Listing 1 - 10 of 28 | << page >> |
Sort by
|
Choose an application
Choose an application
Ecology --- Animal populations --- Stability --- Ecologie --- Animaux --- Stabilité --- Mathematical models --- Modèles mathématiques --- Populations --- Stabilité --- Modèles mathématiques --- Ecology - Mathematical models --- Animal populations - Mathematical models
Choose an application
Animal populations --- Ecology --- Stability. --- Mathematical models. --- Mathematical statistics --- General ecology and biosociology --- Stability --- Dynamics --- Mechanics --- Motion --- Vibration --- Benjamin-Feir instability --- Equilibrium --- Demography, Wildlife --- Populations, Animal --- Wildlife demography --- Wildlife populations --- Animal ecology --- Population biology --- Mathematical models --- Ecologie --- Animaux --- Stabilité --- Modèles mathématiques --- Populations
Choose an application
Choose an application
Choose an application
Choose an application
Choose an application
57.07 --- 56.017.4 --- Extinction (Biology) --- Animals --- Extirpation (Biology) --- Biology --- Extinct animals --- Extinct species, orders etc. Fossil plants, animals, humans --- Causes of extinction of organisms in various eras --- Extinction --- Extirpation --- CON Bioconservation --- bioconservation --- ecology --- endangered species --- extinction --- extinction rates --- 56.017.4 Causes of extinction of organisms in various eras --- 57.07 Extinct species, orders etc. Fossil plants, animals, humans --- Extinction (Biology). --- Extinction (Biologie)
Choose an application
Choose an application
We know, down to the tiniest details, the molecular structure of the human immunodeficiency virus (HIV). Yet despite this tremendous accomplishment, and despite other remarkable advances in our understanding of individual viruses and cells of the immune system, we still have no agreed understanding of the ultimate course and variability of the pathogenesis of AIDS. Gaps in our understanding like these impeded our efforts towards developing effective therapies and preventive vaccines. The authors describe the emerging field of theoretical immunology in this accessible and well-written text. Using mathematical modelling techniques, the authors set out their ideas about how populations of viruses and populations of immune system cells may interact in various circumstances, and how infectious diseases spread within patients. They explain how this approach to understanding infectious diseases can reveal insights into the dynamics of viral and other infections, and the interactions between infectious agents and immune responses. The book is structured around the examples of HIV/AIDS and Hepatitis B virus, although the approaches described will be more widely applicable. The authors use mathematical tools to uncover the detailed dynamics of the infection and the dynamics of immune responses, viral evolution, and mutation. The practical implications of this work for optimization of the design of therapy and vaccines are discussed. The book concludes with a glance towards the future of this fascinating, and potentially highly useful, field of study.
Virus diseases --- Immune response --- Mathematical models --- Biomathematics. Biometry. Biostatistics --- Immunology. Immunopathology --- Medical microbiology, virology, parasitology --- Mathematical models. --- Virus diseases - Mathematical models --- Immune response - Mathematical models --- VIRUSES --- DRUG RESISTANCE, MICROBIAL --- ANTIGENIC VARIATION --- HIV --- HTLV-BLV VIRUSES --- IMMUNOLOGY
Listing 1 - 10 of 28 | << page >> |
Sort by
|