Muscle pain perception and sympathetic nerve activity to exercise during opioid modulation

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Muscle pain perception and sympathetic nerve activity to exercise during opioid modulation

Dane B. Cook¹, Patrick J. O'Connor², and Chester A. Ray³

¹ Departments of Neuroscience and Anesthesiology, University of Medicine and Dentistry of New Jersey-New Jersey Medical School, Newark, New Jersey 07107-3000; ³ Departments of Medicine and Cellular and Molecular Physiology, Pennsylvania State University College of Medicine, Hershey, Pennsylvania 17033; and ² Department of Exercise Science, University of Georgia, Athens, Georgia 30602-6554

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

The purpose of this experiment was to examine the effects of the endogenous opioid system on forearm muscle pain and musclesympathetic nerve activity (MSNA) during dynamic fatiguing exercise.Twelve college-age men (24 ± 4 yr) performed graded (1-min stages;30 contractions/min) handgrip to fatigue 1 h after the ingestionof either 60 mg codeine, 50 mg naltrexone, or placebo. Pain (0-10scale) and exertion (0-10 and 6-20 scales) intensities were measuredduring the last 15 s of each minute of exercise and every 15 sduring recovery. MSNA was measured continuously from the peronealnerve in the left leg. Pain threshold occurred earlier [1.8 ±1, 2.2 ± 1, 2.2 ± 1 J: codeine, naltrexone, and placebo, respectively]and was associated with a lower rating of perceived exertion (RPE)(2.7 ± 2, 3.6 ± 2, 3.8 ± 2: codeine, naltrexone, and placebo,respectively) in the codeine condition compared with either thenaltrexone or placebo conditions. There were no main effects (i.e.,drugs) or interaction (i.e., drugs × time) for either forearmmuscle pain or RPE during exercise [pain: F (2, 22) = 0.69, P= 0.51]. There was no effect of drug on MSNA, heart rate, or bloodpressure during baseline, exercise, or recovery. Peak exerciseMSNA responses were 21 ± 1, 21 ± 2.0, and 21 ± 2.0 bursts/30 sfor codeine, naltrexone, and placebo conditions, respectively.Peak mean arterial pressure responses were 135 ± 4, 131 ± 3, and132 ± 4 mmHg for codeine, naltrexone, and placebo conditions,respectively. It is concluded that neither 60 mg codeine nor 50mg naltrexone has an effect on forearm muscle pain, exertion,or MSNA during high- intensity handgrip tofatigue.

codeine; rating of perceived exertion; pain perception; autonomic nervous system

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

CERTAIN TYPES OF MODERATE-TO-HIGH intensity exercise are perceived as painful. For example, reproducible relationships betweenobjective measures of exercise intensity and subjective judgmentsof leg and forearm muscle pain intensity during cycle ergometryand rhythmic handgrip have been reported (6, 14). Althoughit is clear that the firing rate of nociceptive afferent fibers(type III and IV) from skeletal muscle is increased in responseto noxious stimuli, including exercise, the mechanisms underlyingmuscle pain during exercise are poorly understood (16, 17).

Endogenous opioids, such as endomorphin, enkephalins, dynorphins, and beta-endorphins have well-established analgesic actions(11, 31, 33), and opioid receptors are found on nociceptiveafferent fibers as well as spinal and supraspinal sites involvedin pain processing. The endogenous opioid system has been demonstratedto modulate nociceptive afferent fiber activity in both animaland human experiments (10, 26). Consequently, endogenous opioidsmay be involved in muscle pain during exercise. Peripheral concentrationsof endogenous opioids consistently have been shown to increaseduring moderate and intense exercise (2, 12, 27). Nevertheless,the role of opioids in naturally occurring muscle pain experiencedduring exercise isunknown.

