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The Journal of Neurophysiology Vol. 83 No. 3 March 2000, pp. 1329-1337
Copyright ©2000 by the American Physiological Society
1Division of Neuroscience, Center for Theoretical Neuroscience, Baylor College of Medicine, Houston, Texas 77030; and 2Sloan Center for Theoretical Neurobiology, The Salk Institute, La Jolla, California 92037
Wiest, Michael C.,
David M. Eagleman,
Richard D. King, and
P. Read Montague.
Dendritic Spikes and Their Influence on Extracellular Calcium
Signaling. J. Neurophysiol. 83: 1329-1337, 2000. Extracellular calcium is critical for many neural
functions, including neurotransmission, cell adhesion, and neural
plasticity. Experiments have shown that normal neural activity is
associated with changes in extracellular calcium, which has motivated
recent computational work that employs such fluctuations in an
information-bearing role. This possibility suggests that a new style of
computing is taking place in the mammalian brain in addition to current `circuit' models that use only neurons and connections. Previous computational models of rapid external calcium changes used only rough
approximations of calcium channel dynamics to compute the expected
calcium decrements in the extracellular space. Using realistic calcium
channel models, experimentally measured back-propagating action
potentials, and a model of the extracellular space, we computed the
fluctuations in external calcium that accrue during neural activity. In
this realistic setting, we showed that rapid, significant changes in
local external calcium can occur when dendrites are invaded by
back-propagating spikes, even in the presence of an extracellular
calcium buffer. We further showed how different geometric arrangements
of calcium channels or dendrites prolong or amplify these fluctuations.
Finally, we computed the influence of experimentally measured synaptic
input on peridendritic calcium fluctuations. Remarkably, appropriately
timed synaptic input can amplify significantly the decrement in
external calcium. The model shows that the extracellular space and the
calcium channels that access it provide a medium that naturally
integrates coincident spike activity from different dendrites that
intersect the same tissue volume.
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