Analgesic Synergy between Topical Lidocaine and Topical Opioids

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Vol. 295, Issue 2, 546-551, November 2000

Analgesic Synergy between Topical Lidocaine and Topical Opioids¹

Yuri A. Kolesnikov, Igor Chereshnev and Gavril W. Pasternak

The Departments of Anesthesiology (Y.A.K.) and Neurology (I.C., G.W.P.), Memorial Sloan-Kettering Cancer Center, New York, New York

	Abstract

Top Abstract Introduction Materials and Methods Results Discussion References

Topical drugs avoid many of the problematic side effects of systemic agents. Immersion of the tail of a mouse into a solutionof dimethyl sulfoxide (DMSO)-containing morphine produces a dose-dependent,naloxone-sensitive, analgesia (ED₅₀ 6.1 mM; CL 4.3, 8.4) limitedto the portion of the tail exposed to the drug. DMSO alone inthis paradigm had no analgesic activity. Like morphine, the opioidslevorphanol (ED₅₀ 5.0 mM; CL 3.8, 7.8) and buprenorphine (ED₅₀1.1 mM; CL 0.7, 1.5) were effective topical analgesics. Lidocainealso was active in the tail-flick assay (ED₅₀ 2.5 mM; CL 2.0,3.4), with a potency greater than morphine. As expected, the freebase of lidocaine was more potent than its salt. Combinationsof a low dose of lidocaine with a low dose of an opioid yieldedsignificantly greater than additive effects for all opioids tested.Isobolographic analysis confirmed the presence of synergy betweenlidocaine and morphine, levorphanol and buprenorphine. These studiesdemonstrate a potent interaction peripherally between opioidsand a local anesthetic and offer potential advantages in the clinicalmanagement ofpain.

	Introduction

Top Abstract Introduction Materials and Methods Results Discussion References

Topical treatments offer many advantages over systemic drugs. By limiting the exposure of a drug to the periphery, centralside effects can be markedly reduced. For opioids, this mightdecrease limiting side effects, such as sedation, respiratorydepression, and nausea. Further limiting the drug to the actualsite of action has even more advantages, by avoiding peripherallymediated side effects, such as constipation. In earlier studies,we demonstrated the activity of topical morphine in the radiantheat tail-flick assay after immersion in a dimethyl sulfoxide(DMSO) solution (Kolesnikov and Pasternak, 1999a). The analgesicactions seen with topical morphine were limited to the regionof the tail exposed to the drug and were not seen in more proximalareas not exposed to the drug. DMSO alone was inactive in thisparadigm. Other opioid ligands acting through kappa and deltareceptors have activity peripherally in the radiant heat tail-flickassay as well (Kolesnikov et al., 1996a; Kolesnikov and Pasternak,1999b). Thus, topical opioids might be useful in paincontrol.

Synergy is important in opioid action. First described between supraspinal and spinal sites (Yeung and Rudy, 1980), it hasalso been described between brainstem nuclei (Rossi et al., 1993)and between peripheral and central sites (Kolesnikov et al., 1996b).Synergy has been observed between opioids of different classes(Horan et al., 1992; Adams et al., 1993; Rossi et al., 1994; Heand Lee, 1998).

Opioid actions also can be modulated by nonopioid classes of drugs. For example, opioid tolerance can be prevented or reversedby N-methyl-D-aspartate (NMDA) antagonists (Trujillo and Akil,1991; Ben-Eliyahu et al., 1992; Tiseo and Inturrisi, 1993; Elliottet al., 1994) and nitric oxide synthase inhibitors (Kolesnikovet al., 1992, 1993). Unfortunately, NMDA antagonists have provendifficult to use systemically due to their profound psychomimeticand dysphoric actions. These problems might be avoided by a topicalapproach. We were able to demonstrate in our topical paradigmthat the combination of an NMDA antagonist with an opioid blockedtolerance to the opioid (Kolesnikov and Pasternak, 1999a,c). Thisactivity of NMDA antagonists topically presumably would avoidthe limiting side effects that preclude their usesystemically.

