Role of Spinal gamma -Aminobutyric AcidA Receptors in Formalin-Induced Nociception in the Rat

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Vol. 282, Issue 2, 928-938, 1997

Role of Spinal $gamma$ -Aminobutyric Acid_A Receptors in Formalin-Induced Nociception in the Rat¹

Megumi Kaneko and Donna L. Hammond

Department of Anesthesia and Critical Care, The University of Chicago, Chicago, Illinois

	Abstract

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This study investigated the role of $gamma$ -aminobutyric acid (GABA) and GABA_A receptors in the spinal cord in the expression ofpain behaviors evoked by injection of formalin in concentrationsranging from 0.25 to 2.5% in the hindpaw of the rat. Two approacheswere used. The first approach compared the effect of drug treatmentto saline at each concentration of formalin. The second approachexamined the effect of drug treatment on the concentration-responsefunctions of formalin, i.e., its EC₅₀. Intrathecal (i.t.) pretreatmentwith 0.03 to 0.3 µg of bicuculline, a GABA_A receptor antagonist,dose-dependently increased the number of flinches and weightedpain scores in the interphase and phase 2, but did not alter responsesin phase 1. In the interphase, the EC₅₀ values of formalin fornumber of flinches or weighted pain score in bicuculline-pretreatedrats were decreased to one-third or one-fourth, respectively,of their values in saline-pretreated rats. In phase 2, the EC₅₀values of formalin for number of flinches or weighted pain scorein bicuculline-pretreated rats were similarly decreased to one-halfof their value in saline-pretreated rats. These results suggestthat formalin was a significantly more noxious stimulus in thepresence of bicuculline. Pretreatment with the GABA_A receptoragonists, muscimol (0.3 µg) or isoguvacine (10 or 30 µg i.t.),significantly decreased the number of flinches in phase 1 andphase 2, but produced only a marginal decrease in the weightedpain score at the highest doses. These findings suggest that thereis little tonic activation of GABA_A receptors by GABA in the spinalcord before or immediately after the injection of formalin. However,approximately 10 min after the induction of injury by formalin,there is a release of GABA and activation of GABA_A receptors inthe spinal cord that 1) contributes to the period of quiescencebetween phase 1 and phase 2 and 2) coincidentally diminishes themagnitude of pain behaviors in phase 2, possibly by limiting thedevelopment of central sensitization in the spinal cord.

	Introduction

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Persistent nociceptive input to the spinal cord induces prolonged alterations in the response properties, neurochemistry andphenotype of dorsal horn neurons (Dubner and Ruda, 1992) and primaryafferent fibers (Neumann et al., 1996; Woolf, 1996a). One suchchange is the induction of central sensitization in dorsal hornneurons after electrical stimulation of C-fiber afferents or theperipheral application of noxious substances such as mustard oil,carrageenan or formalin (Woolf and Wall, 1986; Neugebauer andSchaible, 1990; Woolf et al., 1994; Xu et al., 1995). The enhancedexcitability of dorsal horn neurons is thought to mediate thehyperalgesia and allodynia that develop after tissue injury. Studiesof the mechanisms responsible for the induction and maintenanceof central sensitization and the behavioral sequelae to tissueinjury have predominantly emphasized the role of excitatory neurotransmitterssuch as glutamate and substance P, as well as intracellular messengers(Coderre et al., 1993). Despite substantial evidence that GABAand its receptors are appropriately situated to modulate nociceptivetransmission in the dorsal horn of the spinal cord (Hammond, 1997),comparatively little attention has been paid to the role of GABAin central sensitization in the spinal cord (Sivilotti and Woolf,1994) or in the behavioral sequelae to tissue injury (Hao et al.,1991; Yamamoto and Yaksh, 1991; Smith et al., 1994; Dirig andYaksh, 1995). Most of these studies examined the effects of GABAreceptor agonists, and only a very few used GABA receptor antagoniststo assess the role of endogenous GABA in central sensitizationand the behavioral sequelae to tissue injury (Yamamoto and Yaksh,1993). Yet, small-diameter primary afferent neurons are knownto make synaptic contacts on the dendrites of GABAergic neuronsin the dorsal horn (Carlton and Hayes, 1990; Hayes and Carlton,1992), and stimulation of afferent inputs to slices of the spinalcord evokes GABA_A receptor-mediated inhibitory postsynaptic potentialsin dorsal horn neurons (Yoshimura and Nishi, 1995). Activationof nociceptive afferents by injection of formalin, carrageenanor the topical application of mustard oil is therefore likelyto evoke a release of GABA, as well as glutamate, substance Pand calcitonin gene-related peptide, in the spinal cord. It isreasonable to expect that the behavioral sequelae to tissue injuryreflect the summation of inhibitory processes mediated by GABA_Aand GABA_B receptors, and excitatory processes mediated by NMDAand neurokinin receptors. The recent report that i.t. administrationof GABA receptor antagonists does not alter formalin-evoked painbehaviors (Dirig and Yaksh, 1995) is contrary to this expectation.However, the use of a single, high concentration of formalin (5%)and the existence of a "ceiling effect" for the number of flinchesmay have precluded identification of an increase in formalin-inducedpain behaviors by GABA receptor antagonists. This observationled us to reexamine the role of GABA and GABA_A receptors in thedevelopment and maintenance of persistent pain behaviors as modeledby the formalin test with the important distinction that the effectsof the GABA_A receptor ligands were examined at concentrationsof formalin ranging from 0.25% to 2.5%. Subsequent comparisonof the concentration-effect curves for formalin in the presenceof increasing doses of the GABA_A receptor antagonist bicucullineor the GABA_A receptor agonists, muscimol and isoguvacine, permitteda quantitative estimate of the extent to which antagonism or mimicryof the actions of GABA at the GABA_A receptor, respectively, enhancedor suppressed nociception. It was hypothesized that i.t. administrationof low doses of bicuculline would enhance formalin-induced painbehaviors. Moreover, a preferential enhancement of pain behaviorsin phase 2 of the formalin test, which are mediated by activationof NMDA receptors (Coderre and Melzack, 1992; Yamamoto and Yaksh,1992), was expected as removal of an inhibitory GABAergic inputto dorsal horn neurons should facilitate the activation of NMDAreceptors by glutamate. Intrathecal administration of isoguvacineor muscimol was expected to suppress pain behaviors in both phase1 and phase 2. A preliminary report of some of these data hasappeared (Kaneko and Hammond, 1997).

