Mechanical sensitization, increased axonal excitability, and spontaneous activity in C-nociceptors after ultraviolet B irradiation in pig skin.

ABSTRACT: Ultraviolet B (UVB) irradiation induces hyperalgesia in human and animal pain models. We investigated mechanical sensitization, increase in axonal excitability, and spontaneous activity in different C-nociceptor classes after UVB in pig skin. We focused on units with receptive fields covering both irradiated and nonirradiated skin allowing intraindividual comparisons. Thirty-five pigs were irradiated in a chessboard pattern, and extracellular single-fibre recordings were obtained 10 to 28 hours later (152 fibers). Units from the contralateral hind limb served as a control (n = 112). Irradiated and nonirradiated parts of the same innervation territory were compared in 36 neurons; low threshold C-touch fibers (n = 10) and sympathetic efferents (n = 2) were unchanged, but lower mechanical thresholds and higher discharge frequency at threshold were found in mechanosensitive nociceptors (n = 12). Half of them could be activated with nonnoxious brush stimuli in the sunburn. Four of 12 mechanoinsensitive nociceptors were found sensitized to mechanical stimulation in the irradiated part of the receptive field. Activity-dependent slowing of conduction was reduced in the irradiated and in the nonirradiated skin as compared with the control leg, whereas increased ability to follow high stimulation frequencies was restricted to the sunburn (108.5 ± 37 Hz UVB vs 6.3 ± 1 Hz control). Spontaneous activity was more frequent in the sunburn (72/152 vs 31/112). Mechanical sensitization of primary nociceptors and higher maximum after frequency are suggested to contribute to primary hyperalgesia, whereas the spontaneous activity of silent nociceptors might offer a mechanistic link contributing to ongoing pain and facilitated induction of spinal sensitization.

Maximum axonal following frequency separates classes of cutaneous unmyelinated nociceptors in the pig.

KEY POINTS: C-nociceptors are generally assumed to have a low maximum discharge frequency of 10-30 Hz. However, only mechano-insensitive 'silent' C-nociceptors cannot follow electrical stimulation at 5 Hz (75 pulses) whereas polymodal C-nociceptors in the pig follow stimulation at up to 100 Hz without conduction failure. Sensitization by nerve growth factor increases the maximum following frequency of 'silent' nociceptors in pig skin and might thereby contribute in particular to intense pain sensations in chronic inflammation. A distinct class of C-nociceptors with mechanical thresholds >150 mN resembles 'silent' nociceptors at low stimulation frequencies in pigs and humans, but is capable of 100 Hz discharge and thus is suited to encode painfulness of noxious mechanical stimuli. ABSTRACT: Using extracellular single-fibre recordings from the saphenous nerve in pig in vivo, we investigated peak following frequencies (5-100 Hz) in different classes of C-nociceptors and their modulation by nerve growth factor. Classes were defined by sensory (mechano-sensitivity) and axonal characteristics (activity dependent slowing of conduction, ADS). Mechano-insensitive C-nociceptors (CMi) showed the highest ADS (34% ± 8%), followed only 66% ± 27% of 75 pulses at 5 Hz and increasingly blocked conduction at higher frequencies. Three weeks following intradermal injections of nerve growth factor, peak following frequency increased specifically in the sensitized mechano-insensitive nociceptors (20% ± 16% to 38% ± 23% response rate after 72 pulses at 100 Hz). In contrast, untreated polymodal nociceptors with moderate ADS (15.2% ± 10.2%) followed stimulation frequencies of 100 Hz without conduction failure (98.5% ± 6%). A distinct class of C-nociceptors was exclusively sensitive to strong forces above 150 mN. This class had a high ADS (27.2% ± 7.6%), but displayed almost no propagation failure even at 100 Hz stimulation (84.7% ± 17%). Also, among human mechanosensitive nociceptors (n = 153) those with thresholds above 150 mN (n = 5) showed ADS typical of silent nociceptors. C-fibres with particularly high mechanical thresholds and high following frequency form a distinct nociceptor class ideally suited to encode noxious mechanical stimulation under normal conditions when regular silent nociceptors are inactive. Sensitization by nerve growth factor increases maximum discharge frequency of silent nociceptors, thereby increasing the frequency range beyond their physiological limit, which possibly contributes to excruciating pain under inflammatory conditions.

