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Three examples …

Computational Sustainability March 12, 2010 at 1:25PM – 2:40PM 1150 Snee Hall Optimizing Intervention Strategies in Food Animal Systems: modeling production, health and food safety.

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Three examples …

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  1. Computational Sustainability March 12, 2010 at 1:25PM – 2:40PM 1150 Snee Hall Optimizing Intervention Strategies in Food Animal Systems: modeling production, health and food safety Elva Cha, DVM, PhD candidate, Rebecca Smith, DVM, PhD candidate, Zhao Lu, PhD, Research Associate and Cristina Lanzas, DVM, PhD, Research Associate and Yrjö T. Gröhn, DVM, MPVM, MS, PhD Department of Population Medicine and Diagnostic Sciences, College of Veterinary Medicine, Cornell University

  2. Perhaps I should start with “ a disclaimer”…If I understood correctly, your approach is to assume the model is 'correct', then optimize the system.As veterinarians, our responsibility is to build a model based on subject matter representing reality.Of course, our goal is to find the optimal way to control disease (not necessarily eradication). And sometimes we need to learn the economically optimal way to coexist with them.

  3. Food Supply Veterinary Medicine….all aspects of veterinary medicine's involvement in food supply systems, from traditional agricultural production to consumption.Modeling production, health and food safety: 1. Optimizing health and management decisions 2.Mathematical modeling of zoonotic infectious diseases (such as L. monozytogenes, E. coli, MDR salmonella and paratuberculosis).

  4. Three examples … Modeling production and health: Project 1.“Optimal Clinical Mastitis Management in Dairy cows.” Elva Cha’s PhD research Project 2. “Cost Effective Control Strategies for The Reduction of Johne’s Disease on Dairy Farms.” Zhao Lu, Research Associate and Becky Smith’s PhD research 2. Modeling Food Safety: Project 3.“Food Animal Systems-Based Mathematical Models of Antibiotic Resistance among Commensal Bacteria.” Cristina Lanzas, Research Associate

  5. Let’s start with…1. Modeling production and health: Our overall goal is to develop a comprehensive economic model, dynamic model (DP), to assist farmers in making treatment and culling decisions. Our 1st example:Elva Cha’s PhD research: “Optimal Clinical Mastitis Management in Dairy cows”

  6. Mastitis (inflammation in mammary gland)Common, costly disease (major losses: milk yield, conception rates, and culling). The question we address is whether it is better to treat animals at the time CM is first observed or whether it is worthwhile collecting more information related to the nature of the pathogen involved (Gram-positive or Gram-negative, or even the actual pathogen), and then make a treatment decision.More information would seem to be of benefit when deciding what to do with diseased cows, but unless the additional tests provide a different recommended outcome, they are only an extra cost.

  7. Objective: • To determine the economically optimal amount of information needed to make mastitis treatment decisions • We will build upon our existing Dynamic Programming model. • This work requires us to determine the risk and consequences of CM (milk loss, delayed conception, mortality) as functions of cow characteristics, including the disease history and disease prognosis of the cow. To do this

  8. How do we address our objective? • We will compare 2 models • Model 1 which will identify cows based on generic (non-specific) mastitis • And Model 2, whereby if a cow has mastitis, it will be specified as gram-positive, gram-negative or other types of mastitis • We will then compare the profit of each model What is this model?

  9. The models • The models will calculate the optimal policy for each individual cow • This can be done by ‘dynamic programming’

  10. Dynamic programming • Numerical method for solving sequential decision problems • Based on the ‘Bellman principal of optimality’ • In our case, the ‘system’ is dairy cows, observed over an infinite time horizon split into ‘stages’ i.e. months of a cow’s life

  11. Dynamic programming At each stage, the state of the system is observed • E.g. pregnancy status, disease status, milk yield And a decision is made • Replace, keep (treat and inseminate) or sell This decision influences stochastically the state to be observed at the next stage Depending on the state and decision, a reward is gained

  12. Dynamic programming • Value function is the expected total rewards from the current stage until the end of the horizon • Optimal decisions depending on stage and state are determined backwards step by step

  13. Structure of the hierarchic Markov process optimization model

  14. Parameters in our model • For each type of mastitis • Risk of mastitis • Repeated risk of mastitis • Effect on milk yield • Effect on conception • Effect on mortality and culling

  15. Limitations • Now we can only study 3 different types of mastitis, although we have data for very specific types of mastitis! (i.e. >3!) Why is this a limitation? Can’t we simply expand the model?