	Materials and Methods

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Animal preparation. This study was approved by the Institutional Animal Care and Use Committee of the University of Chicago. Male Sprague-Dawleyrats (Sasco, Madison, WI; 300-350 g) were housed in groups ofthree and maintained on a 12-hr light/dark cycle with free accessto food and water. The rats were anesthetized with halothane,and a polyethylene catheter (PE-10) was inserted through an incisionin the atlanto-occipital membrane. One end of the catheter wasadvanced caudally to the rostral edge of the lumbar enlargement,and the other end was tunneled subcutaneously and externalizedon top of the head (Yaksh and Rudy, 1976; Hammond, 1988). Therats were housed individually after surgery and allowed at least7 days to recover before testing.

Formalin test. Animals were placed individually in Plexiglas testing chambers (30.5 × 30.5 × 30.5 cm) and allowed to acclimate for at least60 min. A mirror was situated behind the chamber and another wassituated at a 45° angle below the floor of the chamber to allowan unobstructed view of the rat's paws. After acclimation, 100µl of formalin (0.25-2.5%) was injected s.c. into the plantarsurface of the left hind paw, and the rat was returned to thetesting chamber. Its behavior was observed for the next 60 min.The time spent in each of four mutually exclusive categories ofbehavior was determined by use of a BASIC computer program generouslyprovided by Dr. K.B.J. Franklin (Department of Psychology, McGillUniversity, Montreal, Canada). The behaviors were those originallydescribed by Dubuisson and Dennis (1977) and reiterated by Abbottet al. (1995) as "0 = normal weight bearing on the injected paw,1 = limping during locomotion or resting the paw lightly on thefloor, 2 = elevation of the injected paw so that at most the nailstouch the floor, and 3 = licking, biting" or shaking the injectedpaw. A weighted pain score was calculated by multiplying the amountof time spent in each category by its assigned category weight,summing these products and then dividing by the total time ineach 5-min block of time. In addition, the number of flinchesthat occurred was counted (Wheeler-Aceto and Cowan, 1991). Properplacement of the i.t. catheter was verified at the conclusionof the formalin test by the occurrence of hindlimb paralysis afteran i.t. injection of 10 µl of 2% tetracaine hydrochloride or,in rats sacrificed by CO₂ inhalation, by direct visualizationof the catheter tip after laminectomy and injection of India ink.

Experimental design. Animals were used only once in this study and received only one dose of drug and one concentration of formalin. The firstseries of experiments was designed to determine the time courseand dose dependence of the effect of the GABA_A receptor antagonistbicuculline methiodide on nociceptive behaviors induced by injectionof formalin in the hindpaw. In the pretreatment study, rats receivedan i.t. injection of either saline or 0.03, 0.1 or 0.3 µg of bicuculline10 min before the injection of a concentration of formalin rangingfrom 0.25% to 2.5%. In the post-treatment study, either salineor 0.3 µg of bicuculline was injected i.t. 7 to 8 min after theinjection of a concentration of formalin ranging from 0.25% to1.25%. Doses of bicuculline greater than 0.3 µg were not testedbecause 1) higher doses produce spontaneous vocalization, allodyniaand caudally directed biting and scratching behavior (Yaksh, 1989;McGowan and Hammond, 1993) and 2) 0.3 µg of bicuculline effectivelyantagonizes the increase in tail-flick latency produced by i.t.administration of the GABA_A receptor agonist isoguvacine (McGowanand Hammond, 1993).

The second series of experiments examined the time course and dose dependence of the effect of i.t. administration of a GABA_Areceptor agonist on formalin-evoked nociceptive behaviors. Inthese experiments, either 10 or 30 µg of isoguvacine or 0.3 µgof muscimol was injected i.t. 10 min before the injection of aconcentration of formalin ranging from 0.25% to 2.5%.

