Alteration of Medullary Dorsal Horn Neuronal Activity Following Inferior Alveolar Nerve Transection in Rats

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Alteration of Medullary Dorsal Horn Neuronal Activity Following Inferior Alveolar Nerve Transection in Rats

Koichi Iwata,¹ Takao Imai,² Yoshiyuki Tsuboi,² Akimasa Tashiro,¹^,² Akiko Ogawa,¹ Toshifumi Morimoto,¹ Yuji Masuda,¹ Yoshihisa Tachibana,¹ and James Hu³

¹Department of Oral Physiology, Faculty of Dentistry, Osaka University, Osaka 565-0871; ²Department of Physiology, School of Dentistry, Nihon University, Tokyo 101, Japan; and ³Department of Oral Biology, Faculty of Dentistry, University of Toronto, Toronto, Ontario M5G 1G6, Canada

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Iwata, Koichi, Takao Imai, Yoshiyuki Tsuboi, Akimasa Tashiro, Akiko Ogawa, Toshifumi Morimoto, Yuji Masuda, Yoshihisa Tachibana, and James Hu. Alteration of Medullary Dorsal Horn Neuronal Activity Following Inferior Alveolar Nerve Transection in Rats. J. Neurophysiol. 86: 2868-2877, 2001. The effects of inferior alveolar nerve (IAN) transection on escape behavior and MDH neuronal activity to noxious and nonnoxiousstimulation of the face were precisely analyzed. Relative thresholdsfor escape from mechanical stimulation applied to the whiskerpad area ipsilateral to the transection were significantly lowerthan that for the contralateral and sham-operated whisker paduntil 28 days after the transection, then returned to the preoperativelevel at 40 days after transection. A total of 540 neurons wererecorded from the medullary dorsal horn (MDH) of the nontreatednaive rats [low-threshold mechanoreceptive (LTM), 27; wide dynamicrange (WDR), 31; nociceptive specific (NS), 11] and sham-operatedrats with skin incision (LTM, 34; WDR, 30; NS, 23) and from theipsilateral (LTM, 82; WDR, 82; NS, 31) and contralateral MDH relativeto the IAN transection (LTM, 77; WDR, 82; NS, 33). The electrophysiologicalproperties of these neurons were precisely analyzed. Backgroundactivity of WDR neurons on the ipsilateral side relative to thetransection was significantly increased at 2-14 days after theoperation as compared with that of naive rats. Innocuous and noxiousmechanical-evoked responses of LTM and WDR neurons were significantlyenhanced at 2-14 days after IAN transection. The mean area ofthe receptive fields of WDR neurons was significantly larger onthe ipsilateral MDH at 2-7 days after transection than that ofnaive rats. We could not observe any modulation of thermal responsesof WDR and NS neurons following IAN transection. Also, no MDHneurons were significantly affected in the rats with sham operations.The present findings suggest that the increment of neuronal activityof WDR neurons in the MDH following IAN transection may play animportant role in the development of the mechano-allodynia inducedin the area adjacent to the area innervated by the injurednerve.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

It has been reported that peripheral-nerve injury induces a wide variety of changes in spinal dorsal horn neurons involvedin the transmission of noxious information to the higher CNS (Bennett1994; Bennett and Xie 1988; Burchiel 1984; Carlton et al. 1991;Doubell et al. 1997; Kim and Chung 1992; Laird and Bennett 1993;Lisney and Devor 1987; Molander et al. 1992; Palecek et al. 1992a,b;Seltzer et al. 1990; Woolf et al. 1992, 1995). Most of the papersstudying nerve-injury-induced changes of the CNS were focusedon the area innervated by the injured nerve. However, changesin noxious responses were observed at the area adjacent to theareas innervated by the injured nerve as well. Peripheral-nerveinjury produces many different types of sensory changes that havebeen described as an abnormal sensation and decrement of painthreshold in both the center and surrounding areas innervatedby the injured nerves. These sensory deficits have been attributedto mechanisms originating in the CNS or primary afferents neurons(Bennett 1994; Kajander and Bennett 1992; Laird and Bennett 1992,1993; Miki et al. 1998). After inferior alveolar nerve transection,the primary afferent nerve fibers increased their spontaneousactivity with abnormal firing and this firing lasted for 2-3 days(Bongenhielm and Robinson 1996, 1998; Chudler et al. 1997). Thisincreased activity of the primary afferent fibers could lead toneuronal hyperactivity of the secondary order neurons in the medullarydorsal horn (MDH). Furthermore, Woolf et al. (1992, 1995) andShortland and Woolf (1993) have reported that peripheral-nerveinjury produces sprouting of large-diameter primary afferent nervefibers from laminae III-IV to lamina II in the spinal cord at7 days after nerve injury. These data suggest the possibilitythat peripheral-nerve injury produces increments of the primaryafferent nerve fiber activity with an abnormal pattern at theearly period after injury and reorganization of the large diameternerve fiber terminals at the later period, which is manifestedas "allodynia," a phenomenon where nonnoxious touch stimuli inducedpain sensation. This primary afferent discharge and reorganizationof large-diameter nerve fiber terminals in the CNS following peripheral-nerveinjury may occur in a wide area of the spinal cord, beyond thearea innervated by the injurednerve.