In addition to their role in pain regulation, endogenous opioids also have been implicated in the modulation of muscle sympatheticnerve activity (MSNA) responses to exercise (8, 22, 23).The opioid antagonist naloxone has been found to either increase(8) or have no effect (23) on MSNA responses to exercise.Specifically, Farrell et al. (8) reported that 1.2 mg intravenousnaloxone significantly increased arterial pressure, plasma epinephrine,and muscle sympathetic nerve responses to 3 min of isometric handgripat 25% maximal voluntary contraction (MVC). However, this findingwas not reproduced by Ray and Pawelczyk (23), who did not observean effect of naloxone on MSNA, arterial pressure, or heart rate.Moreover, preliminary data from Ray et al. (22) showed thatmorphine (0.075 mg/kg bolus+1 mg/h maintenance) resulted in increasedresting mean arterial pressure but had no effect on arterial pressure,heart rate, or MSNA responses to 2 min of isometric handgrip at30% MVC. Thus literature regarding the role of endogenous opioidsin MSNA responses to exercise is both sparse and equivocal. Onelimitation of the studies that have employed a direct measureof sympathetic nervous system activity has been the focus on short-duration(2-3 min), low-intensity (25-30% MVC), isometric exercise thatmay be inadequate to stimulate the endogenous opiatesystem.

The primary purpose of this experiment was to examine, in a double-blind setting, the effects of codeine and naltrexone onthe perception of forearm muscle pain during and after dynamichandgrip performed to fatigue. On the basis of the known influenceof opioids in reducing both the activity of nociceptive afferentfibers and pain, it was hypothesized that the ingestion of codeinewould result in lower pain intensity ratings compared with boththe naltrexone and placebo conditions and that the ingestion ofnaltrexone would result in higher pain ratings compared with boththe codeine and placebo conditions. The rationale for using adynamic handgrip stimulus to fatigue was to 1) achieve longerand more intense exercise sessions, thus increasing the likelihoodof an endogenous opioid response and 2) allow for the measurementof MSNA. Additionally, rhythmic exercise differs from the isometricprotocols employed by previous investigators (8, 23) in thatit does not result in continuous muscle ischemia. A second purposewas to examine the effects of codeine and naltrexone on MSNA duringand after dynamic fatiguing handgrip. It was hypothesized thatthe ingestion of codeine would decrease MSNA responses to exercisecompared with both the naltrexone and placebo conditions and thatnaltrexone would increase MSNA responses to exercise comparedwith both the codeine and placeboconditions.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Participants. A total of 12 college-age (18-35 yr) men who were not on any medication and pain and injury free volunteered to participatein the study. A sample size of 12 provided a statistical powerof 0.76 for the primary question concerning the main effect ofdrug on pain. This value was calculated on the basis of statisticalpower tables for repeated measures designs (19) and with thefollowing assumptions: an alpha level of 0.05; a one-half SD (0.50)for the drug main effect; a correlation across exercise intensity(trials) of 0.6; and a correlation across conditions (codeine,naltrexone, and placebo) of 0.4. All participants signed a consentform approved by the Institutional Review Board at The Universityof Georgia. Selected characteristics (means ± SD) were as follows:age (24 ± 4 yr), height (176 ± 5 cm), and weight (75 ± 9kg).

Procedures. The participants completed three questionnaires: a medical and a 24-h health history, and the multiple affect adjective checklist(MAACL). The 24-h and medical histories were used to inquire aboutthe use of medications and to ensure that the participants werehealthy, injury free, able to perform the maximal exercise test,and not allergic to codeine or naltrexone. None of the participantsreported any forearm muscle soreness before the exercise sessions.The MAACL was employed to examine the potential role of eithercodeine, naltrexone, or placebo on the participant's affectivestate before exercise and to examine possible relationships betweensituational affect and muscle pain during exercise. The 132-itemMAACL provides valid measures of anxiety, depression, hostility,positive affect, and sensation seeking (34). Participants weregiven the MAACL before each exercise session exactly 50 min afteringestion of the placebo or activedrug.

MSNA. MSNA measurements were made as described by Ray et al. (24). Briefly, multiple nerve fiber recordings of MSNA were madeby using a tungsten microelectrode inserted in the peroneal nervenear the head of the fibula. A reference electrode was placedsubcutaneously ~2 cm from the recording electrode. Adjustmentsof the microelectrode were made until a site exhibiting clearspontaneously occurring sympathetic bursts was found. MSNA wasexpressed as burst frequency (bursts/30 s) and total activity(area/30 s). Total activity was the sum of area of all burstsin a given timeperiod.

