Sex Differences in Supraspinal Morphine Analgesia Are Dependent on Genotype

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Vol. 289, Issue 3, 1370-1375, June 1999

Sex Differences in Supraspinal Morphine Analgesia Are Dependent on Genotype¹

Benjamin Kest, Sonya G. Wilson and Jeffrey S. Mogil

The College of Staten Island/City University of New York and College of Staten Island/Institute for Basic Research Center for Developmental Neuroscience, Staten Island, New York (B.K.); and Department of Psychology and Program in Neuroscience, University of Illinois at Urbana-Champaign, Champaign, Illinois (S.G.W., J.S.M.)

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

Several variables have been reported to affect the expression of sex differences in the analgesic potency of morphine. Althoughthe effect of genetic background on morphine analgesia has beenwell documented, the relevance of genotype to sex differencesin morphine analgesia has rarely been considered. The presentstudy investigated morphine dose-response relationships in maleand female mice of 11 inbred mouse strains on the tail-withdrawaltest after i.c.v. administration. Large differences in morphineanalgesic potency were observed between strains, reflecting theimportant influence of genotype on this trait. We identified threestrains (AKR/J, C57BL/6J, and SWR/J) in which males displayedapproximately 3.5- to 7.0-fold greater sensitivities to the analgesiceffects of morphine than did their female counterparts. In contrast,in the CBA/J strain, females were found to be approximately 5-foldmore sensitive to morphine than were the males. In all other strains,morphine potency estimates between the sexes were not statisticallydifferent. These data support the importance of genotype, sex,and their interaction in the mediation of morphine analgesia andsuggest that equivocal findings regarding opioid sex differencesin the literature may be partially accounted for by the use ofdifferent subject populations. The fact that female mice of theAKR/J and CBA/J strains exhibit 35-fold different morphine analgesicpotency and that males of these strains are equally sensitiveshould facilitate the mapping and identification of sex-specificgenes of relevance to morphineanalgesia.

	Introduction

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The analgesic effect of morphine in humans is subject to wide individual differences (Lasagna and Beecher, 1954), and it isbecoming increasingly appreciated that sex differences may contributeto this variability (for reviews, see Berkley, 1997; Kest et al.,1998). Our understanding of the contribution of sex differencesin morphine analgesia has been largely aided by research in rodentpopulations. For example, the peak, total, and duration of morphineanalgesia after systemic administration have been shown to begreater in males than in females in both rats (Baamonde et al.,1989; Islam et al., 1993; Cicero et al., 1996) and mice (Kavaliersand Innes, 1987; Lipa and Kavaliers, 1990; Candido et al., 1992;Kavaliers and Innes, 1992a, b). A strong case that sex differencesin morphine analgesia may be mediated by differential centralnervous system mechanisms can be made based on the observationsthat male rats display greater analgesic effect than females afterthe administration of morphine into the cerebral ventricles (Kepleret al., 1989) or the rostral ventromedial medulla (Boyer et al.,1998).

