The Role of Spinal Neuroimmune Activation in Morphine Tolerance/Hyperalgesia in Neuropathic and Sham-Operated Rats

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The Journal of Neuroscience, November 15, 2002, 22(22):9980-9989

The Role of Spinal Neuroimmune Activation in Morphine Tolerance/Hyperalgesia in Neuropathic and Sham-Operated Rats
Vasudeva Raghavendra¹, Maria D. Rutkowski¹, and Joyce A. DeLeo¹^,²
Departments of ¹ Anesthesiology and ² Pharmacology, Dartmouth Hitchcock Medical Center, Lebanon, New Hampshire 03756

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Hypersensitivity resulting from nerve injury or morphine tolerance/hyperalgesia is predicted to involve similar cellular andmolecular mechanisms. One expected but incompletely explored mechanismis the activation of central neuroimmune responses associatedwith these conditions. To begin to address this, we undertookthree separate studies: First, we determined the acute antinociceptiveaction of morphine, the rate of development of opioid tolerance,and withdrawal-induced hyperalgesia/allodynia in nerve-injuredand sham-operated rats using noxious (thermal and mechanical)and non-noxious (mechanical allodynia) behavioral paradigms. Second,we investigated the impact of chronic morphine treatment on spinalglial activation and cytokine expression after L5 spinal nervetransection or sham surgery. Third, we examined the consequencesof spinal administration of cytokine inhibitors on the developmentof morphine tolerance and morphine withdrawal-induced hyperalgesiaand allodynia. Results demonstrated that after nerve injury, theantinociceptive effect of acute morphine was significantly decreased,and the rate of development of tolerance and opioid withdrawal-inducedhyperalgesia/allodynia was significantly enhanced compared withthat after sham surgery. Chronic administration of morphine tosham-operated rats activated spinal glia and upregulated proinflammatorycytokines [interleukin (IL)-1 $beta$ , IL-6, and tumor necrosis factor- $alpha$ ].This neuroimmune activation was further enhanced in nerve-injuredrats after chronic morphine treatment. Spinal inhibition of proinflammatorycytokines restored acute morphine antinociception in nerve-injuredrats and also significantly reversed the development of morphinetolerance and withdrawal-induced hyperalgesia and allodynia innerve-injured or sham-operated rats. Targeting central cytokineproduction and glial activation may improve the effectivenessof morphine and reduce the incidence of morphine withdrawal-inducedhyperalgesia and allodynia in neuropathic painconditions.

Key words: neuropathy; morphine tolerance; hyperalgesia; glia; interleukin-1 $beta$ ; interleukin-6; tumor necrosis factor- $alpha$

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Neuropathic pain is associated with severe, chronic sensory disturbances characterized by spontaneous pain, increased responsivenessto painful stimuli (hyperalgesia), and pain perceived in responseto normally non-noxious stimuli (allodynia). Pain associated withneuropathy is difficult to treat, often being only partially relievedby high doses of opioids in humans (Cherny et al., 1994). A completeunderstanding of decreased opioid efficacy in the treatment ofneuropathic pain has eluded the research community. Moreover,the literature on the analgesic effect and development of toleranceto opioids in neuropathic pain is contradictory. Several studieshave demonstrated that neuropathy-induced hyperalgesia leads toa decrease in antinociception and to early development of toleranceto morphine (Mao et al., 1995; Christensen and Kayser, 2000).On the contrary, Backonja et al. (1995) and Catheline et al. (1996)reported that peripheral nerve injury increased the antinociceptivepotency and delayed the development of tolerance to morphine.From these behavioral studies, it appears that the efficacy ofmorphine in attenuating hyperalgesia and/or allodynia is largelydependent on the animal model, the behavioral measure, and theroute of drugadministration.

Neuronal plasticity associated with hyperalgesia and morphine tolerance has similar cellular and molecular mechanisms, suggestingpredictable interactions between hyperalgesia and morphine tolerance(Mao et al., 1995; Mayer et al., 1999). In addition to neuronsand neurotransmitters, the role of non-neuronal cells, such asglia, and their secretory products in the development of hyperalgesiahas been studied recently. Both microglia, the intrinsic macrophagesof the CNS, and astrocytes release a variety of proinflammatorycytokines [interleukin (IL)-1, IL-6, and tumor necrosis factor(TNF)- $alpha$ ], which play a role in mediating or maintaining hyperalgesiaand allodynia (DeLeo and Yezierski, 2001; Milligan et al., 2001;Watkins et al., 2001a,b). Similar to that in nerve injury, glialactivation is also reported in the course of development of morphinetolerance (Song and Zhao, 2001), and neural effects of opioids,including analgesia, are altered by cytokines (Peterson et al.,1998; Gul et al., 2000; Rady and Fujimoto, 2001).