Lidocaine, a local anesthetic, is active topically, by blocking sodium channels, a mechanism distinct from the opioids (Woosleyand Funck-Brentano, 1988). Clinical studies have shown advantagesto the combination of intrathecal lidocaine and opioids (Atanassoffet al., 1997; Saito et al., 1998a,b), leading us to question whethersimilar advantages might be seen topically. We therefore haveexamined the activity of topical lidocaine in the tail-flick assayalone and in combination with a number ofopioids.

	Materials and Methods

Top Abstract Introduction Materials and Methods Results Discussion References

Male Crl:CD-1(ICR)BR mice (25-30 g; Charles River Breeding Laboratory, Bloomington, MA) were maintained on a 12-h light/darkcycle with food and water available ad libitum. Mice were housedin groups of five until testing. Opioids were generously providedby the Research Technology Branch of the National Institute onDrug Abuse (Rockville, MD). Lidocaine was purchased from SigmaChemical Co. (St. Louis, MO). Lidocaine base was used in all experimentsunless indicatedotherwise.

Topical Administration. Drugs were administered topically and analgesia assessed as previously described (Kolesnikov and Pasternak, 1999a). In thisprocedure, the distal portion of the tail (2-3 cm) is immersedin a DMSO solution containing the indicated drugs for the statedtime, typically 2 min (Kolesnikov and Pasternak, 1999a). Priorstudies have documented that DMSO alone has no effect when testedin this manner in the radiant heat tail-flick assay (Kolesnikovand Pasternak, 1999a). Furthermore, DMSO provides an effectiveway of solubilizing a wide range of drugs and facilitating theirtransport through the skin. The onset of analgesia is rapid, withpeak effects seen immediately after the removal of the tail fromthe treatment solution. Therefore, we tested animals immediatelyafter termination of topicaladministration.

Radiant Heat Tail-Flick Test. Testing was performed on the portion of the tail immersed in the treatment solution, because the analgesic actions of agentsadministered in this manner are restricted to the exposed portionsof the tail; proximal regions are not affected (Kolesnikov andPasternak, 1999a). Antinociception, or analgesia, was definedquantally as a tail-flick latency for an individual animal thatwas twice its baseline latency or greater. Baseline latenciestypically ranged from 2.5 to 3.0 s, with a maximum cutoff latencyof 10 s to minimize tissue damage in analgesic animals. Groupcomparisons were performed with the Fisher's exact test. ED₅₀values were determined with the Bliss program (Finney, 1976; Umansand Inturrisi, 1981), as previously reported (Kolesnikov et al.,1999a).

Drug Interactions. Isobolographic analysis was used to determine drug interactions (Talaradia et al., 1997). ED₅₀ values were determined foreach agent alone. They were then tested together at various dosesat a constant ratio based on their respective ED₅₀ values. Inthe figures, all points represent ED₅₀ values. Values on the axesrepresent the ED₅₀ values for the indicated drug alone, and theline connecting them corresponds to simple additive interactions.Points lying below the line of additivity indicate synergism.Significance was assumed by the lack of overlap of the confidencelimits of the combination value with the confidence limits ofthe line ofadditivity.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

Topical Lidocaine and Morphine Interactions. First, we assessed the activity of topical lidocaine using the same administration paradigm previously shown active for opioidsand NMDA antagonists (Kolesnikov and Pasternak, 1999a). Earlierstudies emphasized the importance of exposure time in the activityof morphine. Similarly, the analgesic response to lidocaine wasdependent on the exposure time (Fig. 1A). The response from aconstant concentration of lidocaine increased from 20% at 30 sto 70% at 2 min. Time action curves revealed a maximal responseimmediately after removal of the tail from the solution, witha gradual decrease to baseline levels within 20 min (Fig. 1B).This response was slightly shorter in duration than a morphinedose giving the same maximal response. A lower lidocaine dosegave both a decreased maximal response and a shorter durationof action.