Arterial pressure and heart rate were measured continuously by using an Ohmeda Finapres recorder (model 2300, Englewood, NJ).The photoplethysmographic cuff was placed on the middle fingerof the nonexercising arm, which was maintained at the level ofthe heart duringtesting.

For each exercise test MSNA, arterial pressure, and heart rate data were obtained before (5 min), during (~14 min), and after(5 min) exercise. In the event that the recording electrode cameout of the nerve, one of the investigators quickly adjusted theelectrode until the MSNA recording was reestablished. This problemoccurred once in only one subject during recovery fromexercise.

Codeine/naltrexone/placebo conditions. In the codeine condition the participants received 60 mg of codeine in one capsule. Studies using similar doses have demonstratedthe analgesic effectiveness of 60 mg of codeine to experimentalpain stimuli (18, 29), whereas others have reported littleor no side effects when a single oral dose is taken (1, 20).The codeine was ingested with 8 oz of water 60 min before exercise,and consumption was witnessed by one of the investigators. Thetiming of drug administration was based on previous reports thatmaximal plasma concentrations of codeine occur ~1 h after a singleoral dose of 60 mg (11, 20). The capsule was identical tothe capsules used in the placebo and naltrexone conditions, aprocedure designed to blind the participant as to the condition.In the naltrexone condition the participants received 50 mg ofnaltrexone in one capsule taken orally. Naltrexone is an opioidantagonist that exhibits no agonist effects. The naltrexone wasadministered with 8 oz. of water 60 min before exercise in a manneridentical to the codeine and placebo condition (lactose capsule).Naltrexone taken orally has a peak plasma concentration within60 min and has been reported to produce sustained effects forup to 24 h from a single oral dose (11). To ensure a double-blindadministration, one investigator, who did not conduct the exercisetests (P. J. O'Connor), distributed the capsules to a second investigator(D. B. Cook). The second investigator, who was unaware of whatthe capsules contained, administered all the capsules and conductedall of the exercise tests. The order in which the participantscompleted the conditions was randomized andcounterbalanced.

Graded handgrip protocol. Each participant completed a minimum of three graded, dynamic handgrip exercise tests to fatigue. The exercise sessions wereperformed on 3 separate days. Before exercise the participantsreceived either codeine, naltrexone, or placebo in a randomized,counterbalanced order. Exercise was performed with the dominanthand while the participants were in a supine position. The dominanthand and arm were extended laterally (60-90° angle) from the bodyand fully supported. Handgrip was performed at a rate of 30 contractions/minwith the aid of a calibrated metronome. The first minute of exercisewas done with no load. For each subsequent 1-min stage, the weightwas increased by 1.13 kg until an exercise stage could not becompleted. The participants were given 15 s of rest every minutewhile one of the investigators added 1.13 kg to the weight-supportbar.

Pain and exertion assessment. Forearm muscle pain intensity was assessed by using a category scale with ratio properties. The pain intensity scale rangesfrom 0 (no pain at all) to 10 (extremely intense pain, almostunbearable). With this scale, if the subjective intensity increasesabove 10, the subject is free to choose any number larger in proportionto 10 that describes the proportionate growth of the sensation.Prior work with this instrument has provided evidence for boththe validity and reliability of this tool for quantifying naturallyoccurring muscle pain during exercise (6).

The participants listened to a taped set of instructions, which informed them that they would be repeatedly asked to ratethe intensity of the pain and exertion in their forearms and thatthey were to report aloud the number that corresponds to thatintensity. Additionally, participants were instructed to rememberto say the word "pain" when the pain in their forearm became justnoticeable (pain threshold). An investigator recorded the minutesand seconds from a digital timer that was started at the beginningof exercise, and this quantified painthreshold.

Ratings of perceived exertion (RPE) were assessed during and after exercise by using Borg's 6-20 category scale (4) afterexplicit audiotaped and oral instructions (cf. 6). Our previouslyemployed instructions were modified to obtain local ratings offorearm muscle exertion. A second scale for measuring perceivedexertion [0-10 category-ratio scale; Borg, (3)] was employedto examine the relationship between ratings of pain and RPE byusing scales that were both based on ratio-scalingmethods.