Kim and Chung (1992) have reported that tight peripheral-nerve ligation produces hypersensitivity to mechanical stimulationof the area adjacent to the innervated regions. This is believedto be produced by a reorganization of primary afferent terminalsin the CNS or hyperactivity of the primary afferent fibers. Itis necessary to analyze the change in response properties of dorsalhorn neurons driven by mechanical and/or thermal stimulation ofthe adjacent regions of the area innervated by the injured nervesto clarify the central mechanism of the hypersensitivity in theadjacent areas as well as the areas innervated by the injurednerves. The trigeminal system can provide such an opportunitybecause the innervation territory of its three branches is welldemarcated.

Furthermore, most of the previous papers studying nerve-injury pain described the data from the sciatic-nerve-lesion model(Bennett 1994; Bennett and Xie 1988; Burchiel 1984; Carlton etal. 1991; Doubell et al. 1997; Kim and Chung 1992; Laird and Bennett1993; Lisney and Devor 1987; Molander et al. 1992; Palecek etal. 1992a,b; Seltzer et al. 1990; Woolf et al. 1992, 1995). Thesciatic nerve includes motor nerves as well as sensory nerves.On the other hand, the trigeminal nerve is purely sensory withouta motor component. It is very important to study the effect ofpure sensory nerve lesion on nociception, without motor nervedamage, to clarify the underlying mechanism of the nerve-injury-inducedneuropathicpain.

Given these findings, we decided first to establish a behavioral model and second to use the single-neuron recording techniqueto clarify the response properties of nociceptive and nonnociceptiveneurons in the MDH of the rat with inferior alveolar nerve (IAN)transection.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Behavioral test

Before the start of training, water was restricted to 100 ml · kg¹ · d¹ for 1 wk. First, rats were trained to stay in the plastic cagefor 20 min and drink 10% sucrose in water through a hole madein the wall of the plastic cage. The experimenter was kept blindto the experimental conditions. In daily sessions, using sucrosewater as reward, rats were trained to stay in the plastic cageand to keep drinking water through a hole on the wall during noxiousmechanical stimulation of the whisker pad area. The criterionperformance was when the rats could keep drinking sucrose waterfor 20 min without escape from the 40-g mechanical stimuli appliedto the whisker pad. Forty grams was the maximum intensity usedin the present study. The absence of an escape response to the40-g stimulus was defined as a relative escape threshold of 1.0.The daily training sessions took place until criterion performancewas reached. At this time, IAN transection was performed. Thevon Frey hair mechanical stimulation was applied to the whiskerpad when the rats were drinking sucrose water and mechanical thresholdof escape behavior was measured in IAN transected, sham-operated,and naive rats. When the relative threshold value 1.0 was obtainedafter surgery, the threshold value was defined as 1.0. Two, 7,14, and 60 days after IAN transection or sham operation, ratswere used for the acute recording experiments. The experimentalconditions were similar for naive and experimentalrats.

Inferior alveolar nerve transection

Sixty-six male Sprague-Dawley rats weighing 300-400 g (ipsilateral to the transection: n = 20, contralateral to transection:n = 15, sham operation: n = 11, naive: n = 20) were initiallyanesthetized with pentobarbital sodium (50 mg/kg ip). For theIAN transection, rats were placed on a warm mat, and a small incisionwas made on the surface of the facial skin over the massetericmuscle and to the alveolar bone through the masseteric muscle.The surface of the alveolar bone was exposed, and the bone surfacecovering the IAN was removed and the IAN was exposed. The IANwas tightly ligated at two points of the nerve trunk at just abovethe angle of the mandible and 1 mm proximal from the angle ofthe mandibular bone. For the sham-operated rats, the facial skinand the masseter muscle were cut and the surface of the alveolarbone was removed. After surgery, penicillin G potassium (20,000U im) was injected to preventinfection.

Rat preparation

In the present study, rats were classified into four groups according to their surgical preparation: ipsilateral to IAN transectiongroup, contralateral to IAN transection group, sham-operated group(which received facial skin incision and lower jaw bone scratching),and naive group (which did not receive any surgical procedures).For neuronal recording, each group of rats was anesthetized withpentobarbital sodium (50 mg/kg ip), and the trachea and left jugularveins were cannulated to allow artificial respiration and intravenousadministration of drugs. Anesthesia was maintained with halothane(2-3%) mixed with oxygen during surgery. The rats were mountedin a stereotaxic frame, the medulla was exposed, and a mineral-oilpool was made with the skin flaps surrounding the laminectomy.A head holder was rigidly secured to the skull by stainless-steelscrews and dental acrylic resin, and the ear bars and nose holderwere removed. This setup allowed convenient access to orofacialreceptive fields(RFs).