However, the effect of sex on morphine analgesia remains equivocal because several studies have failed to observe significantsex differences (Kasson and George, 1984; Islam et al., 1993;Ali et al., 1995). This lack of consistent findings may reflectmethodological differences between studies. Indeed, among thevariables that have been demonstrated to affect sex differencesin opioid analgesia are dose (Kepler et al., 1989; Bartok andCraft, 1997), nociceptive assay used (Baamonde et al., 1989; Islamet al., 1993; Bartok and Craft, 1997), postinjection testing latency(Bartok and Craft, 1997), time of testing (i.e., circadian rhythmicity)(Kavaliers and Innes, 1987), and subject age (Islam et al., 1993).Not usually considered is the well documented fact that the analgesicpotency of morphine can vary between subpopulations of a singlespecies (for a review, see Mogil et al., 1996b). For example,large differences in morphine analgesia have been reported betweencompared selectively bred, inbred, and recombinant inbred mousestrains, reflecting a strong genetic component in the mediationof morphine analgesic sensitivity. However, experiments directlyaddressing the issue of whether the expression of sex differencesin morphine or opioid analgesia varies with genotype are rare.One study reported that the magnitude of sex differences in morphineanalgesia (males > females) differed between Sprague-Dawley andWistar-Furth rats (Kasson and George, 1984). We observed greateranalgesia from the enkephalin-derived µ-opioid receptor agonist[D-Ala²,N-MePhe⁴,Gly-ol⁵]-enkephalin in male than in female mice selectively bred forhigh-, but not low-, stress-induced analgesia (Kest et al., 1995).In an intriguing finding, Rady and Fujimoto (1997) report thatheroin analgesia is mediated alternately by µ- and $delta$ -opioid receptors,respectively, in ICR and Swiss-Webster (SW) strains; this geneticdifference displays sex-influenced dominant inheritance, suchthat male (ICR × SW)F₁ hybrids display the ICR phenotype, whereasfemale F₁ hybrids display the SW phenotype. Finally, endogenousopioid analgesic mechanisms, which are known to represent thesubstrate on which morphine acts to produce pain inhibition, areactivated by forced cold-water swims in inbred male DBA/2 micebut not in female mice of this same strain or in C57BL/6 miceof either sex (Mogil and Belknap, 1997). These studies all suggestthat genotype (i.e., allelic differences at relevant genetic loci)may contribute to sex differences in opioid analgesia and thatthe use of different subject populations may be at least partiallyresponsible for the ambiguous state of the literature regardingthesedifferences.

The aim of the present study was to begin a more comprehensive examination of the putative interaction of genotype and sexin the potency of morphine analgesia. Toward this end, morphinehalf-maximal analgesic dose (AD₅₀) estimates in male and femalemice of 11 inbred strains were compiled using the tail-withdrawaltest. To minimize the possible influence of sex differences inmorphine pharmacokinetic parameters (Candido et al., 1992; Craftet al., 1996; but see Cicero et al., 1996, 1997), we used thei.c.v. route of administration. The data demonstrate that themagnitude and direction of sex differences in morphine analgesiaare dependent ongenotype.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

Strains. Naïve, adult mice of both sexes (n = 8/sex/strain) of the following inbred strains were obtained from The Jackson Laboratory(Bar Harbor, ME): 129/J, A/J, AKR/J, BALB/cJ, C3H/HeJ, C57BL/6J,CBA/J, LP/J, SJL/J, and SWR/J. For clarity, the J substrain identifierwill be omitted. All mice were shipped at 6 weeks of age (exceptBALB/c mice, which are only available at $<=$ 4 weeks of age), housedfour to a cage in a temperature-controlled (22°C) environment,and maintained on a 12:12-h light/dark cycle (lights on at 7:00AM). Mice were allowed free access to food (Purina chow) and water.Testing occurred at 7 to 8 weeks of age in allcases.

Morphine Administration. Morphine sulfate was generously supplied by the National Institute for Drug Abuse (Rockville, MD) and was dissolved in 0.9%physiological saline. Injections were made into the lateral cerebralventricle according to the method of Haley and McCormick (1957)with animals under oxygen/isoflurane inhalant anesthesia. Briefly,a small midline incision was made in the scalp of anesthetizedmice, and the lambda was located. Drug then was injected directlythrough the skull at a point 2 mm rostral and lateral to $lambda$ ata depth of 3 mm using a 10-µl Hamilton microsyringe with a 27-gaugeneedle. All injections were made in a volume of 5 µl. After eachinjection, the incision was closed with a stainless steel woundclip.

Tail-Withdrawal Assay. Testing proceeded in two daily sessions near mid-photophase (10:00 AM to 12:00 noon; 2:00-4:00 PM) to reduce circadian effectson nociceptive and analgesic sensitivity. Because of availabilityrestrictions and practical considerations, strains were testedin groups based on their arrival date (group 1: AKR, C3H/He, SJL,SWR; group 2: BALB/c, C57BL/6, CBA; group 3: 129, A, LP). Withineach group, however, both strain and sex were completely counterbalanced,so one mouse per strain per sex was tested in eachsession.