Although proinflammatory cytokines may modulate the analgesic effects of morphine, and chronic morphine treatment activatesspinal glial cells, it is not known whether long-term morphineadministration in a neuropathic pain rat model affects spinalneuroimmune activation. Considering that opioids have diverseeffects on the peripheral immune system, it is important to knowthe consequences of opioid treatment on CNS-related immune responses.One can expect an enhanced disease process or worsening of withdrawalin the course of opioid treatment during neuropathic conditions.In view of this, the present study had a threefold design: (1)to evaluate and compare the antinociceptive action of acute morphineand the rate of development of morphine tolerance and withdrawal-inducedhyperalgesia/allodynia in sham-operated and L5 spinal nerve-injuredrats using noxious and non-noxious behavioral paradigms, (2) toexplore possible effects of chronic morphine on spinal glial activationusing immunocytochemistry and cytokine expression using RNaseprotection assays (RPAs) and ELISA in nerve-injured and sham-operatedrats, and (3) to determine the effect of spinal inhibition ofIL-1 $beta$ , IL-6, and TNF- $alpha$ on the acute analgesic action of morphine,development of opioid tolerance, and withdrawal-induced hyperalgesia/allodyniain sham-operated and nerve-injuredrats.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animals
Male Sprague Dawley rats (Harlan Sprague Dawley, Indianapolis, IN) weighing 175-200 gm at the start of surgery were used.The animals were allowed to habituate to the housing facilitiesfor $>=$ 1 week before the experiments began. Behavioral studies wereperformed in a quiet room between the hours of 9:00 and 11:00A.M. The Institutional Animal Care and Use Committee at DartmouthCollege approved the procedures in this study. Efforts were madeto limit distress and use the minimum number of animals necessaryto achieve statistical significance as set forth by InternationalSociety for the Study of Pain guidelines (Covino et al., 1980).

Surgery
The unilateral peripheral mononeuropathy was produced according to the method described previously by Colburn et al. (1999).Briefly, rats were anesthetized with halothane in O₂ carrier (induction,4%; maintenance, 2%). A small incision to the skin overlying L5-S1was made followed by retraction of the paravertebral musculaturefrom the vertebral transverse processes. The L6 transverse processwas partially removed, exposing the L4 and L5 spinal nerves. TheL5 spinal nerve was identified, lifted slightly, and transected.The wound was irrigated with saline and closed in two layers with3-0 polyester suture (facial plane) and surgical skinstaples.

Behavioral tests
The antinociceptive and antiallodynic properties of morphine were evaluated within 45-60 min after injection. Opioid withdrawal-inducedhyperalgesia and allodynia were recorded 16 hr after the lastinjection of morphine. Mechanical sensitivity to non-noxious stimuliwas measured by applying 2 and 12 gm von Frey filaments (Stoelting,Wood Dale, IL) on the plantar surface of the ipsilateral hindpaw, as described previously (Colburn et al., 1999). The numberof paw withdrawals in three sets of 10 stimulations for each setto this normally non-noxious stimulus determined mechanical allodynia.Mechanical nociceptive thresholds were evaluated using an Analgesy-Meter(Ugo Basile, Comerio, Italy), as explained by Stein et al. (1990).Rats were gently held, and incremental pressure (maximum of 250gm) was applied onto the dorsal surface of the ipsilateral hindpaw. The pressure required to elicit paw withdrawal, the paw-pressurethreshold (PPT), was determined. Thermal nociceptive thresholdswere evaluated by the hot water tail-flick test (Bian et al.,1999), which consisted of immersing the tail in water maintainedat 49°C and recording the latency to a rapid flick. A 15 sec cutofftime was used. In the noxious test paradigms, the mean of threeconsecutive measurements made, separated by 10 sec, was determinedand expressed as a percentage of maximal possible effect (%MPE).

