Functional roles played by the sympathetic supply to lip blood vessels in the cat

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Functional roles played by the sympathetic supply to lip blood vessels in the cat

Hiroshi Izumi

Department of Orofacial Functions, Tohoku University School of Dentistry, Sendai 980-8575, Japan

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

In the anesthetized cat we used laser-Doppler flowmetry to investigate the part played by cervical superior sympathetic trunk(CST) fibers in the control of blood vessels in an orofacial area(the lower lip). The blood flow increase (antidromic vasodilatation)elicited by inferior alveolar nerve (IAN) stimulation was notaffected by ongoing repetitive CST stimulation over the frequencyrange examined (0.2-10 Hz), although reflex parasympathetic vasodilatationwas attenuated. The vasoconstrictor responses elicited by IANstimulation in some preparations were reduced in a frequency-dependentmanner (at 0.2-1 Hz) during ongoing CST stimulation (and replacedby vasodilator responses). The vasoconstrictor response evokeddirectly by brief CST stimulation was attenuated, but not transformedto a vasodilator response, by ongoing CST stimulation. Thus inthe cat lower lip 1) sympathetic stimulation attenuated one typeof vasodilator response (parasympathetic-mediated vasodilatation),but not another (antidromic vasodilatation), and 2) ongoing sympathetic(CST) stimulation at low frequencies (<1 Hz) prevented furthersympathetic-mediatedvasoconstriction.

parasympathetic vasodilatation; antidromic vasodilatation; orofacial area; vasoresponse

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

IN THE OROFACIAL AREA, the blood vessels in the skin and exocrine glands, such as the salivary and lacrimal glands, are consideredto be amply supplied with vasoconstrictor fibers of sympatheticorigin in both animals and humans. One indication of this is thatelectrical stimulation of the peripheral cut end of the superiorcervical sympathetic trunk (CST) always elicits vasoconstrictorresponses in all the orofacial tissue areas examined (see reviewby Izumi, Ref. 8). Even so, the functional significance ofthese sympathetic nerves is still unclear and, with respect tothe orofacial area, the traditional view of a diffusely organizedsympathetic system is no longer tenable. In fact, no sympatheticallymediated vasoconstrictor responses have been found to occur reflexlyin orofacial tissues in response to a variety of stimuli (suchas trigeminal, gustatory, and visceral stimuli) (16), althoughparasympathetically mediated vasodilatation is evoked reflexlyby the same stimuli (8). However, possible roles for the sympatheticsupply to the orofacial area were suggested by reports that thesympathetic nerves to this area exert inhibitory effects on antidromicvasodilatation, muscle spindle afferent activity, and electromyographicactivity, and that these inhibitory effects are not secondaryto sympathetic vasoconstriction (5, 20, 26).

A lot of evidence has accumulated in recent years in favor of interactions between sympathetic nerves and sensory, parasympathetic,and other sympathetic nerves (6, 7, 10, 23-25, 29, 31-33).On the basis of these reports, a general conclusion about therole of the sympathetics could be that they exert inhibitory effectson vasodilatation regardless of whether it is of antidromic orparasympatheticorigin.

In the present study, we began by examining whether sympathetic inhibitory effects within a particular orofacial vascularbed are or are not specific to one type of vasodilatation (viz.,antidromic or parasympathetic). We also studied the modulatingeffect of ongoing sympathetic activation on the vasoconstrictorresponse elicited by brief stimulation of the CST and on thatsometimes elicited by electrical stimulation of the peripheralend of the inferior alveolar nerve (IAN), and we compared theseeffects with the modulating effect of an adrenergic $alpha$ -blocker.We did this to test the idea that reflex sympathetic vasoconstrictionis not seen in the orofacial area because it is prevented in someway by the ongoing discharge in the sympathetic supply to thesevascular beds. The vascular bed of the cat's lower lip was selectedfor these experiments because 1) the blood vessels are innervatedby cranial parasympathetic, superior cervical sympathetic, andtrigeminal (sensory) fibers (see reviews by Gibbins, Ref. 3,and Izumi, Ref. 8) and 2) the blood flow responses evoked inthis tissue by electrical stimulation of each of the above fibertypes have been well studied (8).