During the graded exercise test forearm muscle pain and exertion ratings were obtained during the last 15 s of every 1-minexercise stage. At the point of fatigue (i.e., failure to maintaina handgrip contraction rate of 30 repetitions/min), the test wasstopped, and the participants were asked to immediately stop contractingtheir forearm. Pain and exertion ratings were obtained every 15s for 5 min during the recovery period to assess the abatementof pain and exertionperceptions.

Posttest information. Within 5 min after the completion of the exercise test, participants indicated in writing the reason they stopped exercising.Thereafter, they completed the short-form of the McGill Pain Questionnaire(MPQ) (15) to provide a multidimensional description of theforearm muscle pain experienced during the exercisetest.

Primary statistical analyses. Pain ratings, RPE, and MSNA were analyzed by using a two-way [condition (codeine, naltrexone, placebo) × trials] repeated-measuresANOVA. The trials factor ranged from 5 different intensities fordata obtained in association with exercise intensity [20, 40,60, 80, and 100% of peak work (J)] to 20 time points associatedwith recovery (ratings obtained every 15 s for 5 min). When appropriate,eta² was used as a measure of the magnitude of an association amongvariables. Rough guidelines for the strength of association fora given eta² value are that 0.01 is considered a small effect, 0.09 medium,and 0.15 large. Pain threshold, peak pain, and baseline MSNA,arterial pressure, and heart rate among conditions were analyzedby using a one-way repeated-measures ANOVA. Significant main effectswere followed up by simple contrast analysis to further delineatewhere the significant differences occurred. T-tests were usedto analyze baseline MSNA, arterial pressure, heart rate, and selectedpain threshold and peak variables between the control and placeboconditions. Pearson correlations were used to examine relationshipsbetween and among arterial pressure, MSNA, pain, and RPE. Effectsizes (d) were calculated according to the method described byCohen (5) (mean 1 $-$ mean 2/pooled SD) to provide a measureof the magnitude of the differences between selected variables.All table values are expressed as means ± SD, and all graphicvalues are means ±SE.

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Pain threshold. Forearm muscle pain threshold data for codeine, naltrexone, and placebo conditions are presented in Table 1. One-way repeated-measuresANOVA revealed significant main effects for the amount of workcompleted at pain threshold and the perceived exertion using boththe 0-10 and the 6-20 scales. Contrast analysis revealed thatpain threshold was reported at a lower weight and RPE ratingswere lower in the codeine condition compared with both the naltrexoneand placebo conditions.

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Table 1. Measures of exercise intensity at pain threshold for codeine, naltrexone, and placebo conditions

Peak exercise data. Peak exercise data for the codeine, naltrexone, and placebo conditions are shown in Table 2. There were no significant differencesacross conditions for any of the variables measured at peak exercise.Data based on verbal reports obtained postexercise indicated thatsix individuals, in at least one of three exercise tests, stoppedexercising due in part to the pain they felt in their forearms.Overall, pain was a factor in the decision to stop exercisingin 10 of the 36 exercise tests, whereas fatigue was indicatedin 34 of 36 tests (both pain and fatigue were reported by somesubjects).

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Table 2. Peak exercise data

Pain during exercise. Pain intensity ratings at 20, 40, 60, 80, and 100% of peak work (J) are shown in Fig. 1, top. Pain increased as a positivelyaccelerating function of percent peak work (J) during maximalhandgrip exercise [F (2, 22) = 55.7, P < 0.001]. There was nosignificant main effect for condition or interaction.

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Fig. 1. Pain intensity (0-10 scale; top) and rating of perceived exertion [RPE; 0-10 (middle) and 6-20 scales (bottom)] at 20, 40, 60, 80, and 100% of peak work (J) during fatiguing handgrip for codeine, naltrexone, and placebo conditions (n = 12).

