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Previous Article | Next Article
Volume 16, Number 24, Issue of December 15, 1996 pp. 8149-8159
Copyright ©1996 Society for NeuroscienceSpontaneous Discharge and Peripherally Evoked Orofacial Responses of Trigemino-Thalamic Tract Neurons during Wakefulness and Sleep
Brian E. Cairns, Shelly A. McErlane, Miguel C. Fragoso, William G. Jia, and Peter J. Soja Division of Pharmacology and Toxicology, Faculty of Pharmaceutical Sciences, The University of British Columbia, Vancouver, British Columbia, Canada V6T 1Z3
ABSTRACT
In the present study, ongoing and evoked activity of antidromically identified trigemino-thalamic tract (TGT) neurons was examined over the sleep-wake cycle in cats. There was no difference in the mean spike discharge rate of TGT neurons when quiet sleep (QS) and active sleep (AS) were compared with wakefulness (W). However, tooth pulp-evoked responses of TGT neurons were decreased during AS when compared to W. Conversely, the responses of TGT neurons to air puff activation of facial hair mechanoreceptors reciprocally increased during AS when compared to W. The present data demonstrate that ascending sensory information emanating from distinct orofacial areas is differentially modified during the behavioral state of AS. Specifically, the results obtained suggest that during AS, sensory information arising from hair mechanoreceptors is enhanced, whereas information arising from tooth pulp afferents is suppressed. These data may provide functional evidence for an AS-related gate control mechanism of sensory outflow to higher brain centers.
Key words: behavioral state; brainstem; hair mechanoreceptor; main sensory nucleus; nucleus oralis; sensory; sleep; tooth pulp; trigeminothalamic
INTRODUCTION
The trigemino-thalamic tract (TGT) is a major somatosensory pathway that conveys sensory information from orofacial regions rostrally to the thalamus and on to the cerebral cortex. Both electrophysiological (Sessle and Greenwood, 1976
; Sessle and Hu, 1981
Given the high density of TGT neurons located in the rostral TSNC in concert with our recent findings of AS-related suppression of these neurons, we hypothesize that synaptic transmission via the TGT is suppressed during the behavioral state of AS. To test this hypothesis, the present study was performed to identify TGT neurons and measure their ongoing and peripherally evoked activity recorded during sleep and wakefulness in chronically instrumented behaving cats. The results obtained via stimuli applied to tooth pulp afferents versus facial hair mechanoreceptors suggest that the source of the peripheral input used to activate the recorded neurons is critical in determining the active sleep-related changes that occur in synaptic transmission through the TGT.
A portion of this work has been presented previously (Soja et al., 1996b
MATERIALS AND METHODS
Surgical implant procedures. Experiments were conducted in four intact, unanesthetized, chronically instrumented cats that were implanted with a head-restraining device and electrodes for monitoring various states of sleep and wakefulness. In addition, tripolar strut electrodes were chronically implanted in the (contralateral) ventrobasal thalamus (HC: A, 6-8; L, 4-6; H,1 to 2) to allow for antidromic activation of rostral TSNC neurons. Further details regarding these surgical implant procedures and those for implanting stimulating electrodes into the canine tooth pulp and inferior alveolar nerve (IAN) may be found elsewhere (Cairns et al., 1995
Cats were allowed to recover fully from each aseptic procedure over a 2 month period, during which time the animal was gradually trained to accept painless head restraint in a chronic stereotaxic frame as described previously (Soja et al., 1993
Recording procedures. Behavioral state was constantly monitored by recording electroencephalogram (EEG), electro-oculogram (EOG), ponto-geniculo-occipital (PGO), and electromyogram (EMG) activities. Behavioral state scoring was performed using previously established criteria (Soja et al., 1993
The boundaries of the rostral TSNC were demarcated as outlined in detail previously (Cairns et al., 1995 ) using an AC-coupled amplifier (bandpass, 0.3-10 kHz, 1000×, Model 1800, A-M Systems).