After a 30-min habituation to the testing room, mice were assessed for baseline nociceptive sensitivity on the 49°C tail-withdrawaltest. In this assay of acute, thermal nociception, the mouse isgently restrained, and the distal half of the tail is immersedin water maintained at 49.0 ± 0.2°C with an immersion circulatorpump (Fisher Isotemp model 71). Latency to reflexive withdrawalof the tail was measured twice by an experimenter to the nearest0.1 s, with each determination separated by 20 s. The two determinationswere later averaged. The tail-withdrawal test was chosen becauseof its stability even after repeated exposures at this highlynoxious water temperature. A cutoff latency of 15 s was used toprevent the possibility of tissuedamage.

Dose-Response Studies. Immediately after baseline latency assessment, morphine analgesic potency was determined, using cumulative dose-response curvesto reduce the number of mice required. All subjects were injectedwith increasing doses of morphine (0.1, 0.5, 1.0, 2.0, 3.6, 6.5,and 11.7 µg) in succession. Tail-withdrawal latencies were retested15 min after each injection, and subsequent doses of morphinewere administered immediately after withdrawal latency assessmentat each dose. This procedure was repeated until each mouse displayeda cutoff tail-withdrawal latency average of >15s.

Data Analysis. Analgesia at each dose was expressed as a percentage of the maximum possible effect (%MPE) as calculated by the formula: %MPE= [(postmorphine latency $-$ baseline latency)/(cutoff latency $-$ baseline latency)] × 100. The use of %MPE takes into account thecutoff latency and individual baseline latencies, so these willnot bias the quantification ofanalgesia.

Two-way ANOVA was used to examine the main effects of strain and sex, and their interaction, on tail-withdrawal baseline latencies.Student's t test was used for pairwise comparisons between sexwithin each strain. The morphine dose-response data (%MPE values)were analyzed using the BLISS-21 computer program. This programmaximizes the log-likelihood function to fit a parallel set ofgaussian sigmoid curves to the dose-response data and providesAD₅₀ values, 95% confidence intervals (CIs), and estimates ofrelative potency (Umans and Inturrisi, 1981

). To evaluate thegenetic codetermination between thermal nociceptive sensitivityand morphine analgesia, baseline withdrawal latencies and morphineAD₅₀ strain means were correlated using Pearson's r statistic.Variances of strain mean AD₅₀ values between sex were also comparedusing a two-tailed F test. In all statistical tests, a criterion $alpha$ level of .05 wasused.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

Baseline Sensitivity on Tail-Withdrawal Test. Baseline tail-withdrawal latencies for all strains, between and across sex, are presented in Table 1. There was a highlysignificant main effect of strain (P < .001) and of sex (P < .001),and the interaction between strain and sex approached significance(P = .084). Indeed, pairwise comparisons of sex for each strainindicate that in three strains, AKR, C3H/He, and C57BL/6, malesexhibited significantly higher baseline tail-withdrawal latenciesthan their female counterparts, reflecting lower nociceptive sensitivity.Thus, sex differences in baseline sensitivity on the tail-withdrawaltest are genotype dependent. One-way ANOVAs performed on baselinewithdrawal latencies for each sex indicate a significant effectof strain in both males (F_10,75 = 5.90, P < .001) and females(F_10,72 = 12.02, P < .001), although strain rank order sensitivitywas not identical.