Slow depolarizing stimuli differentially activate mechanosensitive and silent C nociceptors in human and pig skin.

ABSTRACT: High-threshold mechanosensitive and mechanoinsensitive ("silent") nociceptors have similar electrical thresholds for transcutaneous sine wave stimulation at 4 Hz that selectively activates cutaneous C nociceptors in human skin. Their fundamentally different functions particularly in chronic pain warrant differential stimulation protocols. We used transcutaneously delivered slow depolarizing stimuli (half-sine, 500 ms duration, 0.01-1 mA) in humans to assess intensity-response relations for the induction of pain psychophysically and recorded activation of mechanosensitive and silent nociceptors in healthy volunteers by microneurography. Differential C-fiber activation was confirmed in single-fiber recordings in pig allowing for stimulation amplitudes up to 10 mA. Perception and pain thresholds to half-sine wave pulses were 0.06 ± 0.03 mA and 0.18 ± 0.1 mA, respectively, and caused pain in an amplitude-dependent manner (n = 24). When matched for pain intensity, only sine wave stimulation induced an instant widespread axon reflex erythema (n = 10). In human microneurography, half-sine stimulation activated mechanosensitive nociceptors (n = 13), but only one of 11 silent nociceptors. In pig skin, the amplitude-dependent activation of mechanosensitive nociceptors was confirmed (0.2-1 mA, n = 28), and activation thresholds for most silent nociceptors (n = 13) were found above 10 mA. Non-nociceptive low-threshold mechanosensitive C fibers (n = 14) displayed lower activation thresholds for half-sine wave stimuli with an amplitude-dependent discharge increase between 0.01 and 0.1 mA. We conclude that transcutaneous electrical stimulation with 500-ms half-sine wave pulses between 0.2 and 1 mA causes amplitude-dependent pain by preferential activation of mechanosensitive C nociceptors.

TTX-Resistant Sodium Channels Functionally Separate Silent From Polymodal C-nociceptors.

Pronounced activity-dependent slowing of conduction has been used to characterize mechano-insensitive, "silent" nociceptors and might be due to high expression of NaV1.8 and could, therefore, be characterized by their tetrodotoxin-resistance (TTX-r). Nociceptor-class specific differences in action potential characteristics were studied by: (i) in vitro calcium imaging in single porcine nerve growth factor (NGF)-responsive neurites; (ii) in vivo extracellular recordings in functionally identified porcine silent nociceptors; and (iii) in vitro patch-clamp recordings from murine silent nociceptors, genetically defined by nicotinic acetylcholine receptor subunit alpha-3 (CHRNA3) expression. Porcine TTX-r neurites (n = 26) in vitro had more than twice as high calcium transients per action potential as compared to TTX-s neurites (n = 18). In pig skin, silent nociceptors (n = 14) characterized by pronounced activity-dependent slowing of conduction were found to be TTX-r, whereas polymodal nociceptors were TTX-s (n = 12) and had only moderate slowing. Mechano-insensitive cold nociceptors were also TTX-r but showed less activity-dependent slowing than polymodal nociceptors. Action potentials in murine silent nociceptors differed from putative polymodal nociceptors by longer duration and higher peak amplitudes. Longer duration AP in silent murine nociceptors linked to increased sodium load would be compatible with a pronounced activity-dependent slowing in pig silent nociceptors and longer AP durations could be in line with increased calcium transients per action potential observed in vitro in TTX-resistant NGF responsive porcine neurites. Even though there is no direct link between slowing and TTX-resistant channels, the results indicate that axons of silent nociceptors not only differ in their receptive but also in their axonal properties.

Nerve growth factor locally sensitizes nociceptors in human skin.