Rostral TSNC neurons were identified as TGT neurons if they satisfied the following criteria in response to low-intensity (0.2 msec, 500 µA) thalamic stimuli: (1) constant latency (variability < 0.2 msec), (2) high frequency following (
333 Hz), and (3) collision with ongoing and/or peripherally evoked action potentials (see Fig. 1) (Price et al., 1976
Fig. 1. Criteria used to antidromically identify TGT neurons. Five superimposed oscilloscope traces are presented of an antidromic action potential recorded in the rostral trigeminal sensory nuclear complex (TSNC) after stimulation of the thalamus using (A) single pulse (95 µA, 0.1 msec, 1 Hz) and (B) a high-frequency (500 Hz, 5 pulses) train of stimuli. The asterisks in A and B denote the stimulus onset. Consecutive antidromic responses displayed constant latency-to-onset indicating that the action potential resulted from antidromic activation of the axon of the recorded unit. Note that during the high-frequency train in B, a progressive increase in the soma-dendritic conduction time is apparent (arrow), indicating that successive antidromic spikes were generated within the relative refractory period for this cell. Both spontaneous (C) and evoked (D) types of collision are presented. In C, single oscilloscope sweeps illustrate a collision between the antidromic spike and a spontaneous action potential. The sweeps are aligned by the onset of thalamic stimuli (S1) as indicated by the dashed vertical line. In D, single oscilloscope sweeps illustrate a collision between an orthodromically activated action potential evoked by stimulation of the IAN (S2: 0.2 msec, 150 µA) and the antidromic spike. The extracellular field potential evoked by IAN stimulation in D indicates that this neuron was located within the boundaries of the TSNC (Cairns et al., 1995
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Data analysis procedures. The ongoing spike discharge of TGT neurons was measured over 60 sec epochs during each physiologically identified behavioral state (Soja et al., 1996a
Peripherally evoked responses of TGT neurons were investigated via electrical stimulation of a mandibular branch of the trigeminal nerve, the IAN (0.2 msec, 100-500 µA) and the canine tooth pulps (0.2 msec, 5-20 µA), as well as by activation of facial hair mechanoreceptors via innocuous air puffs (FHM; 10-50 msec puff, 0.5 Hz). Poststimulus histograms (PSTHs) were constructed from 50 consecutive responses, and the mean activity was calculated and expressed as spikes/stimulus. Behavioral state-related changes in neuronal excitability were assessed for each neuron by comparing the mean activity during wakefulness with that obtained during corresponding periods of QS and AS (see Cairns et al., 1995
All data were videotaped, and analyses were performed off-line using computerized data acquisition software (A/DVANCE, Spike 2-1401 plus). A repeated-measures ANOVA followed by a univariate F test, where appropriate, was applied to determine whether significant changes in spontaneous and evoked activity were occurring during different behavioral states. p was set at 0.05, and all values are reported as mean ± SE.
Terminal procedures. After completion of all recording sessions and under halothane anesthesia, the ventrobasal thalamus was injected with 1 µl of cholera toxin B subunit conjugated with colloidal gold (List Biological, Campbell, CA). Stereotaxic coordinates for injection corresponded to those used for the chronically implanted thalamic stimulating electrode. Approximately 36-48 hr after injection, each cat was killed with pentobarbital and then perfused with saline followed by 4% paraformaldehyde in phosphate buffer, pH 7.4. The brainstem and thalamus were removed, and 60 µm slices were made with a vibratome slicer. Colloidal gold labeling of TGT neurons was enhanced using a silver-intensifying reagent (InteSEM, Amersham, Buckinghamshire, UK) for 90 min at 21°C. All sections were counterstained with neutral red.
