Mathematical Modeling of the Immune Response
Mathematical Modeling of the Immune Response
Stochastic Stage-structured Modeling of the Adaptive Immune System
CSB '03 Proceedings of the IEEE Computer Society Conference on Bioinformatics
On The Feasibility of Running Entity-Level Simulations on Grid Platforms
GRID '04 Proceedings of the 5th IEEE/ACM International Workshop on Grid Computing
CAFISS: a complex adaptive framework for immune system simulation
Proceedings of the 2005 ACM symposium on Applied computing
Computational modelling and simulation of the immune system
International Journal of Bioinformatics Research and Applications
Multi-agent modeling of the immune system: The situated cellular agents approach
Multiagent and Grid Systems - Multi-agent systems for medicine, computational biology, and bioinformatics
BioCrawler: An intelligent crawler for the semantic web
Expert Systems with Applications: An International Journal
Granularity and the validation of agent-based models
Proceedings of the 2008 Spring simulation multiconference
Agent-based modeling of host-pathogen systems: The successes and challenges
Information Sciences: an International Journal
Simulating antigenic drift and shift in influenza A
Proceedings of the 2009 ACM symposium on Applied Computing
Object-Oriented Refactoring of Existing Immune Models
ICARIS '09 Proceedings of the 8th International Conference on Artificial Immune Systems
A mathematical model of the competition between acquired immunity and virus
AISC'10/MKM'10/Calculemus'10 Proceedings of the 10th ASIC and 9th MKM international conference, and 17th Calculemus conference on Intelligent computer mathematics
Formally specifying t cell cytokine networks with b method
CIS'04 Proceedings of the First international conference on Computational and Information Science
The swarming body: simulating the decentralized defenses of immunity
ICARIS'06 Proceedings of the 5th international conference on Artificial Immune Systems
Immune system modeling: the OO way
ICARIS'06 Proceedings of the 5th international conference on Artificial Immune Systems
An evolution hypothesis of bacterial populations
WIRN'05 Proceedings of the 16th Italian conference on Neural Nets
Modelling the immune system with situated agents
WIRN'05 Proceedings of the 16th Italian conference on Neural Nets
Fuzzy continuous petri net-based approach for modeling immune systems
WIRN'05 Proceedings of the 16th Italian conference on Neural Nets
An AIS-based dynamic routing (AISDR) framework
ICARIS'05 Proceedings of the 4th international conference on Artificial Immune Systems
Inspiration for the next generation of artificial immune systems
ICARIS'05 Proceedings of the 4th international conference on Artificial Immune Systems
Evaluating theories of immunological memory using large-scale simulations
ICARIS'05 Proceedings of the 4th international conference on Artificial Immune Systems
IDReAM: intrusion detection and response executed with agent mobility
Engineering Self-Organising Systems
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When a foreign substance (antigen) is introduced into our bodies, our immune system acts to eliminate that substance. This response is a complex process involving the collective and coordinated response of approximately 1012 cells, which is comparable to the number of synapses in the human brain. In an effort to fit detailed experimental observations into a comprehensive model of the immune system, computer simulations are just beginning to play a role. The approach that we describe uses a modified cellular automaton (or lattice gas). Although our automaton is much more complex than the automata usually considered by mathematicians and is not subject to analytical analysis by presently known methods, it has several advantages over traditional ODE models