF)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Centre National de la Recherche Scientifique (CNRS), Laboratoire de Lyon [ANSES], and Université de Lyon-Agence nationale de sécurité sanitaire de l'alimentation, de l'environnement et du travail (ANSES)

Subjects

Male, 040301 veterinary sciences, MESH: Probability, Population, MESH: Sheep, Scrapie, Biology, MESH: Risk Assessment, Risk Assessment, Statistical power, 0403 veterinary science, POPULATION HETEROGENEITY, 03 medical and health sciences, DISEASE FREEDOM, Food Animals, HYPERGEOMETRIC DISTRIBUTION, Statistics, Prevalence, Genetic predisposition, Animals, Genetic Predisposition to Disease, MESH: Animals, education, MESH: Prevalence, Probability, 030304 developmental biology, 0303 health sciences, education.field_of_study, Sheep, [SDV.BA.MVSA]Life Sciences [q-bio]/Animal biology/Veterinary medicine and animal Health, MESH: Genetic Predisposition to Disease, Sampling (statistics), 04 agricultural and veterinary sciences, Confidence interval, Hypergeometric distribution, MESH: Male, Relative risk, MESH: Scrapie, MESH: Sentinel Surveillance, Female, Animal Science and Zoology, [SDV.SPEE]Life Sciences [q-bio]/Santé publique et épidémiologie, Sentinel Surveillance, MESH: Female, [STAT.ME]Statistics [stat]/Methodology [stat.ME]

Abstract

International audience; Demonstrating disease freedom is becoming important in different fields including animal disease control. Most methods consider sampling only from a homogeneous population in which each animal has the same probability of becoming infected. In this paper, we propose a new methodology to calculate the probability of detecting the disease if it is present in a heterogeneous population of small size with potentially different risk groups, differences in risk being defined using relative risks. To calculate this probability, for each possible arrangement of the infected animals in the different groups, the probability that all the animals tested are test-negative given this arrangement is multiplied by the probability that this arrangement occurs. The probability formula is developed using the assumption of a perfect test and hypergeometric sampling for finite small size populations. The methodology is applied to scrapie, a disease affecting small ruminants and characterized in sheep by a strong genetic susceptibility defining different risk groups. It illustrates that the genotypes of the tested animals influence heavily the confidence level of detecting scrapie. The results present the statistical power for substantiating disease freedom in a small heterogeneous population as a function of the design prevalence, the structure of the sample tested, the structure of the herd and the associated relative risks.

Published

2010