RESULTS
Identification of TGT neurons in the awake cat
The antidromic latency for all 51 TGT neurons recorded during quiet wakefulness (mean 1.54 ± 0.08 msec; Fig. 2A) is similar to antidromic latencies reported in acute studies (Dubner and Sessle, 1971
Fig. 2. Histograms illustrating the distribution of antidromic latency-to-onset (A), conduction velocity (B), and mean ongoing spike discharge (C) of 51 TGT neurons recorded during the behavioral state of wakefulness. A population mean ± SE is located above each histogram. Calculated means for antidromic latency-to-onset and conduction velocity do not differ from those reported in anesthetized cats (Sessle and Greenwood, 1976
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The conduction distance was estimated by calculating the length of a straight line distance between the stereotaxic coordinates of the thalamic stimulating electrode and the stereotaxic coordinates corresponding to each TGT neuron recorded. Using this technique, the estimated straight line conduction distance from the thalamic stimulating electrodes to TSNC neurons varied from 17.2 to 20.0 mm (mean 18.0 ± 0.1 mm). Our calculated conduction velocities ranged from 4.5 to 24.4 m/sec (mean 12.9 ± 0.5 m/sec; Fig. 2B) and are commensurate with conduction velocities reported for TGT neurons in anesthetized cats (Hu et al., 1981
During quiet wakefulness, the vast majority of TGT neurons (>90%) exhibited ongoing spike activity that varied extensively between cells (mean firing rate 12 ± 1 Hz, range 1-43 Hz; Fig. 2C). TGT neurons in acute, anesthetized cats exhibit relatively little or no ongoing spike discharge (Hu et al., 1981 TGT neuronal responses to peripheral stimuli
Table 1 summarizes the response characteristics of 27 TGT neurons that were definitively activated by one or more of the peripheral inputs tested during the state of drowsy wakefulness (see Cairns et al., 1995
Table 1. Summary of 27 TGT neurons that were distinguished on the basis of their discharge characteristics to various peripheral inputs
Facial hair mechanoreceptor (FHM) Inferior alveolar nerve (IAN) FHM and IAN Tooth pulp long latency Tooth pulp short latency Number of TGT neurons 10 6 4 4 3 Mean antidromic latency (msec) 1.3 ± 0.1 1.6 ± 0.2 1.2 ± 0.1 1.9 ± 0.3 2.1 ± 0.9 Mean firing rate (Hz) 12 ± 3 10 ± 2 12 ± 3 13 ± 9 0 Mean orthodromic latency from IAN (msec) NA 3.6 ± 0.9 4.0 ± 1.2 4.2 ± 0.8 5.7 ± 2.2 Mean orthodromic latency from tooth pulp (msec) NA NA NA 18 ± 4 7.0 ± 0.6 TGT neurons were activated: exclusively by air puff activation of facial hair mechanoreceptors (FHM; 37%), exclusively by electrical stimulation of the inferior alveolar nerve (IAN; 22%), by both FHM and IAN (15%), by tooth pulp stimulation characterized by a long-latency burst of action potentials (15%), and by tooth pulp stimulation characterized by short-latency action potentials (11%). FHM-activated TGT neurons tended to have shorter mean antidromic latencies than tooth pulp-evoked TGT neurons; however, these differences were not statistically significant (p > 0.05, Student's t test). Note that, in contrast to other TGT neurons, cells displaying short-latency responses to tooth pulp stimulation did not exhibit ongoing spike activity. All tooth pulp-evoked TGT neurons also responded to stimulation of the IAN. Latencies to IAN and tooth pulp stimuli were obtained using threshold stimuli.
Facial hair mechanoreceptor-activated TGT neurons tended to have shorter mean antidromic latencies than tooth pulp-evoked TGT neurons; however, these differences were not statistically different (p > 0.05, Student's t test). The mean firing rate was similar between different categories of TGT neurons, except for the short-latency tooth pulp-evoked neurons, which did not exhibit any ongoing spike activity.
Finally, TGT neurons were identified that responded distinctly when electrical stimuli were applied to the tooth pulps. Four neurons displayed long-latency (>15 msec) bursts of action potentials (4-6 spikes/stimulus), and 3 neurons responded with one or two short-latency (<10 msec) action potentials to tooth pulp stimuli. Spontaneous activity during wakefulness was only observed in the long-latency TGT neurons. All 7 TGT neurons responding to tooth pulp stimuli also responded to stimulation of the IAN. In 2 of the long-latency cells that were tested, air puff stimuli also evoked a response.
