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Plant disease epidemiology: concepts and techniques for rice disease management through breeding and crop husbandry
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2. Why plant disease epidemiology? Importance of plant diseases because of epidemics
Need to understand epidemics – as we know them today
to implement effective control tools (incl. HPR)
to deploy efficient, durable control tools (ditto)
Need to predict epidemics – which will inevitably occur (possibly new diseases) – tomorrow
climate change (incl. water scarcity)
labor resource, natural resources, energy shortage
drivers of agricultural change affect crop health: (1) the relative importance of diseases is changing, (2) factors underpinning epidemics are changing—mechanisms remain
Many diseases: need for a framework, for methodology
New approaches (general theory, R0)
3. Plant disease epidemiology can Help control epidemics (good)
host plant resistance - 1 (partial HPR)
host plant resistance - 2 (deployment: complete HPR, partial HPR; over space and/or time)
tactical decisions: crop (health) management
Help prevent epidemics (better)
host plant resistance - 3 (complete HPR)
disease exclusion techniques (e.g., seed health)
Provide a conceptual framework: so many diseases, some barely known, biologically
4. seven questions Why do some diseases take off, whereas others do not?
Why do some strains, races, or pathotypes die out, some coexist, and others come to dominate pathogen populations?
How does the inherent variability associated with epidemics translate into risk?
Given that new infections occur at the small scale but epidemics are manifest at the large scale, how can we scale from individual to population behavior?
How can this information be used to identify control methods?
How can this information be used to optimize the efficient deployment and durability of control methods?
How does the way we grow and protect our crops or manage our natural and seminatural environment affect these outcomes?
6. Shapes of a few rice disease epidemics
7. the SEIR model SEIR = Suscepts, Exposed, Infectious, Removed
or (Plant Pathology):
H, Healthy sites
L, Latent sites
I, Infectious sites, and
P, post-infectious sites
One key rate: infection rate
Two delays: latency period, infectious period
8. the SEIR model: applications medical epidemiology
measles
HIV
influenza
tuberculosis
animal epidemiology
Pseudorabies virus in pigs
Mouse typhoid
computer viruses?
… and botanical epidemiology
9. infection rate (RI) - equation dL/dt = RI = Rc I Ca
L: latent sites; I: infectious sites
Rc: basic infection rate corrected for removals = number of new infections, per unit time, per infectious site (I)
C: “correction factor” = fraction of healthy sites (H), relative to the total number of sites in the system
a: disease aggregation coefficient
10. infection rate (RI) – over time dL/dt = RI = Rc I Ca
11. some additional ‘detail’ growth of the host = crop growth = growth of healthy sites
senescence = physiological (or/and) pathological
additional effects (on rate of infection only):
plant age (variable susceptibility)
temperature
canopy moisture
12. spatial scales of plant disease epidemics
13. scaling the model structure to address different diseases definition for a site (a lesion)
sites: levels of hierarchy chosen:
portion of leaf area: leaf blast, brown spot
a leaf: bacterial blight
a tiller: sheath blight
a plant: tungro
14. the SEIR model in plant pathology
15. the SEIR model in plant pathology
16. SEIR – system of differential ordinal equations H : number of healthy individuals
L : number of latent individuals
I : number of infectious individuals
R : number of post-infectious (removed) individuals
1/? : mean latent period
1/µ : mean infectious period
ß : per capita transmission rate (new diseased individuals per diseased individual per healthy individual per unit time).
17. A few rice disease epidemics simulated
18. A few rice disease epidemics simulated