Perceived exertion during exercise. Perceived exertion ratings at 20, 40, 60, 80, and 100% of peak work (J) are illustrated in Fig. 1, middle and bottom. Perceivedexertion ratings using both the 0-10 and 6-20 scales increasedas a function of percent peak work (J) [0-10 scale: F (2, 22)= 179.9, P < 0.001; 6-20 scale: F (2, 22) = 455.9, P < 0.001].There were no significant main effects for condition or interactionsfor eitherscale.

Pain and exertion during recovery from handgrip exercise. Pain intensity ratings during recovery from maximal handgrip are shown in Fig. 2. Two-way repeated-measures ANOVA revealedno significant main effect for condition [F (2, 22) = 2.5, P =0.10]; however, a significant interaction was detected [F (38,418) = 1.5, P = 0.026, eta² = 0.12]. The SE bands in Fig. 2 show greater variability in theplacebo condition. Inspection of individual responses revealedone influential subject exhibiting ratings that were >2 SD abovethe group mean at trials 3, 4, and 6-14 in the placebo condition.There were no significant main effects or interactions for RPEduring recovery (0-10 or 6-20 scales).

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Fig. 2. Pain intensity ratings (0-10 scale) during recovery from fatiguing handgrip for codeine, naltrexone, and placebo conditions (n = 12).

MPQ data. MPQ data for the codeine, naltrexone, and placebo conditions are presented in Table 3. There were no differences among theconditions for any of the verbal descriptors chosen to describethe forearm muscle pain, or its intensity, experienced duringmaximal handgrip.

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Table 3. McGill Pain Questionnaire data for codeine, naltrexone, and placebo conditions

Baseline cardiovascular and MSNA data. Preexercise baseline values for MSNA, heart rate, and mean arterial pressure are shown in Fig. 3. MSNA, heart rate, and meanarterial pressure were not significantly different across conditionsbefore exercise.

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Fig. 3. Preexercise baseline values for muscle sympathetic nerve activity (MSNA; frequency: average bursts/30 s; total activity average area/30 s), heart rate (HR; beats/min), and mean arterial pressure (MAP; mmHg) for codeine, naltrexone, and placebo conditions (n = 10).

MSNA, heart rate, and arterial pressure during exercise. MSNA burst frequency (bursts/30 s) and total activity (area/30 s) during handgrip for codeine, naltrexone, and placebo conditionsare illustrated in Fig. 4. MSNA burst frequency increased duringhandgrip exercise [trial main effect: F (4, 44) = 65.1, P < 0.001];however, there was no main effect for condition or interaction.Total MSNA increased during exercise [trial main effect: F (4,44) = 10.6, P < 0.001], but there was no main effect for conditionor interaction. A similar pattern of response, both physiologicallyand in terms of the ANOVA results, was observed for heart rate(peak values: codeine = 136 ± 16, naltrexone = 130 ± 10, placebo= 135 ± 14) and mean arterial pressure (peak values: codeine =79 ± 14, naltrexone = 78 ± 12, placebo = 81 ± 9).

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Fig. 4. MSNA [burst frequency (top) and total activity (bottom)] expressed as percent change from baseline at 20, 40, 60, 80, and 100% of peak work (J) during fatiguing handgrip for codeine, naltrexone, and placebo conditions (n = 12).

MSNA, heart rate, and arterial pressure during recovery from handgrip exercise. No significant main effects or interactions were observed during recovery from maximal handgrip for any of the MSNA, heartrate, or arterial pressuredata.

Selected relationships of interest. A strong negative relationship between forearm muscle pain ratings and systolic arterial pressure at 100% of peak exerciseintensity in the placebo condition was observed (r = $-$ 0.84) andis illustrated in Fig. 5. Correlations between pain ratings andsystolic arterial pressure during submaximal exercise ranged from $-$ 0.27 to 0.17. A significant negative correlation between painand arterial pressure at 100% of peak exercise in the naltrexonecondition was also observed (r = $-$ 0.64), whereas a significantpositive correlation between pain and arterial pressure at 100%of peak exercise (r = 0.74) was observed in the codeine condition.

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Fig. 5. Illustration of the relationship between pain and systolic arterial pressure (SAP) at 100% of peak work (J) in the placebo condition during fatiguing handgrip (n = 12).