To determine whether the long-latency tooth pulp-evoked responses observed were the consequence of reflex jaw movement, the masseter and anterior digastric muscles were stimulated at intensities that resulted in jaw closing or opening, respectively. Direct stimulation of either muscle failed to mimic the long-latency tooth pulp-evoked responses in the same cells. In fact, the majority of TGT neurons (44/51) did not respond to tooth pulp stimuli at intensities supramaximal for evoking a jaw opening reflex, suggesting that the observed responses were directly attributable to activation of tooth pulp afferents. State-dependent changes in the ongoing activity of TGT neurons
The ongoing spike discharge of 29 of the 51 TGT neurons recorded during quiet W was also recorded during the behavioral states of QS and AS. Overall, there was no significant difference in ongoing discharge when QS or AS was compared with W (p > 0.05, repeated-measures ANOVA). Nevertheless, the histograms of Figure 3 indicate that there was a large range in the mean relative activity, i.e., certain individual neurons were subjected to considerable increases or decreases in spontaneous spike activity during quiet and/or AS. Throughout AS, TGT neurons also displayed paroxysmal bursts of action potentials (Fig. 4). Their paroxysmal spike activity resulted in a 19% increase in coefficient of variation during AS as compared to wakefulness (mean coefficient of variationW, 100 ± 4%; mean coefficient of variationQS, 114 ± 5%; mean coefficient of variationAS, 119 ± 6%).
Fig. 3. Histograms depicting the distribution of relative change in spontaneous activity of TGT neurons during (QS; A) and (AS; B) as compared with wakefulness (n = 29 TGT neurons). Relative activity was calculated for each TGT neuron based on the measured firing rate (FR) during sleep and wakefulness, according to the formula 100 × (FRW
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Fig. 4. Ongoing spike discharge of a TGT neuron over a sleep/wake cycle. In A, the top four traces represent electroencephalogram (EEG), electro-oculogram (EOG), pontine-occipital-geniculate (PGO) wave, and electromyogram (EMG) activities characteristic of the behavioral states indicated above them. The bottom trace represents a rate meter output of ongoing spike discharge (binwidth 1 msec). The mean firing rate of this cell was 13.9 Hz during quiet sleep (QS), 14.1 Hz during active sleep (AS), and 17.3 Hz during wakefulness (W). Note the occurrence of paroxysmal burst discharges that begins at the onset and continues throughout the state of AS (demarcated by the dashed vertical lines). A sliding average depicted by the dotted hairline (binwidth 15 sec) is superimposed on the rate meter trace to emphasize further the irregular pattern of spike discharge during AS. In B, interspike interval histograms (ISIHs) determined during each state are shown. Compared with W, ISIHs constructed during QS and AS are skewed to the right. This skewing of the ISIH is a result of longer pauses in the firing pattern. Above each ISIH is the mean interval and the coefficient of variation, expressed as a percent. The increased coefficient of variation in quiet and active sleep as compared with wakefulness corroborates the observed paroxysmal burst discharge pattern of spike discharge observed in A.
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To explore whether the sleep-related changes (decreases or increases, Fig. 3) in ongoing firing rate depended on the type of afferent input to these cells, the spike rate for 19 neurons was evaluated on the basis of these cells' response characteristics to peripheral stimuli. Nine cells were found to be activated by FHM afferents and 3 were activated by IAN afferents only, whereas 4 were driven by both types of afferent input. Finally, 3 cells displayed long-latency responses to tooth pulp stimuli. There was no difference in the ongoing spike discharge of any of these categories of TGT neurons when QS or AS was compared to W (p > 0.05, repeated-measures ANOVA). State-dependent changes in peripherally evoked activity of TGT neurons
In addition to spontaneous activity, the responses of TGT neurons to peripherally applied stimuli were also examined across the sleep-wake cycle. Synchronous inputs arising from periodontal mechanoreceptors, tooth pulp afferents, as well as input from cutaneous afferents innervating the chin and lower lip were tested by applying low-intensity stimuli to the ipsilateral IAN.