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Preparation of animals. Thirty-four adult cats, unselected as to sex and of 2.8-4.1 kg body wt (approximate age 2-4 years),were initially sedated with ketamine hydrochloride (30 mg/kg im)and then anesthetized with a mixture of $alpha$ -chloralose (50 mg/kgiv) and urethan (100 mg/kg iv). These anesthetics were supplementedif and when necessary throughout the experiment. The anesthetizedanimals were intubated, paralyzed by intravenous injection ofpancuronium bromide (Mioblock; Organon, Teknika, Netherlands;0.4 mg/kg initially, supplemented with 0.2 mg/kg every hour orso after testing the level of anesthesia; see below), and artificiallyventilated via the tracheal cannula with a mixture of 50% air-50%O₂. The ventilator (model SN-480-6; Shinano, Tokyo, Japan) wasset to deliver a tidal volume of 10-12 cm³/kg at a rate of 20 breaths/min, and the end-tidal concentrationof CO₂ was determined by means of an infrared analyzer (CapnomacUltima; Datex, Helsinki, Finland) as reported previously (10).Blood pH, arterial PO₂, and arterial PCO₂ datawere obtained at intervals of 90 min using a blood gas analyzer(model 148; Ciba-Corning, Medfield, MA), and ventilation was adjustedto keep these parameters within normal limits. Ringer solutionwas continuously infused at a rate of ~8 ml/h, and 8.4% NaHCO₃solution was added if necessary (both solutions from Otsuka Pharmaceutical,Tokyo, Japan). Rectal temperature was maintained at 37-38°C withthe use of a heatingpad.

The criteria for maintenance of an adequate depth of anesthesia were the persistence of miotic pupils and the absence of areflex elevation of heart rate and arterial blood pressure duringstimulation of the central end of the lingual nerve. If the depthof anesthesia was considered inadequate, additional $alpha$ -chloraloseand urethan (i.e., intermittent doses of 5 and 10 mg/kg iv, respectively)were administered. Once an adequate depth of anesthesia had beenattained, supplementary doses of pancuronium were given approximatelyevery 60 min to maintain immobilization during periods ofstimulation.

In all experiments, the vagi and superior CSTs were cut bilaterally in the neck before any stimulation. All cats were killedat the end of the experiment by an overdose (~150 mg) of pentobarbitalsodium.

The experimental protocols were reviewed by the Committee on the Ethics of Animal Experiments in Tohoku University Schoolof Medicine, and they were carried out in accordance with boththe Guidelines for Animal Experiments issued by Tohoku UniversitySchool of Medicine and The Law (No. 105) and Notification (No.6) issued by the Japanese Government. All animals were cared forand used in accordance with the recommendations in the currentNational Research Councilguide.

Electrical stimulation of the superior CST, IAN, and lingual nerve. The present experiments involved electrical stimulationof the peripheral cut end of the IAN (Fig. 1A), the central cutend of the lingual nerve (LN; Fig. 1B), or the peripheral cutend of the CST (Fig. 1C). When the LN was to be stimulated, theIAN was not sectioned. In this study, all nerves were sectionedand stimulated unilaterally under a binocular microscope. A bipolarsilver electrode attached to a Nihon Kohden model SEN-7103 Stimulatorwas used for stimulation. For "ongoing" sympathetic stimulation,the CST was stimulated for periods of 7 min each using a supramaximalvoltage (10 V) and pulses of 2 ms duration at various frequencies(0.2-10 Hz, Figs. 2-6). The IAN was dissected free from the mandibularcanal on the side on which lip blood flow (LBF) was to be measuredand was stimulated [for 20 s using supramaximal voltage (30 V)at 10 Hz with pulses of 2 ms duration] either alone or duringongoing repetitive CST stimulation. In some experiments, withthe vagi and sympathetic trunks both cut in the neck, the IANwas stimulated alone or some 5-7 min after an intravenous injectionof phentolamine (1 mg/kg via the femoral vein). The LN was stimulated[for 20 s using a supramaximal voltage (30 V) at 20 Hz with pulsesof 2 ms duration] either alone or during ongoing repetitive CSTstimulation. In some experiments, the CST was stimulated briefly(for 20 s at 10 Hz) during ongoing CST stimulation at 0.2-10 Hz.The two types of CST stimulation were delivered via the same setof electrodes, the ongoing stimulation being interrupted for the20 s needed to deliver the brief CST test stimulation. Electricalstimulation of the IAN, LN, or CST was begun some 3-4 min afterthe start of a period of repetitive ongoing sympathetic stimulation,unless otherwise noted.

