Insulin release at the molecular level: Metabolic-electrophysiological modeling of the pancreatic beta-cells

The role of pancreatic /spl beta/-cells is fundamental in the control endocrine system, maintaining the blood glucose homeostasis in a physiological regime, via the glucose-induced release of insulin. An increasing amount of detailed experimental evidences at the cellular and molecular biology level...

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Bibliographic Details
Published in:IEEE transactions on biomedical engineering 2000-05, Vol.47 (5), p.611-623
Main Authors: Giugliano, M., Bove, M., Grattarola, M.
Format: Article
Language:English
Subjects:
Biochemistry
Biological and medical sciences
Biological system modeling
Biology computing
Blood
Calcium
Cells
Cells (biology)
Computer Simulation
Control systems
Electrophysiology
Endocrine pancreas
Endocrine system
Fundamental and applied biological sciences. Psychology
Glucose
Glucose - metabolism
Glucose - physiology
Hormones. RĂ©gulation
Humans
Insulin
Insulin - metabolism
Insulin Secretion
Ions
Islets of Langerhans - metabolism
Markov Chains
Mathematics
Metabolism
Models, Biological
Molecular dynamics
Pancreas
Rodents
Sugar
Vertebrates: endocrinology
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Summary:The role of pancreatic /spl beta/-cells is fundamental in the control endocrine system, maintaining the blood glucose homeostasis in a physiological regime, via the glucose-induced release of insulin. An increasing amount of detailed experimental evidences at the cellular and molecular biology levels have been collected on the key factors determining the insulin release by the pancreatic /spl beta/-cells. The direct transposition of such experimental data into accurate mathematical descriptions might contribute to considerably clarify the impact of each cellular component on the global glucose metabolism. Under these perspectives, we model and computer-simulate the stimulus-secretion coupling in /spl beta/-cells by describing four interacting cellular subsystems, consisting in the glucose transport and metabolism, the excitable electrophysiological behavior, the dynamics of the intracellular calcium ions, and the exocytosis of granules containing insulin. We explicit the molecular nature of each subsystem, expressing the mutual relationships and the feedbacks that determine the metabolic-electrophysiological behavior of an isolated /spl beta/-cell. Finally, we discuss the simulation results of the behavior of isolated /spl beta/-cells as well as of population of electrically coupled /spl beta/-cells in Langerhans islets, under physiological and pathological conditions, including noninsulin dependent diabetes mellitus (NIDDM) and hyperinsulinemic hypoglycaemia (PHHI).
ISSN:0018-9294
1558-2531
DOI:10.1109/10.841333