  16. Implications of a larger model • By expanding the model, we will encounter the ‘curse of dimensionality’ • An opportunity cost of including another disease, and hence the parameters associated with it • The model increases as a power function, not by a factor of 1, 2 or 3… • This makes computations even more challenging and time consuming

  17. The curse of dimensionalityexample: Houben et al. 1994 • State variables: • Age (monthly intervals, 204 levels) • Milk yield, present lactation (15 levels) • Milk yield, previous lactation (15 levels) • Length of calving interval (8 levels) • Mastitis, present lactation (4 levels) • Mastitis, previous lactation (4 levels) • Clinical mastitis (yes/no) • Total state space 6,821,724 states

  18. The curse of dimensionalityexample: Gröhn et al. 2003 • State variables: • Parity (12 levels) • Conception in month (10 levels) • Stage of lactation (20 levels) • Milk yield (5 levels) • Month of calving (12 levels) • Disease index (212 levels) • Total state space 144,000 x 212= 30,528,000

  19. Structure of the hierarchic Markov process optimization model:First level:5 milk yield levelsSecond level:8 possible lactations and 2 carry-over mastitis states from previous lactation (yes/no).Third level:20 lactation stages (max calving interval of 20 months). 5 temporary milk yield levels (relative to permanent milk yield),9 pregnancy status levels (0=open, 1-7 months pregnant, and 8=to be dried off), one involuntary culled state13 mastitis states: 0=no mastitis 1 = 1st occurrence of CM (observed at the end of the stage), 2, 3, 4 = 1, 2, 3 and more months after 1st CM, 5 = 2nd CM, 6, 7, 8 = 1, 2, 3 and more months after 2nd CM, 9 = 3rd CM, 10, 11, 12 = 1, 2, 3 and more months after 3rd CM, CM events > 3 assigned same penalties as if they were 3rd occurrence.After deleting impossible stage-state combinations, the model described 560,725 stage-state combinations.

  20. If we were able to overcome the curse of dimensionality … No longer only generic guidelines for the generic cow. The DP recommendations could be tailored to the individual cow in real time according to her cow characteristics and economics of the herd.

  21. Project 2: “Cost Effective Control Strategies for The Reduction of Johne’s Disease on Dairy Farms”Zhao Lu, PhD, Research Associate, and Becky Smith, DVM, PhD student

  22. Johne’s disease (paratuberculosis) • Johne’s disease is a chronic, infectious, intestinal disease caused by infection with Mycobacterium avium subspecies paratuberculosis(MAP). • Infection process of paratuberculosis on a dairy cow: Infection status Infection Transient shedding High shedding Latency Low shedding No clinical signs Sub-clinical Clinical Disease status

  23. Issues of Johne’s disease • Economic loss: > 200 million $ per year (Ott, 1999) due to the reduced milk production, lower slaughter value, etc. • Public health: a potential association between Johne’s disease and human Crohn’s disease has been debated. • Control of Johne’s disease: • Test and cull strategies, i.e., to cull/remove infectious animals form herd by test-positive results using diagnostic testing methods, such as culture and ELISA tests. • Improved hygiene management; • Vaccination. However, it is difficult to control JD spread: • Long incubation period; • Low diagnostic test sensitivity for animals shedding low levels of MAP; • Cross reactivity of Johne’s disease vaccines with tuberculosis (TB).