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Fig. 1. Schematic representation of sites of electrical stimulation. Stimulation sites: peripheral cut end of inferior alveolar nerve (A), central cut end of lingual nerve (B), and peripheral cut end of superior cervical sympathetic trunk (C). Dashed lines, parasympathetic vasodilator fibers from inferior salivatory nuclei. Solid lines, trigeminal and facial sensory inputs to brain stem. Sympathetic supply, via superior cervical ganglion, is shown at bottom. IAN, inferior alveolar nerve; ISN, inferior salivatory nucleus; LDF, laser-Doppler flowmeter; NST, nucleus of solitary tract; OG, otic ganglion; CST, superior cervical sympathetic trunk; SCG, superior cervical ganglion; V, trigeminal nerve root; VII, facial nerve root; IX, glossopharyngeal nerve root.

Measurement of lower LBF and systemic arterial blood pressure. Changes in blood flow in the lower lip adjacent to the caninetooth were monitored on one side using a laser-Doppler flowmeter(LDF; ALF21R, Advance, Tokyo, Japan) as described before (10,11, 13, 16). The probe was placed against the lower lipwithout exerting any pressure on the tissue. The LDF values obtainedin this way represent the blood flow in superficial vessels. Previousstudies have indicated a significant correlation between bloodflow recordings from oral tissues obtained by laser-Doppler flowmetryand by other well-established methods (2, 22). The analogoutput of the equipment does not give absolute values but showsrelative changes in blood flow (for technical details and evaluationof the LDF method, see Stern et al., Ref. 34). Electrical calibrationfor zero blood flow was performed for all recordings. Severalgains were selectable and the maximum output of a given gain level(defined electrically) was taken as 100%. At the settings usedin this study, the ratio between the magnitude of the LBF increasesand the amplitude of the baseline fluctuations ("signal-to-noiseratio") was 8-10 when either the IAN or LN was stimulated witha supramaximal voltage. The output from the various devices wascontinuously displayed on an eight-channel chart recorder (modelW5000; Graphtec, Tokyo, Japan) at a speed of 10 mm/min. The magnitudeof the blood flow changes elicited by nerve stimulation or intravenousphentolamine and the amplitude of the basal LBF level were assessedby making measurements in millimeters on the chart record. InFigs. 3 and 5, flow levels are expressed in arbitraryunits.

Systemic arterial blood pressure was recorded from the femoral catheter via a Statham pressure transducer. A tachograph (modelAT-610G; Nihon Kohden, Tokyo, Japan) triggered by the arterialpulse was used to monitor heartrate.

Types of tests performed. The main tests carried out in this study were as follows: 1) effects on LBF induced by electricalstimulation of CST, the peripheral cut end of IAN, and the centralcut end of LN and 2) effects of ongoing electrical stimulationof CST on the various changes in LBF (increases, decreases, andbiphasic changes) evoked by IAN and LNstimulation.

Statistical analysis. All numerical data are given as the mean ± SE. The significance of changes in the test responses wasassessed using a paired Student's t-test, Welch's t-test, or anANOVA followed by a contrast test. Differences were consideredsignificant at the level P < 0.05. Data were analyzed using aMacintosh computer with StatView 4.5 and SuperANOVA.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Effects of CST stimulation and phentolamine on LBF and systemic arterial blood pressure. Figure 2 shows the effects of ongoingCST stimulation and intravenous phentolamine on the basal LBFlevel (Fig. 2A) and on systemic arterial blood pressure (Fig.2B) with the ipsilateral IAN intact or sectioned. Such CST stimulationreduced the basal LBF level [F(4,28) = 53.32, P < 0.001, n = 8in each group] in a frequency-dependent manner (for intact IAN,r = 0.715, n = 5 in each group, P < 0.0001; for sectioned IAN,r = 0.839, n = 5 in each group, P < 0.0001) (Fig. 2A). Slightincreases in arterial blood pressure were elicited by CST stimulationregardless of whether the IAN was cut [for cats with intact IAN,F(4,36) = 4.321, n = 10 in each group, P < 0.01; for IAN-sectionedcats, F(4,28) = 2.831, n = 8 in each group, P < 0.05]. However,a statistically significant blood pressure increase was elicitedby CST stimulation only at 2 Hz in both IAN-intact and -sectionedcats. In terms of the changes in these two variables evoked byCST stimulation, no significant difference was observed betweenthe intact and IAN-sectioned cats (NS, ANOVA). On the other hand,intravenous infusion of phentolamine (1 mg/kg) elicited a markeddecrease in systemic arterial blood pressure (by 29.9 ± 5.1 mmHg,n = 10, P < 0.01), but it had no statistically significant effecton the basal LBF level (NS, Welch's t-test; n = 13)

