Brain Advance Access published online on February 25, 2004
Brain, doi:10.1093/brain/awh134
© 2004 by Guarantors of Brain
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Article
1 Klinik für Neurologie, Universitätsklinikum Schleswig-Holstein, Campus Kiel, Niemannsweg 147, D-24105 Kiel, Germany
* Corresponding author. E-mail: g.wasner{at}neurologie.uni-kiel.de.
Received 13 June 2003
; revised 1 December 2003
; accepted 8 January 2004
Although cold hyperalgesia is a frequent symptom in patients with neuropathic pain, it is poorly understood. We investigated the mechanisms of cold pain by studying the effect of menthol on pain, temperature perception, touch sensation and skin perfusion. In 10 subjects, 40% L-menthol, and ethanol, serving as control, were topically applied to the forearm in a double-blinded two-way crossover study. Menthol induced significant pain and cold sensations, punctate and cold hyperalgesia and an increase in cutaneous perfusion. Other mechano-sensory and thermal tests were unchanged (touch, cold and warm detection thresholds, heat pain threshold; no dynamic and static hyperalgesia, no wind-up). To investigate the underlying mechanisms, the effects of menthol versus ethanol on the dorsum of the hand were tested during A fibre conduction blockade of the superficial radial nerve in another 10 subjects. The block itself led to hypoaesthesia for mechanical stimuli and anaesthesia for cold perception, but induced an increase in cold-mediated pain. This was due to lack of inhibition of C nociceptors normally exerted by concomitant activation of A fibres. Under these conditions, menthol-induced cold sensation and punctate hyperalgesia were abolished. However, menthol induced spontaneous pain with a trend to higher values than without block. Furthermore, the hyperalgesia to cold stimuli, that was already present during A fibre block, was further increased significantly by menthol. We suggested that menthol acts to sensitize cold-sensitive peripheral vasoactive C nociceptors and activates cold-specific A delta fibres. Punctate hyperalgesia is due to central sensitization based on the ongoing activity in the sensitized cold-sensitive peripheral C nociceptors. In conclusion, topical menthol is a human model for cold pain by exposing for the first time the mechanism of sensitized peripheral cold C nociceptors that may also be involved in neuropathic pain.
Keywords: menthol; cold pain; nociceptor; sensitization; A fibre conduction blockade
Topical menthol--a human model for cold pain by activation and sensitization of C nociceptors
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