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Fig. 1. Time dependence of topical lidocaine analgesia. A, groups of mice (n $>=$ 10) were exposed to a fixed concentration of topical lidocaine (4.3 mM) for 30 s, 1 min, and 2 min and then were tested in the tail-flick assay immediately after termination of drug exposure. B, groups of mice (n $>=$ 10) were treated with lidocaine (4.3 or 2.15 mM) or morphine (15 mM) for 2 min and then tested in tail-flick assay at the indicated time over 30 min.

Both the free base and salt of lidocaine were examined (Fig. 2). Both were active, but the salt was less effective and plateauedat a 50% to 60% response. As expected, the free base form of lidocainewas more active, achieving a 75% response. However, it displayeda biphasic dose-response curve, with increases in concentrationbeyond 20 mM revealing a progressive lowering of analgesic activity.Morphine also was active, as previously reported (Kolesnikov andPasternak, 1999a

), with a potency intermediate between the twoforms of lidocaine (Table 1). The antagonist naloxone given alonewas without effect.

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Fig. 2. Effects of topical lidocaine and morphine. Groups of mice (n $>=$ 10) were exposed to the indicated concentration of the free base of lidocaine, lidocaine HCl, or morphine for 2 min and tested immediately afterward.

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TABLE 1
Analgesic potency of lidocaine and opioids alone and in combination
ED₅₀ values were determined from dose-response curves and presented with 95% confidence limits. For lidocaine, the ED₅₀ value was determined only from the initial portion of the curve. Combinations were also examined using increasing doses of a fixed ratio of the indicated drugs. ED₅₀ values were determined and presented with the 95% confidence limits. The relative potency of the various drugs in combination were compared with the same drug alone as a ratio. The fixed ratios were as follows: lidocaine/morphine, 0.5; lidocaine/buprenorphine, 2.4; lidocaine/levorphanol, 0.5.

Initially we assessed potential interactions between lidocaine and morphine using a fixed, low dose of each (Fig. 3A). Alone,lidocaine and morphine produced peak responses of only 20%. Together,their peak response was 80%, far greater than anticipated fromsimple additive interactions (P < .004). Comparing the areas underthe curve gave even more dramatic differences. As anticipated,naloxone (1 mg/kg, s.c.), given 20 min before agonist treatment,completely reversed the effects of the combination (data not shown).

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Fig. 3. Topical lidocaine and morphine interactions. A, groups of mice received either topical morphine (1.5 mM; n = 10) or lidocaine (0.9 mM; n = 10) alone or both together (n = 20). The combination was significantly (P < .004) more active at peak effect than the sum of two individual agents. B, using a fixed lidocaine/morphine ratio of 0.5, the ED₅₀ value of combination was determined with the 95% confidence limits. The presence of the ED₅₀ value below the line of additivity indicates the presence of synergy, confirmed by the lack of overlap between the 95% confidence limits for the drugs.

To further assess the possibility of synergy, we next employed isobolographic analysis (Tallarida et at., 1997

). A dose-responsecurve was generated using increasing doses of a fixed ratio oflidocaine/morphine. The ED₅₀ value fell well below the line ofadditivity, indicating synergism (Fig. 3B). The lack of overlapof the confidence limits of the combination value with those ofthe line of additivity confirmed itssignificance.

We also explored the relationship of lidocaine and morphine combinations by defining the ED₅₀ values of each agent alone andin combination with a fixed dose of the other rather than a ratio(Table 2). Low doses of morphine with little activity alone markedlyenhanced the potency of lidocaine. The effect seemed to plateau,with little advantage seen by increasing the morphine concentrationfrom 3 to 4.5 mM. Similar results were seen with the morphinedose-response curves. Again, a low dose of lidocaine facilitatedmorphine analgesia, with little additional effect seen after doublingthe lidocaine concentration from 0.9 to 1.8 mM. Thus, the enhancedactivity of the combination of the drugs was most evident at lowconcentrations of each.