Statistical analysis. The number of flinches and weighted pain scores were determined for each 5-min interval after the injection of formalin, andthe data were expressed as the mean ± S.E.M. for that 5-min interval.Two approaches were used to assess the effect of drug treatmenton formalin-induced pain behaviors. The first approach comparedthe effect of drug treatment with that of saline at each concentrationof formalin. This analysis was performed by a two-way analysisof variance for repeated measures in which drug treatment wasone factor and time was the second (repeated) factor. Post hoccomparisons of individual mean values were made by the Newman-Keulstest. The second approach examined the effect of drug treatmenton the stimulus-response functions of formalin. For this analysis,concentration-effect curves for formalin were constructed in drug-and saline-treated rats for phase 1, phase 2 and interphase behaviors.For this purpose, phase 1 was defined as the first 5 min, interphasewas defined as the period 10 to 15 min after injection of formalinand phase 2 was defined as the period 20 to 50 min after injectionof formalin. The analysis of phase 1 behaviors used the totalnumber of flinches and the weighted pain score for that 5-mininterval. The analysis of interphase behaviors used the averagenumber of flinches and the average of the weighted pain scoresdetermined 10 and 15 min after the injection of formalin. Theanalysis of phase 2 behaviors used the average number of flinchesand the average of the weighted pain scores determined between20 and 50 min after the injection of formalin, respectively. Least-squareslinear regression of the individual data was used to determinethe concentration of formalin (EC₅₀) that produced one-half themaximal number of flinches or increase in weighted pain score.These criteria corresponded to a weighted pain score of 1.1 (maximumpain score was 2.2) and 50 flinches for phases 1 and 2 and toa weighted pain score of 0.6 (maximum pain score was 1.2) and25 flinches for the interphase. Fieller's theorem was used todetermine CL (Finney, 1964). The significance of differences inthe EC₅₀ values of formalin in drug- and saline-treated rats wasdetermined by analysis of covariance (Zar, 1984). P $<=$ .05 wasconsidered significant.

Drugs and injections. All drugs were injected i.t. in a volume of 10 µl followed by 10 µl of saline to flush the catheter. The drugs were freshlyprepared, adjusted to pH 6.8 to 7.1 and filtered before administration.Bicuculline methiodide, muscimol and tetracaine hydrochloridewere purchased from Sigma Chemical Co. (St. Louis, MO). Isoguvacinehydrochloride was purchased from Research Biochemicals Inc. (Natick,MA).

	Results

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Stimulus-response function of formalin in saline-treated animals. Subcutaneous injection of formalin into the plantar surface of one hindpaw of saline-pretreated rats evoked concentration-and time-dependent increases in the number of flinches (fig. 1)and in weighted pain score (fig. 2). These increases were biphasic,with an initial increase occurring within the first 5 min (phase1), followed by a quiescent period characterized by fewer flinchesand pain behaviors (interphase; between 5 and 15 min), and a secondincrease in flinching and nociceptive behaviors beginning about20 min and continuing for at least 50 min (phase 2) after theinjection of each concentration of formalin. Figure 3 illustratesthe stimulus-response relationships of formalin for the numberof flinches and for weighted pain scores in phases 1 and 2, andin the interphase. The numbers of flinches and weighted pain scoresin phase 1, interphase and phase 2 were linearly related to theconcentration of formalin in the range of 0.25% to 1.25%. In general,1.25% formalin produced the maximal number of flinches or greatestweighted pain score, with the exception of the number of flinchesin the interphase in which 2.5% formalin elicited a significantlygreater number of flinches than did 1.25% formalin. Table 1 presentsthe EC₅₀ values for formalin in saline-treated rats for phase1, phase 2 and interphase pain behaviors as determined by numberof flinches and by weighted pain score.

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Fig. 1. Effects of i.t. pretreatment with saline ( $bullet$ ) or with 0.03 ( $open circle$ ), 0.1 ( $square$ ) or 0.3 ( $black-square$ ) µg of bicuculline on the number of flinchesevoked by either 0.25% (A), 0.5% (B), 1.25% (C) or 2.5% (D) formalin.Saline or bicuculline was administered i.t. 10 min before s.c.injection of formalin into the plantar surface of one hindpaw.Each symbol represents the mean ± S.E.M. of determinations madein five to eight animals.

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Fig. 2. Effects of i.t. pretreatment with saline ( $bullet$ ) or with 0.03 ( $open circle$ ), 0.1 ( $square$ ) or 0.3 ( $black-square$ ) µg of bicuculline on weighted pain scoreevoked by injection of either 0.25% (A), 0.5% (B), 1.25% (C) or2.5% (D) formalin. Saline or bicuculline was administered i.t.10 min before s.c. injection of formalin into the plantar surfaceof one hindpaw. Each symbol represents the mean ± S.E.M. of determinationsmade in five to eight animals.

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Fig. 3. Concentration-effect relationship of formalin during phase 1 (A, B), interphase (C, D) and phase 2 (E, F) in rats pretreatedi.t. with saline ( $bullet$ ) or with 0.03 ( $open circle$ ), 0.1 ( $square$ ) or 0.3 ( $black-square$ ) µg ofbicuculline. Responses during phase 1, interphase and phase 2are presented as the mean of the number of flinches (A, C, E)or weighted pain score (B, D, F) determined 0 to 5, 10 to 15 and20 to 50 min after injection of formalin, respectively. The concentrationsof formalin are plotted on a log scale. Each symbol representsthe mean ± S.E.M. of determinations in five to eight animals.

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TABLE 1
EC₅₀ values and 95% CL of formalin for phase 1, interphase and phase 2 responses in saline- or bicuculline-treated rats^a

Effects of i.t. pretreatment with the GABA_A receptor antagonist bicuculline. Formalin-induced pain behaviors in phase 1 were generally unaffected by i.t. pretreatment with bicuculline. Although the numberof flinches was slightly increased in phase 1 by 0.03, 0.1 or0.3 µg of bicuculline, the magnitude of the effect was small andwas not dose-dependent (figs. 1 and 3A). Comparison of the EC₅₀values for formalin did not reveal any differences among salineand bicuculline-treated rats for number of flinches in phase 1(table 1). Intrathecal pretreatment with these doses of bicucullinedid not increase the weighted pain scores during phase 1 at anyconcentration of formalin (figs. 2 and 3B). The EC₅₀ of formalinfor weighted pain scores in phase 1 also did not differ amongsaline- or bicuculline-treated rats (table 1).