IAN evoked responses were obtained for 5 TGT neurons during sleep and wakefulness. When compared with W, the overall group mean magnitude of these evoked responses was not different during either QS and AS (mean activityW, 1.3 ± 0.3 spikes/stimulus; mean activityQS, 1.3 ± 0.3 spikes/stimulus; mean activityAS, 1.3 ± 0.3 spikes/stimulus; p > 0.05, repeated-measures ANOVA). Individually, both increases (n = 3; range 8-15%) and decreases (n = 2, range 22-26%) in evoked response were observed during AS. An example of an experiment in which the IAN-evoked response in a TGT neurons was modestly suppressed (26%) during AS is presented in Figure 5. 
Fig. 5. Inferior alveolar nerve (IAN)-evoked activity of a TGT neuron during sleep and waking states. The first four traces represent 10 sec epochs of EEG, EOG, PGO, and EMG activity characteristic of wakefulness (W), quiet sleep (QS), and active sleep (AS) and re-awakening (RW). The vertical calibration bars to the right of each trace (EEG, EOG, PGO, EMG) correspond to 50 µV. Bottom, Five overlaid oscilloscope traces illustrate the spike discharge evoked by low-intensity bipolar electrical stimuli (asterisks) applied to the IAN (0.2 msec, 100 µA, 1 Hz). Poststimulus histograms (PSTH) were constructed from 50 consecutive responses. The number above each histogram indicates the mean evoked activity (in spikes per stimulus ± SE). Note that in this neuron, IAN-evoked activity decreased by 16% during QS and 26% during AS compared with W. In addition, the amplitude of the IAN-evoked extracellular field was also decreased (see Cairns et al., 1995
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The nonuniform results reported above for the IAN might have been caused by the diverse origins of the information conveyed by this nerve. To investigate this possibility, we tested TGT neuronal responses evoked by activation of the ipsilateral canine tooth pulps and hair mechanoreceptors innervating the ipsilateral facial areas surrounding the oral cavity. Tooth pulp-evoked responses were obtained for 6 TGT neurons during sleep and wakefulness. When compared with wakefulness, the overall group mean magnitude of these evoked responses was suppressed by 58% during AS (mean activityW, 2.6 ± 0.9 spikes/stimulus; mean activityQS, 2.2 ± 0.8 spikes/stimulus; mean activityAS, 1.1 ± 0.5 spikes/stimulus; p < 0.05, repeated-measures ANOVA). Figure 6 illustrates an example of AS-related suppression of tooth pulp-evoked activity in a TGT neuron. Note that the magnitude of tooth pulp-evoked activity was decreased during both QS and AS in this TGT neuron. This pattern of suppression was observed in 3 TGT neurons, whereas in the other 3 cells suppression was only observed during AS. 
Fig. 6. Active sleep-related suppression of tooth pulp-evoked TGT neuronal activity. Oscilloscope traces represent behavioral state and neuronal activity as described in Figure 5. PSTHs were constructed from 50 consecutive responses to low-intensity bipolar electrical stimuli applied to the canine tooth pulps (0.2 msec, 12 µA, 1 Hz). The number above each PSTH indicates the mean evoked activity (in spikes per stimulus ± SE). Note that tooth pulp-evoked activity in this neuron was reversibly suppressed by 33% during QS and 67% during AS when compared with W.
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Finally, 8 TGT neurons were driven by air puff stimuli during sleep and wakefulness. When compared with W, the group mean magnitude of these evoked responses was unchanged during QS but increased by a mean 38% during AS (mean activityW, 2.1 ± 0.3 spikes/stimulus; mean activityQS, 2.3 ± 0.4 spikes/stimulus; mean activityAS, 2.9 ± 0.3 spikes/stimulus; p < 0.05, repeated-measures ANOVA). An example of an AS-related increase in air puff-evoked activity in a TGT neuron is presented in Figure 7. This is a typical example of a robust increase in evoked activity occurring specifically during the state of AS. The results of the above experiments are summarized in Figure 8 and indicate that sensory transmission through the TGT may be controlled during AS in an input-selective manner. 