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Fig. 2. Mean data (±SE) for effects of electrical stimulation of CST on circulatory parameters. Effects of ongoing CST stimulation (0-2 Hz) on basal blood flow level in lower lip (LBF) and on systemic arterial blood pressure with IAN intact (open bars) or cut (solid bars). Effects of phentolamine (1 mg/kg iv) are also shown (hatched bars). Ordinate in A shows percentage decrease in basal blood flow (a decrease of 100% being taken as the response to CST stimulation at 2 Hz with the IAN cut; n = 8). Ordinate in B shows absolute changes in systemic arterial blood pressure (mmHg; n = 8). Statistical significance was assessed by means of ANOVA followed by a contrast test. ** P < 0.01, *** P < 0.001 vs. response in absence of either CST stimulation or phentolamine (control).

Effects of IAN and LN stimulation on LBF. In the 34 animals in which IAN and LN stimulation was performed, stimulation ofthe peripheral cut end of the IAN sometimes evoked a simple risein LBF (in 22 animals), sometimes a simple fall (in 5 animals),and sometimes a biphasic response (a fall followed by a rise;in 7 animals). By contrast, stimulation of the central cut endof the LN always evoked a simple rise inLBF.

Effects of ongoing CST stimulation on the LBF increase evoked by IAN and LN stimulation. During ongoing CST stimulation atfrequencies of 0.2-10 Hz, blood flow responses were evoked inthe lower lip by stimulating the IAN in a peripheral directionor the LN in a central direction. Typical examples of evoked LBFincreases are shown in Fig. 3, A and B, and mean data are shownin Fig. 4. There was no statistically significant difference inthe blood flow increase elicited by IAN stimulation whether theIAN was stimulated without (control) or during CST stimulation(over the frequency range examined) (NS, ANOVA, n = 8 in eachgroup; Figs. 3A and 4). On the other hand, the LBF response toLN stimulation was reduced in a frequency-dependent manner byCST stimulation [F(6,60) = 40.62, n = 8 in each group, P < 0.0001(Figs. 3B and 4)], an effect previously reported by us (10).

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Fig. 3. Typical examples of effects of ongoing sympathetic stimulation on vasodilator responses. Effects on lower LBF evoked by electrical stimulation of the peripheral cut end of IAN (A) and of central cut end of lingual nerve (LN; B). Above stimuli were delivered either alone (control) or during ongoing repetitive CST stimulation (both in vagosympathectomized cats). IAN and LN were stimulated where indicated (

) for 20 s at a supramaximal voltage (30 V) at 10 Hz with pulses of 2 ms duration. Frequencies (0.2-10 Hz) of CST stimulation (10 V) are shown at top. au, Arbitary units.

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Fig. 4. Mean data (±SE) for effects of ongoing sympathetic stimulation on vasodilator responses. Effects on lower LBF evoked by electrical stimulation of peripheral cut end of IAN (

; n = 8) and of central cut end of LN ( $open circle$ ; n = 8) (both in vagosympathectomized cats). Above stimuli were delivered either alone (control) or during ongoing repetitive CST stimulation (at 0.2-10 Hz). Ordinate shows IAN- and LN-stimulated increases in LBF during CST stimulation (expressed as a percentage of response to IAN and LN stimulation in the absence of CST stimulation; "control"). Statistical significance was assessed by means of ANOVA followed by a contrast test. * P < 0.05, ** P < 0.01, *** P < 0.001 vs. control.