Intrathecal pretreatment with 0.1 or 0.3 µg of bicuculline significantly increased the number of flinches and weighted painscores determined during the interphase period as compared tosaline-treated rats at each concentration of formalin (figs. 1and 2; table 1). Thus, an enhancement of formalin-induced nociceptivebehaviors began within 10 min of the injection of formalin. Thisenhancement was apparent as a leftward shift in the concentration-effectcurve of formalin in the interphase (fig. 3). Both the numberof flinches and the weighted pain scores during interphase weresignificantly greater in rats treated with 0.1 and 0.3 µg of bicucullinecompared with saline-treated rats (figs. 1 and 2); the greatestenhancement occurred at the lower concentrations of formalin.The highest dose of bicuculline decreased the EC₅₀ of formalinfor the number of flinches to 0.33%, or nearly one-third the valueof 1.1% determined in saline-treated rats. This same dose of bicucullinedecreased the EC₅₀ of formalin for weighted pain score to 0.43%,or nearly one-quarter the value of 1.67% determined in saline-treatedrats (table 1).

Intrathecal pretreatment with bicuculline also increased nociceptive responses to formalin in phase 2. This increase was apparentas a leftward shift in the concentration-effect curve for formalin(fig. 3, E and F). Pretreatment with 0.1 or 0.3 µg of bicucullinemarkedly increased the number of flinches in phase 2 evoked by0.25, 0.5 or 1.25% formalin as compared with saline-treated rats(fig. 1). Pretreatment with 0.03 µg of bicuculline also increasedthe number of flinches; however, this enhancement was small andwas most consistently apparent at the two lowest concentrationsof formalin. Although i.t. pretreatment with 0.3 µg of bicucullineincreased the number of flinches evoked by 2.5% formalin, thiseffect was evident only during the earliest aspect of phase 2(i.e., 20-35 min). Table 1 illustrates that the EC₅₀ values offormalin for flinches in rats pretreated with bicuculline weredecreased in a dose-dependent manner with significant differencesobserved in rats pretreated with either 0.1 or 0.3 µg as comparedwith saline-treated rats. The 0.3-µg dose of bicuculline decreasedthe EC₅₀ of formalin for number of flinches to 0.48%, or nearlyone-half the value of 0.85% in saline-treated rats. Weighted painscores during phase 2 were also enhanced by pretreatment withbicuculline (fig. 2). In rats that received the two lowest concentrationsof formalin, doses as little as 0.03 µg of bicuculline significantlyincreased weighted pain score as compared with saline-treatedrats. In rats that received 1.25% or 2.5% formalin, the most consistentenhancement was produced by 0.3 µg of bicuculline (fig. 2). TheEC₅₀ of formalin for weighted pain score was decreased in a dose-dependentmanner in the presence of increasing doses of bicuculline, witha comparable effect produced by either 0.1 or 0.3 µg of bicuculline(table 1). As observed for number of flinches, 0.3 µg of bicucullinedecreased the EC₅₀ of formalin for weighted pain score to 0.36%,or nearly one-half the value of 0.80% determined in saline-treatedrats.

In addition to the quantitative changes described above, i.t. pretreatment with bicuculline produced qualitative changes informalin-evoked nociceptive responses. For example, during thephase 2 response to injection of either 1.25% or 2.5% formalin,saline-treated rats exhibited two characteristic types of flinches.One type of flinch was limited to the ipsilateral hindquarterand was accompanied by small-amplitude, high-frequency shakesof the paw, whereas the other was bilateral and involved the entirehindquarters. These flinches were considered equivalent for purposesof quantitation. These forms of flinching were not elicited bylower concentrations of formalin in saline-treated rats. However,these two types of flinching were frequently elicited by concentrationsof formalin as low as 0.5% in rats pretreated with bicuculline.Furthermore, bicuculline pretreatment altered the amount of timespent in the three different categories of pain behavior. Onefactor that contributed to the increase in weighted pain scoresin bicuculline-treated animals was the increase in the amountof time spent in category 3 behaviors. For example, 0.3 µg ofbicuculline increased the total time spent in category 3 duringphase 2 to 167 ± 40 sec from 99 ± 13 sec at 0.5% formalin. Moreover,licking of the contralateral paw (`mirror pain' (Aloisi et al.,1993

)), which was not observed in saline-treated animals at 0.5%formalin, occurred in 8 of 11 rats treated with either 0.1 or0.3 µg bicuculline at this formalin concentration.

The 0.3-µg dose of bicuculline was administered to four rats in the absence of formalin to determine whether this dose byitself could elicit formalin-like nociceptive behaviors. No formalin-likenociceptive behaviors were observed in three of the rats. In thefourth rat, the injected hindpaw was favored for less than 4 min.A total of two flinches occurred among the four rats during the60-min observation period.