Nerve growth factor (NGF) injected into the human skin causes local hyperalgesia to mechanical and electrical stimuli lasting for weeks. Pig data suggested axonal sensitization of C-nociceptors as a contributing mechanism. Here, we recorded single C-nociceptors in 11 human subjects 3 weeks after intracutaneous injection of 1 µg NGF into the foot dorsum. For each identified unit, the receptive field was mapped and, whenever possible, we recorded 2 terminal branches of the same unit, 1 from the hyperalgesic NGF-site ("inside") and the other from the nonsensitized skin ("outside"). In the saline-treated control feet, mechano-insensitive nociceptors (CMi) were more abundant than at the NGF sites (36% vs 19%). Units with axonal properties of CMi fibres but displaying positive mechanical responses ("CMi-like") dominated at the NGF site (27% vs 6%). Moreover, axonal branches innervating the hyperalgesic skin displayed significantly lower electrical thresholds and less activity-dependent conduction velocity slowing when compared with "outside" or control skin. The "inside" branches also showed long-lasting after-discharges and less adaptation to repeated mechanical stimuli. NGF-induced long-term nociceptor hyperexcitability was maximum at the terminal branches directly treated with NGF. The sensitization included sensory and axonal components affecting both activation thresholds and supra-threshold responses. Our data suggest that a combination of sensory sensitization and axonal hyperexcitability is underlying the localized hyperalgesia by facilitating action potential generation and conduction. Axonal changes were also found in the asymptomatic skin surrounding the NGF-treatment sites, thereby possibly reflecting "nociceptive priming."

C-fiber recovery cycle supernormality depends on ion concentration and ion channel permeability.

Following each action potential, C-fiber nociceptors undergo cyclical changes in excitability, including a period of superexcitability, before recovering their basal excitability state. The increase in superexcitability during this recovery cycle depends upon their immediate firing history of the axon, but also determines the instantaneous firing frequency that encodes pain intensity. To explore the mechanistic underpinnings of the recovery cycle phenomenon a biophysical model of a C-fiber has been developed. The model represents the spatial extent of the axon including its passive properties as well as ion channels and the Na/K-ATPase ion pump. Ionic concentrations were represented inside and outside the membrane. The model was able to replicate the typical transitions in excitability from subnormal to supernormal observed empirically following a conducted action potential. In the model, supernormality depended on the degree of conduction slowing which in turn depends upon the frequency of stimulation, in accordance with experimental findings. In particular, we show that activity-dependent conduction slowing is produced by the accumulation of intraaxonal sodium. We further show that the supernormal phase results from a reduced potassium current Kdr as a result of accumulation of periaxonal potassium in concert with a reduced influx of sodium through Nav1.7 relative to Nav1.8 current. This theoretical prediction was supported by data from an in vitro preparation of small rat dorsal root ganglion somata showing a reduction in the magnitude of tetrodotoxin-sensitive relative to tetrodotoxin -resistant whole cell current. Furthermore, our studies provide support for the role of depolarization in supernormality, as previously suggested, but we suggest that the basic mechanism depends on changes in ionic concentrations inside and outside the axon. The understanding of the mechanisms underlying repetitive discharges in recovery cycles may provide insight into mechanisms of spontaneous activity, which recently has been shown to correlate to a perceived level of pain.

Comparison of nerve growth factor-induced sensitization pattern in lumbar and tibial muscle and fascia.

INTRODUCTION: Nerve growth factor (NGF) induces profound hyperalgesia. In this study we explored patterns of NGF sensitization in muscle and fascia of distal and paraspinal sites. METHODS: We injected 1 µg of NGF into human (n = 8) tibialis anterior and erector spinae muscles and their fasciae. The spatial extent of pressure sensitization, pressure pain threshold, and mechanical hyperalgesia (150 kPa, 10 s) was assessed at days 0.25, 1, 3, 7, 14, and 21. Chemical sensitization was explored by acidic buffer injections (pH 4, 100 µl) at days 7 and 14. RESULTS: The mechanical hyperalgesia area was larger in tibial fascia than in muscle. Pressure pain thresholds were lower, tonic pressure pain ratings, and citrate buffer evoked pain higher in fascia than in muscle. CONCLUSIONS: Spatial mechanical sensitization differs between muscle and fascia. Thoracolumbar fasciae appear more sensitive than tibial fasciae and may be major contributors to low back pain, but the temporal sensitization profile is similar between paraspinal and distal sites. Muscle Nerve 52: 265-272, 2015.

