Your search keyword '"Fonnesbeck CJ"' showing total 4 results

1. Real-time decision-making during emergency disease outbreaks.

Author

Probert WJM, Jewell CP, Werkman M, Fonnesbeck CJ, Goto Y, Runge MC, Sekiguchi S, Shea K, Keeling MJ, Ferrari MJ, and Tildesley MJ

Subjects

Animals, Animals, Domestic, Cattle, Cattle Diseases epidemiology, Cattle Diseases prevention & control, Cattle Diseases transmission, Foot-and-Mouth Disease transmission, Foot-and-Mouth Disease Virus immunology, Humans, Japan epidemiology, Sheep, Sheep Diseases epidemiology, Sheep Diseases prevention & control, Sheep Diseases transmission, Swine, Swine Diseases epidemiology, Swine Diseases prevention & control, Swine Diseases transmission, Time Factors, United Kingdom epidemiology, Viral Vaccines administration & dosage, Decision Making, Organizational, Disease Outbreaks prevention & control, Foot-and-Mouth Disease epidemiology, Foot-and-Mouth Disease prevention & control, Health Policy, Models, Theoretical

Abstract

In the event of a new infectious disease outbreak, mathematical and simulation models are commonly used to inform policy by evaluating which control strategies will minimize the impact of the epidemic. In the early stages of such outbreaks, substantial parameter uncertainty may limit the ability of models to provide accurate predictions, and policymakers do not have the luxury of waiting for data to alleviate this state of uncertainty. For policymakers, however, it is the selection of the optimal control intervention in the face of uncertainty, rather than accuracy of model predictions, that is the measure of success that counts. We simulate the process of real-time decision-making by fitting an epidemic model to observed, spatially-explicit, infection data at weekly intervals throughout two historical outbreaks of foot-and-mouth disease, UK in 2001 and Miyazaki, Japan in 2010, and compare forward simulations of the impact of switching to an alternative control intervention at the time point in question. These are compared to policy recommendations generated in hindsight using data from the entire outbreak, thereby comparing the best we could have done at the time with the best we could have done in retrospect. Our results show that the control policy that would have been chosen using all the data is also identified from an early stage in an outbreak using only the available data, despite high variability in projections of epidemic size. Critically, we find that it is an improved understanding of the locations of infected farms, rather than improved estimates of transmission parameters, that drives improved prediction of the relative performance of control interventions. However, the ability to estimate undetected infectious premises is a function of uncertainty in the transmission parameters. Here, we demonstrate the need for both real-time model fitting and generating projections to evaluate alternative control interventions throughout an outbreak. Our results highlight the use of using models at outbreak onset to inform policy and the importance of state-dependent interventions that adapt in response to additional information throughout an outbreak., Competing Interests: The authors have declared that no competing interests exist.

Published

2018

2. Quantifying the Value of Perfect Information in Emergency Vaccination Campaigns.

Author

Bradbury NV, Probert WJ, Shea K, Runge MC, Fonnesbeck CJ, Keeling MJ, Ferrari MJ, and Tildesley MJ

Subjects

Animal Culling statistics & numerical data, Animals, Emergency Medical Services economics, Emergency Medical Services statistics & numerical data, Foot-and-Mouth Disease epidemiology, Immunization Programs statistics & numerical data, Mass Vaccination economics, Mass Vaccination statistics & numerical data, Population Surveillance methods, Prevalence, Risk Assessment economics, Risk Assessment methods, United Kingdom epidemiology, Viral Vaccines economics, Viral Vaccines therapeutic use, Animal Culling economics, Cost-Benefit Analysis economics, Foot-and-Mouth Disease economics, Foot-and-Mouth Disease prevention & control, Health Care Costs statistics & numerical data, Immunization Programs economics

Abstract

Foot-and-mouth disease outbreaks in non-endemic countries can lead to large economic costs and livestock losses but the use of vaccination has been contentious, partly due to uncertainty about emergency FMD vaccination. Value of information methods can be applied to disease outbreak problems such as FMD in order to investigate the performance improvement from resolving uncertainties. Here we calculate the expected value of resolving uncertainty about vaccine efficacy, time delay to immunity after vaccination and daily vaccination capacity for a hypothetical FMD outbreak in the UK. If it were possible to resolve all uncertainty prior to the introduction of control, we could expect savings of £55 million in outbreak cost, 221,900 livestock culled and 4.3 days of outbreak duration. All vaccination strategies were found to be preferable to a culling only strategy. However, the optimal vaccination radius was found to be highly dependent upon vaccination capacity for all management objectives. We calculate that by resolving the uncertainty surrounding vaccination capacity we would expect to return over 85% of the above savings, regardless of management objective. It may be possible to resolve uncertainty about daily vaccination capacity before an outbreak, and this would enable decision makers to select the optimal control action via careful contingency planning.