Effect of i.t. post-treatment with bicuculline. Post-treatment with 0.3 µg i.t. bicuculline 7 to 8 min after injection of formalin significantly enhanced both the numberof flinches and the weighted pain score in phase 2 as comparedwith saline-treated rats. This effect was consistent at each concentrationof formalin (0.25-1.25%) that was tested (time course not shown).The magnitude of nociceptive behaviors in phase 1, before theinjection of drug, did not differ between the saline- and bicuculline-treatmentgroups (table 1). In rats that received 0.3 µg of bicuculline,the concentration-effect curves for formalin were shifted to theleft (fig. 4) and the EC₅₀ values of formalin were significantlydecreased as compared with values in saline-treated rats for bothnumber of flinches and for weighted pain score (table 1). Importantly,the EC₅₀ values of formalin for rats in which 0.3 µg of bicucullinewas administered 7 to 8 min after formalin did not differ fromthe EC₅₀ values determined in rats in which this same dose wasadministered 10 min before formalin (table 1). This result indicatesthat bicuculline was equally effective when administered eitheras a pre- or post-treatment. The effects of post-treatment withbicuculline on nociceptive behaviors during the interphase couldnot be determined as the injection interfered with assessmentof these behaviors.

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Fig. 4. Concentration-effect relationship of formalin for (A) number of flinches and (B) weighted pain score in phase 2 in rats thatreceived an i.t. injection of either saline ( $bullet$ ) or 0.3 µg of bicuculline( $black-square$ ) 7 to 8 min after injection of formalin in one hindpaw. Theconcentrations of formalin are plotted on a log scale. Each symbolrepresents the mean ± S.E.M. of determinations in six to sevenanimals.

Effect of i.t. pre-treatment with a GABA_A receptor agonist. The effect of GABA_A receptor agonists was somewhat dependent on the measure of nociception (figs 5 and 6). The numbers offlinches in both phase 1 and phase 2 were significantly decreasedin a dose-dependent manner by i.t. pretreatment with 10 or 30µg of isoguvacine at each concentration of formalin (fig. 5).Both doses of isoguvacine also significantly decreased the numberof flinches in the interphase, albeit not in a dose-dependentmanner (fig. 5). However, isoguvacine appeared to be less effectivewith respect to its ability to decrease weighted pain score ineither phase 1 or phase 2. Only pretreatment with 30 µg of isoguvacinedecreased weighted pain scores in phase 1 and phase 2 at eachconcentration of formalin, and this suppression was small. (fig.6). In rats pretreated with 10 µg of isoguvacine, a significantdecrease in weighted pain scores occurred only at the 0.25% concentrationof formalin. The reduction in weighted pain scores by isoguvacineduring phase 2 was predominantly the result of a decrease in thetime spent in category 3 behaviors. The time spent in category3 behaviors in rats pretreated with 30 µg of isoguvacine at 0.25%,0.5% and 1.25% formalin was 0 ± 0, 24 ± 19.9 and 97.1 ± 26.8 sec,respectively. By comparison, the time spent in this category insaline-treated rats was 22.6 ± 12.1, 106.2 ± 17.5 and 169.8 ±25.6 sec, respectively (P < .05, each concentration). Pretreatmentwith 30 µg of isoguvacine shifted the concentration-effect curveof formalin for weighted pain scores to the right (fig. 7) andsignificantly increased the EC₅₀ value (CL) of formalin in phase1 and phase 2 to 0.55 (0.41-0.69)% and 1.26 (1.07-1.52)%, respectively(P < .05 compared with saline, table 1). The EC₅₀ values of formalincould not be calculated for the number of flinches as this responsedid not exceed the criterion value of 50 even in those isoguvacine-treatedrats that received 2.5% formalin. However, fig. 7 illustratesthat the concentration-effect curve of formalin for the numberof flinches was shifted to the right in a nonparallel manner inrats pretreated with either 10 or 30 µg of isoguvacine. It wasestimated that the EC₅₀ of formalin for number of flinches inrats pretreated with 30 µg of isoguvacine was increased by atleast 4-fold compared with saline-treated rats. As qualitativeobservations indicated that 30 µg of isoguvacine caused mild muscleweakness of the hindlimbs in 3 of 21 rats, higher doses were notadministered in this study. These three rats were not includedin the data analysis.

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Fig. 5. Effects of i.t. pretreatment with saline ( $bullet$ ), 10 ( $triangle$ ) or 30 ( $open circle$ ) µg of isoguvacine or 0.3 µg of muscimol ( $square$ ) on the number offlinches evoked by injection of either 0.25% (A), 0.5% (B), 1.25%(C) or 2.5% (D) formalin. Saline, isoguvacine or muscimol wasadministered i.t. 10 min before s.c. injection of formalin intothe plantar surface of one hindpaw. Each symbol represents themean ± S.E.M. of determinations made in five to eight animals.

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Fig. 6. Effects of i.t. pretreatment with saline ( $bullet$ ), 10 ( $triangle$ ) or 30 ( $open circle$ ) µg of isoguvacine, or 0.3 µg of muscimol ( $square$ ) on weighted painscore after injection of either 0.25% (A), 0.5% (B), 1.25% (C),or 2.5% (D) formalin. Saline, isoguvacine or muscimol was administeredi.t. 10 min before s.c. injection of formalin into the plantarsurface of one hindpaw. Each symbol represents the mean ± S.E.M.of determinations made in five to eight animals.

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Fig. 7. Concentration-effect relationship of formalin during phase 1 (A, B) and phase 2 (C, D) in rats pretreated i.t. with saline( $bullet$ ), 10 ( $triangle$ ) or 30 ( $open circle$ ) µg of isoguvacine, or 0.3 µg of muscimol( $square$ ). Responses during phase 1 and phase 2 are presented as themean of the number of flinches (A, C) or weighted pain score (B,D) determined 0 to 5 min and 20 to 50 min after injection of formalin,respectively. The concentrations of formalin are plotted on alog scale. Each symbol represents the mean ± S.E.M. of determinationsin five to eight animals.

