TY - JOUR
T1 - Homeostasis of peripheral immune effectors
AU - Warrender, Christina
AU - Forrest, Stephanie
AU - Segel, Lee
N1 - Funding Information:
The authors gratefully acknowledge the partial support of the National Institutes of Health (P20 GM066283), the National Science Foundation (grants ANIR-9986555, CCR-0311686, and DBI-0309147), Defense Advanced Research Projects Agency (grants AGR F30602-00-2-0584 and F30602-02-1-0146), the Intel Corporation, and the Santa Fe Institute. Dennis Chao and an anonymous referee provided many helpful suggestions.
PY - 2004/11
Y1 - 2004/11
N2 - In this paper, we use both mathematical modeling and simulation to explore homeostasis of peripheral immune system effector cells, particularly alveolar macrophages. Our interest is in the distributed control mechanisms that allow such a population to maintain itself. We introduce a multi-purpose simulator designed to study individual cell responses to local molecular signals and their effects on population dynamics. We use the simulator to develop a model of growth factor regulation of macrophage proliferation and survival. We examine the effects of this form of regulation in the context of two competing hypotheses regarding the source of new alveolar macrophages. In one model, local cells divide to replenish the population; in the other, only cells migrating from circulation divide. We find that either scenario is plausible, although the influx-driven system is inherently more stable. The proliferation-driven system requires lower cell death and efflux rates than the influx-driven system.
AB - In this paper, we use both mathematical modeling and simulation to explore homeostasis of peripheral immune system effector cells, particularly alveolar macrophages. Our interest is in the distributed control mechanisms that allow such a population to maintain itself. We introduce a multi-purpose simulator designed to study individual cell responses to local molecular signals and their effects on population dynamics. We use the simulator to develop a model of growth factor regulation of macrophage proliferation and survival. We examine the effects of this form of regulation in the context of two competing hypotheses regarding the source of new alveolar macrophages. In one model, local cells divide to replenish the population; in the other, only cells migrating from circulation divide. We find that either scenario is plausible, although the influx-driven system is inherently more stable. The proliferation-driven system requires lower cell death and efflux rates than the influx-driven system.
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U2 - 10.1016/j.bulm.2004.02.003
DO - 10.1016/j.bulm.2004.02.003
M3 - Article
C2 - 15522343
AN - SCOPUS:7444259673
SN - 0092-8240
VL - 66
SP - 1493
EP - 1514
JO - Bulletin of mathematical biology
JF - Bulletin of mathematical biology
IS - 6
ER -