Differential axonal conduction patterns of mechano-sensitive and mechano-insensitive nociceptors--a combined experimental and modelling study.

Cutaneous pain sensations are mediated largely by C-nociceptors consisting of both mechano-sensitive (CM) and mechano-insensitive (CMi) fibres that can be distinguished from one another according to their characteristic axonal properties. In healthy skin and relative to CMi fibres, CM fibres show a higher initial conduction velocity, less activity-dependent conduction velocity slowing, and less prominent post-spike supernormality. However, after sensitization with nerve growth factor, the electrical signature of CMi fibres changes towards a profile similar to that of CM fibres. Here we take a combined experimental and modelling approach to examine the molecular basis of such alterations to the excitation thresholds. Changes in electrical activation thresholds and activity-dependent slowing were examined in vivo using single-fibre recordings of CM and CMi fibres in domestic pigs following NGF application. Using computational modelling, we investigated which axonal mechanisms contribute most to the electrophysiological differences between the fibre classes. Simulations of axonal conduction suggest that the differences between CMi and CM fibres are strongly influenced by the densities of the delayed rectifier potassium channel (Kdr), the voltage-gated sodium channels NaV1.7 and NaV1.8, and the Na+/K+-ATPase. Specifically, the CM fibre profile required less Kdr and NaV1.8 in combination with more NaV1.7 and Na+/K+-ATPase. The difference between CM and CMi fibres is thus likely to reflect a relative rather than an absolute difference in protein expression. In support of this, it was possible to replicate the experimental reduction of the ADS pattern of CMi nociceptors towards a CM-like pattern following intradermal injection of nerve growth factor by decreasing the contribution of Kdr (by 50%), increasing the Na+/K+-ATPase (by 10%), and reducing the branch length from 2 cm to 1 cm. The findings highlight key molecules that potentially contribute to the NGF-induced switch in nociceptors phenotype, in particular NaV1.7 which has already been identified clinically as a principal contributor to chronic pain states such as inherited erythromelalgia.

Modeling activity-dependent changes of axonal spike conduction in primary afferent C-nociceptors.

Action potential initiation and conduction along peripheral axons is a dynamic process that displays pronounced activity dependence. In patients with neuropathic pain, differences in the modulation of axonal conduction velocity by activity suggest that this property may provide insight into some of the pathomechanisms. To date, direct recordings of axonal membrane potential have been hampered by the small diameter of the fibers. We have therefore adopted an alternative approach to examine the basis of activity-dependent changes in axonal conduction by constructing a comprehensive mathematical model of human cutaneous C-fibers. Our model reproduced axonal spike propagation at a velocity of 0.69 m/s commensurate with recordings from human C-nociceptors. Activity-dependent slowing (ADS) of axonal propagation velocity was adequately simulated by the model. Interestingly, the property most readily associated with ADS was an increase in the concentration of intra-axonal sodium. This affected the driving potential of sodium currents, thereby producing latency changes comparable to those observed for experimental ADS. The model also adequately reproduced post-action potential excitability changes (i.e., recovery cycles) observed in vivo. We performed a series of control experiments replicating blockade of particular ion channels as well as changing temperature and extracellular ion concentrations. In the absence of direct experimental approaches, the model allows specific hypotheses to be formulated regarding the mechanisms underlying activity-dependent changes in C-fiber conduction. Because ADS might functionally act as a negative feedback to limit trains of nociceptor activity, we envisage that identifying its mechanisms may also direct efforts aimed at alleviating neuronal hyperexcitability in pain patients.

Inflammation meets sensitization--an explanation for spontaneous nociceptor activity?