The disparate effects of isoguvacine on the number of flinches and weighted pain scores elicited by formalin prompted examinationof the effects of another GABA_A receptor agonist, muscimol. Muscimolproduced effects similar to those of isoguvacine. Intrathecalpretreatment with 0.3 µg of muscimol significantly decreased thenumber of flinches in phase 1 and phase 2 at each concentrationof formalin (fig. 5). It also shifted the concentration-effectcurve of formalin for the number of flinches to the right in anonparallel manner, increasing the EC₅₀ of formalin by at leastfour-fold (fig. 7). An EC₅₀ value for formalin in muscimol-treatedrats could not be calculated as the number of flinches did notexceed the criterion value of 50 even in rats that received 2.5%formalin. Like isoguvacine, muscimol appeared to be less effectivein decreasing the weighted pain score (fig. 6). A small, but significantincrease in the EC₅₀ (CL) of formalin to 1.07 (0.95-1.22)% occurredin rats pretreated with 0.3 µg of muscimol. Higher doses of thisGABA_A receptor agonist could not be tested as these caused mildmuscle weakness of the hindlimbs (D. L. Hammond and M. K. McGowan,unpublished observations).

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

A different approach to the formalin test. The formalin test is generally used to measure persistent nociception. However, most studies with the formalin test have restrictedtheir examination to an analysis of drug effects at a single concentrationof formalin and often to a single measure, either the number offlinches or weighted pain score. This approach, although efficientand cost-effective, has limitations. Use of a high concentrationof formalin can hinder identification of weak analgesics and,because of the existence of a ceiling effect, preclude identificationof agents that increase nociceptive behaviors. The inability ofDirig and Yaksh (1995) to detect an enhancement of formalin-inducedpain behaviors by i.t. administered bicuculline most likely arisesfrom these factors. Conversely, low concentrations of formalin,which are suitable for studies of hyperalgesia, may not producean effect of sufficient magnitude to permit reliable detectionof antinociception. The present study, in which the effects ofdifferent doses of bicuculline, muscimol or isoguvacine were examinedover a wide range of concentrations of formalin, represents animportant advance in the use of the formalin test as a measureof nociception. This systematic approach generates a "matrix"of data that can be used for several different types of analyses.First, comparison of the EC₅₀ values of formalin in saline- anddrug-treated animals enables a quantitative analysis of the extentto which a drug treatment alters the perceived intensity of thenoxious stimulus. For example, i.t. pretreatment with 0.3 µg ofbicuculline halved the EC₅₀ values of formalin for both weightedpain score and number of flinches in phase 2, which suggests thatformalin is nearly twice as noxious in the presence of bicuculline.Conversely, i.t. pretreatment with either 0.3 µg of muscimol or30 µg of isoguvacine shifted the concentration-effect relationshipof formalin for the number of flinches in phase 2 at least 4-foldto the right, which suggests that formalin was perceived to beone-quarter as noxious in the presence of these GABA_A receptoragonists. Generation of concentration-effect curves for formalintherefore enabled detection of both the enhancement, as well asthe suppression of nociceptive behaviors. Second, it is possiblethat different concentrations of formalin may induce differentpharmacologic mechanisms in the spinal cord and in the periphery,or alter the balance of central and peripheral mechanisms thatcontribute to the nociception. The systematic analysis of drugeffects over a wide range of concentrations of formalin can identifysuch important occurrences. Finally, this approach remains suitablefor the standard determination of the ED₅₀ of a drug at any specifiedconcentration of formalin. Moreover, comparison of the ED₅₀ valuesof the drug across increasing concentrations of formalin, whichare presumably increasingly more noxious, can be used to determinethe relative efficacy and fractional receptor occupancy requirementsof antinociceptive agents in a model of persistent chemicallyinduced nociception. This approach is analogous to previous studiesin which different intensities of noxious thermal stimuli wereused to determine the relative efficacy and fractional receptoroccupancy requirements of i.t. administered opioid or alpha-2adrenoceptor agonists (Saeki and Yaksh, 1992; Saeki and Yaksh,1993).

Intrathecal bicuculline increases formalin-induced pain behaviors. A principal finding of this study was that i.t. pretreatment with bicuculline, a GABA_A receptor antagonist, increased formalin-inducedpain behaviors in a dose-dependent manner in the interphase andphase 2, but did not affect pain behaviors in phase 1. Bicucullinewas equally effective when administered 7 to 8 min after formalin.Antagonists, by definition, bind to receptors but have no efficacy.For bicuculline to enhance formalin-induced pain behaviors, theremust be an inhibitory action of GABA mediated by GABA_A receptors.These data therefore suggest that within minutes of the injectionof formalin there is a release of GABA and an activation of GABA_Areceptors in the spinal cord. These doses of bicuculline by themselvesdid not produce allodynia or hyperalgesia, nor did they increaseformalin-induced pain behaviors in phase 1. The lack of effectof bicuculline in phase 1 does not reflect an insensitivity ofphase 1 to modulation by GABA_A receptor ligands as GABA_A receptoragonists were able to suppress pain behaviors in phase 1. Rather,these data suggest that there is little tonic activation of spinalGABA_A receptors before or during the first few minutes after injectionof formalin.