Effects of ongoing CST stimulation and phentolamine on the falls and biphasic changes in LBF evoked by IAN stimulation. Figure5 shows typical examples of the effects of electrical stimulationof the CST at various frequencies (0-2 Hz; Fig. 5, A and B) andof phentolamine administration (Fig. 5D) on blood flow responses(biphasic responses or simple falls in LBF) in the lower lip elicitedby electrical stimulation of the peripheral cut end of the IAN.Mean data are shown in Fig. 6, A and C, for the biphasic responsesand in Fig. 6, B and D, for similar experiments in which IAN stimulationevoked a simple fall in LBF. The falls in LBF elicited by IANstimulation (whether or not they were followed by a rise) werereduced in a frequency-dependent manner during concurrent CSTstimulation at 0.2-1 Hz [F(4,16) = 13.58, n = 5 in each group,P < 0.001 in Fig. 6A; F(4,12) = 35.06, n = 4 in each group, P< 0.001 in Fig. 6B], and they were completely abolished at 2 HzCST stimulation (Figs. 5, A and B, and 6, A and B). By contrast,the magnitude of the increases in LBF that formed part of thebiphasic responses was almost unchanged by concurrent CST stimulationat any of the frequencies examined [F(4,16) = 2.16, n = 5 in eachgroup, NS in Fig. 6A]. In experiments in which only a fall inLBF was elicited by IAN stimulation without CST stimulation, arise in LBF appeared during ongoing CST stimulation at all frequenciesexamined (Fig. 5B). In such experiments, there was no statisticallysignificant difference in the magnitude of the LBF increases whateverthe frequency of CST stimulation (0.2-2 Hz; NS, ANOVA, n = 4;Fig. 6B).

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Fig. 5. Typical examples of effects of ongoing sympathetic stimulation or phentolamine on biphasic and vasoconstrictor blood flow responses to electrical stimulation of IAN and CST. Effects on blood flow responses elicited by stimulation of the peripheral cut end of IAN induced by ongoing repetitive CST stimulation (biphasic, A; vasoconstrictor, B) and by intravenous administration of phentolamine at 1 mg/kg (D) and effects of ongoing CST stimulation on the vasoconstrictor response evoked by brief CST stimulation (C). Traces show lower LBF and systemic arterial blood pressure (ABP). IAN and CST stimuli were delivered ipsilaterally [in A and B, either alone (control) or during ongoing repetitive CST stimulation; in D, before or after phentolamine; all in vagosympathectomized cats]. IAN and CST were stimulated where indicated (

and $open circle$ , respectively), IAN for 20 s at a supramaximal voltage (30 V) at 10 Hz with pulses of 2 ms duration and CST for 20 s at a supramaximal voltage (10 V) at 10 Hz with pulses of 2 ms duration. Frequencies (0.2-10 Hz) of ongoing CST stimulation (10 V) are shown below the stimulus marker.

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Fig. 6. Mean data (±SE) for effects of ongoing sympathetic stimulation or phentolamine on biphasic and vasoconstrictor responses evoked by electrical stimulation of IAN. Effects of ongoing CST stimulation (0-2 Hz; A and B) and phentolamine (1 mg/kg iv; C and D) on biphasic vascular responses [vasoconstriction (solid bars) followed by vasodilatation (open bars), A and C] and monophasic vasoconstrictor responses (B and D) in lower lip elicited by electrical stimulation of peripheral cut end of IAN. IAN stimulation was delivered either alone (control), during ongoing repetitive CST stimulation, or after phentolamine (all in vagosympathectomized cats). IAN was stimulated for 20 s at a supramaximal voltage (30 V) at 10 Hz with pulses of 2 ms duration. Frequencies (0.2-10 Hz) of CST stimulation are shown at bottom in A and B. Experimental conditions were as in Fig. 5. Ordinate expresses IAN-stimulated changes in lower LBF as a percentage change from baseline (scaled by setting the vasodilator response in absence of CST stimulation in A as 100%). Number of cats used was 5 in A and C, 4 in B and D. Statistical significance was assessed by means of ANOVA followed by a contrast test. * P < 0.05, ** P < 0.01 vs. control.