Anti-nerve growth factor (anti-NGF) treatment is analgesic in chronic inflammatory pain conditions without reducing inflammation. Hypothesizing that ongoing pain induced by inflammatory mediators is increased by long term sensitization of nociceptors, we combined the non-inflammatory NGF-sensitization model with an inflammatory ultraviolet-B (UV-B) model in human volunteers. UV-B irradiation of the skin presensitized with NGF 3 weeks before intensified the pre-existing NGF hyperalgesia during the inflammatory phase of UV-B and caused spontaneous pain in about 70% of the subjects. Pain levels paralleled the intensity of UVB inflammation. Hyperalgesia recorded on a VAS (0-100) was additive after combined NGF/UV-B treatment versus single NGF or UV-B treatment for mechanical impact and tonic heat stimuli, again paralleling the intensity of the UV-B inflammation. In contrast, ratings to tonic mechanical pressure (100 kPa for 10 seconds, peak VAS 58 ± 7 vs VAS 21 ± 5 [NGF] and VAS 12 ± 3 [UV-B]) and pinprick (150 mN for 5 seconds, peak VAS 33 ± 7 vs VAS 10 ± 2 [NGF] and VAS 8 ± 3 [UV-B]) increased in a supra-additive manner. This supra-additive effect faded 24 hours after irradiation, although heat sensitization remained increased. Hyperalgesia and spontaneous pain coexisted in NGF/UV-B treated skin but did not significantly correlate (r < -0.1 at day 1 and r < 0.2 at day 3). We conclude that NGF can sensitize nociceptive endings such that inflammatory mediators may cause sufficient excitation to provoke spontaneous pain. Our results suggest that neuronal sensitization and level of inflammation represent independent therapeutic targets in chronic inflammatory pain conditions.

Nerve growth factor induces sensitization of nociceptors without evidence for increased intraepidermal nerve fiber density.

Nerve growth factor (NGF) is involved in the long-term sensitization of nociceptive processing linked to chronic pain. Functional and structural ("sprouting") changes can contribute. Thus, humans report long-lasting hyperalgesia to mechanical and electrical stimulation after intradermal NGF injection and NGF-induced sprouting has been reported to underlie cancer bone pain and visceral pain. Using a human-like animal model we investigated the relationship between the structure and function of unmyelinated porcine nociceptors 3 weeks after intradermal NGF treatment. Axonal and sensory characteristics were studied by in vivo single-fiber electrophysiology and immunohistochemistry. C fibers recorded extracellularly were classified based on mechanical response and activity-dependent slowing (ADS) of conduction velocity. Intraepidermal nerve fiber (IENF) densities were assessed by immunohistochemistry in pigs and in human volunteers using the same NGF model. NGF increased conduction velocity and reduced ADS and propagation failure in mechano-insensitive nociceptors. The proportion of mechano-sensitive C nociceptors within NGF-treated skin areas increased from 45.1% (control) to 71% and their median mechanical thresholds decreased from 40 to 20 mN. After NGF application, the mechanical receptive fields of nociceptors increased from 25 to 43 mm(2). At the structural level, however, IENF density was not increased by NGF. In conclusion, intradermal NGF induces long-lasting axonal and mechanical sensitization in porcine C nociceptors that corresponds to hyperalgesia observed in humans. Sensitization is not accompanied by increased IENF density, suggesting that NGF-induced hyperalgesia might not depend on changes in nerve fiber density but could be linked to the recruitment of previously silent nociceptors.

Differential effects of low dose lidocaine on C-fiber classes in humans.