Nonsignificant bivariate correlations in the placebo condition indicated that pain was nonsignificantly related to exertion(0-10) during exercise (20% r = 0.25, 40% r = $-$ 0.04, 60% r = 0.06,80%, r = 0.14, 100% r = $-$ 0.02). Relationships between pain andMSNA in the placebo condition also were low and nonsignificant(pain and burst frequency: 20% r = $-$ 0.04, 40% r = $-$ 0.14, 60% r= $-$ 0.44, 80% r = 0.24, 100% r = 0.20; pain and area: 20% r = 0.12,40% r = $-$ 0.22, 60% r = $-$ 0.21, 80% r = $-$ 0.08, 100% r = 0.24).

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The primary findings of the present investigation are that 1) post-pain threshold, neither codeine nor naltrexone alteredthe perception of forearm muscle pain and 2) neither drug hadan effect on MSNA burst frequency or totalactivity.

Muscle pain. The lack of an effect for either codeine or naltrexone on muscle pain during exercise would seem to be at odds with what isknown about type III and IV afferent fiber activity and the rolethat opioids play in regulating their activity. However, it isworth emphasizing that pain is a complex phenomenon that involvesmultiple systems working in parallel to regulate nociceptive activity.The simple act of inhibiting one of the modulatory systems maynot result in an alteration in the subjective experience becauseof the redundancy of the system. Bradykinin, potassium, serotonin,and histamine, all of which have been shown to be released duringexercise (16, 25, 30), act directly on type IV fibers, resultingin an increased firing rate (16). These algesics also sensitizethe type III fibers that respond to the increased intramuscularpressure during exercise (16, 25). There are also a populationof small afferent fibers reported to become active only duringmuscular contractions and that respond linearly to the force ofthe contraction (16). Combined, these algesic mechanisms increasethe likelihood that the afferent nociceptive signal will be transmittedto supraspinal sites that are important in pain perception evenwhen one possible mechanism iseliminated.

The timing of the administration of both drugs was based on reports that peak plasma concentrations of both codeine (and itsO-demethylation to morphine) and naltrexone occur ~1 h after oraladministration (20). We chose a dosage that is double that frequentlyprescribed for mild-to-moderate pain (28). Moreover, we didnot want to exceed 60 mg because it has been reported that codeineadministered at doses above this amount increases the likelihoodof unwanted side effects, which in and of themselves could havealtered pain responses (28). Other researchers consider thedose of naltrexone used in this study to be large (9, 11).Consequently, the naltrexone dose should have been adequate forthe purposes of the present investigation. Thus the present resultssuggest that the endogenous opioid system, particularly the mureceptor-mediated portion, does not play a major role in the perceptionof muscle pain duringexercise.

In accordance with our previous research examining leg muscle pain during maximal cycle ergometry (6), forearm muscle painexperienced during maximal handgrip exercise increased as a functionof the exercise stimulus. Pain threshold in the placebo conditionoccurred on average at ~ 46% (6.6 kg) of the peak exercise intensity(14.3 kg), which is comparable to leg muscle pain threshold (~50%)observed during ramped maximal cycling exercise (6). Peak forearmmuscle pain ratings averaged 8.2 on the 0-10 scale, a value identicalto the average peak leg muscle pain reported in our previous cycleergometry study (6). Moreover, the MPQ verbal descriptors mostfrequently used to describe forearm muscle pain were tiring-exhausting,aching, hot-burning, and cramping pain, which are also the samedescriptors that were used to describe leg muscle pain duringexercise. These results provide additional support for the reliabilityand validity of the 0-10 pain intensity scale used to quantifymuscle pain during exercise. Moreover, these findings suggestthat the intensity and quality of muscle pain experienced duringgraded or ramped maximal exercise tests are similar whether alarge or small muscle mass isemployed.

