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TB Cluster Models, Time Scales and Relations to HIV

This study explores non-autonomous models to understand the impact of HIV on TB dynamics, test CDC's TB control goals, and analyze the effects of casual and close contacts on TB transmission.

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TB Cluster Models, Time Scales and Relations to HIV

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  1. TB Cluster Models, Time Scales and Relations to HIV Carlos Castillo-Chavez Department of Biological Statistics and Computational Biology Department of Theoretical and Applied Mechanics Cornell University, Ithaca, New York, 14853 MTBI Cornell University

  2. Outline • A non-autonomous model that incorporates the impact of HIV on TB dynamics. • Model to test CDC’s TB control goals. • Casual versus close contacts and their impact on TB. • Time scales and singular perturbation approaches in the study of the dynamics of TB. MTBI Cornell University

  3. TB in the US(1953-1999) MTBI Cornell University

  4. Reemergence of TB • New York City and San Francisco had • recent outbreaks. • Cost of control the outbreak in NYC alone • was estimated to be about 1 billion. • Observed national TB case rate increase. • TB reemergence became an international • issue. • CDC sets control goal in 1989. MTBI Cornell University

  5. Basic Model Framework • N=S+E+I+T, Total population • F(N): Birth and immigration rate • B(N,S,I): Transmission rate (incidence) • B`(N,S,I): Transmission rate (incidence) MTBI Cornell University

  6. Model Equations MTBI Cornell University

  7. CDC Short-Term Goal: 3.5 cases per 100,000 by 2000. Has CDC met this goal? CDC Long-term Goal: One case per million by 2010. Is it feasible? TB control in the U.S. MTBI Cornell University

  8. Model Construction Since d has been approximately equal to zero over the past 50 years in the US, we only consider Hence, N can be computed independently of TB. MTBI Cornell University

  9. Non-autonomous model (permanent latent class of TB introduced) MTBI Cornell University

  10. Effect of HIV MTBI Cornell University

  11. Upper Bound and Lower Bound For Epidemic Threshold If R<1, L1(t), L2(t) and I(t) approach zero; If R>1, L1(t), L2(t) and I(t) all have lower positive boundary; If (t) and d(t) are time-independent, R and R are Equal to R0 . MTBI Cornell University

  12. Parameter estimation and simulation setup MTBI Cornell University

  13. Parameter estimation and simulation setup N(t) is from census data and population projection MTBI Cornell University

  14. RESULTS MTBI Cornell University

  15. CONCLUSIONS MTBI Cornell University

  16. CONCLUSIONS MTBI Cornell University

  17. CDC’s Goal Delayed • Impact of HIV. • Lower curve does not include HIV impact; • Upper curve represents the case rate when HIV is included; • Both are the same before 1983. Dots represent real data. MTBI Cornell University

  18. Regression approach A Markov chain model supports the same result MTBI Cornell University

  19. Cluster Models • Incorporates contact type (close vs. casual) and focus on the impact of close and prolonged contacts. • Generalized households become the basic epidemiological unit rather than individuals. • Use natural epidemiological time-scales in model development and analysis. MTBI Cornell University

  20. Close and Casual contacts Close and prolonged contacts are likely to be responsible for the generation of most new cases of secondary TB infections. “A high school teacher who also worked at library infected the students in her classroom but not those who came to the library.” Casual contacts also lead to new cases of active TB. WHO gave a warning in 1999 regarding air travel. It announced that flights of more than 8 hours pose a risk for TB transmission. MTBI Cornell University

  21. Transmission Diagram MTBI Cornell University

  22. Key Features • Basic epidemiological unit: cluster (generalized household) • Movement of kE2 to I class brings nkE2 to N1population, where by assumptions nkE2(S2 /N2) go to S1 and nkE2(E2/N2) go to E1 • Conversely, recovery of I infectious bring nI back to N2 population, where nI (S1 /N1)=  S1 go to S2 and nI (E1 /N1)=  E1 go to E2 MTBI Cornell University

