Theories of Immune Networks [electronic resource] /

Theories of Immune Networks [electronic resource] /

Show other versions (1)

For a long time, immunology has been dominated by the idea of a simple linear cause-effect relationship between the exposure to an antigen and the production of specific antibodies against that antigen. Clonal selection was the name of the theory based on this idea and it has provided the main concepts to account for the known features of the immune response. More recently, immunologists have discovered a wealth of new facts, in the form of different regulatory cells (helpers, suppressors, antigen presenting cells), genetic determinations of immune responses such as those involved in graft re­ jections, different molecular structures responsible for intercellular interactions such as interleukins, cytokins, idiotype-antiidiotype recognition and others. While furthering our understanding of the local interactions (molecular and cellular) in­ volved in the immune response, these discoveries have led to a questioning of the simplicities of the classical clonal selection theory. It is clear today that every single immune response is a cooperative phenomenon involving several different molecular and cellular interactions taking place in a coupled manner. In addition, cross reactivity to different antigens has shown that responses of the whole im­ mune system to different antigens are not completely isolated from one another and that the history of encounters with different antigens plays a crucial role in the maturation of the whole system. Thus, problems of complexity, generation of di­ versity and self-organization have entered the field of immunology.

Saved in:
Bibliographic Details
Main Authors: Atlan, Henri. editor., Cohen, Irun R. editor., SpringerLink (Online service)
Format: Texto biblioteca
Language:eng
Published: Berlin, Heidelberg : Springer Berlin Heidelberg, 1989
Subjects:Medicine., Immunology., Physical chemistry., Allergy., Biochemistry., Biophysics., Biological physics., Biomedicine., Biophysics and Biological Physics., Physical Chemistry., Allergology., Biochemistry, general.,
Online Access:http://dx.doi.org/10.1007/978-3-642-83935-1
Tags: Add Tag
No Tags, Be the first to tag this record!
id KOHA-OAI-TEST:173464
record_format koha
institution COLPOS
collection Koha
country México
countrycode MX
component Bibliográfico
access En linea
En linea
databasecode cat-colpos
tag biblioteca
region America del Norte
libraryname Departamento de documentación y biblioteca de COLPOS
language eng
topic Medicine.
Immunology.
Physical chemistry.
Allergy.
Biochemistry.
Biophysics.
Biological physics.
Biomedicine.
Immunology.
Biophysics and Biological Physics.
Physical Chemistry.
Allergology.
Biochemistry, general.
Medicine.
Immunology.
Physical chemistry.
Allergy.
Biochemistry.
Biophysics.
Biological physics.
Biomedicine.
Immunology.
Biophysics and Biological Physics.
Physical Chemistry.
Allergology.
Biochemistry, general.
spellingShingle Medicine.
Immunology.
Physical chemistry.
Allergy.
Biochemistry.
Biophysics.
Biological physics.
Biomedicine.
Immunology.
Biophysics and Biological Physics.
Physical Chemistry.
Allergology.
Biochemistry, general.
Medicine.
Immunology.
Physical chemistry.
Allergy.
Biochemistry.
Biophysics.
Biological physics.
Biomedicine.
Immunology.
Biophysics and Biological Physics.
Physical Chemistry.
Allergology.
Biochemistry, general.
Atlan, Henri. editor.
Cohen, Irun R. editor.
SpringerLink (Online service)
Theories of Immune Networks [electronic resource] /
description For a long time, immunology has been dominated by the idea of a simple linear cause-effect relationship between the exposure to an antigen and the production of specific antibodies against that antigen. Clonal selection was the name of the theory based on this idea and it has provided the main concepts to account for the known features of the immune response. More recently, immunologists have discovered a wealth of new facts, in the form of different regulatory cells (helpers, suppressors, antigen presenting cells), genetic determinations of immune responses such as those involved in graft re­ jections, different molecular structures responsible for intercellular interactions such as interleukins, cytokins, idiotype-antiidiotype recognition and others. While furthering our understanding of the local interactions (molecular and cellular) in­ volved in the immune response, these discoveries have led to a questioning of the simplicities of the classical clonal selection theory. It is clear today that every single immune response is a cooperative phenomenon involving several different molecular and cellular interactions taking place in a coupled manner. In addition, cross reactivity to different antigens has shown that responses of the whole im­ mune system to different antigens are not completely isolated from one another and that the history of encounters with different antigens plays a crucial role in the maturation of the whole system. Thus, problems of complexity, generation of di­ versity and self-organization have entered the field of immunology.
format Texto
topic_facet Medicine.
Immunology.
Physical chemistry.
Allergy.
Biochemistry.
Biophysics.
Biological physics.
Biomedicine.
Immunology.
Biophysics and Biological Physics.
Physical Chemistry.