In the codeine condition, pain threshold occurred earlier and corresponded with lower exertion ratings than both the naltrexoneand placebo conditions. The difference represented about one exercisestage (1.13 kg or 1 min of exercise) and corresponded to a moderateeffect (d = ~0.50) for both comparisons. It is unclear why suchan effect occurred. This effect, however, did not translate intoaltered pain ratings or performance during exercise or alteredpain ratings during recovery. Therefore, simply altering someone'sthreshold for pain detection does not necessarily mean that theindividual will experience changes in pain intensity above painthreshold. This is important because pain threshold is usuallyof little concern in sports. For example, with endurance athletesthe greater concern is how long they can tolerate an intense boutofexercise.

There is a great deal of literature showing relationships between arterial pressure and pain (13, 21). It has been reportedthat both chronic hypertension and acute experimental increasesin arterial pressure are associated with reduced pain sensitivity(13, 21). Experimental stimulation of arterial and cardiopulmonarybaroreceptors (e.g., neck suction, physiological volume expansion,or pharmacological sympathetic stimulation) results in antinociceptivebehavior in both animals and humans (7, 13, 21). Conversely,significant and parallel relationships between the degree of ischemicforearm muscle pain (produced during a submaximal-effort tourniquettest) and arterial pressure have been reported (14).

In the present investigation, there was a significant negative relationship between pain ratings and systolic arterial pressure,but only at the highest exercise intensity (100% of peak exerciseintensity) and only in the placebo and naltrexone conditions.It is unclear why this occurred only at the peak of exercise.This finding does suggest a link between elevated arterial pressureand pain inhibition and is in agreement with previous researchdemonstrating that arterial baroreceptor stimulation inhibitspain in rats and humans (7, 13, 21). However, given oursample size and lack of consistency across conditions, these resultsshould be interpreted with caution. Nevertheless, this observation,were it found to generalize, would have potentially importantclinical implications. For example, it might aid in our understandingand identification of those at risk for "silent" myocardial infarctionsduringexercise.

Perceived exertion. There was no effect of drug on perceived exertion during exercise or in recovery. This is not surprising given the lack ofan effect of drug on the perception of pain and performance. Inour previous work examining pain and exertion during exercise,we chose to employ the Borg 6-20 category scale for the measurementof perceived exertion and a 0-10 category-ratio scale to assesspain. The goal of that research was to determine the extent towhich the constructs of pain and exertion could be differentiatedduring exercise. During the cycle ergometry protocol, perceivedeffort ratings were reported at low exercise intensities, butnaturally occurring leg muscle pain typically did not occur untila moderate intensity of ~ 50% of peak power output was reached.Moreover, leg pain was only moderately related to exertion duringexercise. From that study, it was concluded that pain and exertionwere two separate, albeit related, constructs (6). However,the Borg 6-20 category scale is theoretically and empiricallydistinct from the 0-10 category-ratio scale, and the use of thetwo different scales may have made the original comparison lesscompelling. Therefore, in the present investigation we chose toadd a measure of RPE and use Borg's 0-10 category-ratio scale(3). The pain and RPE 0-10 category-ratio scales are designedto overcome limitations of category scales (e.g., ceiling effects)by allowing users to choose a number above 10 when necessary.These scales are not only designed to have ratio properties (i.e.,possessing a true 0 and unbounded), but they have been shown toperform similarly compared with ratio scaling methods (3, 6).The low correlations observed (r = $-$ 0.04 to 0.25) between pain(0-10) and RPE (0-10) in this experiment, and the occurrence ofexertion before pain, again support the contention that pain andexertion are two separate constructs. The distinction betweenpain and exertion is potentially important because it allows researchersto determine the role of pain in various types of exercise performance.It also allows researchers to learn whether pain per se influencesexertionalperceptions.

MSNA. The results of the present experiment, while not directly comparable, appear to be in contrast to previous results obtainedby Farrell et al. (8), who showed an augmentation of naloxoneon MSNA during moderate-intensity, brief-duration, isometric handgrip.However, the results are in agreement with Ray and Pawelczyk (23),who showed no effect of naloxone on MSNA during moderate-intensity,brief-duration, isometrichandgrip.