Experimental design
Evaluation of the acute analgesic effect of morphine in sham-operated or nerve-injured rats. On postoperative days 6 or 11,when behavior reached steady state, both sham-operated and L5nerve-transected rats were administered a 1-10 mg/kg intravenousinjection of morphine via tail vein under halothane anesthesia(n = 6 rats per group). The analgesic effect was evaluated usingthe hot water tail-flick and paw-pressure Analgesy Meter. Thethreshold response of animals to noxious stimuli before administrationof morphine served as the basallatency.
Evaluation of development of morphine tolerance and withdrawal-induced hyperalgesia and allodynia in sham-operated and L5nerve-transected rats. Rats were treated with subcutaneous injectionsof either saline or morphine (10 mg/kg) (Sigma, St. Louis, MO).The injections were given twice daily at 8:00-9:00 A.M. and 4:00-5:00P.M. for 5 d, beginning on day 6 and ending on day 10 after surgeryto induce opioid tolerance. Development of analgesic and antiallodynictolerance to chronic morphine was recorded on days 1, 3, and 5(i.e., postsurgery days 6, 8, and 10) of the morphine treatment.Chronic morphine withdrawal-induced hyperalgesia or allodyniain these animals was assessed 16 hr after the last injection ofmorphine (i.e., on postsurgery day 11). Behavior recorded on day6 before the beginning of morphine treatment served as the basallatency (n = 8 rats pergroup).
Qualitative assessment of glial fibrillary acidic protein and OX-42 immunoreactivity in lumbar spinal cord. On day 11 afterthe recording of morphine withdrawal-induced hyperalgesia andallodynia, animals were anesthetized and transcardially perfusedwith 0.1 M PBS, pH 7.4, followed by 4% paraformaldehyde in PBS.Lumbar spinal cord sections were harvested and processed as describedpreviously (Colburn et al., 1999). Immunohistochemistry was performedon 20 µm free-floating L5 spinal cord sections. A monoclonal antibodyto OX-42 (1:2 working dilution from William F. Hickey, DartmouthHitchcock Medical Center) was used to label the expression ofCR3/CD11b on activated microglia. A polyclonal antibody to glialfibrillary acidic protein (GFAP) (1:20,000 working dilution; Dako,Carpinteria, CA) was used to label astrocytes (n = 4 rats pergroup).
Tissue collection for quantifying cytokine mRNA and proteins. To quantify cytokine mRNA and protein levels, a separate groupof animals than those discussed in the aforementioned paragraphB was killed by CO₂ asphyxiation followed by decapitation immediatelyafter behavioral testing on day 11 after surgery. Inserting an18 gauge needle into the caudal end of the vertebral column andflushing the spinal cord out with ice-cold PBS achieved spinalcord isolation. The spinal cord was flash frozen immediately ondry ice and stored at $-$ 80°C until homogenization. L5 lumbar spinalcord was removed from the intact frozen cord at the time of quantifyingmRNA andprotein.
RNase protection assay. Assessment of temporal cytokine mRNA expression in the L5 lumbar spinal cord was performed using aRibonuclease MultiProbe RPA system (PharMingen, San Diego, CA).Total RNA from L5 lumbar spinal cord was isolated by the TRIzolextraction method (Invitrogen, Carlsbad, CA). Total RNA (15 µg)was hybridized to ³²P-labeled antisense RNA probes transcribed using the rat cytokine-1(rCK-1) multiprobe template set [including IL-1 $alpha$ / $beta$ , IL-2, IL-3,IL-4, IL-5, IL-6, IL-10, TNF- $alpha$ / $beta$ , interferon (IFN)- $gamma$ , L32, andglycera-ldehyde-3-phosphate dehydrogenase], resulting in double-strandedtarget RNA. After RNase digestion, protected RNA and probe wereresolved on a denaturing polyacrylamide gel and visualized byovernight autoradiography. Semiquantitative image analysis wasused to compare mRNA levels based on band intensities for eachcytokine; the intensity of each band was measured using NIH Imagesoftware and assigned an arbitrary unit based on the measuredintensity levels. Image intensity for the housekeeping gene (L32)and background levels were used to normalize cytokine measurementsand were compared with the relative levels of mRNA. The relativemean level of cytokine mRNA in different groups of rats (saline-or morphine-treated in sham or L5 nerve-transected rats) was determined,and levels were normalized by those for normal animals and reportedas ratios to normal (n = 4 rats pergroup).
Protein estimation by ELISA. Standard ELISA was performed for quantitative determination of IL-1 $beta$ , IL-6, and TNF- $alpha$ protein.L5 lumbar spinal cord homogenization was prepared as explainedpreviously (Sweitzer et al., 2001b). In brief, weighed sectionsof L5 spinal cord were homogenized in homogenization buffer consistingof a protease inhibitor (Boehringer Mannheim, Mannheim, Germany)using a Power Gen 125 tissue tearer (Fisher Scientific, Suwanee,GA). Samples were spun at 20,000 × g for 30 min at 4°C. Supernatantwas aliquoted and stored at $-$ 80°C for future protein quantification.IL-1 $beta$ , TNF- $alpha$ (R & D Systems, Minneapolis, MN), and IL-6 (Biosource,Camarillo, CA) protein concentrations were determined using thequantitative sandwich enzyme immunoassay according to the manufacturer'sdirections. IL-1 $beta$ , IL-6, and TNF- $alpha$ protein quantification wasdetermined by comparing samples to the standard curve generatedfrom the respective kits (n = 4 rats pergroup).
Evaluation of the inhibition of spinal proinflammatory cytokines (IL-1 $beta$ , IL-6, and TNF- $alpha$ ) on acute analgesic action of morphine,development of morphine tolerance, and opioid withdrawal-inducedhyperalgesia in sham or L5 nerve-transected rats. Separate groupsof rats (either sham operated or nerve transected) received eithersaline or morphine and were treated once daily (at 11:00 A.M.to 12:00 P.M.) with a cocktail consisting of a fixed-dose combinationof IL-1 receptor antagonist (IL-1ra; 100 µg/rat), soluble TNFreceptor (sTNFR; 30 µg/rat) (both were kind gifts from Amgen,Thousand Oaks, CA), and goat anti-rat IL-6-neutralizing antibody(0.08 µg/rat; R & D Systems). This cocktail (in PBS) was administeredvia direct lumbar puncture under brief halothane anesthesia ata volume of 15 µl/rat on postoperative days 6-10. On day 11, afterrecording morphine withdrawal-induced hyperalgesic and allodynicbehavior, these rats were treated with morphine (2 mg/kg, i.v.)via the tail vein, and the antihyperalgesic activities were evaluated.The threshold latency recorded before the intravenous administrationof morphine (day 11) was used as the basal latency (n = 6 ratsper group). The selection of IL-1ra, sTNFR, and anti IL-6 antibodydoses was based on our previous reports (Arruda et al., 2000;Sweitzer et al., 2001b).