Fig. 7. Active sleep-related enhancement of air puff-evoked TGT neuronal activity. Oscilloscope traces represent behavioral state and neuronal activity, respectively, as described in Figure 5. PSTHs were constructed from 50 consecutive responses to a puff of air directed at the ipsilateral face (air puff: 10 msec, 0.5 psi, 0.5 Hz). The number above each histogram indicates the mean evoked activity (in spikes per air puff ± SE). Note that the air puff-evoked activity in this cell remained unchanged during QS; however, during AS, activity was increased by 88% as compared with W.
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Fig. 8. Histograms depicting the distribution of relative change in the evoked spike discharge of TGT neurons to different peripheral inputs during active sleep when compared with wakefulness. Negative values on the abscissa indicate suppression; positive values represent facilitation. Note that tooth pulp-evoked responses of TGT neurons were suppressed, whereas the responses to air puff stimuli were enhanced, during active sleep. The curve indicates the distribution of these data around their mean.
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Antidromic firing index of TGT neurons during sleep and wakefulness
To determine whether a process involving postsynaptic inhibition might be involved in the suppression of tooth pulp-evoked responses, the firing index (FI), a measure of the frequency of antidromic invasion, was calculated during W, QS, and AS (Cairns et al., 1996Anatomical location of labeled TGT neurons
Search stimuli (0.2 msec, 500 µA, 1 Hz) applied to the contralateral ventrobasal thalamus evoked an extracellular field potential when the recording electrode was within the electrophysiologically defined boundaries of the TSNC (Cairns et al., 1995
Fig. 9. Photomicrographs of TGT neurons located within the rostral TSNC. Stereotaxic coordinates for injection of cholera toxin B subunit conjugated with colloidal gold (1 µl) corresponded to those used for the chronically implanted thalamic stimulating electrode. The photomicrographs to the left illustrate the cytoarchitectural features of the main sensory nucleus (MSN) and nucleus oralis (NO). The dashed boxes indicate the area of each photomicrograph that was magnified to the right. These higher-power photomicrographs show examples of labeled TGT neurons in each subnucleus. 5M, Trigeminal motor nucleus; 7N, facial nerve; 7M, facial motor nucleus; 5ST, spinal trigeminal tract.
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DISCUSSION
Characteristics of TGT neurons in the awake cat
The present study was performed to examine the activity of individual TGT neurons in chronic unanesthetized cats during the behavioral states of wakefulness, quiet sleep, and AS. This was accomplished by combining extracellular recording methodologies with classical antidromic techniques to identify TGT neurons in unanesthetized cats. The basic physiological characteristics of these neurons, i.e., antidromic latency and conduction velocity, and their anatomical location substantiate results obtained for TGT neurons in acute anesthetized cats (Mizuno, 1970
The only apparent difference noted in the characteristics of TGT neurons recorded in the awake cat compared with the anesthetized cat preparation is that 90% of the population of neurons recorded during wakefulness display ongoing spike discharge. In our study, the group mean firing rate for the entire population of active neurons measured ~12 spikes/sec. In anesthetized cats, TGT neurons exhibit little or no ongoing spike discharge (Dostrovsky and Hellon, 1978
It was possible to identify TGT neurons that received peripheral input either from the tooth pulp or from FHMs. Overall, the vast majority of these TGT neurons responded to air puff stimuli activating FHMs. Nevertheless, the proportion of TGT neurons responding to these peripheral inputs in awake cats is consistent with that described for anesthetized cats (Sessle and Greenwood, 1976 Characteristics of tooth pulp-evoked TGT neurons during wakefulness
Tooth pulp-evoked TGT neurons recorded during wakefulness comprised two groups based on their response profiles. One group of tooth pulp-evoked TGT neurons responded to tooth pulp stimuli with one or two short-latency action potentials and lacked ongoing spike discharge. The tooth pulp-evoked response characteristics of this group of TGT neurons coincide with ``stimulus intensity-independent'' TSNC neurons recorded in the awake cat (Cairns et al., 1995