It is not immediately clear why different results were obtained in the earlier works by Ray and Pawelczyk (23) and Farrellet al. (8). However, one criticism of prior work attemptingto examine the influence of the endogenous opioid system on MSNAresponses to exercise has been the use of exercise stimuli thatwere of low intensity, short duration, and involved static contractions.Thus the exercise stimulus itself may not have been sufficientto stimulate the endogenous opioid system. Alternatively, it maybe that the exercise stimulus used previously was not painfuland thus negated the potential effects of naloxone. The strengthof the present experimental design was that we employed painful,high-intensity, and dynamic exercise to fatigue while examiningthe MSNA responses after administration of both an opioid agonistand antagonist. Rhythmic exercise is different from isometricexercise used in our earlier studies because rhythmic exercisedoes not elicit continuous ischemia. Therefore, our results extendour previous findings to rhythmic exercise and strongly suggestthat the endogenous opioid system does not modulate MSNA duringhandgrip.

No prior studies have adequately determined whether pain and MSNA are related. One study, in which muscle pain was poorlyassessed and experienced by only 3 of 25 subjects, reported norelationship between pain and MSNA (32). In the present investigation,pain ratings during exercise were weakly or moderately relatedto MSNA burst frequency or total activity (pain and burst frequency:r = $-$ 0.44 to 0.24 and pain and total activity: r = $-$ 0.21 to 0.23).This lack of a strong relationship is not surprising given thatnociceptive signals are modified at spinal and supraspinal sitesthat are independent of the sympathetic nervous system. Moreover,pain perception was not altered in the present study, which mayhave limited the potential for observing stronger relationshipsbetween MSNA andpain.

The present study could not definitively assess whether pain perception during exercise was altered by central mechanisms(i.e., higher brain systems). It is possible that "central command,"associated with volitional effort, may have interacted with afferentfeedback from the muscle to modulate pain perception. Future studiesusing postexercise muscle ischemia, which eliminates central command,may be useful in addressing this issue. In the present study,postexercise muscle ischemia was not assessed because it wouldhave confounded our postexerciseresponses.

In summary, the results from this study indicate that the ingestion of either 60 mg of codeine or 50 mg of naltrexone doesnot alter the perception of forearm muscle pain or exertion duringmaximal handgrip exercise to fatigue. Additionally, neither drughad an effect on MSNA when expressed in terms of burst frequencynor total integrated activity. We conclude that codeine and naltrexone,in practical doses, do not have an effect on naturally occurringmuscle pain, exertion, or MSNA during exercise. Whether this findinggeneralizes to other opioid agonists and different modes of exerciseremains to betested.

Perspectives

The experience of muscle pain during exercise is a common phenomenon: the runner rounding the final curve and sprinting towardthe finish of the 1,500 m at the Olympic Games, the 90-yr-oldgreat-grandmother climbing a flight of stairs, and the patientwith peripheral vascular disease simply walking to the grocerystore all can experience intense muscle pain during exercise.These perceptions of pain provide strong motivation. Pain motivatesthe athlete, the great-grandmother, and the peripheral vasculardisease patient all to slow down, presumably so they do not seriouslyinjure themselves. By learning more about the mechanisms underlyingthis type of exercise-generated muscle pain, we may eventuallybe able to improve both well-being and athletic performance. Weare surprised that muscle pain is one of the least studied typesof pain and urge applied physiologists interested in muscle toconsider including the perception of pain as a dependent measurein their future investigations involvingexercise.

	ACKNOWLEDGEMENTS

We acknowledge Keith M. Hume for invaluable services during the data collection stages of thisproject.

	FOOTNOTES

This investigation was supported by the Department of Exercise Science at the University of Georgia via the 1997 Louise E.Kindig Research Award (to D. B. Cook), National Institutes ofHealth Grants AR-44571 and HL-8503, and National Aeronautics andSpace Administration Grant 9-1034 (to C. A.Ray).

Address for reprint requests and other correspondence: D. B. Cook, UMDNJ-New Jersey Medical School, ADMC Complex 1524A, 30Bergen St., Univ. Heights, Newark, NJ 07107-3000 (E-mail: cookdb{at}umdnj.edu).

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

Received 20 March 2000; accepted in final form 28 June 2000.

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