After surgery, anesthesia was maintained throughout the experiment by continuous inhalation of halothane (1-2%) mixed withoxygen. During recording sessions, the rats were immobilized withpancuronium bromide (1 mg · kg¹ · h¹ iv) and ventilated artificially. The expired CO₂ concentrationwas monitored and maintained between 3.0 and 4.0%. Rectal temperaturewas maintained at 37-38°C by a thermostatically controlled heatingpad (FHC), and the electrocardiogram was monitored. Blood pressurewas measured every 30 min indirectly from the tail and kept at90-120 mmHg during theexperiments.

Stimulation and recording

Enamel-coated tungsten microelectrodes (impedance = 10-12 M $Omega$ , 1,000 Hz) were advanced into the MDH about 2 mm caudal to theobex in 1-µm steps. Medullary dorsal horn neurons were searchedby applying mechanical stimulation (pressure or brush) to thecraniofacial region. When a single neuron was isolated, the responsesto mechanical stimulation of the facial skin were carefully examinedand the RFs were mapped. Only cutaneous RFs were mapped in thepresentstudy.

Graded mechanical stimuli were applied to the most sensitive areas of the RFs. Mechanical stimuli consisted of brushing witha camel hair brush, pressure produced by a large arterial clip,and pinch produced by a small arterial clip. To avoid sensitizationdue to repeated stimulation, noxious mechanical stimuli were appliedto only small areas of the RFs of each neuron. If the nonnoxiousRFs of first and second encountered nociceptive neurons overlappedwith each other, the second neuron was not included in the analysis.Each neuron was classified as a low-threshold mechanoreceptive(LTM) neuron that had only transient firing at the onset and terminationof the mechanical stimulus or had tonic responses during mechanicalstimulation of the RFs but decreased its firing frequency afternoxious mechanical stimulation; a wide dynamic range (WDR) neuronthat responded to both nonnoxious and noxious mechanical stimuliand increased its firing frequency as stimulus intensity increased;or a nociceptive specific (NS) neuron that responded exclusivelyto noxious mechanical stimulation of the RFs. To avoid sensitizationof the RFs by noxious stimulation, we did not use repeated noxiousstimuli to search for NS neurons. If a neuron showed weak responsesto a pressure stimulus and not to brushing, noxious pinch wasapplied to verify if it a NSneuron.

After characterization of medullary dorsal horn (MDH) neurons with mechanical stimuli, thermal stimuli (heating and cooling)were applied to the most sensitive area of the cutaneous mechanicalRF. When the WDR neurons or NS neurons were identified, heat andcold stimuli were applied to the most sensitive areas of the mechanicalRFs. On the other hand, when LTM neurons were identified, a coldstimulus was applied to the most sensitive areas of the mechanicalRFs. If these neurons responded to cooling of the RFs, they werethen tested with heat stimulation. The thermal probe used in thepresent study was described in our previous study (Iwata et al.1990). The tip of the thermal probe was 5 mm in diameter, andthe rate of temperature change was set at 10°C/s. Before applicationof the thermal stimulus to the RF, the surface temperature wasadapted to 38°C for 180 s. Skin heating ranged from 42-55°C andlasted for 30 s. Cold stimuli consisted of cooling of the skinto 10-30°C. The thermal stimuli were applied to the RFs at 210-sintervals (adaptation time: 180 s, stimulus time: 30 s) to avoidsensitization of peripheral nociceptors. Neuronal responses werefed into a tape recorder (bandwidth DC to 20 kHz) for subsequentanalysis of the signals. After recording of the response propertiesof the MDH neurons, lesions were made at the recording site bypassing DC of 20 µA for 10s.

Histology

At the end of the experiment, the rats were overdosed with pentobarbital sodium and perfused transcardially with 50 ml 0.01M phosphate-buffered saline (PBS, pH 7.4) followed by 10% formalinin 0.1 M PB. The brains were removed and placed in cold fixativefor a few days, then transferred to cold phosphate-buffered 30%sucrose for 48 h. Serial sections (50-µm-thick) were cut alongthe path of the electrode penetration. The sections were counterstainedwith Thionin for identification of recording sites. Precise cameralucida tracings of the recording sites were drawn at ×400 magnificationwith a drawingtube.