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TABLE 1
Nociceptive sensitivity and morphine analgesia in male and female mice of 11 inbred mouse strains

Supraspinal Morphine Analgesia. Cumulative dose-response curves for all strains collapsed across sex are presented in Fig. 1, with corresponding AD₅₀ estimates(micrograms per mouse) and 95% CIs presented in Table 1. We observeda wide range of potency estimates between strains, confirmingthe relevance of genetic background on morphine analgesic sensitivity.Figure 1 also shows cumulative dose-response curves for all strainsseparately by sex. The larger strain variability apparent forfemale mice is reflected in the corresponding AD₅₀ estimates foreach sex in Table 1. For example, although the largest differencein morphine analgesic potency in males (approximately 14-fold)is observed between the C3H/He and SJL strains, a 41-fold differencein morphine potency distinguishes CBA and SWR females. Subjectingthe ratio of the variances to an F test confirmed that this variabilitybetween strain AD₅₀ estimates in females was significantly greaterthan that in males (F_10,10 = 3D 12.5, P < .001).

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Fig. 1. Morphine analgesia dose-response relationships of male and female mice of 11 inbred strains. All mice (n = 9-10/sex/strain) were tested for baseline nociceptive sensitivity on the 49°C tail-withdrawal assay and then injected i.c.v. with progressively higher doses of morphine (see text). Symbols represent strain mean percentages of the %MPE at each cumulative dose. Top, data from males and females combined. Middle, data from males only. Bottom, data from females only. Error bars were omitted for clarity; S.E.M. values can be found in Fig. 2.

Figure 2 displays pairwise sex comparisons of morphine analgesic potency for each strain, with derived AD₅₀ estimates presentedin Table 1. In three strains (AKR, C57BL/6, and SWR), males exhibitedsignificantly lower morphine AD₅₀ values relative to their femalecounterparts. Calculated potency ratios (female AD₅₀/male AD₅₀)reveal an approximately 6.9-, 3.6-, and 3.5-fold increase in morphineanalgesic sensitivity for male AKR, C57BL/6, and SWR males relativeto females, respectively. Conversely, female CBA mice displayedan approximately 5.5-fold increase in analgesic sensitivity tomorphine relative to males of this strain. Thus, in the majorityof strains tested, there were no significant sex differences inmorphine analgesic potency, nor were males exclusively more sensitivethan females when sex differences were observed.

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Fig. 2. Sex differences in supraspinal morphine analgesia on the 49°C tail-withdrawal assay in 11 inbred mouse strains (n = 9-10/sex/strain). Symbols ( $black-triangle$ , males; $open circle$ , females) represent strain mean percentages (±S.E.M.) of the %MPE at each cumulative dose. Significant male > female sex differences were found in AKR, C57BL/6, and SWR strains. Significant female > male sex differences were found in the CBA strain.

We observed negative correlations between baseline tail-withdrawal latencies and morphine AD₅₀ values for all strains acrosssex (r = $-$ 0.61) and for males (r = $-$ 0.40) and females (r = $-$ 0.68)alone, confirming in females the inverse relationship betweeninitial nociceptive sensitivity and morphine analgesia previouslyreported for males (Mogil et al., 1996a

; Elmer et al., 1997

A separate experiment performed on AKR and CBA mice of both strains, in which seven repeated i.c.v. injections of saline weremade, revealed an expected but modest (1-2 s) anesthesia/injection-relatedanalgesia (data not shown). Importantly, this analgesia did notincrease in magnitude with injection number and was statisticallyindistinguishable in both sexes and strains. Thus, it is veryunlikely that our conclusions are confounded by sex or genotypedifferences in stressanalgesia.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

The present findings clearly demonstrate that sex differences in morphine analgesia are genotype dependent. Although in themajority of the strains examined, there was no significant sexdifference in the AD₅₀ estimate for morphine analgesia, significantlygreater analgesic potency was observed in male AKR, C57BL/6, andSWR mice relative to their female counterparts. The lack of sexdifferences in most strains may truly reflect the absence of suchdifferences in these genotypes or our lack of statistical powerto detect differences of modest magnitude. The present findingthat female CBA mice were approximately 5.5-fold more sensitiveto the analgesic effects of morphine than were males of this strainhighlights the importance of genetic background on not only themagnitude but also the direction of sexdifferences.