Statistical analysis
Values are expressed as means ± SEM and were analyzed for significance with one-way ANOVA followed by a post hoc Bonferronianalysis using STATA 5.0 (STATA Corp., College Station, TX). pvalues of <0.05 were considered significant. To access morphineanalgesia, the data of noxious mechanical and thermal tests wereconverted to a percentage of MPE using the following formula:%MPE = (WT $-$ CT)/(CO $-$ CT) × 100, where WT equals withdrawal latency(in seconds) or threshold (in grams) after morphine/saline treatment,and CT equals the cutoff value (i.e., 250 gm for mechanical testand 15 sec for the tail-flicktest).

  RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

General results

The mean paw-withdrawal pressure to noxious mechanical stimuli or tail-flick latency to thermal stimuli between unoperatedand sham-operated rats showed no significant difference. However,in L5 nerve-transected rats, mean PPT and tail-flick latency weresignificantly decreased compared with the sham-operated or controlgroup of animals, indicating development of mechanical and thermalhyperalgesia in L5 nerve-transected animals. Similarly, nerve-injuredrats also developed mechanical allodynia to both 2 and 12 gm ofmechanical stimuli (Table 1). The development of mechanical andthermal hyperalgesia and mechanical allodynia increased in a time-dependentmanner after nerve transection and reached steady state betweendays 6 and 11 after surgery. This steady-state period was usedto study the acute analgesic effect of morphine, the developmentof morphine tolerance, and its withdrawal-induced hyperalgesiain neuropathic rats.


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Table 1. Neuropathy (by L5 spinal nerve transection) induced hyperalgesia and allodynia in rats

Neuropathy decreased the acute analgesic effect of morphine
When tested on days 6 or 11 after the surgical procedure (steady state), administered morphine (1-10 mg/kg, i.v.) producedsignificant and dose-dependent antinociception to both noxiousthermal and mechanical stimuli in sham-operated rats. In nerve-injuredrats, lower doses of morphine (1 and 2 mg/kg) failed to elicitany antinociceptive effect in either noxious test paradigm. However,with increasing doses (5 and 10 mg/kg), morphine retained itsantinociceptive effect in nerve-injured rats. A cumulative dose-responsecurve of morphine in nerve-injured rats showed a clear rightwardshift in its antinociceptive effect, indicating decreased analgesicproperties of morphine in nerve-injured rats (Fig. 1). Althoughmorphine produced a dose-dependent antiallodynic effect in L5nerve-transected animals, it was not compared directly with sham-operatedrats; the sham group did not demonstrate tactile allodynia, preventingevaluation of the antiallodynic activity of morphine in theserats.

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Figure 1. Decreased antinociceptive activity of acute morphine in L5 nerve-transected rats. Behavioral response to noxious thermal (tail-flick test) and mechanical (paw-pressure test) stimuli was recorded on postoperative days 6 or 11. Antinociceptive activity of acute morphine (M; 1-10 mg/kg) was recorded 45 min after its intravenous administration and expressed as a percentage of MPE. A rightward shift in the dose-response curve of morphine in L5 nerve-transected rats (L5Tx) compared with sham-operated rats indicates decreased antinociceptive activity of morphine in neuropathic conditions. Values are mean ± SEM (n = 6). *p < 0.05 versus basal latency (recorded before morphine administration); ⁺p < 0.05 versus sham-operated rats (Bonferroni test).

Neuropathy enhanced the development of morphine tolerance
In a daily injection paradigm, either sham-operated or nerve-injured rats tested on day 1 of morphine treatment showed nosignificant difference in antinociceptive action. These animalsshowed an almost complete analgesic effect to the first dose ofmorphine (10 mg/kg, s.c.) in both thermal and mechanical testparadigms. On day 3, the percentage of MPE of morphine was reducedto 45 and 19% in the tail-flick test and to 42 and 3% in the paw-pressuretest in sham-operated and neuropathic rats, respectively. On day5 of the morphine treatment, both groups of animals showed completedevelopment of antinociceptive tolerance. A significant decreasein the antinociceptive action of morphine was observed on day3 in nerve-injured rats compared with sham-operated rats. Thisindicates an early development of antinociceptive tolerance inthese animals (Fig. 2). In the present experimental conditions,unlike antihyperalgesic action, complete tolerance to antiallodynicactivity of morphine was not observed. However, there was a significantdecrease in the antiallodynic activity of morphine (for 12 gmof stimuli) on day 5 compared with day 1 treatment (Fig. 2), suggestinga slower rate of tolerance development to non-noxious mechanicalstimuli. Development of tolerance to the antiallodynic activityof morphine in nerve-injured rats was not compared with sham-operatedrats, because they did not develop allodynia to a non-noxiousmechanical stimulus.