The falls in LBF elicited by IAN stimulation, regardless of whether they were (Fig. 6C) or were not (Fig. 6D) followed byincreases, disappeared completely on administration of phentolamine(1 mg/kg iv; Fig. 5D). The magnitude of the rise in LBF that formedpart of the biphasic response was unaffected by phentolamine administration(Fig. 6C; NS, paired t-test; n = 5). When a simple fall in LBFwas elicited by IAN stimulation, this was replaced by an increaseafter phentolamine administration (Fig. 6D).

Effect of ongoing CST stimulation on the fall in LBF evoked by brief CST stimulation. The amplitude of the fall in LBF evokedby brief (20 s) CST stimulation was attenuated by ongoing CSTstimulation in a frequency-dependent manner (Fig. 5C). However,this response was not transformed to a rise in LBF by ongoingCST stimulation (Fig. 5C), a result in accordance with our previousfindings (19).

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The blood flow changes elicited in this study by stimulation of the IAN, LN, or CST were either too large or in the wrongdirection to have been the passive result of any evoked bloodpressure changes (which were anyway quite small). Thus we feeljustified in referring to them as "vasoconstriction" or "vasodilatation,"asappropriate.

Vascular responses to IAN stimulation. We previously reported that electrical stimulation of the peripheral cut end of theIAN elicits one of three different patterns of vascular responsein the cat gingiva and lower lip: vasodilatation, vasoconstriction,or a biphasic response (vasoconstriction followed by vasodilatation)(12, 17). These vasodilator and vasoconstrictor responsesor components were considered to be due to activation of sensoryfibers and sympathetic $alpha$ -adrenergic fibers, respectively, becausethey were abolished by prior treatment with capsaicin, the pungentagent of the hot pepper, and phentolamine, an adrenergic $alpha$ -receptorblocker, respectively. At this time, we cannot be sure why parasympatheticallymediated vasodilatation does not occur in the lower lip on electricalstimulation of the peripheral cut end of the IAN, although wefound evidence for parasympathetic vasodilator fibers in the IANoriginating from the otic ganglion in our previous studies (15,16).

Sympathetic supply to the lower lip. The sympathetic fibers that run from the superior cervical ganglion to innervate structuresin the head are known to travel both along branches of the carotidartery and via cranial nerves such as the facial and trigeminalnerves (e.g., Kandel et al., Ref. 18). The presence of sympatheticvasoconstrictor fibers in the IAN has previously been reportedby a number of investigators (17, 27, 30). In the presentstudy, frequency-dependent basal blood flow decreases were observedin the lower lip after electrical stimulation of the peripheralcut end of the CST regardless of whether the IAN was or was notcut (Fig. 2B). This indicates that some sympathetic vasoconstrictorfibers travel to the lower lip without joining the IAN (see Fig.1), a conclusion consistent both with the observation of Matthewsand Robinson (27) that section of this nerve did not abolishthe vasoconstriction in the lower lip produced by stimulationof the CST in the cat and with the finding of Kerezoudis et al.(21) that section of the IAN failed to modify the dopamine levelin the gingiva of therat.

Effects of sympathetic activation on vasodilator responses. There is now considerable evidence that activation of sympatheticnerves exerts an inhibitory influence on afferent nerve-induced(antidromic) vasodilatation in both body skin (6, 7, 29)and dental pulp (20, 31). This inhibition is thought to resultfrom an attenuation of the release of the vasodilator agents viaan activation of presynaptic $alpha$ -adrenoreceptors on the sensorynerve terminals. Whatever the mechanism actually is, these datasuggest that sympathetic vasoconstrictor activity can effectivelyoverride the vasodilator effect induced by antidromic stimulationof nociceptive C fibers in some tissues (body skin and dentalpulp). However, the present results suggest that the situationis different in the lower lip. Indeed, as shown in Figs. 3 and4, the LBF increase we elicited by electrical stimulation of theperipheral cut end of the IAN was not significantly affected byconcurrent stimulation of the cervical superior sympathetic trunkat frequencies within the range 0.2-10 Hz. The above results suggestthat inhibition of vasodilatation by ongoing CST stimulation (whenit occurs) is not due to a simple additive effect at the smoothmuscle level and that sympathetic vasoconstriction does not necessarilyoverride a vasodilator response. At present, we know of no datato explain the apparent tissue-specific nature of the interactionbetween sympathetic vasoconstrictor activity and antidromicvasodilatation.