Data analysis

The waveform of single or multiple neuronal activity was analyzed off-line. The waveform of each neuron was identified usingSpike 2 software (CED). Peristimulus time histograms (binwidth= 1 s) were generated in response to each stimulus. Backgrounddischarges were first recorded for 10 s before application ofmechanical or thermal stimulus, and they were subtracted fromthe neuronal responses during analysis. The peak firing frequencywas calculated as the highest frequency that occurred during mechanicalor thermal stimulation. Stimulus-response (S-R) functions of eachMDH neuron were obtained in response to the mechanical (brush,pressure, pinch) or thermal (42-50°C) stimuli. The combined mechanicalresponses of WDR neurons were calculated as mean value of peakfiring frequency minus background activity at each stimulus intensity(brush, pressure, and pinch). The mechanical or thermal stimulationof the RFs was considered to have induced an effect when the peakfiring frequency at 5 s after mechanical and 30 s (1 trial foreach neuron with 180-s intervals) after thermal stimulation differedfrom the mean background discharge rate by ±2 SD. Results arepresented as means ± SE. The RFs of all neurons were drawn toscale on standard diagrams of a rat head. Areas of the RFs werecalculated using image analysis software (NIH image 1.60).

Statistical analysis

The ANOVA was performed on the behavioral test at each time point after the operation. We used ANOVA on rank with post hocTukey or Dunnett tests where appropriate. To analyze the relationshipbetween the firing frequency, days after operation and stimulusstrength, we used three-way ANOVA. Similar tests were performedon the contralateral side and sham-operated rats. Differenceswere considered significant at P < 0.05.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Escape behavior from mechanical stimulation of the whisker pad

After completion of the training, in which the rats accepted the noxious mechanical stimulation applied to the whisker padarea, rats received the IAN transection. During mechanical stimulationof the whisker pad area, vocalization and autotomy was never observed.Figure 1 illustrates the relative threshold for escape behaviorelicited by mechanical stimulation of the whisker pad. The decrementof threshold value was significantly greater in the rats withipsilateral IAN transection than the contralateral and sham-operatedrats. Furthermore, the threshold of rats on the contralateralside relative to the IAN transection was significantly lower thanthat of the sham-operated rats. One day after transection, therelative threshold on the ipsilateral side relative to IAN transectionwas decreased to 10% of that before transection, that of the contralateralside decreased to 50% and sham-operated rats was reduced to 70%.The decrement of the relative escape threshold on the side ipsilateralto the transection was significantly lower than that for the contralateraland sham-operated whisker pad until 28 days after the transection.The relative threshold of the ipsilateral and contralateral whiskerpad increased gradually with time after transection and reacheda level similar to the sham-operated rats at 40 days after transection.In the present experiment, sham-operated rats showed slight hypersensitivityto mechanical stimulation just after the sham operation becausesham-operated rats received skin surgery such as the cheek skincut and approaching to the alveolar bone. This decrement of escapethreshold returned to the preoperative level at 7 days after theoperation.

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Fig. 1. Change in the threshold intensity for eliciting escape behavior following inferior alveolar nerve (IAN) transection. The change in threshold intensity was plotted as relative values where escape threshold values are compared before transection and at different periods after IAN transection. A relative threshold of 1.0 was defined as the absence of a response to the highest stimulus intensity (40 g). Sham, sham-operated rats; contralateral, changes of escape threshold from the mechanical stimulation applied to the contralateral side relative to the IAN transection; ipsilateral, changes of escape threshold from the mechanical stimulation applied to the ipsilateral side relative to the IAN transection.

Spatial arrangement of neurons in the MDH

A total of 540 nociceptive and nonnociceptive neurons were recorded from the medullary dorsal horn (MDH) (naive, 69; sham-operatedrats, 84; ipsilateral to the IAN transection, 195; contralateralto the IAN transection, 192) and detailed electrophysiologicalproperties were precisely analyzed (Tables 1 and 2). Figure2 illustrates the intra-laminar distribution of LTM, WDR, andNS neurons recorded from the MDH of naive rats and that on theipsilateral and contralateral side relative to the IAN transection.Basically, WDR and NS neurons were distributed both in the superficial(laminae I-II) and deep laminae (laminae III-IV) of the MDH innaive rats and rats with IAN transection. In naive rats, NS neuronswere mainly distributed in the superficial laminae and LTM andWDR neurons were in the deeper laminae of the MDH.

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Table 1. Incidence of LTM, WDR, and NS neurons recorded from the MDH

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Table 2. Incidence of LTM, WDR and NS neurons responded to thermal stimulation

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Fig. 2. Intra-laminar distribution of low-threshold mechanosensitive (LTM), wide dynamic range (WDR), and nociceptive specific (NS) neurons in the medullary dorsal horn (MDH).

