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Vol. 297, Issue 1, 352-356, April 2001
Neuroscience Research, Pharmacology Laboratories, Institute for
Drug Discovery Research, Yamanouchi Pharmaceutical Co., Ltd., Tsukuba,
Ibaraki, Japan
We examined the current stimulus threshold in rats with the Neurometer,
a device used clinically for measuring perception and pain thresholds.
Although many studies have indicated the usefulness of this device in
the quantification of nerve dysfunction in patients, we have found no
published reports on the use of the Neurometer in animals.
Transcutaneous nerve stimuli of the three sine-wave pulses produced by
the Neurometer (at 2000, 250, and 5 Hz) were applied to plantar surface
of rats. The intensity of each stimulation at which rats vocalized or
were hardly startled was defined as the current stimulus threshold.
With repeated stimulation, the thresholds were almost constant.
Repeated topical application to the area around the stimulating
electrode of a high concentration of capsaicin, which acts on
small-diameter fibers, increased the thresholds at 250 and 5 Hz, but
did not affect the 2000-Hz threshold. Intravenous morphine (2-5 mg/kg)
increased all three thresholds, whereas intrathecal morphine (20 or 80 µg) increased only the 5-Hz threshold. Intravenous injection of
a minor tranquilizer, diazepam, at 1 mg/kg raised the thresholds at
2000 and 250 Hz, but did not affect the 5-Hz threshold. Higher dose of
diazepam increased all three thresholds. These results suggest that the Neurometer makes possible selective examination of subsets of nerve
fibers that differ in diameter not only in humans but also in animals.
The present study in rats, in which we established a method of
measurement, may provide helpful suggestions for the interpretation of
data in humans.
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