That genotype should have an impact on sex differences in morphine analgesia is consistent with previous reports that haveconsidered sex as a variable in genetic models of exogenous µreceptor-mediated analgesia in rats (Kasson and George, 1984)and mice (Kest et al., 1995). To our knowledge, sex differencesin morphine analgesia have without exception been examined incommercially available outbred strains of rats and mice. Largephenotypic differences of relevance to analgesia have been documentedbetween different outbred strains and even between populationsof the same outbred strain maintained in different breeding institutions(i.e., vendor effects) (Mogil et al., 1996b). We suggest thatvariability in genetic background, perhaps acting in concert withother variables (see the introductory paragraphs), may have contributedto some of the conflicting findings in the literature on sex differencesin both basal nociceptive sensitivity and opioid analgesia. Todirectly investigate this possibility, the testing of common outbredstrains would be required. We instead chose to investigate onlyinbred mouse strains, the rodent populations of greatest use forgene-mapping efforts that may shed light on the responsible mechanisms(seebelow).

It is difficult to assess the accuracy of our AD₅₀ estimates because there are virtually no instances in the literature inwhich the inbred mouse strains tested here were administered morphineby the i.c.v. route. In the one experiment, to our knowledge,in which more than one of these strains were used, Frigeni etal. (1981) obtained morphine AD₅₀ estimates in male DBA/2 andC57BL/6 mice of 0.21 and 0.82 µg, respectively. These values cannotbe easily compared with the values obtained presently (0.36 and2.02 µg, respectively) because these investigators used a differentnociceptive assay, the 51.5°C hot-plate test. It is notable, however,that the potency ratio between these strains from their and ourstudies are comparable (4.0 and 5.6, respectively). Also engenderingconfidence in the accuracy of the presently obtained data is thehighly significant correlation (r = 0.87, P = .005, eight commonstrains) between baseline latencies of male mice in the presentstudy and in a separate study conducted 1 year earlier in a differentlaboratory (Mogil et al., 1998).

Proposed Mechanisms Underlying Sex Differences in Morphine Analgesia. One obvious possibility is that morphine bioavailability might differ between the sexes. Higher concentrations of morphinein the brains of male rodents relative to females have been observedafter systemic injection in some (Candido et al., 1992; Craftet al., 1996) but not other (Cicero et al., 1996, 1997) studies.The present demonstration of sex differences in morphine potencyafter i.c.v. administration in mice, as previously reported inrats (Kepler et al., 1989), argues against an exclusive role forpharmacokinetics in accounting for the differential analgesicresponse of males and females tomorphine.

Other investigations have attempted to relate sex differences in opioid analgesia to opioid pharmacodynamic factors. For example,sex differences in the immunoreactive density of the endogenousopioid peptides leu- and met-enkephalin (and their proteolyticenzymes) (Kavaliers and Innes, 1993

), which can affect morphinepotency (Vaught and Takemori, 1979

), have been demonstrated inthe rat (Watson et al., 1986

). With respect to opioid receptors,no consistent sex differences in µ or $delta$ opioid receptor populationsare observed in rats (Kepler et al., 1991

). In mice, both increasedlevels in males (Mogil et al., 1994

) and no differences (Candidoet al., 1992

) in whole-brain opioid binding between sexes havebeen reported. The disconnection between analgesia and receptordensity is well evidenced by the fact that male mice exhibit asignificantly greater morphine analgesic supersensitivity thanfemales after chronic treatment with the opioid antagonist naltrexonedespite the absence of sex differences in the magnitude of opioidreceptor up-regulation (Candido et al., 1992

Attempts have also been made to relate sex differences in opioid analgesia to gonadal hormone levels of male and female rodents.Although female rats are reported to display greater analgesicsensitivity to systemic morphine on the mornings of diestrus (Banarjeeet al., 1983