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Figure 2. L5 nerve transection enhances the development of morphine tolerance to analgesic and antiallodynic actions. Chronic morphine (10 mg/kg, s.c., twice daily for 5 d) treatment was initiated on postoperative day 6 to L5 nerve-transected (L5Tx) and sham-operated rats. Antinociceptive and antiallodynic activity of morphine in these rats was accessed on days 1, 3, and 5 of the treatment (i.e., postoperative days 6, 8, and 10). Behavior recorded before the beginning of morphine treatment represents baseline responses. Analgesic activity of morphine against noxious thermal and mechanical stimuli was expressed as a percentage of MPE, whereas antiallodynic activity was expressed as average numbers of paw withdrawals to 30 stimuli of 12 gm of von Frey filament. A significant decrease in the antinociceptive action of morphine (both in the tail-flick and in the paw-pressure tests) in L5 nerve-transected rats (L5Tx-morphine) compared with sham rats (Sham-morphine) on day 3 of the treatment indicates early development of morphine tolerance in neuropathic conditions. Values are mean ± SEM (n = 8-10). *p < 0.05 versus antinociceptive or antiallodynic activity of morphine observed on the first day of its treatment; ⁺p < 0.05 versus morphine-treated, sham-operated (Sham-morphine) rats (Bonferroni test). Note that sham-operated rats did not develop tactile allodynia, preventing evaluation of the antiallodynic activity of morphine in these animals.

Neuropathy enhanced morphine withdrawal-induced hyperalgesia and allodynia
Chronic administration of morphine (10 mg/kg, s.c., twice daily for 5 d) to sham-operated or neuropathic rats led to withdrawal-inducedthermal and mechanical hyperalgesia and mechanical allodynia whenrecorded 16 hr after the last injection. Morphine withdrawal-inducedhyperalgesia and allodynia were significantly greater in the nerve-injuredrats compared with sham-operated rats (Table 2). Unlike the saline-treatedneuropathic rats, in which the development of mechanical allodyniaand hyperalgesia was primarily restricted to the ipsilateral paw,chronic morphine treatment showed the development of hyperalgesiaand allodynia even in the contralateral paw (data not shown).


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Table 2. Chronic morphine withdrawal-induced hyperalgesia and allodynia in sham-operated and L5 nerve-transected rats

Chronic morphine treatment enhanced OX-42 and GFAP immunoreactivity in lumbar spinal cord of sham-operated and neuropathic rats
As shown in Figures 3, A and C, and 4, A and C, immunoreactive OX-42 and GFAP were significantly elevated in the lumbar spinalcord in nerve-injured rats compared with sham-operated rats onday 11 after surgery. Acute administration of morphine did notenhance OX-42 or GFAP immunoreactivity in the lumbar spinal cordof control or sham-operated rats (data not shown), but after chronictreatment, a significant increase in OX-42 and GFAP immunoreactivityin the L5 lumbar dorsal horn of the spinal cord of these animalswas observed (Figs. 3B, 4B). Chronic administration of morphineto nerve-injured rats further increased OX-42 and GFAP immunoreactivityin the L5 lumbar spinal cord of these animals (Figs. 3D, 4D).Unlike the saline-treated neuropathic rats, in which increasedexpression of OX-42 and GFAP was primarily observed in the ipsilateralside, chronic morphine treatment demonstrated increases in glialactivity in both ipsilateral and contralateral dorsal horns (datanot shown).

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Figure 3. Increased microglial activation by chronic morphine treatment in sham-operated and neuropathic rats. Chronic administration of morphine to either sham-operated rats (B) or L5 nerve-transected rats (D) showed enhanced OX-42 immunostaining in the dorsal horn of the L5 lumbar spinal cord compared with saline-treated, sham-operated rats (A) or neuropathic rats (C), respectively. Scale bar, 150 µm (n = 4 per group).

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Figure 4. Increased astrocyte activation by chronic morphine treatment in sham-operated and neuropathic rats. Chronic administration of morphine to either sham-operated rats (B) or L5 nerve-transected rats (D) showed enhanced GFAP immunostaining in the dorsal horn of the L5 lumbar spinal cord compared with saline-treated, sham-operated rats (A) or neuropathic rats (C), respectively. Scale bar, 150 µm (n = 4 per group).

Chronic morphine treatment enhanced transcription of proinflammatory cytokines in L5 lumbar spinal cord of sham-operated and neuropathic rats
Constitutive expression of mRNA for IL-1 $alpha$ / $beta$ , TNF- $alpha$ / $beta$ , and IL-6 was observed in L5 lumbar spinal cord of sham-operated, saline-treatedrats. After an L5 spinal nerve transection (on postoperative day11), significant increases in mRNA levels of IL-1 $alpha$ / $beta$ , TNF- $alpha$ / $beta$ ,and IL-6 were observed compared with sham-operated animals. Chronicadministration of morphine (10 mg/kg, s.c., twice daily for 5d) to sham-operated rats significantly increased the mRNA levelsfor IL-1 $beta$ , IL-6, and TNF- $alpha$ compared with saline-treated animals,whereas the levels of IL-1 $alpha$ and TNF- $beta$ (lymphotoxin) were unaffected.Chronic treatment of morphine to L5 nerve-transected rats furtherenhanced the level of IL-1 $beta$ , TNF- $alpha$ , and TNF- $beta$ compared with saline-treated,nerve-transected rats (Fig. 5 and Table 3). Under the presentexperimental conditions, other cytokines included in the RPA kit(rCK-1) were not consistently detected.