Background activity of MDH neurons

Time course changes in background activity of MDH neurons following IAN transection are shown in Fig. 3. In IAN transectionedrats, MDH WDR neurons began increasing in background activityat 2 days after IAN transection on the ipsilateral side (ipsi/naive:680% at 2 days, 556% at 7 days, and 419% at 14 days; ipsi/sham:1249% at 14 days). The increase in background activity lastedfor 14 days after transection then gradually decreased. A significantincrement of the background activity on the ipsilateral side toIAN transection was observed at 2, 7, and 14 days after IAN transectionas compared with that of naïve rats (P < 0.05). On the otherhand, when compared with the background activity of sham-operatedrats, a significant increment was observed only at 14 days aftersurgery (P < 0.05). Background activity on the ipsilateral sideto the IAN transection was also significantly increased in LTMneurons at 2 and 14 days after surgery as compared with naïverats (ipsi/naive: 422% at 2 days and 933% at 7 days). On the otherhand, NS neurons did not show any significant increase in backgroundactivity after surgery. On the contralateral side relative toIAN transection and sham-operated rats, LTM and NS neurons didnot show clear changes in their firing following IAN transection.On the other hand, WDR neurons slightly increased their backgroundactivity on the contralateral side relative to the transection,but this increase did not reach a significant level. We did notfind any significant differences of background activities of LTM,WDR, and NS neurons between sham and naïve rats (P > 0.05). Thesedata reveal that only WDR neurons in the ipsilateral MDH relativeto the transected side were affected by IAN transection in termsof their background activity.

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Fig. 3. Comparison of mean background activity of LTM (A; naive: n = 27; at 2, 7, 14, and 60 days, n, respectively, is sham: 8, 10, 6, and 10; ipsi: 29, 28, 13, and 15; contra: 7, 19, 18, and 26), WDR (B; naive: n = 31; at 2, 7, 14, and 60 days, n, respectively, is sham: 7, 6, 6, and 8; ipsi: 26, 16, 14, and 27; contra: 20, 20, 21, and 21), and NS neurons (C; naive: n = 11; at 2, 7, 14, and 50 days, n, respectively, is sham: 6, 5, 8, and 4; ipsi: 7, 5, 6, and 5; contra: 4, 6, 9, and 5). The data are based on neuronal activity before the first stimulation of the receptive fields.

Evoked responses of MDH neurons

Figure 4 illustrates an example of responses of a WDR neuron recorded from lamina III of the ipsilateral MDH relative to theIAN transection (Fig. 4B). The IAN in this rat was transected2 days before recording. The RF of this neuron was relativelylarge, extending from the eyelid to the whisker pad region asillustrated in Fig. 4A. In the present study, RFs with low (center)-and high-threshold areas (peripheral) were identified in the WDRneurons. Mechanical responses of WDR neurons increased their firingfrequency following increases in stimulus intensity applied toboth center and peripheral RFs. Mechanical responses in IAN transectionrats were significantly larger on the ipsilateral side relativeto the transection at 2-7 days after surgery, whereas responsesto heat stimulation were not significantly affected by transection(Figs. 6 and 7). Nonnoxious brush (ipsi/naive: 229% at 7 days,276% at 14 days), pressure (ipsi/naive: 253% at 2 days, 184% at7 days, ipsi/sham: 220% at 2 days), and noxious mechanical responses(ipsi/naive: 162% at 2 days) were significantly larger in WDRneurons recorded from the ipsilateral side relative to the IANtransection as compared with that of naïve rats illustrated inFig. 6B (P < 0.05). On the other hand, when compared with sham-operatedanimals, a significant increment of the evoked response was observedafter application of the nonnoxious pressure stimulus to the RFon the ipsilateral side at 2 days after transection. LTM neuronson the side ipsilateral to the transected showed a slight increasein firing frequency following IAN transection (Fig. 6A). As illustratedin Fig. 5, a WDR neuron recorded from the deep laminae of theMDH ipsilateral to transection responded to both heating and coolingof the RF. RF size and mechanical responses showed a similar patternto that observed in a WDR neuron as shown in Fig. 4. Furthermore,cold responses were not clearly graded following graded decreasesin stimulus temperature (Fig. 5F). In the LTM neurons recordedfrom the ipsilateral or contralateral side relative to the transection,significant increases in responses to innocuous brushing (contra/naive:192%) and pressure (contra/naive: 212%, ipsi/naive: 209%; Fig.6) were observed at 2 days after nerve injury (P < 0.05) and inresponses to noxious pinch at 14 days after transection (ipsi/naive:194%; P < 0.05). We could not observe significant changes in evokedresponses of LTM, WDR, and NS neurons following the sham operation.

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Fig. 4. An example of a wide dynamic range (WDR) neuron in the rat at 2 days after IAN transection. A: the receptive field. The solid area indicates the low-threshold area and the hatched area shows the high-threshold area. B: the recording site is indicated. T2: electrode penetration track 2. C and D: the poststimulus time histograms (PSTHs) of responses to mechanical stimulation of the low- (C) and high-threshold area (D) of the receptive field. E: the PSTHs of responses to thermal stimulation of the low-threshold area of the receptive field. BR, brushing with camel brush; PR, pressure with large forceps; PI, pinch with small arterial clip. The same abbreviations are used in the subsequent figures.

