Nonsynaptic Modulation of Neuronal Activity in the Brain: Electric Currents
and Extracellular Ions.
Jefferys, J. G. R.
Neuronal Network Group, Dept. of Physiology and Biophysics, St. Mary's
Hospital Medical School, Imperial College of Science, Technology, and
Medicine, London, United.
APStracts 2:0009P, 1995.
ABSTRACT
Nonsynaptic interactions between neurons have been eclipsed by our
increasingly detailed understanding of chemical synapses, but they do play
significant roles in the nervous system. This review considers four classes of
nonsynaptic interaction, mainly in mammalian brain. [i]1[r]) Electrotonic (and
chemical) coupling through gap junctions has effects during development and
under some, often pathological, conditions in the mature brain. [i]2[r])
Ephaptic transmission is mediated by electrical coupling between specific
neuronal elements in the absence of specialized contacts, notably in the
cerebellum, and in axon tracts affected by demyelination. [i]3[r]) Field
effect interactions are mediated by large extracellular currents and potential
fields generated by the hippocampus and other cortical structures. Both
endogenous and applied electric fields alter neuronal excitability at field
strengths over a few millivolts per millimeter. Weaker fields have more subtle
effects, for instance, on axonal growth during development and repair and,
more controversially, in behavioral responses to environmental fields.
[i]4[r]) There are fluctuations in extracellular ions such as K[sup]+[r],
which are released during neuronal activity and which alter neuronal
excitability. Field effects and ion fluctuations probably have modest effects
during physiological activity but have a significant impact on epileptic
seizures, and can sustain them in the absence of synaptic transmission.
APS Manuscript Number P-0011-5.
Article publication scheduled October 1995 Physiological Reviews.
ISSN 1080-4757 Copyright 1995 The American Physiological Society.
Published in APStracts on 23 September 1995.