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Figure 5. Representative RNase protection assay depicting cytokine mRNA expression for IL-1 $alpha$ , IL-1 $beta$ , IL-6, TNF- $alpha$ , and TNF- $beta$ in L5 lumbar spinal cord of saline-treated, sham-operated rats (A) and neuropathic rats (B), chronic morphine-treated neuropathic rats (C), and sham-operated rats (D) (n = 4 per group). Note that mRNA for IL-2, IL-4, IL-5, IL-10, and IFN- $gamma$ was inconsistent or not readable in nontransected animals at present experimental conditions. GAPDH, Glyceraldehyde-3-phosphate dehydrogenase.


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Table 3. mRNA levels of IL-1 $alpha$ , IL-1 $beta$ , TNF- $beta$ , IL-6, and TNF- $alpha$ in L5 lumbar spinal cord after peripheral neuropathy, chronic morphine treatment, or a combination of both

Chronic morphine treatment enhanced proinflammatory cytokine protein levels in L5 lumbar spinal cord of sham-operated and neuropathic rats
Results from the analysis of L5 lumbar spinal cord homogenates demonstrated that L5 spinal nerve transection produced significantincreases in IL-1 $beta$ , IL-6, and TNF- $alpha$ protein levels compared withsaline-treated, sham-operated rats. In sham-operated rats, chronicadministration of morphine increased protein levels of IL-1 $beta$ andIL-6 compared with saline-treated rats. Although levels of TNF- $alpha$ increased in chronic morphine-treated rats, these values werenot statistically significant. In L5 spinal nerve-transected rats,chronic administration of morphine significantly enhanced theIL-1 $beta$ and TNF- $alpha$ protein levels, whereas increased levels of IL-6in these animals were not statistically significant compared withsaline-treated, nerve-transected rats (Table 4).


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Table 4. Proinflammatory cytokine level in L5 lumbar spinal cord after peripheral neuropathy, chronic morphine treatment, or a combination of both

Intrathecally administered IL-1ra, sTNFR, and anti-IL-6 antibody restored morphine analgesia and reversed the development of morphine tolerance and withdrawal-induced hyperalgesia in neuropathic and sham-operated rats
Chronic administration of a fixed-dose combination of IL-1ra, sTNFR, and anti-IL-6 antibody to sham-operated rats on postoperativedays 6-10 did not modulate the analgesic actions of acute morphine(2 mg/kg, i.v.). However, in L5 spinal nerve-transected rats,chronic administration of IL-1ra, sTNFR, and anti-IL-6 antibodysignificantly restored the analgesic actions of acute morphine.Chronic administration of morphine (10 mg/kg, s.c., twice daily)for 5 d (postoperative days 6-10) induced complete analgesic tolerancein both sham and nerve-transected rats as evidenced by their inabilityto exhibit an analgesic effect to the administered morphine (2mg/kg, i.v.) tested on postoperative day 11. However, chronicadministration of IL-1ra, sTNFR, and anti-IL-6 antibody duringthe induction of morphine tolerance to both sham and L5 nerve-transectedrats showed significant antinociceptive action to administeredmorphine (2 mg/kg, i.v.) on postoperative day 11 (Fig. 6). Chronicadministration of IL-1ra, sTNFR, and anti-IL-6 antibody duringinduction of morphine tolerance significantly reversed the developmentof opioid withdrawal-induced hyperalgesia and allodynia in shamand L5 nerve-transected rats (Table 5).

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Figure 6. Inhibition of spinal proinflammatory cytokines restores acute analgesic action of morphine in neuropathic- and morphine-tolerant rats. Sham-operated and L5 nerve-transected rats received chronic saline (A); chronic IL-1ra, sTNFR, and anti IL-6 antibody (B); chronic morphine (C); and chronic morphine plus IL-1ra, sTNFR, and anti IL-6 antibody (D) treatment on postoperative days 6-10. Acute antinociceptive action of morphine (2 mg/kg, i.v.) in these rats was evaluated against noxious thermal (tail-flick test) and mechanical (paw-pressure test) stimuli on postoperative day 11 (for details, see Materials and Methods). Data show that chronic inhibition of proinflammatory cytokines restores the acute antinociceptive actions of intravenously administered morphine in saline- or morphine-tolerant, nerve-transected and morphine-tolerant, sham-operated rats. Values are mean (%MPE) ± SEM (n = 5). *p < 0.05 versus group A nerve-transected rats; ⁺p < 0.05 versus group C sham or nerve-transected rats (Bonferroni test).


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Table 5. Effect of chronic administration of IL-1ra, sTNFR, and anti-IL-6 antibody on the development of morphine withdrawal-induced hyperalgesia and allodynia in sham-operated or L5 nerve-transected rats

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The main findings of this study show that persistent pain induced by an L5 spinal nerve transection in rats decreased theacute analgesic action of morphine, enhanced the development ofanalgesic tolerance to chronic morphine treatment, and aggravatedopioid withdrawal-induced hyperalgesia and allodynia. Similarto what has been observed after peripheral nerve injury, chronicmorphine treatment led to glial activation and enhanced proinflammatorycytokine expression in the L5 lumbar spinal cord of normal orsham-operated rats. Chronic morphine treatment to neuropathicrats further enhanced nerve injury-associated increases in spinalneuroimmune activation. In addition, a decrease in the acute antinociceptiveresponse of morphine in neuropathic rats, development of morphinetolerance, and withdrawal-induced hyperalgesia and allodynia innerve-injured or sham-operated rats were partially reversed byneutralizing or antagonizing proinflammatorycytokines.