  23. Basic Cluster Model MTBI Cornell University

  24. Basic Reproductive Number where is the expected number of infections produced by one infectious individual within his/her cluster. denotes the fraction who survives the latency period and become active cases. MTBI Cornell University

  25. Diagram of Extended Cluster Model MTBI Cornell University

  26.  (n) Both close casual contacts are included in the extended model. The risk of infection per susceptible,  , is assumed to be a nonlinear function of the average cluster size n. The constant p measures the average proportion of the time that an “individual spends in a cluster. MTBI Cornell University

  27. R0 Depends on n in a non-linear fashion MTBI Cornell University

  28. Role of Cluster Size E(n) denotes the ratio of within cluster to between cluster transmission. E(n) increases and reaches its maximum value at The cluster size n* is defined as optimal as it maximizes the relative impact of within to between cluster transmission. MTBI Cornell University

  29. Full system Hoppensteadt’s Theorem(1973) Reduced system where x Rm, y Rn and  is a positive real parameter near zero (small parameter). Five conditions must be satisfied (not listed here) to apply the theorem. In addition, it is shown that if the reduced system has a globally asymptotically stable equilibrium then the full system has a g.a.s. equilibrium whenever 0<  <<1. MTBI Cornell University

  30. Two time Scales • Latent period is long and roughly has the same order of magnitude as that associated with the life span of the host. • Average infectious period is about six months (wherever there is treatment, is even shorter). MTBI Cornell University

  31. Rescaling Time is measured in average infectious periods (fast time scale), that is, = k t. The state variables are rescaled as follow: Where   / is the asymptotic carrying capacity. MTBI Cornell University

  32. Rescaled Model MTBI Cornell University

  33. Rescaled Model MTBI Cornell University

  34. Dynamics on Slow Manifold Solving for the quasi-steady states y1, y2 and y3in terms of x1 and x2 gives Substituting these expressions into the equations for x1 and x2 lead to the equations of motion on the slow manifold. MTBI Cornell University

  35. Slow Manifold Dynamics Where is the number of secondary infections produced by one infectious individual in a population where everyone is susceptible MTBI Cornell University

  36. Theorem If Rc0  1,the disease-free equilibrium (1,0) is globally asymptotically stable. While if Rc0 > 1, (1,0) is unstable and the endemic equilibrium is globally asymptotically stable. This theorem characterizes the dynamics on the slow manifold MTBI Cornell University

  37. Dynamics for Full System Theorem: For the full system, disease-free equilibrium is globally asymptotically stable whenever R0c <1; while R0c >1 there exists a unique endemic equilibrium which is globally asymptotically stable. Proof approach: Construct Lyapunov function for the case R0c <1; for the case R0c >1, we use Hoppensteadt’s Theorem. A similar result can be found in Z. Feng’s 1994, Ph.D. dissertation. MTBI Cornell University

  38. 1 Bifurcation Diagram Global bifurcation diagram when 0<<<1 where  denotes the ratio between rate of progression to active TB and the average life-span of the host (approximately). MTBI Cornell University

  39. Numerical Simulations MTBI Cornell University

  40. Conclusions from cluster models • TB has slow dynamics but the change of • epidemiological units makes it possible to identify • non-traditional fast and slow dynamics. • Quasi steady assumptions (adiabatic elimination of • parameter) are valid (Hoppensteadt’s theorem). • The impact of close and casual contacts can be study • using this approach as long as progression rates • from the latently to the actively-infected stages are • significantly different. MTBI Cornell University

  41. Conclusions from cluster models • Singular perturbation theory can be used to study the global asymptotic dynamics. • Optimal cluster size highlights the relative impact of close versus casual contacts and suggests alternative mechanisms of control. • The analysis of the system for the case where the small parameter  is not small has not been carried out. Simulations suggest a wider range. MTBI Cornell University

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