) and proestrus (Banarjee et al., 1983

; Berglund andSimpkins, 1988

), Kepler et al. (1989)

reported a relative decreasein sensitivity during met/diestrus. Studies with gonadectomizedsubjects are even more conflicting. For example, although it appearsthat the effect of adult ovariectomy on morphine analgesia maybe nociceptive modality specific (Baamonde et al., 1989

; Ali etal., 1995

), reductions (Banarjee et al., 1983

; Kepler et al.,1989

), increases (Kasson and George, 1984

), and no alterations(Cicero et al., 1996

) in morphine analgesia have all been reportedjust for the tail-withdrawal test. Like females, the analgesicpotency of systemic morphine in castrated adult rats (Chatterjeeet al., 1982

; Kasson and George, 1984

; Ali et al., 1995

; Ciceroet al., 1996

) and mice (Candido et al., 1992

; Ali et al., 1995

)is dependent on the nociceptive modality tested, and contradictoryfindings are reported within the same assay (tail-withdrawal test)for rats (Chatterjee et al., 1982

; Kasson and George, 1984

; Ciceroet al., 1996

Finally, sex differences have been noted in other neurochemical systems that have an impact opioid analgesia. For example,there is evidence indicating that N-methyl-D-aspartate-sensitiveexcitatory amino acid receptors mediate morphine analgesia butthat selective N-methyl-D-aspartate receptor blockade significantlyreduces morphine analgesia in males only (Lipa and Kavaliers,1990

). Sex differences in the antiopioid effects of the endogenouspeptides Tyr-MIF-1 and neuropeptide FF on morphine analgesia inmice have also been noted (Kavaliers and Innes, 1992a

). However,the relevance of these findings remains highly speculative. Overall,no clear consensus haso emerged regarding the mechanisms underlyingsex differences in morphineanalgesia.

Application of Gene Mapping Strategies. We believe that further investigation of sex differences in opioid analgesia requires the application of new strategies. Weare attempting to delineate the physiological mechanisms underlyingdifferential opioid analgesic sensitivity between the sexes bymapping the relevant genetic loci by linkage analysis (Landerand Botstein, 1989). This approach, called quantitative traitlocus (QTL) mapping, can reveal chromosomal regions (and, ultimately,genes) associated with continuously distributed traits such asopioid sensitivity. QTL mapping has been successfully used toidentify loci associated with systemic morphine analgesic magnitudeon the hot-plate test using C57BL/6 and DBA/2 progenitors (Belknapet al., 1995). However, several important issues remain unexamined.First, these experiments examined morphine analgesia on the hot-platetest, and we and others have determined that the genetic mediationof this trait is at least partially specific to the nociceptiveassay used (Mogil et al., 1996a; Elmer et al., 1997). Furthermore,the QTLs identified so far are limited to those polymorphic betweenDBA/2 and C57BL/6 mice. Finally, this mapping study consideredonly male mice, and we have provided evidence in two other experimentsfor the existence of sex-specific, pain-relevant QTLs: a locus(containing the $delta$ -opioid receptor gene Oprd1) statistically associatedwith basal nociception on the hot-plate test in male mice only(Mogil et al., 1997a) and a locus on chromosome 8 mediating nonopioidstress-induced analgesia in female mice only (Mogil et al., 1997b).

Therefore, based on the present findings, we have begun a QTL mapping study using AKR and CBA strains as progenitors. The35-fold difference in morphine AD₅₀ values between females ofthese strains should facilitate the identification of QTLs mediatinganalgesic magnitude in this sex (Lander and Botstein, 1989

). Inaddition, the virtually identical AD₅₀ values between males ofthese strains should decrease the probability that the QTLs identifiedwill be highly relevant to males. Given the previous success inidentifying sex-specific QTLs of relevance to pain processing,it seems reasonable to expect that sex differences in morphineanalgesia might also be due at least partially to the action ofseparate genes in each sex. The identification of such genes andtheir protein products may shed further light on inconsistenciesin the existing literature and, more importantly, on mechanismsunderlying the variable actions of this clinically usefuldrug.

