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Quantitative analysis of electrical properties of dendritic spines

Biological Cybernetics volume 50pages 447–454 (1984)Cite this article

Abstract

Several sugestions have been made with regard to the functional significance of dendritic spines in connection with synaptic plasticity. We have shown that for a constant synaptic current, when the synaptic resistance is large compared to the spine-stem resistance, a morphological change in the spine does not produce a marked change in the postsynaptic potential (PSP). When the synaptic resistance is comparable to the spine-stem impedance a morphological change in the spine can induce changes in the synaptic current and the PSP due to the so-called nonlinear effect to the synapse (Kawato and Tsukahara, 1983, 1984). Consequently, in a study of the electrical properties of dendritic spines the input impedance of the parent dendrite, the spinestalk conductance and the conductance change associated with synaptic activity must be considered. We quantitatively estimated all three factors. By comparing electrophysiological data with morphological data, we estimated the synaptic conductance which causes corticorubral EPSP. Its maximum amplitude was 43 nS with a time-to-peak value of 0.3 ms. With this value, the effects of the spine were examined using an improved algorithm based on that of Butz and Cowan (1974). It uses a three-dimensional morphology of the rubrospinal (RS) neurons, which was reconstructed from serial sections containing HRP-filled RS cells. As the spine shortens, the amplitude of the EPSP becomes considerably larger, but its time-to-peak value does not markedly change. Moreover, if unitary EPSP in the RS cell is produced by the activation of several synaptic terminals a morphological change of the spine has a smaller effect on the EPSPs.

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Affiliations

  1. Department of Biophysical Engineering, Faculty of Engineering Science, Osaka University, Toyonaka 560, Osaka, Japan

    Mitsuo Kawato, Takahiro Hamaguchi & Fujio Murakami

  2. National Institute for Physiological Sciences, Myodaiji, Okazaki 444, Aichi, Japan

    Nakaakira Tsukahara

Authors
  1. Mitsuo Kawato
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  2. Takahiro Hamaguchi
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  3. Fujio Murakami
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  4. Nakaakira Tsukahara
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Kawato, M., Hamaguchi, T., Murakami, F. et al. Quantitative analysis of electrical properties of dendritic spines. Biol. Cybern. 50, 447–454 (1984). https://doi.org/10.1007/BF00335202

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  • DOI: https://doi.org/10.1007/BF00335202

Keywords

  • Morphological Change
  • Electrical Property
  • Synaptic Plasticity
  • Serial Section
  • Maximum Amplitude