Allergology.
Biochemistry, general.
author Atlan, Henri. editor.
Cohen, Irun R. editor.
SpringerLink (Online service)
author_facet Atlan, Henri. editor.
Cohen, Irun R. editor.
SpringerLink (Online service)
author_sort Atlan, Henri. editor.
title Theories of Immune Networks [electronic resource] /
title_short Theories of Immune Networks [electronic resource] /
title_full Theories of Immune Networks [electronic resource] /
title_fullStr Theories of Immune Networks [electronic resource] /
title_full_unstemmed Theories of Immune Networks [electronic resource] /
title_sort theories of immune networks [electronic resource] /
publisher Berlin, Heidelberg : Springer Berlin Heidelberg,
publishDate 1989
url http://dx.doi.org/10.1007/978-3-642-83935-1
work_keys_str_mv AT atlanhenrieditor theoriesofimmunenetworkselectronicresource
AT cohenirunreditor theoriesofimmunenetworkselectronicresource
AT springerlinkonlineservice theoriesofimmunenetworkselectronicresource
_version_ 1756263729341661184
spelling KOHA-OAI-TEST:1734642018-07-30T22:51:10ZTheories of Immune Networks [electronic resource] / Atlan, Henri. editor. Cohen, Irun R. editor. SpringerLink (Online service) textBerlin, Heidelberg : Springer Berlin Heidelberg,1989.engFor a long time, immunology has been dominated by the idea of a simple linear cause-effect relationship between the exposure to an antigen and the production of specific antibodies against that antigen. Clonal selection was the name of the theory based on this idea and it has provided the main concepts to account for the known features of the immune response. More recently, immunologists have discovered a wealth of new facts, in the form of different regulatory cells (helpers, suppressors, antigen presenting cells), genetic determinations of immune responses such as those involved in graft re­ jections, different molecular structures responsible for intercellular interactions such as interleukins, cytokins, idiotype-antiidiotype recognition and others. While furthering our understanding of the local interactions (molecular and cellular) in­ volved in the immune response, these discoveries have led to a questioning of the simplicities of the classical clonal selection theory. It is clear today that every single immune response is a cooperative phenomenon involving several different molecular and cellular interactions taking place in a coupled manner. In addition, cross reactivity to different antigens has shown that responses of the whole im­ mune system to different antigens are not completely isolated from one another and that the history of encounters with different antigens plays a crucial role in the maturation of the whole system. Thus, problems of complexity, generation of di­ versity and self-organization have entered the field of immunology.to Immune Networks -- I -- Natural Id-Anti-Id Networks and the Immunological Homunculus -- Self-Nonself Immunological Tolerance and Idiotype Networks -- II -- Extensive Percolation in Reasonable Idiotypic Networks -- The Concept of Idiotypic Network: Deficient or Premature? -- Dynamical Behavior of Discrete Models of Jerne’s Network -- Some Reflections on Memory in Shape Space -- III -- Regulation of the Immune Response: A Discrete Mapping Approach -- Simulation of the Immune Cellular Response by Small Neural Networks -- Discrete Time Versus Continuous Time Approach to the Autoimmune Response -- Optimizing the Immune Control of Parasitic Invasion -- Index of Contributors.For a long time, immunology has been dominated by the idea of a simple linear cause-effect relationship between the exposure to an antigen and the production of specific antibodies against that antigen. Clonal selection was the name of the theory based on this idea and it has provided the main concepts to account for the known features of the immune response. More recently, immunologists have discovered a wealth of new facts, in the form of different regulatory cells (helpers, suppressors, antigen presenting cells), genetic determinations of immune responses such as those involved in graft re­ jections, different molecular structures responsible for intercellular interactions such as interleukins, cytokins, idiotype-antiidiotype recognition and others. While furthering our understanding of the local interactions (molecular and cellular) in­ volved in the immune response, these discoveries have led to a questioning of the simplicities of the classical clonal selection theory. It is clear today that every single immune response is a cooperative phenomenon involving several different molecular and cellular interactions taking place in a coupled manner. In addition, cross reactivity to different antigens has shown that responses of the whole im­ mune system to different antigens are not completely isolated from one another and that the history of encounters with different antigens plays a crucial role in the maturation of the whole system. Thus, problems of complexity, generation of di­ versity and self-organization have entered the field of immunology.Medicine.Immunology.Physical chemistry.Allergy.Biochemistry.Biophysics.Biological physics.Biomedicine.Immunology.Biophysics and Biological Physics.Physical Chemistry.Allergology.Biochemistry, general.Springer eBookshttp://dx.doi.org/10.1007/978-3-642-83935-1URN:ISBN:9783642839351

Similar Items