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Dynamic Modeling of Diseases and Pests
Dynamic Modeling of Diseases and Pests
Edición/Edição: VIII
Autores: Hannon, Bruce; Ruth, Matthias
ISBN: 9780387095592
Formato: Rústica/Paperback
Nº volumenes: 1 Páginas: 290
Año publicación/Ano de publicação: 2009
Disponibilidad/Disponibilidade: 3 días
Precio/Preço : 57,70 € 57,00 € (54,81€ + iva)
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Cómpralos juntos y ahorra
Dynamic Modeling of Diseases and Pests Emery Elementos de Genética Médica + Acceso Online 15ª Ed.
· Dynamic Modeling of Diseases and Pests (Hannon, Bruce; Ruth, Matthias)
· Emery Elementos de Genética Médica + Acceso Online 15ª Ed. (Peter Turnpenny | Sian Ellard)
121,16 € 115,10 €
About this textbook
  • Introduces students to hands-on dynamic modeling in the context of disease, and challenges them to use their models and insights to explore interventions that may help restrain contagion
  • The structure is based on the assumption that modeling is best learned by doing and by then critically evaluating the structure, performance and outcome of the model
  • Contains generic models of epidemics and chapters on individual diseases, as well as other forms of "pests" for which humanity has devised intervention and control mechanisms, based on the use of STELLA software
  • Begins with simple models, focusing on the motivation and act of modeling as much as on the specific features of what is modeled, and gradually proceeds to the development of fairly complicated models

Models help us understand the nonlinear dynamics of real-world processes by using the computer to mimic the actual forces that result in a system’s behavior. The growing complexity of human social systems, from individual behavior to that of entire populations makes us increasingly vulnerable to diseases and pests. The ecology of the disease agents and the pests when considered in this social context only adds to the complexity. The feedbacks, lags in the effects of our preventive actions and the randomness in the environment make understanding of these vulnerabilities seem insurmountable. The amount and pace of modern travel provides virus and pest alike with the means to quickly find new hosts in untouched human populations and the ecosystems.

We thus have compelling reasons to understand the dynamics of these combined systems. This book begins with simple examples of human epidemics and then insect dynamics. Next comes the models of ever more complex models of disease carried by interaction of the two. An invasive species model is followed by insect-ecosystem interactions. The general models of chaos and catastrophe are linked to models of disease and pest. The final model is a spatial dynamic spread of disease among a wild animal population.

By using the STELLA programs (runtime versions and digital forms of all models are available with the book) we show how with a minimum of mathematical preparation and programming experience, these complex processes can be simulated and their emergent properties discovered. The programs run on both Macintosh and PC based machines.

Written for:

Students and researchers in epidemiology, medicine, veterinary biosciences, animal and plant sciences, biochemistry, microbiology, public policy

  • Contagious
  • Disease management
  • Infectious disease
  • Pestilence
  • Population biology

Table of contents

Part I: Introduction

1. The Why and How of Dynamic Modeling

1.1. Introduction

1.2. Static, Comparative-Static and Dynamic Models

1.3. Model Complexity and Explanatory Power

1.4. Model Components

1.5. Modeling in STELLA

1.6. Analogy and Creativity

1.7. STELLA’s Numeric Solution Techniques

1.8. Sources of Model Errors

1.9. The Detailed Modeling Process

1.10. Questions and Tasks

2. Basic Epidemic Models

2.1. Basic Model

2.2. Epidemic Model with Randomness

2.3. Loss of Immunity

2.4. Two Population Epidemic Model

2.5. Epidemic with Vaccination

2.6. Questions and Tasks

3. Insect Dynamics

3.1. Matching Experiments and Models of Insect Life Cycles

3.2. Optimal Insect Switching

3.3. Two-Age Class Parasite Model

3.4. Questions and Tasks

Part II: Applications

4. Malaria and Sickle Cell Anemia

4.1. Malaria

4.1.1. Basic Malaria Model

4.1.2. Questions and Tasks

4.2. Sickle Cell Anemia and Malaria in Balance

4.2.1. Sickle Cell Anemia

4.2.2. Questions and Tasks

5. Encephalitis

5.1. St. Louis Encephalitis

5.2. Questions and Tasks

6. Chagas Disease

6.1. Chagas Disease Spread and Control Strategies

6.2. Questions and Tasks

7. Lyme Disease

7.1. Lyme Disease Model

7.2. Questions and Tasks

8. Chicken Pox and Shingles

8.1. Model Assumptions and Structure

8.2. Questions and Tasks

9. Toxoplasmosis

9.1. Introduction

9.2. Model Construction

9.3. Results

9.4. Questions and Tasks

10. The Zebra Mussel

10.1. Introduction

10.2 Model Development

10.3 Model Results

10.4 Questions and Tasks

11. Biological Control of Pestilence

11.1. Herbivory and Algae

11.1.1. Herbivore-Algae Predator-Prey Model

11.1.2. Questions and Tasks

11.2. Bluegill Population Management

11.2.1. Bluegill Dynamics

11.2.2. Impacts of Fishing

11.2.3. Impacts of Disease

11.2.4. Questions and Tasks

11.3. Woolly Adelgid

11.3.1. Infestation of Fraser Fir

11.3.2. Adelgid and Fir Dynamics

11.3.3. Questions and Tasks

12. Indirect SIR Models of Arboviral Encephalitis Transmission

12.1. Emily Wheeler and Traci Barkley

12.2. Susceptible-Infected-Resistant (SIR) Models in Dynamic Populations

12.2.1. Model Structure and Behavior

12.2.2. Questions and Tasks

12.3. Base WNV SIR Model with a Dynamic Vector Population

12.3.1. Base Model Structure and Behavior

12.3.2. Questions and Tasks

12.4. Avian Population Effects and Seasonal Dynamics

12.4.1. Modifications to the Base Model

12.4.2. Avian Demography and Disease Persistence

12.4.3. Weather as an Extrinsic Driver of Outbreak Severity

12.4.4. Questions and Tasks

13. Chaos and Pestilence

13.1. Basic Disease Model with Chaos

13.1.1. Model Setup

13.1.2. Detecting and Interpreting Chaos

13.1.3. Questions and Tasks

13.2. Chaos with Nicholson-Bailey Equations

13.2.1. Host-Parasitoid Interactions

13.2.2. Questions and Tasks

14. Catastrophe and Pestilence

14.1. Basic Catastrophe Model

14.2. Spruce Budworm Catastrophe

14.3. Questions and Tasks

15. Spatial Dynamics of Pestilence

15.1. Diseased and Healthy Migrating Insects

15.1.1. Questions and Tasks

15.2. The Spatial Dynamic Spread of Rabies in Foxes

15.2.1. Introduction

15.2.2. Fox Rabies in Illinois

15.2.3. Previous Fox Rabies Models

15.2.4. The Rabies Virus

15.2.5. Fox Biology

15.2.6. Model Design

15.2.7. Cellular Model

15.2.8. Model Assumptions

15.2.9. Georeferencing the Modeling Process

15.2.10. Spatial Characteristics

15.2.11. Model Constraints

15.2.12. Model Results

15.2.13. Rabies Pressure

15.2.14. The Effects of Disease Alone

15.2.15. Hunting Pressure

15.2.16. Controlling the Disease

Part III: Conclusions

16. Conclusions

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