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TABLE 2
Effects of fixed doses of morphine or lidocaine on the others analgesic potency
ED₅₀ values with 95% confidence limits were determined from at least three doss of topical lidocaine alone or with the indicated morphine concentration, or with topical morphine alone or with the indicated concentration of lidocaine.

Topical Lidocaine and Other Opioids. We next explored whether the synergy seen with morphine/lidocaine combinations extended to other opioids with other receptormechanisms of action, including levorphanol and buprenorphine.Topically, levorphanol and buprenorphine both yielded full analgesicresponses, with ED₅₀ values of 5.0 and 1.1 mM, respectively (Fig.4; Table 1).

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Fig. 4. Effects of topical buprenorphine and levorphanol. Groups of mice (n $>=$ 10) were exposed to the indicated concentration of the drug for 2 min and were tested immediately afterward.

Combinations of low doses of lidocaine and these opioids gave greater than additive analgesic actions (Fig. 5). The resultswith levorphanol closely resembled those of morphine, with thecombination of low lidocaine and levorphanol doses giving a maximalresponse far beyond that expected by simple additive interactions(P < .03) as well as a prolonged duration far exceeding that ofeither alone (Fig. 5A). Although each drug alone had no effectbeyond 5 min, together their response lasted for greater than20 min. The effects of the combination of doses were readily antagonizedby naloxone. The response to lidocaine alone (2.5 mM) was insensitiveto naloxone (1 mg/kg, s.c.). (Data not shown.)

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Fig. 5. Effects of combinations of low doses of opioids with lidocaine. A, groups of mice (n = 20) received either topical lidocaine (0.9 mM) or levorphanol (1.8 mM) or the combination of the two for 2 min and were tested in the tail-flick assay over 30 min. Another group of mice (n = 10) received naloxone (1 mg/kg, s.c.) 20 min before the topical drug application and was tested in tail-flick assay. Naloxone significantly reduced the response. B, groups of mice (n = 20) received either topical lidocaine (0.9 mM) or buprenorphine (0.5 mM) or the combination of the two for 2 min and then were tested in the tail-flick assay over 60 min. Another group of animals received naloxone (1 mg/kg, s.c.) 20 min before the topical drug application. Naloxone significantly reduced the response.

Buprenorphine and lidocaine gave similar results. The maximal responses of the two together were far beyond those anticipatedby simple additive interactions (Fig. 5B). The duration of theresponse of the combination also markedly differed from that ofeither agent alone. Alone, each drug lasted less than 10 min.In contrast, the duration of the response of the combination wasquite prolonged. The peak effect of the combination was 80% andpersisted for 10 min. Analgesia could still be demonstrated after45 min. Indeed, the duration of the response from the lidocaine/buprenorphinecombination exceeded that seen with any of the other opioids tested.Naloxone significantly lowered the response of thecombination.

Isobolographic Analysis of Lidocaine/Opioid Interactions. We next examined the combinations of the additional opioids isobolographically using dose-response curves with fixed ratiosof the two drugs in combination (Fig. 6; Table 1). Combininglevorphanol with lidocaine enhanced their relative potencies over5-fold, which was more than the enhancement of morphine by lidocaine.Isobolographic analysis was consistent with synergy (Fig. 6A).Buprenorphine and lidocaine together shifted their individualED₅₀ values approximately 6-fold. Again, isobolographic analysisindicated synergy (Fig. 6B).

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Fig. 6. Isobolographic analysis of lidocaine interactions with levorphanol and buprenorphine. A, using a fixed lidocaine/levorphanol ratio of 0.5, the ED₅₀ value of the combination with the 95% confidence limits was determined from the dose-response curve. The point falls below the theoretical line of additivity between the ED₅₀ values for each drug alone, indicating synergy. The lack of overlap between the 95% confidence limits for the drugs alone and the combination implies the synergy is significant. B, using a fixed lidocaine/buprenorphine ratio of 2.4, the ED₅₀ value of the combination with the 95% confidence limits was determined from the dose-response curve. The point falls below the theoretical line of additivity between the ED₅₀ values for each drug alone, indicating synergy. The lack of overlap between the 95% confidence limits for the drugs alone and the combination implies the synergy is significant.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