Published

2017

3. Adaptive management and the value of information: learning via intervention in epidemiology.

Author

Shea K, Tildesley MJ, Runge MC, Fonnesbeck CJ, and Ferrari MJ

Subjects

Animals, Humans, Disease Outbreaks prevention & control, Foot-and-Mouth Disease epidemiology, Mass Vaccination organization & administration, Measles epidemiology

Abstract

Optimal intervention for disease outbreaks is often impeded by severe scientific uncertainty. Adaptive management (AM), long-used in natural resource management, is a structured decision-making approach to solving dynamic problems that accounts for the value of resolving uncertainty via real-time evaluation of alternative models. We propose an AM approach to design and evaluate intervention strategies in epidemiology, using real-time surveillance to resolve model uncertainty as management proceeds, with foot-and-mouth disease (FMD) culling and measles vaccination as case studies. We use simulations of alternative intervention strategies under competing models to quantify the effect of model uncertainty on decision making, in terms of the value of information, and quantify the benefit of adaptive versus static intervention strategies. Culling decisions during the 2001 UK FMD outbreak were contentious due to uncertainty about the spatial scale of transmission. The expected benefit of resolving this uncertainty prior to a new outbreak on a UK-like landscape would be £45-£60 million relative to the strategy that minimizes livestock losses averaged over alternate transmission models. AM during the outbreak would be expected to recover up to £20.1 million of this expected benefit. AM would also recommend a more conservative initial approach (culling of infected premises and dangerous contact farms) than would a fixed strategy (which would additionally require culling of contiguous premises). For optimal targeting of measles vaccination, based on an outbreak in Malawi in 2010, AM allows better distribution of resources across the affected region; its utility depends on uncertainty about both the at-risk population and logistical capacity. When daily vaccination rates are highly constrained, the optimal initial strategy is to conduct a small, quick campaign; a reduction in expected burden of approximately 10,000 cases could result if campaign targets can be updated on the basis of the true susceptible population. Formal incorporation of a policy to update future management actions in response to information gained in the course of an outbreak can change the optimal initial response and result in significant cost savings. AM provides a framework for using multiple models to facilitate public-health decision making and an objective basis for updating management actions in response to improved scientific understanding., Competing Interests: The authors have declared that no competing interests exist.

Published

2014

4. Estimating upper bounds for occupancy and number of manatees in areas potentially affected by oil from the Deepwater Horizon oil spill.

Author

Martin J, Edwards HH, Bled F, Fonnesbeck CJ, Dupuis JA, Gardner B, Koslovsky SM, Aven AM, Ward-Geiger LI, Carmichael RH, Fagan DE, Ross MA, and Reinert TR

Subjects

Alabama, Animals, Florida, Geography, Mississippi, Surveys and Questionnaires, Ecosystem, Environmental Monitoring, Petroleum Pollution, Trichechus physiology

Abstract

The explosion of the Deepwater Horizon drilling platform created the largest marine oil spill in U.S. history. As part of the Natural Resource Damage Assessment process, we applied an innovative modeling approach to obtain upper estimates for occupancy and for number of manatees in areas potentially affected by the oil spill. Our data consisted of aerial survey counts in waters of the Florida Panhandle, Alabama and Mississippi. Our method, which uses a Bayesian approach, allows for the propagation of uncertainty associated with estimates from empirical data and from the published literature. We illustrate that it is possible to derive estimates of occupancy rate and upper estimates of the number of manatees present at the time of sampling, even when no manatees were observed in our sampled plots during surveys. We estimated that fewer than 2.4% of potentially affected manatee habitat in our Florida study area may have been occupied by manatees. The upper estimate for the number of manatees present in potentially impacted areas (within our study area) was estimated with our model to be 74 (95%CI 46 to 107). This upper estimate for the number of manatees was conditioned on the upper 95%CI value of the occupancy rate. In other words, based on our estimates, it is highly probable that there were 107 or fewer manatees in our study area during the time of our surveys. Because our analyses apply to habitats considered likely manatee habitats, our inference is restricted to these sites and to the time frame of our surveys. Given that manatees may be hard to see during aerial surveys, it was important to account for imperfect detection. The approach that we described can be useful for determining the best allocation of resources for monitoring and conservation.

Published

2014