Both previous studies (Mao et al., 1995; Nichols et al., 1997; Fundytus et al., 2001) and our present study clearly show thatthe acute antinociceptive effect of morphine against noxious thermaland mechanical stimuli decreased in nerve-injured rats. Althoughnerve-injured rats did not respond to lower doses of morphinebut did respond with increasing doses, the threshold latency toboth noxious thermal and mechanical stimuli was significantlyincreased compared with predrug latency. This suggests that theanalgesic effect of an opioid is reduced during neuropathic pain,and that one can obtain adequate analgesia by increasing the doseof morphine. Repeated administration of morphine for a periodof 5 d developed a complete antinociceptive tolerance in bothsham-operated and nerve-injured rats. However, a significant decreasein the antinociceptive effect in nerve-injured rats compared withthat of sham-operated rats on day 3 of morphine treatment suggestsan earlier development of antinociceptive tolerance in these animals.This observation is in agreement with the findings of Christensenand Kayser (2000), who showed enhanced development of antinociceptivetolerance to systemic morphine in nerve-injured rats. However,in contrast to our observation, Christensen and Kayser (2000)reported that unlike the noxious mechanical stimuli, antinociceptivetolerance to thermal stimuli was not developed in nerve-injuredrats. This observed difference in our studies could be attributableto differences in the methodological approach to evaluate thedevelopment of morphine tolerance or could be attributable todifferences in the behavioral paradigm used to evaluate the thermalhyperalgesia in neuropathic rats. We did not observe completetolerance to the antiallodynic activity of morphine (unlike thedevelopment of complete tolerance to antihyperalgesia). This indicatesthat within the same model of neuropathic pain, pathophysiologicalmechanisms mediating the abnormal reactions to noxious and innocuousstimuli are different. The various animal models used may havea fundamentally different pathophysiology (Bars et al., 2001),and the sensitivity to opioids may vary accordingly (McCormacket al., 1998).

Other interesting results observed in this study were enhanced opioid withdrawal-induced hyperalgesia and allodynia in nerve-injuredrats compared with sham-operated rats. Chronic administrationof opioids followed by its abrupt withdrawal or by naloxone treatmentinduced a hypersensitivity state characterized by hyperalgesiaand allodynia in mice and rats (Devulder et al., 1996; Li et al.,2001a,b; Nozaki-Taguchi and Yaksh, 2002). Results showing an enhancedrate of development of antinociceptive tolerance and withdrawal-inducedhyperalgesia and allodynia during chronic morphine treatment toneuropathic rats suggest cross-interaction between hypersensitivitymechanisms operating during the process of neuropathic pain andchronic opioidtreatment.

Central neuroimmune activation and neuroinflammation have been postulated to mediate and/or modulate the pathogenesis of persistentpain states. Proinflammatory cytokines, such as IL-1 $beta$ , IL-6, andTNF- $alpha$ , induce a long-term alteration of synaptic transmissionin the CNS and play a critical role in the development and maintenanceof neuropathic pain (DeLeo and Yezierski, 2001; Sweitzer et al.,2001a). In the CNS, the major contributors of cytokine releaseare glia. Astrocytes and microglia can produce cytokines on activation(Kreutzberg, 1996; Aloisi, 2001; Dong and Benveniste, 2001). Nerveinjury or peripheral inflammation has been reported to activateglial cells and increase the proinflammatory cytokine levels inthe CNS (DeLeo and Yezierski, 2001; Watkins et al., 2001a,b).In line with this, the present study showed increased microglialand astrocytic activity, as evidenced by increases in OX-42 andGFAP immunoreactivity in the L5 lumbar spinal cord of nerve-injuredrats. Similarly, mRNA for proinflammatory cytokines (IL-1 $beta$ , IL-6,and TNF- $alpha$ ) and lymphotoxin (TNF- $beta$ ) and protein levels of IL-1 $beta$ ,IL-6, and TNF- $alpha$ were also increased in the lumbar spinal cordof L5 nerve-transectedrats.

Central or peripheral administration of IL-1 $beta$ , IL-6, and TNF- $alpha$ is known to induce hyperalgesia and allodynia in rats (Okaand Hori, 1999). Raffa et al. (1993) postulated that cytokinesmight interact with opioid receptors and modulate its actions.Gul et al. (2000) and Rady and Fujimoto (2001) showed a reductionin the analgesic effect of morphine after exogenous administrationof IL-1 $beta$ . In the present study, chronic administration of a fixed-dosecombination of anti-IL-6 antibody, sTNFR, and IL-1ra to nerve-transectedanimals partially restored the acute antinociceptive effect ofmorphine.