Lidocaine is a widely used local anesthetic (Woosley and Funck-Brentano, 1988). It acts through the blockade of sodium channels,a mechanism distinct from the opioids. In the current study, lidocainewas effective topically in the radiant heat tail-flick assay,working only on the portion of the tail exposed to the drug andwith a potency greater than morphine. As anticipated, the freebase was more effective than the salt, presumably due to its greaterlipophilicity. However, its dose-response curve was biphasic,with concentrations greater than 20 mM giving a progressive decreasein response. The reasons for this are not clear, but it is interestingthat lidocaine concentrations above 15 mM can be toxic to neuronsin primary culture (Gold et al., 1998).

All of the opioids tested were effective topical analgesics. The activity of levorphanol and buprenorphine extends the activityto drugs working on opioid systems other than simply mu receptors.Levorphanol elicits analgesia through both mu and kappa₃ receptors(Moulin et al., 1988; Tive et al., 1992). Buprenorphine has acomplex mechanism of action that is not entirely clear (Leander,1987; Kamei et al., 1995a,b, 1997; Walker et al., 1995). Althoughit has high affinity for virtually all classes of opioid receptorsin binding studies, it also has widely varying efficacies forthe various classes of receptors. Topically, buprenorphine wasparticularly effective, with a potency 5-fold greater than thatof morphine. The limited ability of naloxone to reverse the combinationof buprenorphine and lidocaine implies that at least a portionof the response from buprenorphine was evoked from non-mu-opioidreceptors.

Opioid analgesic synergy has been well established. Initially, it was observed among regions simultaneously exposed to opioid(Yeung and Rudy, 1980; Rossi et al., 1993, 1994; Kolesnikov etal., 1996b), followed by the demonstration of synergy betweendifferent classes of opioids (Adams et al., 1993). Morphine alsohas been reported to demonstrate synergy with lidocaine centrally(Saito et al., 1998a,b). We now find synergy peripherally betweentopical opioids and a localanesthetic.

The combination of a low dose of morphine and lidocaine clearly revealed activity far beyond simple additive interactions,as did similar studies with the other opioids. These stronglysuggested synergy among the opioids with lidocaine. This was notunexpected. Synergistic interactions might be more likely whendrugs act on different mechanisms, as shown here with the opioidsand lidocaine. Isobolographic analysis confirmed synergy betweenlidocaine and the opioids. The most impressive interaction wasbetween buprenorphine and lidocaine, which had the greatest potentiationand the longest duration of action. However, it is not clear whetherthis resulted from its receptor selectivity or other factors suchas its greater lipophilicity, which would enhance its abilityto become diffused through theskin.

The demonstration of synergy between lidocaine and more than one opioid receptor ligand deserves more study. It will be ofinterest to define the opioid receptor mechanisms involved moreclearly. However, even without a full understanding of how theseagents interact, the demonstration of topical synergy betweena local anesthetic and opioids opens many clinical possibilitiesin painmanagement.

	Footnotes

Accepted for publication June 28, 2000.

Received for publication April 17, 2000.

¹ This work was supported, in part, by a research grant (DA07241) and a Senior Scientist Award (DA00220) (to G.W.P.) and a MentoredScientist Award (DA00405) (to Y.A.K.) from the National Instituteon Drug Abuse, as well as a core grant (CA08748) from the NationalCancer Institute and a grant from EpiCeptCorporation.

Send reprint requests to: Gavril W. Pasternak, M.D., Ph.D., Department of Neurology, Memorial Sloan-Kettering Cancer Center, 1275 York Ave., New York, NY 10021. E-mail: pasterng{at}mskmail.mskcc.org

	Abbreviations

DMSO, dimethyl sulfoxide; NMDA, N-methyl-D-aspartate; CL, confidence limits.

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Analgesic Synergy between Topical Lidocaine and Topical Opioids1

Analgesic Synergy between Topical Lidocaine and Topical Opioids¹