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Fig. 5. An example of a WDR neuron in the rat at 14 days after IAN transection. A: the receptive field. The solid area indicates the low-threshold area and the hatched area shows the high-threshold area. B: the recording site is indicated. T2: electrode penetration track 2. C and D: the PSTHs of responses to mechanical stimulation of the low-threshold area (C) and the high-threshold area (D) of the receptive field. E and F: the PSTHs of responses to thermal stimulation of the low-threshold area of the receptive field. Note that this neuron responded to both heating and cooling of the receptive field.

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Fig. 6. Effect of IAN transection on LTM, WDR, and NS neurons following innocuous (brushing and pressure) and noxious (pinch) mechanical stimulation of the receptive fields in naive, sham, and the ipsilateral and contralateral MDH. A: responses of LTM neurons to innocuous and noxious stimulation of the receptive fields. B: responses of WDR neurons. C: responses of NS neurons.

Stimulus-response functions of neuronal responses to graded heat (Fig. 7, A, C, E, and G) and cold stimuli (Fig. 7, B, D,F, and H) were constructed for each neuron and were averaged foreach group. In the present study, we obtained the thermal responsesof a relatively small number of nociceptive neurons (Table 2)in sham-operated rats (Fig. 7, C and D) and in the contralateralMDH (Fig. 7, G and H). WDR and NS neurons in the naive and operatedrats that responded to heat stimulation increased their firingfrequency following increases in stimulus temperature (Fig. 7,A, C, E, and G), and some of these neurons responded to coolingof the RFs in a graded manner (Fig. 7, B, D, F, and H). In thepresent study, no significant differences of the slope of theS-R functions to thermal stimulation were observed at differentperiods after the IAN transection in WDR and NS neurons amongthe naive, sham, contralateral, and ipsilateral groups.

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Fig. 7. Stimulus-response (S-R) functions of nociceptive neurons to graded heat (A, C, E, and G) and cold stimulation (B, D, F, and H) of the mechanical low-threshold areas of the receptive fields. A and B: S-R functions of WDR and NS neurons to graded heating of the receptive fields in naive rats (A: n = 7 and 6, respectively, for A and B). C and D: those from sham-operated rats (C: 2 days: n = 1, D: n = 2, 2, 2, and 2 for 2, 7, 14, and 60 days). E and F: S-R functions of the ipsilateral side relative to IAN transection (for 2, 7, 14, and 60 days, n, respectively, is E: 7, 5, 7, and 9; F: 5, , 6, and 12). G and H: S-R functions of the contralateral side relative to IAN transection (G: 4, 6, 4, and 5 for 2, 7, 14, and 60 days, respectively; H: 6, 5, and 7 for 7, 14, and 60 days).

RF size

We investigated the RF size of MDH neurons only with RFs innervated by the first and the second branches or the second branchof the trigeminal nerve. Two to three penetrations were made intothe dorsal part of the MDH (mandibular projection area) in eachexperiment. No neurons could be identified that responded to mechanicalstimulation of the mandibular region of the facial skin on theipsilateral side relative to the IANtransection.

The RF properties were much more strongly affected by the IAN transection as compared with the other electrophysiologicalproperties. The low (ipsi/naive: 243% at 2 days and 224% at 7days; contra/naive: 243% at 2 days) and high-threshold areas (ipsi/naive:371% at 2 days, 241% at 7 days, and 175% at 60 days; ipsi/sham:377% at 2 days, 377% at 7 days, and 370% at 60 days) of WDR neuronssignificantly increased their size at 2 to 7 and 60 days afteroperation on the ipsilateral sides relative to the IAN transectionas illustrated in Fig. 8, B and C (P < 0.05). A significant incrementin the RFs ipsilateral to IAN transection was observed only atthe high-threshold areas at 2, 7, and 60 days after IAN transectionas compared with those of sham-operated animals or contralateralside to IAN transection (Fig. 8C). On the other hand, in the low-thresholdareas, no significant difference of the size of the RFs was observedbetween the ipsilateral side and sham-operated animals (Fig. 8B).LTM neurons also increased their RF size at 2 days after transectionbut this increment did not reach statistical significance (Fig.8A). NS neurons increased their RF sizes at 2-7 days after transectionon the ipsilateral side, but this increment also did not reachstatistical significance (Fig. 8D). We did not find any significanteffect of sham surgery on the RF size in the LTM, WDR and NS neurons.