Both opioid tolerance and neuropathic pain conditions share features of diminished µ-opioid analgesia and abnormal pain (hyperalgesiaand allodynia). These common features have led to suggestionsof common mechanisms in nerve injury or chronic opioid-inducedhyperalgesia (Mayer et al., 1999; Przewlocki and Przewlocka, 2001).Recent evidence suggests that glial cells might possibly modulatechronic opioid actions. Chronic morphine treatment activates spinaland cortical astrocyte activity (Beitner-Johnson et al., 1993;Song and Zhao, 2001), and inhibition of this activation by glialinhibitors partially reversed the development of morphine tolerance(Song and Zhao, 2001). Activated glia release excitatory aminoacids (EAA), nitric oxide (NO), and proinflammatory cytokines(Kreutzberg, 1996; Aloisi, 2001; Dong and Benveniste, 2001). Althoughthe role of EAA and NO in the development of morphine toleranceand opioid withdrawal-induced hyperalgesia has been extensivelystudied, the contribution of proinflammatory cytokines in thismechanism has not yet been reported. In the present study, weshowed that chronic morphine treatment enhanced mRNA and proteinlevels of IL-1 $beta$ and IL-6 in the lumbar spinal cord of sham ornormal rats. In the nerve-injured rats, chronic administrationof morphine further enhanced glial activation and proinflammatorycytokine levels in L5 lumbar spinal cord, suggesting synergisticor additive interaction in this process. The increased proinflammatoryresponse in chronic morphine-treated rats paralleled the behavioralhypersensitivity to noxious and non-noxious stimuli observed duringthe withdrawal period. Furthermore, the ability of a fixed-dosecombination of IL-6 antibody, sTNFR, and IL-1ra administered duringinduction of morphine tolerance to substantially reverse antinociceptiveand antiallodynic tolerance, morphine withdrawal-induced hyperalgesia,and allodynia in sham-operated and nerve-transected rats suggeststhe possible involvement of proinfla-mmatory cytokines in thedevelopment of opioid tolerance and withdrawal-induced hyperalgesiaand allodynia in these rats. Failure of these specific cytokineinhibitors to modulate the acute analgesic effect of morphinein nonoperated animals suggests that a compensatory mechanismmay be in place that leads to activation of spinal proinflammatoryneuroimmune responses during chronic morphine treatment. Supportingthis, acute administration of morphine to normal rats did notenhance OX-42/GFAP immunostaining (Song and Zhao, 2001) (presentobservation), nor did it enhance the mRNA or protein levels ofIL-1 $beta$ , IL-6, and TNF- $alpha$ in the lumbar spinal cord (data notshown).

Activation of spinal proinflammatory cytokines by chronic opioid treatment may be caused by its direct interaction with immunecells of the CNS, or it could be mediated through other mediators,such as dynorphin. Both nerve injury and chronic opioid treatmentincrease spinal dynorphin levels (Chao and Basbaum, 1989; Dubnerand Ruda, 1992; Rattan and Tejwani, 1997). Neutralizing dynorphinactivity in these conditions blocks nerve injury-induced hyperalgesia,restores spinal morphine antinociception (Nichols et al., 1997;Wegert et al., 1997), and prevents development of opioid tolerancein rats (Vanderah et al., 2000). It was shown recently that theantianalgesic action of dynorphin against morphine is mediatedthrough IL-1 $beta$ , suggesting the possible role of cytokines in antianalgesicactions of diverse agents (Laughlin et al., 2000; Rady and Fujimoto,2001). The presence of opioid receptors and the ability of morphineto prime microglia for enhanced production of TNF- $alpha$ (Chao et al.,1994; Peterson et al., 1998) suggest a possible direct interactionof morphine with glial cells. Similarly, chronic administrationof morphine augments the production of proinflammatory cytokinesby macrophages (Wang et al., 2002). Other possibilities for chronicmorphine-induced activation of proinflammatory immune responsescould be the involvement of mitogen-activated protein (MAP) kinaseor protein kinase C (PKC) pathways. MAP kinase and PKC are intriguing,because they are key players in the intracellular signaling cascadeleading to the development of morphine tolerance, neuropathicpain, and production of proinflammatory immune responses (Kontnyet al., 1998; Ji et al., 1999; Mayer et al., 1999; Rausch et al.,2000; Fundytus et al., 2001; Ma et al., 2001; Watkins et al.,2001b).

These observations suggest that opioid therapy for chronic neuropathic pain should be used cautiously, especially in immunocompromisedcases. The use of agents that selectively inhibit glial activationand/or central proinflammatory cytokines may overcome such deleteriouseffects and spare the beneficial effect of opioids during long-termtreatment in neuropathic pain conditions. The present resultsindicate that reduction of the antinociceptive effect of morphinein nerve-injured rats, development of antinociceptive tolerance,and development of withdrawal-induced hyperalgesia and allodyniain sham or nerve-injured rats involves spinal neuroimmune activation.It can be anticipated that further understanding of the neuroimmunemechanisms underlying hyperalgesia, opioid tolerance, and theirinteractions would advance and improve clinical management ofopioid therapy in the management of chronic painsyndromes.

  FOOTNOTES

Received June 5, 2002; revised Sept. 3, 2002; accepted Sept. 3, 2002.

This work was supported by National Institute of Drug Abuse Grant DA11276 (J.A.D.). We thank Tracy Wynkoop for editorial assistance,Dr. William F. Hickey for antibodies and glial expertise, andAmgen for the generous supply of IL-1ra andsTNFR.

Correspondence should be addressed to Joyce A. DeLeo, Department of Anesthesiology, HB 7125, Dartmouth Hitchcock Medical Center,Lebanon, NH 03756. E-mail: Joyce.A.DeLeo{at}Dartmouth.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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