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Department of Physiology and Environmental Science, University of Nottingham School of Agriculture, Sutton Bonington, Loughborough, Leicestershire.

1. Recordings were made from gastrocnemius medialis (GM), semitendinosus (ST) and tibialis anterior/extensor digitorum longus (TA/EDL) motor nerves during mechanical and electrical stimulation of the skin of the foot in decerebrated and spinalized rabbits. 2. GM motoneurones were excited from the heel and not from the toes, whereas TA/EDL responded to stimulation at the toes but not at the heel. ST also responded to electrical and mechanical stimulation at the toes, but there was a disparity between the effects of the two types of stimuli when they were applied at the heel: ST motoneurones fired in response to electrical stimulation of the heel but showed only an 'off' response to mechanical stimulation at this site. 3. The opioid antagonist naloxone caused a dose-dependent increase in all reflexes evoked by electrical stimulation of the skin. The heel-GM, toes-ST and toes-TA/EDL reflexes all increased to more than 3 times control levels with naloxone, which also caused significant decreases in the latencies of these reflex responses. On the other hand, the heel-ST response increased to just 1.4 times control levels and showed no decrease in latency with the opioid antagonist. 4. These data suggest that segmental withdrawal reflex pathways in the rabbit are suppressed by endogenous opioid peptides. This opioid-mediated inhibition seems to operate non-selectively on reflex pathways between cutaneous afferents and motoneurones.

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				J. Harris, C. Joules, C. Stanley, P. Thomas, and R. W. Clarke Glutamate and tachykinin receptors in central sensitization of withdrawal reflexes in the decerebrated rabbit Exp Physiol, March 1, 2004; 89(2): 187 - 198. [Abstract] [Full Text] [PDF]