The GABA that is released in the spinal cord in response to s.c. injection of formalin may originate from two sources. Onesource is interneurons, which are the principal source of GABAin the dorsal horn (Miyata and Otsuka, 1975

; Todd and McKenzie,1989

). Primary afferents, including small-diameter afferents containingcalcitonin gene-related peptide, make synaptic contacts with thedendrites of GABAergic interneurons in the dorsal horn (Carltonand Hayes, 1990

; Hayes and Carlton, 1992

). Also, activation ofA $delta$ primary afferent fibers in slices of rat spinal cord evokesa polysynaptic inhibitory postsynaptic potential in substantiagelatinosa neurons that is mediated by GABA_A receptors and thatis abolished in the presence of 6-cyano-7-nitroquionoxaline-2,3-dione,a non-NMDA receptor antagonist (Yoshimura and Nishi, 1995

). Thus,GABA is likely to be released from interneurons in the dorsalhorn as a result of the direct activation by formalin of small-diameterglutamatergic and peptidergic primary afferents. A second sourceof GABA in the dorsal horn is the spinal projections of GABAergicneurons in the ventromedial medulla (Blessing, 1990

; Reichlingand Basbaum, 1990

; Jones et al., 1991

; Antal et al., 1996

). Inaddition, there is evidence that serotonergic bulbospinal neuronssynapse on GABAergic interneurons in the dorsal horn (Alhaideret al., 1991

). Activation of medullary neurons produces an antinociceptionthat is antagonized by i.t. administration of bicuculline, whichsuggests that bulbospinal pathways can modulate acute nociceptionby a GABA_A receptor-mediated mechanism (McGowan and Hammond, 1993

).There is also evidence that the activity of bulbospinal pain modulatorypathways is increased during the development of acute inflammation(Schaible et al., 1991

). Therefore, tissue injury induced by injectionof formalin may also elicit a release of GABA from the terminalsof GABAergic bulbospinal neurons or from GABAergic interneuronsvia a spino-bulbospinal loop.

The ability of bicuculline to increase pain behaviors in phase 2 suggests that the responses in this phase are normally diminishedby a coincident inhibitory process mediated by GABA_A receptors.Removal of this inhibitory influence by antagonism of GABA_A receptorspermits full expression of the behavioral sequelae to formalin-inducedtissue injury. The increase in pain behaviors in phase 2 is alsoconsistent with the original interpretation that this phase ofthe formalin test reflects the occurrence of central sensitizationin the spinal cord (Coderre et al., 1990

; Yamamoto and Yaksh,1992

; Coderre et al., 1993

). Although more recent studies havequestioned this proposal and concluded that pain behaviors inphase 2 depend on continued activity in primary afferent fibers(Dallel et al., 1995

; Puig and Sorkin, 1995

; Taylor et al., 1995

;McCall et al., 1996

), these two mechanisms are not mutually exclusive.In fact, continued low-frequency input by C fibers could induce"wind-up" in the spinal cord during this phase (McCall et al.,1996

; Woolf, 1996b

). If pain behaviors in phase 2 were solelydependent on activation of primary afferent fibers, then bicucullinewould be expected not to enhance formalin-induced pain behaviorsin phase 2 just as it failed to increase these behaviors in phase1, which more clearly depends on primary afferent input. The abilityof bicuculline to preferentially increase pain behaviors in phase2 is not compatible with the proposal that phase 2 is entirelydependent on primary afferent activity and can therefore be viewedas additional evidence for the occurrence of central sensitizationin the formalin test.

There are interesting parallels between central sensitization in the spinal cord and LTP in the hippocampus. For example,LTP (Bliss and Collingridge, 1993

; Nicoll and Malenka, 1995

) andcentral sensitization (Woolf, 1983

; Woolf and Wall, 1986

; Woolfet al., 1994

) are each induced by brief, repetitive, high-thresholdafferent stimulation. Activation of NMDA receptors mediates theLTP in certain regions of the hippocampus (Collingridge and Davies,1989

; Bliss and Collingridge, 1993

; Nicoll and Malenka, 1995

),as well as the development and maintenance of central sensitizationin the spinal cord (Haley et al., 1990

; Woolf and Thompson, 1991

;Neugebauer et al., 1994

). Finally, LTP and central sensitizationshare a similar dependence on increases in intracellular Ca⁺⁺ (Bliss and Collingridge, 1993

; Coderre et al., 1993

; Woolf, 1996b

).Numerous studies now indicate that GABA and GABA_A receptors alsoplay an important role in the development and induction of LTP.LTP is enhanced in the presence of GABA_A receptor antagonists(Wigström and Gustafsson, 1983

; Hirai et al., 1993

; Tomasuloet al., 1993

; Yasui et al., 1993

). Indeed, in certain regionsof the central nervous system, antagonism of GABA_A receptors isa prerequisite for the occurrence of LTP (Bear et al., 1992

; Kanterand Haberly, 1993

; Watanabe et al., 1995

). A similar situationmay exist with respect to the induction of central sensitizationin the spinal cord after the injection of formalin. It was recentlyreported that injection of formalin did not elicit central sensitizationin the spinal cord (Xu et al., 1995

