Psychophysical measurements of pain and mechanical hyperalgesia were obtained following different doses of capsaicin injected intradermally into the forearms of human subjects. Each subject received a 10 microliter injection of the vehicle and capsaicin doses of 0.01, 0.1, 1, 10 and 100 micrograms. The relationship between capsaicin dose and the magnitude and duration of pain was determined using the method of magnitude estimation. In addition to pain, capsaicin produced a flare and mechanical hyperalgesia. The area of flare and the area and time course of mechanical hyperalgesia were measured as a function of the dose of capsaicin. The magnitude and duration of pain, based on averaged responses of all subjects, increased as a negatively accelerating function of dose. The lowest dose of capsaicin to produce more pain than the vehicle was 0.1 micrograms. The area and duration of mechanical hyperalgesia also increased as a negatively accelerating function of dose. The lowest dose of capsaicin to produce an area of mechanical hyperalgesia was 0.1 micrograms. An area of hyperalgesia was present within seconds following injection. For doses of 10 and 100 micrograms, the area of hyperalgesia grew to reach a maximum within 5 and 7 min following the injection and gradually decreased, disappearing within 15 and 137 min, respectively. Capsaicin doses of 1, 10 and 100 micrograms produced successively greater areas of flare. The results demonstrate that humans can scale the magnitude of pain produced by capsaicin in a dose-dependent fashion. Further, the duration of pain, the area and duration of mechanical hyperalgesia, and the area of flare are dose-dependent.(ABSTRACT TRUNCATED AT 250 WORDS)
1. A local cutaneous injury can produce primary hyperalgesia within the injured area and secondary hyperalgesia in the normal surrounding skin. An intradermal injection of capsaicin in humans causes intense pain and hyperalgesia to heat and to mechanical stimuli in the surrounding skin. Psychophysical studies in humans supported the conclusions that the hyperalgesia was predominantly the secondary type and depended on one set of neurons sensitizing another ("neurogenic hyperalgesia") and that the latter set of neurons is located in the central and not the peripheral nervous system. To further test this hypothesis and to search for peripheral neural mechanisms contributing to the pain and neurogenic hyperalgesia from a local injury, we performed neurophysiological experiments in the monkey (Macaca fascicularis) and recorded the responses of cutaneous primary afferent fibers to an intradermal injection of capsaicin and to mechanical and heat stimuli delivered before and after the injection. 2. Most C- and A-fiber mechanoheat-sensitive nociceptive afferent fibers (CMHs and AMHs, respectively) responded too weakly or transiently to capsaicin to account quantitatively for the magnitude of capsaicin pain. Of the known primary afferents tested with capsaicin injections, only the responses of heat-selective nociceptors could potentially account for the pain measured psychophysically in the human. In addition, a novel type of primary afferent--tentatively termed "chemonociceptive"--may have contributed as well. 3. Nociceptive fibers did not become sensitized to either mechanical or heat stimulation after an injection of capsaicin either outside, adjacent to, or inside the receptive field (RF); any changes that occurred could not explain the hyperalgesia to mechanical or heat stimuli observed in humans. 4. The depressed responsiveness ("desensitization") of both myelinated and unmyelinated nociceptive fibers in the monkey to heat and/or mechanical stimulation of the injection site after capsaicin was injected inside their RFs correlated with the analgesia observed at the capsaicin injection site in the human. 5. Capsaicin, topically applied to the RF in a vehicle of dimethyl sulfoxide or alcohol, excited CMHs and AMHs and enhanced the responses of some of these fibers to heat and/or to stroking the skin. In some cases, similar results were produced by the vehicle alone. However, capsaicin and not the vehicle lowered the thresholds of some CMHs to heat. Thus the sensitization of CMHs contributes to the primary hyperalgesia known to occur within the area of skin directly exposed to topically applied capsaicin.(ABSTRACT TRUNCATED AT 400 WORDS)
Differential A-fibre block of human peripheral nerves changes the sensation evoked by innocuous cooling (∼24• C) of the skin from 'cold' to 'hot' or 'burning', and this has been attributed to activity in unidentified unmyelinated fibres that is normally masked or inhibited by activity in Aδ cold fibres. Application of the TRPM8 agonist menthol to the skin evokes 'burning/stinging' as well as 'cold', and the unpleasant sensations are also enhanced by A-fibre block. In this study we used microneurography to search for C fibres in human skin activated by cooling and menthol, which could be responsible for these phenomena. Afferent C fibres were classified by activity-dependent slowing as Type 1A (polymodal nociceptor), Type 1B (mechanically insensitive nociceptor) or Type 2 (cold sensitive), and their responses to heating and cooling ramps were measured before and after topical application of menthol preparations (2-50%). The only C fibres activated by menthol were the Type 2 fibres, which discharged vigorously with innocuous cooling and were strongly activated and sensitized to cooling by menthol. Unlike an Aδ cold fibre, they continued to discharge at skin temperatures down to 0• C, and most (13/15) were also activated by heating. We propose that the Type 2 C fibres, although resembling Aδ cold fibres in their responses to innocuous cooling and menthol, have a more complex sensory function, colouring with a 'hot-burning' quality the perceptions of low and high temperatures. Their bimodal thermoreceptive properties may help account for several puzzling psychophysical phenomena, such as 'innocuous cold nociception', 'paradoxical heat' and the thermal grill illusion, and also for some neuropathic pains.
This study examined the responses of cultured adult human dorsal root ganglion (hDRG) neurons to protons and capsaicin, two substances known to produce pain and hyperalgesia in humans. Both substances were applied to each neuron and responses were examined under both voltage- and current-clamp recording conditions. Sensitivity to protons was tested with rapid acidification of the extracellular fluid from pH 7.35 to 6.0. In neurons nominally clamped near -60 mV, low pH evoked a transient inward current which, in all 40 hDRG neurons tested, was followed by a more sustained inward current. The sustained current was associated with an increase in membrane conductance in 10 neurons, a decrease in 27 neurons, and no overt change in conductance (< 10%) in 3 neurons. Current-clamp recordings in the same neurons showed that the proton-induced sustained net inward current caused a prolonged depolarization of the membrane potential in all 40 hDRG neurons. The prolonged depolarization was associated with action potential discharge in 5 neurons. Unlike low pH, capsaicin evoked a sustained net inward current in only a subset of neurons tested (10 nM: 1/4, 30 nM: 4/8, 100 nM: 11/18, and 10 microM: 10/10 neurons tested). The capsaicin-evoked currents were accompanied by an increase in membrane conductance in 15 neurons, a decrease in 2, and no overt change in conductance in 9 neurons. Capsaicin currents, like proton-induced currents, resulted in prolonged depolarizations (10 nM: 0/4, 30 nM: 5/8, 100 nM: 8/18, and 10 microM: 10/10 neurons tested). The depolarization resulted in the discharge of action potentials in 14 neurons. It is concluded that, while both protons and capsaicin exert excitatory effects on human sensory neurons, multiple membrane mechanisms lead to the depolarization of cultured hDRG neurons by low pH. Inhibition of resting membrane conductances contributes to the responses to low pH in some hDRG neurons.
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