	Acknowledgments

We thank Brenda Edwards and her staff for their excellent care of animals and Dr. John K. Belknap for helpful discussionsregarding themanuscript.

	Footnotes

Accepted for publication January 19, 1999.

Received for publication September 4, 1998.

¹ This work was supported by National Institutes of Health Grants DA11394 and DE12735 (to J.S.M.) and Professional Staff Congress/CityUniversity of New York Grant 668648 (to B.K.).

Send reprint requests to: Dr. Benjamin Kest, Department of Psychology (4S-223), The College of Staten Island/City University of New York, 2800 Victory Blvd., Staten Island, NY 10314. E-mail: kest{at}postbox.csi.cuny.edu

	Abbreviations

AD₅₀, half-maximal analgesic dose; %MPE, maximum possible effect; CI, confidence interval; NMDA, N-methyl-D-aspartate; SW, Swiss-Webster; QTL, quantitative trait locus.

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				A. Dahan, B. Kest, A. R. Waxman, and E. Sarton Sex-Specific Responses to Opiates: Animal and Human Studies Anesth. Analg., July 1, 2008; 107(1): 83 - 95. [Abstract] [Full Text] [PDF]

				X. Wang, R. J. Traub, and A. Z. Murphy Persistent pain model reveals sex difference in morphine potency Am J Physiol Regulatory Integrative Comp Physiol, August 1, 2006; 291(2): R300 - R306. [Abstract] [Full Text] [PDF]

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				M. L. Chanda and J. S. Mogil Sex differences in the effects of amiloride on formalin test nociception in mice Am J Physiol Regulatory Integrative Comp Physiol, August 1, 2006; 291(2): R335 - R342. [Abstract] [Full Text] [PDF]

				C. D. Cook and M. D. Nickerson Nociceptive Sensitivity and Opioid Antinociception and Antihyperalgesia in Freund's Adjuvant-Induced Arthritic Male and Female Rats J. Pharmacol. Exp. Ther., April 1, 2005; 313(1): 449 - 459. [Abstract] [Full Text] [PDF]

				A. C. Barrett, E. S. Smith, and M. J. Picker Capsaicin-Induced Hyperalgesia and {micro}-Opioid-Induced Antihyperalgesia in Male and Female Fischer 344 Rats J. Pharmacol. Exp. Ther., October 1, 2003; 307(1): 237 - 245. [Abstract] [Full Text] [PDF]

				E. H. Kamp, R. C. W. Jones III, S. R. Tillman, and G. F. Gebhart Quantitative assessment and characterization of visceral nociception and hyperalgesia in mice Am J Physiol Gastrointest Liver Physiol, March 1, 2003; 284(3): G434 - G444. [Abstract] [Full Text] [PDF]

				S. G. Wilson, S. B. Smith, E. J. Chesler, K. A. Melton, J. J. Haas, B. Mitton, K. Strasburg, L. Hubert, S. L. Rodriguez-Zas, and J. S. Mogil The Heritability of Antinociception: Common Pharmacogenetic Mediation of Five Neurochemically Distinct Analgesics J. Pharmacol. Exp. Ther., February 1, 2003; 304(2): 547 - 559. [Abstract] [Full Text] [PDF]

				W. R. Lariviere, E. J. Chesler, and J. S. Mogil Transgenic Studies of Pain and Analgesia: Mutation or Background Genotype? J. Pharmacol. Exp. Ther., April 12, 2001; 297(2): 467 - 473. [Abstract] [Full Text]

				J. S. Mogil The genetic mediation of individual differences in sensitivity to pain and its inhibition PNAS, July 6, 1999; 96(14): 7744 - 7751. [Abstract] [Full Text] [PDF]

Sex Differences in Supraspinal Morphine Analgesia Are Dependent on Genotype1

Sex Differences in Supraspinal Morphine Analgesia Are Dependent on Genotype¹