Nearly 50% of the neurons in the rat superior cervical ganglion project to blood vessels, judged by neurochemical and retrogradetracing studies (4, 35), and tonically active vasoconstrictorneurons have been reported to be present in the superior cervicalganglion of both rat (28) and cat (27). On this basis, a majorrole of the superior cervical sympathetic neurons supplying orofacialareas would seem likely to be the production of vasoconstriction.However, we found recently in cats that no sympathetically mediatedvasoconstrictor responses occurred reflexly in orofacial tissuesin response to a variety of stimuli (such as trigeminal, gustatory,and visceral stimulation) even though parasympathetic-mediatedreflex vasodilatation was evoked by these same stimuli (see reviewby Izumi, Ref. 8). This result was surprising because electricalstimulation of the peripheral cut end of the superior CST consistentlyevokes a vasoconstrictor response in all the orofacial tissuesexamined so far (9, 12, 14, 17). In a previous study,we found that CST stimulation reduced parasympathetic-mediatedblood flow increases in certain orofacial areas (such as the lowerlip and palate) (10). This modulatory effect was also seen inthe present study (Fig. 3B). This modulation was not simply theresult of an additive effect between vasoconstriction and vasodilatationand it did not occur in the tongue or submandibular gland (10).We suggested a possible modulatory action of superior cervicalsympathetic vasomotor neurons within certain vascular beds inthe orofacial area (10). This idea is consistent with otherdata that have accumulated in recent years suggesting a physiologicalrole for sympathetic neurons in the orofacial area that is unrelatedto vasoconstriction (5, 20, 26). Nevertheless, it mustbe admitted that the functional role of the superior cervicalsympathetic neurons supplying the orofacial area is still notentirelyclear.

Effects of sympathetic activation on vasoconstrictor responses. There are now a lot of data confirming the importance of norepinephrine(NE) as a neurotransmitter and neuromodulator at the vascularneuroeffector junction (see review by Wilson and Dunn, Ref. 36).It is unlikely that the reductions in the IAN-evoked vasoconstrictorresponses induced by ongoing CST stimulation and phentolaminewere secondary to effects on circulatory parameters such as bloodpressure or the basal LBF level. In fact, phentolamine (1 mg/kgiv) had much the same effect on the vasoconstrictor responsesas CST stimulation at 1-2 Hz, although its effect on blood pressureand basal LBF was quite different (quantitatively and/or qualitatively;see Fig. 2). It remains to be determined whether the interactionbetween ongoing CST activity and IAN-induced vasodilatation resultsfrom an inhibition of neurotransmitter release from sympatheticnerve terminals (inactivation of sympathetic vasoconstrictor fibers)or from a blockade of adrenergic $alpha$ -receptors on vascular smoothmuscle by unknown substance(s) released from sympathetic nerveterminals during CST stimulation (see Perspectives and Fig. 7).

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Fig. 7. Proposed schema for modulating effects of sympathetic stimulation in cat's lower lip. Schematic illustration of mechanisms that may participate in modulatory effects exerted by sympathetic nerves on parasympathetic and sympathetic nerve-induced vascular responses in cat's lower lip. Norepinephrine (NE; and/or neuropeptide Y) released by ongoing CST stimulation may induce an inhibition of parasympathetic nerve-induced vasodilatation and sympathetic nerve-induced vasoconstriction by acting either on respective nerve terminals or on adrenergic $alpha$ -receptors or vasoactive intestinal peptide (VIP) receptors at postjunctional effectors (smooth muscle cells). Present results suggest no modulating effect of sympathetic activation on antidromic vasodilatation evoked via sensory fibers in this tissue. CGRP, calcitonin gene-related peptide; SP, substance P.

Conversion of vasoconstriction to vasodilatation. The inability of ongoing CST stimulation to transform CST-induced vasoconstrictionto vasodilatation (Fig. 5C) is in marked contrast to its effecton the vasoconstrictor response sometimes evoked by IAN stimulation(Fig. 5, A and B). The simplest explanation for this differenceis as follows. The IAN is a mixed nerve, and so its stimulationactivates vasodilator as well as vasoconstrictor fibers (see Fig.7). An abolition of the vasoconstrictor effect mediated by sympatheticfibers running in the IAN could unmask a previously hidden (Fig.5B) or partially hidden (Fig. 5A) vasodilator response. Thus atransformation of a vasoconstrictor response to a vasodilatorresponse by ongoing CST stimulation would be expected to occuronly when the test response was evoked by stimulation of a mixednerve (such as IAN). This explanation implies that no vasodilatorfibers to the lower lip are activated when the test response isevoked by brief CSTstimulation.