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Fig. 8. Mean areas of receptive fields of LTM (A) (naive: n = 22; for 2, 7, 14, and 60 days, n, respectively, is sham: 8, 10, 6, and 10; ipsi: 23, 28, 14, and 17; contra: 17, 19, 17, and 24), WDR [mechanical low-threshold area (B), naive: n = 31, for 2, 7, 14, and 60 days, n, respectively, is sham: 7, 6, 6, and 8; ipsi: 220, 18, 15, and 29; contra: 20, 20, 21, and 21; mechanical high-threshold area (C), same numbers as those in B], and NS neurons (D; naive: n = 8; for 2, 7, 14, and 60 days, n, respectively, is sham: 6, 5, 8, and 4; contra: 4, 4, 15, and 10; for 2, 7, 14, and 60 days, n, respectively, is ipsi: 4, 12, 8, and 4). The mechanical low-threshold (center) and high-threshold (peripheral) areas of the receptive fields of WDR neurons are shown separately.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Effect of IAN transection on escape from noxious and nonnoxious stimuli

The present study demonstrated the time-dependent changes of escape behavior from mechanical stimulation of the whisker padarea (2nd branch of the trigeminal nerve) after IAN (the 3rd branchof the trigeminal nerve) transection. After IAN transection, thewhisker pad area innervated by the second branch of the trigeminalnerve became hypersensitive to innocuous mechanical stimulation(Fig. 1). This hypersensitivity of the whisker pad area was observedat 2 days after IAN transection and lasted for 28 days as illustratedin Fig. 1. Thus IAN transection established sustained modificationsin sensory processing that produced long-lasting mechano-allodyniain the area adjacent to the area innervated by the IAN. Thereare many reports describing that mechano-allodynia was inducedin the hind paw region within several days after sciatic nerveinjury (Bennett 1994; Bennett and Xie 1988; Kim and Chung 1992;Laird and Bennett 1993; Miki et al. 1998; Palecek et al. 1992a,b;Pitcher et al. 1999; Seltzer et al. 1990), and it has recentlybeen reported that tight partial nerve ligation of the sciaticnerve induced hypersensitivity of the hind paw to innocuous mechanicalstimulation. This hypersensitivity became obvious at 2 days afternerve injury and lasted for 145 days. Thus peripheral-nerve-injury-induceddecrements of paw withdrawal threshold with an early onset thatpersisted for a long period. Furthermore, mechanical hypersensitivityof the whisker pad area was observed on the contralateral siderelative to the IAN transection as well. A bilateral effect ofnerve injury has also been reported by some researchers (Malanet al. 2000; Ossipov et al. 1999). The IAN is classified as apure sensory nerve unlike the sciatic nerve. It is possible thatthis physiological difference between the IAN and sciatic nerveis responsible for the differences of behavioral responses inthe IAN transected and CCI rats. However, the pattern of the escapebehavior observed in the rats with IAN transection was similarto that in the CCIrats.

Ipsilateral effect of IAN transection on MDH neuronal activity

LTM and WDR neurons were distributed in the deep and superficial laminae of the MDH and NS neurons were exclusively foundin the superficial laminae. Furthermore, distribution differencesof these neurons in the MDH were not observed on the ipsilateraland contralateral sides relative to the transection, and in naiverats. The present data are consistent with the previous resultsshowing that peripheral nerve injury does not affect the intraspinaldistribution of nociceptive neurons in rats (Broton et al. 1988;Dubner and Bennett 1983; Dubner et al. 1978; Hu 1990; Iwata etal. 1999). It is likely that IAN transection does not alter thespatial arrangement of nociceptive and nonnociceptive neuronsin theMDH.

It has been reported that the behavioral hypersensitivity to innocuous mechanical stimulation of the RF originated from theincreased excitability of the peripheral and CNS. Numerous studieshave shown that primary afferent nerve fibers have significantlyhigher spontaneous activity following peripheral nerve injury(Kajander and Bennett 1992; Lisney and Devor 1987; Tal and Eliav1996; Wall and Devor 1983). Centrally, spinal and thalamic neuronshave high spontaneous activity and hyperexcitability to mechanicaland/or thermal stimulation of the RFs following nerve injury aswell (Laird and Bennett 1992, 1993; Molander et al. 1992; Paleceket al. 1992a,b). Some reports indicate that peripheral-nerve-injury-inducedchanges in responses to both mechanical and thermal stimulation,whereas some demonstrated that only mechanical responses wereaffected by nerve injury (Catheline et al. 1999; Palecek et al.1992a,b). Therefore it is still controversial whether peripheral-nerveinjury contributes to the development of mechano-allodynia and/orthermal hyperalgesia. These differences may be the result of technicaldifferences in peripheral-nerve treatment in each study. To reducethe involvement of technical artifacts related to nerve treatment,the IAN was chosen because the IAN has only sensory afferent fibers.Thus its lesion would not produce impairment on motor functions.Furthermore, we used complete transection of the IAN to produceconsistent damage on theIAN.