). This finding was surprisingbecause a wide variety of stimuli induce central sensitizationin the spinal cord, including repetitive electrical stimulationof C-fibers, topical application of capsaicin or mustard oil andinjection of other inflammatory agents such as kaolin and carrageenan.The inability to detect central sensitization after the injectionof a single, high concentration of formalin (5%) may actuallyreflect the large amounts of GABA released in the spinal cordand the strength of GABA_A receptor-mediated inhibition. It islikely that under certain conditions of afferent stimulation theamounts of GABA that are released are sufficient to cause hyperpolarizationof dorsal horn neurons, thereby hindering or preventing the activationof NMDA receptors by glutamate. In this respect, it is noteworthythat GABAergic and glutamatergic synapses often exist in closeapposition on neurons in the dorsal horn of the spinal cord (Maxwellet al., 1995

) and so are situated to effectively modulate localmembrane potential (Staley and Mody, 1992

; Tomasulo et al., 1993

),which is likely to be of greater import for NMDA than non-NMDAreceptors (Staley and Mody, 1992

). Exclusion of central sensitizationas a mechanism that contributes to pain behaviors in phase 2 ofthe formalin test is therefore premature until the effects oflower concentrations of formalin are examined alone and in thepresence of bicuculline to remove opposing inhibitory influences.In this regard, it has been demonstrated that antagonism of GABA_Areceptors in the spinal cord enhances central sensitization (Sivilottiand Woolf, 1994

Relatively little is known about the mechanisms responsible for the suppression of pain behaviors that occurs 10 to 20 minafter the injection of formalin. The mean firing rate of C-fiberafferents declines during interphase, which suggests that thequiescent period results from a diminished afferent input. However,some C-fibers continue to discharge during this period (Puig andSorkin, 1995

; McCall et al., 1996

). There is also evidence forcentral modulation because the interphase period is absent indecerebrate rats (Matthies and Franklin, 1992

). The present findingthat i.t. administered bicuculline increases pain behaviors ininterphase provides additional evidence for central modulation.Pretreatment with 0.3 µg of bicuculline shifted the concentration-effectcurve of formalin in the interphase to the left to a greater extent(3- to 4-fold) than it did for phase 2 (approximately 2-fold).This difference suggests that the inhibitory effects of GABA arelargely unopposed by excitatory mechanisms during the interphaseperiod.

Effects of GABA_A receptor agonists in the formalin test. In agreement with a previous report (Dirig and Yaksh, 1995), pretreatment with a GABA_A receptor agonist suppressed formalin-inducedpain behaviors in phase 1, as well as phase 2. The suppressionof pain behaviors in phase 1, which are attributed to direct acuteactivation of nociceptors by the injection of formalin and thereforeanalogous to acute nociception, is consistent with the antinociceptiveeffects of isoguvacine and muscimol in other measures of acutenociception such as the tail-flick and hot-plate tests (Hammondand Drower, 1984; McGowan and Hammond, 1993). The effects of muscimoland isoguvacine depended to a certain extent on the dependentmeasure used in the formalin test. Isoguvacine produced largedecreases in the number of flinches in phase 1 and phase 2, butits reduction of weighted pain score was less remarkable. Becausemuscimol had similar effects, it is likely that this differentialeffect is characteristic of GABA_A receptor agonists. At firstglance, the large decrease in number of flinches is at odds withthe modest decrease in weighted pain score. However, closer examinationof weighted pain scores revealed that proportionately greaterdecreases occurred in the time spent in category 3 (to nearly30% of values in saline-treated rats), than in category 2 (toonly 50 to 60% of values in saline-treated rats). The greatereffect observed with use of number of flinches as the dependentmeasure may therefore reflect a specificity of action of GABA_Areceptor agonists for inhibition of reflexive measures. Alternatively,because the therapeutic index between the antinociceptive effectsand the adverse motor effects of i.t. administered GABA_A receptoragonists is small (Hammond and Drower, 1984; Dirig and Yaksh,1995), it is possible that the robust decrease in number of flinchesmay be confounded by an additional effect on motor function thatwas not behaviorally apparent. Indeed, Dirig and Yaksh (1995)noted that the upper CL for muscimol extended into the dose rangeat which motor depression occurs.

Summary. These findings provide strong evidence for a physiological role of GABA in modulating the behavioral responses to tissue injuryproduced by formalin. Specifically, injection of formalin evokesa coincident "compensatory" release of GABA and activation ofGABA_A receptors in the spinal cord. This release of GABA may contributeto the decrease in pain behaviors that occurs 10 to 20 min afterthe injection of formalin (i.e., the interphase period). Moreimportantly, the resulting coincident increase in inhibition maylimit the development of central sensitization by NMDA receptor-dependentmechanisms in the spinal cord and thereby diminish the magnitudeof pain behaviors in phase 2.

	Footnotes

Accepted for publication April 11, 1997.

Received for publication January 21, 1997.

¹ This work was supported by U.S.P.H.S. grant DE11423 from the National Institute for Dental Research (to D.L.H.).

Send reprint requests to: Donna L. Hammond, Ph.D., Department of Anesthesia & Critical Care, University of Chicago, 5841 South Maryland Avenue M/C 4028, Chicago, IL 60637.

	Abbreviations

GABA, $gamma$ -aminobutyric acid; NMDA, N-methyl-D-aspartate; i.t., intrathecal; LTP, long-term potentiation; EC₅₀, effective concentration; CL, 95% confidence limit.

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[Abstract] [Full Te

Role of Spinal -Aminobutyric AcidA Receptors in Formalin-Induced Nociception in the Rat1

Role of Spinal $gamma$ -Aminobutyric Acid_A Receptors in Formalin-Induced Nociception in the Rat¹