Effect of spontaneous sympathetic discharge on orofacial vasoconstrictor responses. Our previous findings (10) and datareported by other investigators (1) suggest that under thepresent experimental conditions, the spontaneous discharge inthe fibers of the CST innervating the vascular beds supplied bythe common carotid artery or the salivary glands (probably constitutingthe vasoconstrictor population) has a frequency of ~0.5-1 Hz.Ongoing CST stimulation at these frequencies was sufficient toabolish (or almost abolish) the vasoconstrictor effect of IANstimulation (Fig. 6). This may mean that IAN-evoked vasoconstrictionwould not occur under physiological conditions, because it wouldpresumably be suppressed by the spontaneous sympathetic dischargein the CST. It may also indicate that the spontaneous rate ofdischarge in the sympathetic supply to the lower lip (and possiblyother orofacial areas) in some way prevents a significant vasoconstrictionbeing elicited by a higher level of sympathetic discharge. Thisis consistent with the repeated finding (see introduction) thatreflex sympathetic vasoconstriction cannot normally be demonstratedin orofacial tissues (including the lower lip) under resting conditions,although these areas receive a sympathetic vasoconstrictor supply(10).

To conclude, the main findings of this study are 1) that sympathetic vasoconstrictor stimulation does not necessarily overridea vasodilator response (because, in the cat's lower lip, ongoingCST stimulation reduced parasympathetically mediated vasodilatationbut not antidromically mediated vasodilatation) and 2) that activepreconstriction of blood vessels by ongoing CST stimulation atlow frequencies, presumed to be within the physiological rangefor spontaneous sympathetic discharge in the CST, attenuated orabolished the vasoconstriction elicited by stimulation of thesympathetic vasoconstrictor fibers running in theIAN.

Perspectives

At present, we can only speculate on the mechanisms underlying the modulatory effects we have observed. As indicated in Fig.7, two possible explanations for the modulatory effect of ongoingCST activity on IAN-evoked vasoconstriction are that unknown substance(s)released from sympathetic nerve terminals during CST stimulationcould cause 1) an inhibition of neurotransmitter release fromsympathetic nerve terminals (inactivation of sympathetic vasoconstrictorfibers) or 2) a blockade of postjunctional adrenergic $alpha$ -receptors.The latter effect would come into operation if, for example, adrenergic $alpha$ -receptors on vascular smooth muscle could not be activated becausethey were already occupied by NE released from sympathetic nerveterminals by the ongoing CST stimulation. Either effect (1 or2) could also explain the attenuation of brief CST-induced vasoconstrictionby ongoing CST stimulation and the unmasking of a vasodilatorresponse evoked when a mixed nerve (such as IAN) is stimulated.As also indicated in Fig. 7, unidentified substance(s) releasedfrom CST nerve terminals may act in an inhibitory way on parasympatheticnerve terminals in the IAN or on postjunctional vasoactive intestinalpeptide receptors (to attenuate parasympathetic-mediated vasodilatation),but not on the terminals or postjunctional receptors involvedin antidromic vasodilatation. Each of these ideas will requirespecific investigation. Our observation that sympathetic vasoconstrictorresponses (whether evoked by brief CST stimulation or by IAN stimulation)are abolished or nearly abolished by ongoing CST activation atfrequencies around the spontaneous discharge level may explainwhy reflex sympathetic vasoconstrictor responses cannot normallybe evoked in orofacial tissues under physiologicalconditions.

	ACKNOWLEDGEMENTS

This study was supported by grants-in-aid for scientific research from the Ministry of Education, Science, Sports and Cultureof Japan (Nos. 08672115, 09557161, and09671886).

	FOOTNOTES

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Address for reprint requests and other correspondence: H. Izumi, Dept. of Orofacial Functions, Tohoku Univ. School of Dentistry, Sendai 980-8575, Japan.

Received 25 February 1999; accepted in final form 17 May 1999.

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