We observed hyperexcitability of MDH WDR neurons to innocuous and noxious mechanical stimulation of the RFs but not to thermalstimulation in the rats with IAN transection. The present findingsare very consistent with the findings of Catheline et al. (1999),who discovered that significant fos protein expression was producedonly by mechanical stimulation of the RF in the nerve-injuredrats that had mechanically hypersensitivity to innocuous mechanicalstimulation. These data suggest that IAN transection mainly inducedchanges in sensitivity to mechanical stimulation in the rats withnerve injury rather than any thermalhyperalgesia.

It has been reported that the mechanical hypersensitivity of the adjacent region of the area innervated by the injured nerveis produced on the first day after partial transection of thesciatic nerve (Kim and Chung 1992). It has also been reportedthat primary afferent discharges of the IAN start to increasetheir background activity just after nerve injury. Bongenheilmand Robinson (1996, 1998) reported a high spontaneous activityof the IAN primary afferent that diminishes within 10 days aftertransection. It has also been reported that peripheral-nerve injuryproduces a strong effect on the immune system (Amann and Schuligoi2000; Donnerer et al. 1992). It is believed that NGF has an importantfunction for modulating pain sensitivity (Amann and Schuligoi2000; Donnerer et al. 1992). These researchers showed that thechange in the activity of the immune system affects neuronal activityin the CNS soon after nerve injury. These results raise the possibilitythat injury produces discharges in peripheral-nerve fibers andresult in a change in immune activity. This change in immune activitymay be involved in the behavioral hypersensitivity to mechanicalstimulation of the peripheral RFs that is observed soon afterIANtransection.

It has been reported that skin injury causes an increment in spinal dorsal horn neuronal activity (Yaksh et al. 1999). Cutaneoussensory nerve injury induces a high frequency of nerve dischargein primary afferents, resulting in the hyperexcitability of thedorsal horn neurons. We placed a small incision on the lateralface to reach to the IAN. In this experimental procedure, cutaneoussensory nerve fibers are injured as well as the IAN. We observedthat many MDH neurons slightly increased their activity in sham-operatedrats. It is probable that the skin cut of the lateral face alsocontributed to an increment of the MDH neuronal activity in sham-operatedrats.

Woolf et al. (1992, 1995) reported that peripheral-nerve injury induces changes in the central neuronal network and producesrewiring of the neuronal connections at the spinal level. In thepresent study, long-lasting changes of neuronal activity wereobserved at 7 days after IAN transection. The pronounced changesin neuronal activity in the MDH neurons during the late periodafter transection were increases in RF size. RF size was expandedat 2-7 days after transection and then returned to the naive level.Background activity and evoked responses were immediately increasedat just after transection and lasted for 7 days or less. Takencollectively with the previous findings, our data suggest thatthese changes observed during the late period after transectionmay be induced by a central rewiring of the neuronal network ofthe nociceptive neurons in theMDH.

Contralateral effect of IAN transection on MDH neuronal activity

The effects of peripheral-nerve injury on the contralateral side have been reported in many previous studies (Kolzenburg etal. 1999; Malan et al. 2000; Ossipov et al. 1999). Some reportshave shown that the effect of nerve injury on the contralateralside is similar to that of the ipsilateral side. Our behavioraldata showed that a unilateral IAN transection induced hypersensitivityto innocuous mechanical stimulation of the whisker pad bilaterallyeven though the ipsilateral side was much more sensitive thanthe contralateral side. There have been many discussions aboutthe mechanisms responsible for the bilateral effect of unilateralperipheral-nerve injury (Kolzenburg et al. 1999). It has beenreported that plastic changes of the nervous system are frequentlyobserved in the spinal cord after peripheral-nerve injury (Woolfet al. 1992, 1995). These changes are a possible mechanism underlyingthe hypersensitivity to innocuous mechanical stimulation on thecontralateral side relative to the IAN transection. As observedin the present study, LTM neurons recorded from the contralateralside relative to the IAN transection were hypersensitive soonafter nerve injury. It is probable that LTM neurons are involvedin shortening of withdrawal latency to innocuous mechanical stimulationof the whisker pad. Hyper-responsiveness to innocuous mechanicalstimulation of the MDH neurons recorded from the contralateralside relative to the transection may be induced by the mobilizationof the immune system. Further studies may be necessary to clarifythe central mechanism for the contralateral effect of the unilateralIANtransection.

	ACKNOWLEDGMENTS

This study was supported by Grants-in-Aid for Scientific Research (7457442, 9671907, and 9771551) from the Japanese Ministryof Education, Science, and Culture and by the Ministry of Healthand Welfare (H11-Choju-006).

	FOOTNOTES

Address for reprint requests: K. Iwata, Dept. of Oral Physiology, Faculty of Dentistry, Osaka University, 1-8, Yamadaoka,Suita, Osaka 565-0871, Japan (E-mail: iwatak{at}dent.osaka-u.ac.jp).

Received 19 December 2000; accepted in final form 17 August 2001.

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0022-3077/01 $5.00 Copyright © 2001 The American Physiological Society