The second group of TGT neurons responded to tooth pulp stimuli with longer-latency bursts of action potentials and exhibited ongoing spike discharge during wakefulness. It has been demonstrated that tooth pulp stimuli evoke similar long-latency burst responses in unidentified trigeminal sensory neurons recorded in acute and awake cats (Azerad et al., 1982 State-dependent changes in ongoing spike discharge
Overall, there was no change in the mean spontaneous firing rate of TGT neurons during sleep when compared with wakefulness. During AS, individual neurons did undergo significant changes in mean rate, and both decreases and increases were observed (Figs. 3, 4). However, TGT neurons displayed paroxysmal bursts of spike activity throughout the state of AS (Fig. 4). Paroxysmal burst activity during AS was confirmed by significant increases in the coefficient of variation of interspike intervals for the population of TGT neurons (Cocatre-Zilgien and Delcomyn, 1992
These results differ from our previous findings for L3 Clarke's column dorsal spinocerebellar tract (DSCT) neurons (Soja et al., 1996a State-dependent changes in peripherally evoked responses
The conduction velocity of tooth pulp afferents lies primarily within the Arange (Davies et al., 1971
range (Darian-Smith and Yokota, 1966
Although our findings indicate that differential controls are engaged in modifying the responses of TGT neurons during AS, sensory information conveyed via trigemino-thalamic pathways also appears to be modified during changes in attentional focus. In alert monkeys, the magnitude of thermally evoked but not of hair mechanoreceptor-evoked responses is increased when the stimulus becomes the trigger for the performance of a learned task (Bushnell et al., 1984
The present data suggest that an AS-specific gating mechanism may be influencing ascending sensory transmission. The Gate Control Theory introduced by Melzack and Wall (Melzack and Wall, 1965
We have recently reported that tooth pulp afferent terminals are depolarized supporting a role for presynaptic inhibition during AS (Cairns et al., 1996
A central tenet of Melzack and Wall's gate control theory predicts that an increase in afferent input from large-diameter fibers would reduce transmission to projection cells conveyed by small diameter fibers. Because the overall mean spontaneous firing rate of FHM evoked TGT cells did not differ across the sleep-wake cycle, we suggest that an AS-related gating mechanism would be mediated by a descending pathway(s) that may be engaged during AS to exert facilitatory (pre- and/or postsynaptically) and suppressive influences on the pathways from low-threshold hair mechanoreceptors and tooth pulp afferents, respectively. This facilitation of FHM-evoked TGT neurons might underlie the increase responsiveness of thalamic neurons to FHM stimuli that occurs during AS (Mariotti and Formenti, 1990
The only other single-unit recording study of ``pre-thalamic sensory'' neurons during AS was that performed by Kishikawa et al. (1995)
In conclusion, the results of the present study indicate that sensory transmission through the TGT is dependent on behavioral state and source of peripheral input. These findings suggest that during AS, gating of ascending orofacial afferent inputs occurs at the level of second-order tract cells located within the brainstem and may represent an additional site and mechanism whereby tactile and other sensory inputs are modified as a function of behavioral state. Of relevance to our findings are the well established reciprocal interactions between diverse neural pathways (e.g., cholinergic mesopontine vs serotonergic raphe and/or noradrenergic locus coeruleus neurons) underlying behavioral state control (see Hobson and Steriade, 1986
FOOTNOTES
Received Aug. 7, 1996; revised Sept. 26, 1996; accepted Sept. 27, 1996.
This work was supported by Grant NS32306 from National Institutes of Health. B.E.C. was supported by a Pharmaceutical Manufacturers Association of Canada/Medical Research Council of Canada Graduate Studentship.
Correspondence should be addressed to Dr. Peter J. Soja, Faculty of Pharmaceutical Sciences, The University of British Columbia, 2146 East Mall, Vancouver, BC, Canada V6T 1Z3.
Dr. Jia's present address: Departments of Ophthalmology and Surgery, Faculty of Medicine, The University of British Columbia, 2550 Willow Street, Vancouver, BC, Canada V5Z 3N9.
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