UNLABELLED: The nonselective sodium channel blocker lidocaine is widely used as a local anesthetic but also systemically for treatment of postoperative and neuropathic pain. Voltage-gated sodium channels are crucial for action potential generation and conduction, and their availability controls the amount of activity-dependent conduction velocity slowing. This important axonal property, as assessed by microneurography, is used to differentiate human mechanoinsensitive (silent) nociceptors from the classical polymodal nociceptors. In the current study, microneurography was used to assess axonal properties of the 2 main nociceptor classes in humans, before and after intradermal injection of lidocaine .1% or control saline solution in the receptive field. In mechanosensitive nociceptors, lidocaine reduced baseline conduction velocity and turned activity-dependent slowing into speeding of conduction. In contrast, mechanoinsensitive fibers were not affected in their baseline conduction velocity or their activity-dependent slowing, but probability of conduction block with repetitive stimulation increased. Recovery cycles showed reduced hyperpolarization in all C-fiber classes after lidocaine injections. These results support our hypothesis that sodium channel subtypes are differentially expressed in the 2 nociceptor classes of mechanosensitive C-fibers (CMs) and mechanoinsensitive C-fibers (CMis). PERSPECTIVE: This study reveals that microneurography can be used to assess pharmacological effects on single C-fibers directly in humans.

NGF-evoked sensitization of muscle fascia nociceptors in humans.

Nerve growth factor (NGF) induces local hyperalgesia for a few days after intramuscular injection, but longer-lasting muscle pain upon systemic administration. As the muscle fascia is densely innervated by free nerve endings, we hypothesized a lasting sensitization of fascia nociceptors by NGF. We administered 1 µg NGF (dissolved in 100 µL saline) ultrasound-guided to the fascia of the Musculus erector spinae muscle at the lumbar level of 14 male volunteers and assessed hypersensitivity after 6 hours, and 1, 3, 7, 14, and 21 days. Pain upon mechanical stimuli (constant pressure and dynamic impact), upon exercise and electrically induced M. erector spinae contraction, and upon injection of 100 µL phosphate buffer pH4 (at day 7 and 14 only) to the fascia of both NGF- and saline-treated muscles, was investigated. Injections into the muscle fascia did not cause acute pain. Local heat pain thresholds were unchanged following NGF and saline (control) administration. NGF evoked a lasting (days 1-7) and significant reduction of pressure pain, pressure thresholds, exercise-evoked muscle pain, and hyperalgesia to impact stimuli (12 m/s). Pain upon injected protons was significantly elevated (P<0.04) for 2 weeks. NGF induced a sensitization of the muscle fascia to mechanical and chemical stimuli lasting for up to 2 weeks. As nociceptors in the fascia appear to be particularly prone to sensitization, they may contribute to acute or chronic muscle pain.

The differential effects of two sodium channel modulators on the conductive properties of C-fibers in pig skin in vivo.

BACKGROUND: Axonal sodium channels are attractive targets for chronic pain treatment, and recent evidence suggests that specific targeting of the slow inactivation of sodium channels (NaV) might exert analgesic effects. Using a human-like animal model, the pig, we compared changes in the conductive properties of different C-fiber classes on acute administration of lidocaine (nonselective NaV blocker) and lacosamide (selective enhancer of NaV slow inactivation). METHODS: Single-fiber extracellular recordings from saphenous nerves were performed. We classified C-fibers according to mechanical responsiveness and amount of activity-dependent slowing (ADS) of conduction velocity. Lidocaine (4 mM; 100 µL), lacosamide (4 mM; 100 µL), or saline was injected intradermally at the stimulation site, and changes of fibers' conductive properties were assessed. RESULTS: Conduction latencies evoked by lidocaine were more prominent in mechanosensitive (5.5%± 2.1%) than in mechano-insensitive nociceptors (2.5% ± 1%), whereas lacosamide increased conduction latencies to a greater extent in the mechano-insensitive (3% ± 1%) than in mechanosensitive C-nociceptors (2% ± 0.9%). Lidocaine, but not lacosamide, increased electrical thresholds in all mechanosensitive, but not in the mechano-insensitive, C-fibers. Lacosamide blocked conduction and, in addition, reduced ADS in mechano-insensitive nociceptors significantly more than in mechanosensitive nociceptors (ΔADS: 2.4% ± 0.5% vs 1.6% ± 0.5%), whereas lidocaine had opposite effects. Saline had no significant effect on the conductive properties of C-fibers. CONCLUSION: Local application of test compounds in pig skin allows for functional assessment of steady-state and use-dependent modulation of sodium channels in nociceptive and nonnociceptive C-fibers. Increased analgesic specificity might derive from selective enhancement of slow inactivation of sodium channels.

