Dynamic Modeling in the Health Sciences

1. Front Matter

   Pages i-xxiii

   PDF

2. Discoveries with a Computer: Dynamic Behavior

   • James L. Hargrove

   Pages 1-10

3. How to Create Simple STELLA® Models to Solve Basic Equations

   • James L. Hargrove

   Pages 11-23

4. How an Equation from Physiology Can Become a Model

   • James L. Hargrove

   Pages 24-28

5. Rates of Change

   • James L. Hargrove

   Pages 29-39

6. The Steady State: A Question of Balance

   • James L. Hargrove

   Pages 40-45

7. Equations for Model Building: The Surface Law and Body Composition

   • James L. Hargrove

   Pages 46-58

8. A Primer on Biodynamics and Gene Expression

   • James L. Hargrove

   Pages 59-79

9. Chronological Time Versus Physiological Time

   • James L. Hargrove

   Pages 80-91

10. Energy Needs for Work

    • James L. Hargrove

    Pages 92-99

11. The Human Thermostat

    • James L. Hargrove

    Pages 100-105

12. Dietary Polyunsaturated Fats and Your Cell Membranes

    • James L. Hargrove

    Pages 106-119

13. Responses to Nutrients

    • James L. Hargrove

    Pages 120-126

14. Symmetry of Human Growth and Aging

    • James L. Hargrove

    Pages 127-140

15. A Stochastic Model of Senescence and Demise

    • James L. Hargrove

    Pages 141-144

16. Mortality and Risk for Chronic Disease

    • James L. Hargrove

    Pages 145-158

17. Kinetic Genetics: Compartmental Models of Gene Expression

    • James L. Hargrove

    Pages 159-174

18. From Genotype to Phenotype

    • James L. Hargrove

    Pages 175-191

19. The Plateau Principle: A Key to Biological System Dynamics

    • James L. Hargrove

    Pages 192-199

20. Compartmental Models in Metabolic Studies: Vitamin C

    • James L. Hargrove

    Pages 200-210

The world consists of many complex systems, ranging from our own bodies to ecosystems to economic systems. Despite their diversity, complex systems have many structural and functional features in common that can be effec­ tively simulated using powerful, user-friendly software. As a result, virtually anyone can explore the nature of complex systems and their dynamical be­ havior under a range of assumptions and conditions. This ability to model dy­ namic systems is already having a powerful influence on teaching and study­ ing complexity. The books is this series will promote this revolution in "systems thinking" by integrating skills of numeracy and techniques of dynamic modeling into a variety of disciplines. The unifying theme across the series will be the power and Simplicity of the model-building process, and all books are designed to engage the reader in developing their own models for exploration of the dy­ namics of systems that are of interest to them. Modeling Dynamic Systems does not endorse any particular modeling par­ adigm or software. Rather, the volumes in the series will emphasize simplic­ ity of learning, expressive power, and the speed of execution as priorities that will facilitate deeper system understanding.

• Dynamics
• Vitamin
• Vitamin C
• bone
• genetics
• model
• modeling
• physiology
• simulation

• Department of Foods and Nutrition, University of Georgia, Athens, USA

  James L. Hargrove

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