  24. -   ()   X1 H Y1 Tr Y2 Latent Low Susceptible Transient High  d d d d d 1  2 X2 Resistant d Modeling of MAP transmission on a dairy herd • A deterministic compartmental model (Mitchell et al., 2008). The test-based culling rates of low and high shedders are denoted by δ1 and δ2, respectively.

  25. Evaluation of effectiveness of test-based culling in Johne’s disease control • The reproduction ratio R0 was derived and a global parameter uncertainty analysis was performed to determine the effectiveness of test-based culling intervention (Lu et al., 2008)

  26. A stochastic multi-group model(Evaluation of effectiveness of test-based culling) Calves Heifers Cows

  27. Optimal control of Johne’s disease:economic model • Objective function (cost function): • Profit: selling milk, culling cows (meat); • Cost: raising first and second-year calves/heifers; diagnostic testing; • Lost: false-positive testing results. • Control: various scenarios of test-based culling rates and management • Constraints: a system of dynamic equations. • Compartment model providing numbers of calves, heifers, and cows in each compartment, which are needed in the objective functional (cost function). • A deterministic, discrete time economic model has been developed to find optimal test-based culling rates with large (6 and 12 month) time steps.

  28. What do we want?(Optimal control of test-based culling rates) • A deterministic, continuous time economic model. • Analytical studies of linear controls (test-based culling rates); • Numerical search of optimal test-based culling rates. • A stochastic economic model. • Reasons: more realistic (variable prevalence and fadeout due to random events) • Optimal culling rates using stochastic differential equations; • Numerical simulations of optimal culling rates for the mean of cost function. • Economic analysis of Johne’s disease vaccines. • Mathematical modeling of imperfect Johne’s vaccines is in progress.

  29. Vaccines are often imperfect They may not prevent all infections They may have effects other than decreasing susceptibility Efficacy can be considered as the proportional effect on a rate or probability parameter in a compartmental model 5 vaccine effects: Vertical transmission Horizontal transmission Susceptibility Infectiousness Duration of latency Duration of low-infectious period Progression of clinical symptoms Modeling the efficacy of an imperfect vaccine with multiple effects

  30. (1-p)(-) (1-p)  ()   X1 H Y1 Tr Y2 Latent Low Transient High  d d d d d  X2 Resistant d p(-) p e4  e3 e20() VX1 VH VY1 VTr VY2 Latent Low Susceptible Transient High  d d d d d e5 VX2 Resistant d Modeling vaccine efficacy against JD Susceptible

  31. Known information: birth date death date annual test dates and results vaccination status Missing information: Date of infection Onset of low-shedding Onset of high-shedding True infection status (if all tests results were negative) Estimating vaccine efficacy against JD with field data To estimate vaccine efficacy, missing information must also be estimated

  32. Estimating vaccine efficacy with Markov Chain Monte Carlo models MCMC models are Bayesian statistical models, useful for disease modeling because they • Can account for nonlinear systems • parameters may be inter-related • Can account for time-dependence • i.e. infectious pressure • Have a mechanism for missing-data problems: • Missing information can be estimated probabilistically, given a set of parameters drawn from a prior distribution • The full dataset can then be used to determine the relative likelihood of a different set of parameters drawn from the prior • The new set of parameters may be accepted or rejected, based on its relative likelihood • This process is iterated until it converges on a posterior distribution for all parameters

  33. Validating MCMC models • In order to test that an MCMC model predicts the true parameter distribution, we feed it data simulated with known parameters • In the case of the JD model, the full model requires individual animal data: • Infection status • Vaccination status • Dates of birth, compartment transitions, death • We need an individual-animal stochastic model

  34. Optimal control of Johne’s disease using an individual-based (agent-based) modeling approach • Controls: test-based culling, farm management, JD vaccines • Advantages of individual-based modeling (IBM) • Providing a general framework to model infectious disease transmission in a dairy herd; • Integrating all individual information together to predict the dynamics on farms; • Adding controls on farm level and/or individual animals easily. • Economic analysis based on IBM would be more accurate. • Disadvantages of IBM • Individual information collection: a detailed profile for each animal in a herd. (also an advantage) • Simulations: efficient algorithm and powerful computers are necessary.