Double spikes to single electrical stimulation correlates to spontaneous activity of nociceptors in painful neuropathy patients.

Multiple firing of C nociceptors upon a single electrical stimulus has been suggested to be a possible mechanism contributing to neuropathic pain. Because this phenomenon maybe based on a unidirectional conduction block, it might also be related to neuropathic changes without a direct link to pain. We investigated painful neuropathy patients using microneurography and analysed nociceptors for the occurrence of multiple spiking and spontaneous activity. In 11 of 105 nociceptors, double spiking was found, with 1 fibre even showing triple spikes on electrical stimulation. The interval between the main action potential and the multiple spikes ranged from 13 to 100 ms. There was a significant association between spontaneous activity and multiple spiking in C nociceptors, with spontaneous activity being present in 9 of 11 fibres with multiple spiking, but only in 21 of 94 nociceptors without multiple spiking (P<.005, Fisher exact test). Among the 75 C nociceptors without spontaneous activity, only 2 nociceptors showed multiple spiking. In 8 neuropathy patients without pain, double spiking was found only in 4 of 90 nociceptors. Multiple spiking of nociceptors coincides with spontaneous activity in nociceptors of painful neuropathy patients. We therefore conclude that rather than being a generic sign of neuropathy, multiple spiking is linked to axonal hyperexcitability and spontaneous activity of nociceptors. It is still unclear whether it also is mechanistically related to the clinical pain level.

Nerve growth factor selectively decreases activity-dependent conduction slowing in mechano-insensitive C-nociceptors.

Nerve growth factor (NGF) induces acute sensitization of nociceptive sensory endings and long-lasting hyperalgesia. NGF modulation of sodium channel expression might contribute to neurotrophin-induced hyperalgesia. Here, we investigated NGF-evoked changes of the activity-dependent slowing of conduction in porcine C-fibers. Animals received intradermal injections of NGF (2 µg or 8 µg) or saline in both hind limbs. Extracellular recordings from the saphenous nerves were performed 1 week later. Based on sensory thresholds and electrically induced activity-dependent slowing (ADS) of axonal conduction, C-fibers were classified as mechano-sensitive afferents, mechano-insensitive afferents, cold nociceptors, and sympathetic efferents. NGF (2 µg) increased conduction velocity in C-fibers from 1.0±0.05 m/s to 1.2±0.07 m/s. In mechano-insensitive afferents, NGF (8 µg) reduced activity-dependent slowing of conduction, from 5.3±0.2% to 3.2±0.5% (0.125-0.5 Hz stimulation) and from 28.5±1.3% to 20.9±1.9% (2 Hz stimulation), such that ADS no longer differentiated between mechano-sensitive and mechano-insensitive fibers. Accordingly, the number of fibers with pronounced ADS decreased but more units with pronounced ADS were mechano-sensitive. Spontaneously active C-fibers were increased above the control level (1%) by NGF 8 µg (8%). The results demonstrate that NGF changes the functional axonal characteristics of mechano-insensitive C-fibers and enhances spontaneous activity thereby possibly contributing to hyperalgesia.

NGF enhances electrically induced pain, but not axon reflex sweating.

