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. 2016 Nov 15;594(22):6767-6776.
doi: 10.1113/JP272599. Epub 2016 Aug 2.

Secondary hyperalgesia is mediated by heat-insensitive A-fibre nociceptors

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Secondary hyperalgesia is mediated by heat-insensitive A-fibre nociceptors

Emanuel N van den Broeke et al. J Physiol. .

Abstract

Key points: It is believed that secondary hyperalgesia (the increased sensitivity to mechanical nociceptive stimuli that develops after cutaneous tissue injury in the surrounding uninjured skin) is mediated by a subclass of nociceptors: the slowly adapting A-fibre mechano-heat nociceptors (AMH-type I). Here we tested this hypothesis. By using intense long-lasting heat stimuli, which are known to activate these slowly adapting AMH-type I nociceptors, we show that the perceived intensity elicited by these stimuli is not increased in the area of secondary hyperalgesia. Moreover, we show that during an A-fibre nerve conduction block the perception elicited by the long-lasting heat stimuli is significantly reduced in a time window that matches the response profile of the AMH-type I nociceptors. AMH-type I nociceptors contribute to the perception of sustained heat, but they do not mediate secondary hyperalgesia. Therefore, we propose that secondary hyperalgesia is mediated by high threshold mechanoreceptors.

Abstract: Secondary hyperalgesia refers to the increase in sensitivity to mechanical nociceptive stimuli delivered outside the area of tissue injury. Previous studies have suggested that secondary hyperalgesia is mediated by a specific class of myelinated nociceptors: slowly adapting A-fibre mechano- and heat-sensitive (AMH) type I nociceptors. Here, we tested this hypothesis by examining whether long-lasting heat stimuli, which are known to activate AMH-type I nociceptors, elicit enhanced responses when delivered to the area of secondary hyperalgesia induced by high frequency electrical stimulation of the skin (HFS). Before and 20 min after HFS, sustained 30 s radiant heat stimuli were delivered to the area of increased mechanical pinprick sensitivity while participants continuously rated intensity of perception using an online visual analog scale (0-100 mm). After HFS, no significant enhancement of heat perception was observed in the area of increased pinprick sensitivity. To establish that myelinated nociceptors actually contribute to the perception of sustained heat, we conducted a second experiment in which sustained heat stimuli were presented before and during an A-fibre nerve conduction block, achieved by applying a rubber band with weights which compresses the superficial radial nerve against the radius. During the block, heat perception was significantly reduced 17-33 s after the onset of the heat stimulus (before: mean = 53 mm, during: mean = 31 mm; P = 0.03), matching the response profile of AMH-type I nociceptors. These results support the notion that AMH-type I nociceptors contribute to the perception of sustained heat, but also show that these afferents do not mediate secondary hyperalgesia.

Keywords: AMH-type I; secondary hyperalgesia; sustained heat.

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Figures

Figure 1
Figure 1. Time‐line of the experiment
Before (T0) and after (T1) applying HFS on the left or right forearm, the sensitivity to mechanical pinprick stimuli and long‐lasting heat stimuli was assessed at both arms (control vs. HFS). The area of increased mechanical pinprick sensitivity was mapped immediately before T1.
Figure 2
Figure 2. Effect of HFS on mechanical pinprick sensitivity
A, individual (thin black lines) and group‐level average (thick black line) area of increased pinprick sensitivity at the forearm, estimated 20 min after applying HFS. B, group‐level mean (and SD) intensity of perception elicited by pinprick stimulation of the control arm (grey line) and the HFS arm (black line), before (T0) and 20 min after (T1) applying HFS. At the HFS arm, pinprick sensitivity was significantly increased at T1 vs. T0 (*** P < 0.001).
Figure 3
Figure 3. Effect of HFS on the perception of long‐lasting heat stimuli
A, example of the skin heating profiles generated by the temperature‐controlled laser stimulator and measured by the radiometer collinear with the laser beam. The horizontal dashed line indicates baseline skin temperature. The vertical dashed line indicates the end of the heat stimulation. B, group‐level mean rating waveforms obtained during the long‐duration heat stimulation for all conditions. The horizontal dashed line indicates the transition from non‐painful to painful domains of sensation. The vertical dashed line indicates the end of the heat stimulation. C, group‐level average difference rating waveforms (T1 minus T0) for both arms (control and HFS). The vertical lines represent error bars expressing standard deviation.
Figure 4
Figure 4. Effect of the A‐fibre nerve conduction block on the reaction times to short‐lasting heat stimuli, the reaction times to mechanical pinprick stimuli, and the detection of tactile and cold stimuli
A, stacked reaction time distribution for short‐lasting (100 ms) 55°C heat stimuli applied on the dorsum of the left hand before and during the A‐fibre nerve block. The vertical dashed line represents the cut‐off used to distinguish reaction times compatible with the conduction velocities of myelinated vs. unmyelinated fibres. B, stacked reaction time distribution for mechanical pinprick stimulation. Note that during the A‐fibre block the reaction times to both short‐lasting heat stimuli and mechanical pinprick stimuli are shifted towards the right. C, during the A‐fibre block, tactile and cold stimuli were, in almost all cases, not detected.
Figure 5
Figure 5. Effect of the A‐fibre nerve conduction block on the percept elicited by long duration heat stimuli
A, group‐level average rating waveforms obtained before and during the A‐fibre nerve conduction block. During the A‐fibre nerve conduction block heat perception was significantly decreased 17–33 s after the onset of the 30 s heat stimuli (grey area, P < 0.05). The horizontal dashed line indicates the transition from non‐painful to painful domains of sensation. The vertical dashed line indicates the end of stimulation. Inset: note that during the block the delay between the increase in skin temperature and the increase in rating was delayed by approximately 1 s, compatible with the blockade of myelinated afferents. B, individual ratings representing the mean calculated within the time window 17–33 s, before and during the A‐fibre block.

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