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J Neurophysiol (April 1, 2003). 10.1152/jn.00978.2002
Submitted on Submitted 29 October 2002; accepted in final form 10 December 2002
Neuroscience Program, Department of Biological Sciences, Ohio University, Athens, Ohio 45701
DiCaprio, Ralph A.
Nonspiking and Spiking Proprioceptors in the Crab: Nonlinear
Analysis of Nonspiking TCMRO Afferents. J. Neurophysiol. 89: 1826-1836, 2003. The proprioceptor that signals
the position and movement of the first joint of crustacean legs
provides an excellent system for investigating information processing
and transmission in neurons that function in a graded (nonspiking)
manner in the context of a simple motor system. The thoracic-coxal
muscle receptor organ (TCMRO) spans the thoracic-coxal joint and
transmits graded signals to the CNS via two large nonspiking axons. The
response characteristics and nonlinear models of the input-output
relationship for the two nonspiking TCMRO afferents (S and T fibers)
were determined using white noise analysis (Wiener kernel) methods. The
best-fitting linear responses of these neurons was similar, as were
their second-order kernels. The gains of the afferents slowly increased
with increasing frequency and reached a maximum at approximately 40-60
Hz for the S fiber and 60-80 Hz for the T fiber. Above this corner
frequency, the gains of both afferents decreased at approximately 20 dB/decade for the remainder of the 220-Hz stimulus bandwidth. The shape of the first-order kernels, and hence the corresponding (linear) gain
functions, of both afferents were similar when driven with different
amplitudes of noise, covering a 40-fold amplitude range. Predictions of
the S fiber response based on the first two Wiener kernels were
accurate, with the second-order model producing a mean square error of
6-8%. Second-order Wiener models for the T fiber were less accurate
with a mean square error of approximately 22-26%, but this accuracy
improved to 10-16% with the incorporation of the third-order term in
the Wiener expansion. The effect of cable properties on the
transmission of the sensory potentials to the CNS was evaluated by
determining the system characteristics using membrane potentials 5-7
mm distal to the transduction site. The major change after transmission
along the axon was a low-pass filtering of the sensory signals and
consequent reduction in signal bandwidth.
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