High-affinity receptors for nerve growth factor (NGF) are found on nociceptors and sympathetic efferents. NGF is known to sensitize nociceptors, increase innervation density, and fire frequency of sympathetic fibers. We explored axonal sensitization of afferent and efferent fibers following intracutaneous injection of NGF in human and pig skin. In humans, frequency-dependent (5, 20, 100 Hz) electrically induced pain was assessed 1, 3, 7, 21, and 49 days post injection. Sweat output was recorded in parallel using the quantitative sudomotor axon reflex test (QSART). Electrically induced pain ratings (7.5 mA for 30 s) significantly increased at the NGF sites for 5 Hz (numeric rating scale [NRS] 6±0.5 vs 3.7±0.4), 20 Hz (NRS 7.2±0.4 vs 5±0.5), and 100 Hz stimulation (NRS 6.9±0.4 vs 5.4±0.3) at day 21, and also for 5 Hz at day 49 (NRS 5.4±0.4 vs 3.8±0.3). Electrically evoked QSART increased frequency dependent, but was not altered by NGF throughout the entire observation period (average QSART at 5 Hz: 3 mL/h/m(2), 20 Hz: 9 mL/h/m(2), 100 Hz: 10 mL/h/m(2)). Similarly, NGF did not change the activity-dependent slowing of conduction of sympathetic efferents (6±2% vs 5.1±1.5%, for 3 minutes, 2 Hz) in pig single-fiber recordings. In parallel to the increased pain ratings recorded in humans, activity-dependent slowing of mechano-insensitive nociceptors was reduced by NGF (18.1±2% vs 29±1.4%). In summary, axonal sensitization of nociceptors by NGF could underlie the hyperalgesia to electrical stimulation. Enhanced responses were limited to nociceptors, as no sensitization was found in sympathetic efferent neurons.

Nerve growth factor-evoked nociceptor sensitization in pig skin in vivo.

Peripheral sensitization of skin nociceptors by nerve growth factor (NGF) was explored in pig skin in vivo. As an objective output measure, the area of axon-reflex-mediated erythema was assessed upon mechanical, thermal, chemical, and electrical stimuli delivered at 1, 3, and 7 days after i.d. injection of 1 microg NGF into the pig's back skin (n = 8). Pretreatment with NGF provoked a sensitization to mechanical (600 mN), thermal (10 sec 49 degrees C) and chemical (15 microl, pH 3) stimuli that lasted for 7 days. No sensitization, however, was found in response to weak mechanical (100 mN), weak thermal (10 sec 45 degrees C), or electrical stimuli. Irrespective of the skin pretreatment (NGF or PBS vehicle control), the area of electrically induced erythema decreased upon repetition (days 1-7) by 70% (P < 0.05). Sensitization of sensory endings by NGF upon mechanical, heat, and chemical stimuli suggests recruitment of sensory transducer molecules [e.g., TRPV1, acid-sensing ion channels (ASICs)]. In contrast, the gradual decrease in electrically induced erythema over 7 days might be attributable to axonal desensitization and possibly activity-dependent down-regulation of sodium channels. Thus, long-lasting sensitization processes of nociceptor endings or axonal sodium channel desensitization mechanisms can be explored in the pig as a translational experimental animal model.

Patterns of activity-dependent conduction velocity changes differentiate classes of unmyelinated mechano-insensitive afferents including cold nociceptors, in pig and in human.

Activity-dependent slowing of conduction velocity (ADS) differs between classes of human nociceptors. These differences likely reflect particular expression and use-dependent slow inactivation of axonal ion channels and other mechanisms governing axonal excitability. In this study, we compared ADS of porcine and human cutaneous C-fibers. Extracellular recordings were performed from peripheral nerves, using teased fiber technique in pigs and microneurography in humans. We assessed electrically-induced conduction changes and responsiveness to natural stimuli. In both species, the group of mechano-insensitive C-fibers showed the largest conduction slowing ( approximately 30%) upon electrical stimulation (2Hz for 3min). In addition, we found mechano-insensitive cold nociceptors in pig that slowed only minimally (<10% at 2Hz), and a similar slowing pattern was found in some human C-fibers. Mechano-sensitive afferents showed an intermediate conduction slowing upon 2Hz stimulation (pig: 14%, human 23%), whereas sympathetic efferent fibers in pig and human slowed only minimally (5% and 9%, respectively). In fiber classes with more pronounced slowing, conduction latencies recovered slower; i.e. mechano-insensitive afferents recovered the slowest, followed by mechano-sensitive afferents whereas cold nociceptors and sympathetic efferents recovered the fastest. We conclude that mechano-insensitive C-fiber nociceptors can be differentiated by their characteristic pattern of ADS which are alike in pig and human. Notably, cold nociceptors with a distinct ADS pattern were first detected in pig. Our results therefore suggest that the pig is a suitable model to study nociceptor class-specific changes of ADS.