  35. Project 3: “Develop, evaluate and improve food animal systems-based mathematical models of antimicrobial resistance among commensalbacteria” Cristina Lanzas, DVM, PhD, Research Associate

  36. At least 200,000 people suffer from hospital acquired infection every year, and at least 90,000 die in US. • Economical burden of antimicrobial resistance in clinical settings in US is estimated to be as high as $ 80 billion annually. • Pathogens outside the hospital are also becoming progressively resistant to common antimicrobials. • Antimicrobial resistance is also considered a food safety issue because infections with drug resistant foodborne pathogens (e.g. Salmonella) can be particularly serious. Bergstrom and Feldgarden, 2008

  37. Reservoirs of resistant genes are found in commensal bacteria in the human and animal gastrointestinal tracts (small intestine supports ~ 1010 bacterial cells/g). • Commensal bacteria can transfer mobile genes coding antimicrobial resistance among themselves and to pathogen bacteria (e.g. plasmid transfer between Salmonella and E. coli) Molecular mechanisms involved in the spread of antimicrobial resistance. Inter-cellular movement (horizontal spread) is the main cause of acquisition of resistance genes. Boerlin, 2008 Salyers et al., 2004

  38. - + S I BETWEEN HOSTS WITHIN HOST S The host population is divided according its epidemiological status (e.g. susceptible, infectious) “Binary response”: Animal carries the bacteria carrying the resistance or not R Population dynamics of antibiotic-sensitive and –resistant bacteria Linked to antibiotic exposure Emergence of resistance during antibiotic treatment Transmission of resistant clones Individuals colonized with either susceptible or resistant strains Fitness cost linked to microbial growth

  39. Within host dynamics of antimicrobial resistance dissemination Microbial growth for sensitive and resistant strains with horizontal gene transfer Logistic Growth Antibiotic effect Plasmid transfer Plasmid loss during segregation Percentage of resistant bacteria 24 h after the end of the antimicrobial treatment

  40. γ S S susceptible I infectious πη λ IS IR W environment ISR Between host dynamics of antimicrobial resistance dissemination

  41. Integrating within and between host antimicrobial resistance dynamics • Interventions to minimize the dissemination of antimicrobial resistance can be applied at different organizational levels (e.g. within host/between hosts and environment): • Optimize antimicrobial dosage regimes to mitigate the dissemination of antimicrobial resistance within enteric commensal bacteria. • Reduce the exposure of animals to antimicrobial resistant bacteria. • Mathematical approaches that integrate within and between host dynamics are necessary to optimize mitigation strategies acting at different hierarchical scales: • Agent-based/Individual-based models • Dynamic nested models

  42. Modeling On-farm Escherichia coli O157:H7 population dynamics • Metapopulation models has allowed us to investigate the potential role of non-bovine habitats (i.e., water troughs, feedbunks, and the surrounding pen environment) on the persistence and loads of E. coli O157:H7 in feedlots. • O157:H7 survive and reproduce in water troughs, feed, slurry, pen floors. Ayscue et al., FoodbornePathogDis, 6:461-470 (2009)

  43. This metapopulation approach is suitable for modeling the dynamics of antimicrobial resistance dissemination. Pharmacokinetics and pharmacodynamics and biological fitness of antimicrobial resistance can be integrated. Monogastric calf Animal patches Growing ruminant heifer S, R S, R Selective pressures S, R Bred ruminant heifer S, R Lactating cow Dry cow Water (S,R) Environment (S, R) Cull cow Dairy beef

  44. Assuming three types of ecological patches (water, environment and n animals) and assuming indirect transmission (bacteria are transmitted to animals through water and environment): For the j animal: Water patch: Environmental patch:

  45. Potential students projects • Application of optimal control to evaluate strategies in metapopulation models • Development of agent based models to address antimicrobial resistance dissemination. • Optimization in agent based models • Optimization in hierarchical models

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