The effect of pentobarbital on the antinociceptive action of morphine in morphine-tolerant and non-tolerant rats

The interaction of sodium pentobarbital with morphine sulfate in both morphine-tolerant and non-tolerant rats was investigated using the tail-compression test for analgesia. Male Sprague-Dawley rats (300–350 g) were given pentobarbital (4, 8, or 16 mg/kg) 5 min before morphine (2, 4, 6, or 8 mg/kg). Control animals received two saline injections, or pentobarbital plus saline, or saline plus morphine. All injections were subcutaneous. Prior to the first injection, a baseline nociceptive threshold was determined for each rat by applying a modified micrometer to its tail and increasing the pressure until a squeak was elicited. Test readings were taken every half-hour for 2 hr beginning 30 min after the second injection. For the chronic studies, animals were first made tolerant to morphine by the administration of the narcotic twice a day for 3 days, increasing the dose from 10 to 50 mg/kg/injection. Identical testing procedures were then followed with these rats except that the test dose of morphine given on day 4 was in the range 8–128 mg/kg. It was found that Na pentobarbital, in the subanesthetic doses used, had neither antinociceptive nor hyperalgesic properties. Furthermore, the barbiturate had no effect on the antinociceptive action of morphine in either morphine-tolerant or non-tolerant rats.     

Stimulation of either cholecystokinin receptor subtype reduces while antagonists potentiate or sensitize a morphine-induced excitatory response.

Cholecystokinin peptides (CCK) have been shown to antagonize many opioid-mediated effects. The present study was undertaken to determine whether peripheral injections of cholecystokinin sulphated octapeptide (CCK8), cholecystokinin tetrapeptide (CCK4), the CCK(1) (lorglumide) and the CCK(2) (PD-135,158 and LY-225910) receptor antagonists can influence a classic morphine excitatory effect, i.e. the display of Straub tail reaction in mice (STR). A total of 570 female Balb/C mice were tested. Experiment 1 was undertaken to determine whether i.p. injections of CCK8 or CCK4 can influence STR. Each animal was treated with i.p. injections of saline or CCK8 (10 and 20 nmol/kg) or CCK4 (20 and 40 nmol/kg). After 30 min all animals received an i.p. injection of morphine hydrochloride (10.0 mg/kg). The highest doses of both CCK8 (35% STR) and CCK4 (40% STR) significantly reduced STR as compared to saline (85% STR) treated mice (Fisher test; P < 0.01). In experiment 2 each animal was treated with ip injections of saline or 1.0 mg/kg lorglumide or PD-135,158 fifteen minutes before an injection of morphine at doses ranging from 1.0 to 50.0 mg/kg. In experiment 3 animals were treated with injections of saline, 0.1 or 10.0 mg/kg lorglumide or LY-225910 before an injection of a fixed MC dose (2.0 mg/kg). Both lorglumide and PD-135,158 induced a significant shift to the left in the morphine dose-response curves as well as a significant decrease in ED50 of the STR. ED50 for lorglumide was significantly lower than ED50 for PD-135,158. Both doses of lorglumide and the highest dose of LY-225910 significantly increased the percent of animals displaying STR. Experiment 4 was undertaken to determine whether repeated peripheral injections of morphine or the morphine-potentiating agents CCK(1) (lorglumide) and the CCK(2) (LY-225910) receptor antagonists can induce morphine sensitization. Each animal was treated with 5 daily i.p. injections of saline (control group), 1.5 mg/Kg morphine hydrochloride (group morphine), and 1.0 mg/Kg lorglumide (group LOR) or LY-225910 (group LY). One, two, three and four weeks after the last treatment day, all animals were challenged with one i.p. injection of morphine (1.5 mg/Kg). The morphine, LOR groups and group LY showed a significant increase in percentage of animals displaying STR. These data demonstrate that the blockade of endogenous CCK actions leads to morphine sensitization probably through both CCK receptors. The present data are consistent with the antagonistic effects of CCK and opioids in the control of morphine-induced STR. In addition, these results suggest that both CCK receptors are involved in the modulatory effects of CCK on this morphine effect.     

Fluoxetine, a selective inhibitor of serotonin uptake, potentiates morphine analgesia without altering its discriminative stimulus properties or affinity for opioid receptors

The analgesic effect of morphine in the rat tail jerk assay was enhanced by the serotonin uptake inhibitor, fluoxetine. Tail jerk latency was not affected by fluoxetine alone. Morphine's affinity for opioid receptors labeled in vitro with 3H-naloxone or 3H-D-Ala2-D-Leu5-enkephalin was not altered by fluoxetine, which has no affinity for these sites at concentrations as high as 1000 nM. In rats trained to discriminate morphine from saline, fluoxetine at doses of 5 or 10 mg/kg were recognized as saline. Increasing the fluoxetine dose to 20 mg/kg did not result in generalization to either saline or morphine. The dose response curve for morphine generalization was not significantly altered by fluoxetine doses of 5 or 10 mg/kg. Those rats treated with the combination of morphine and 20 mg/kg of fluoxetine did not exhibit saline or morphine appropriate responding. Fluoxetine potentiates the analgesic properties of morphine without enhancing its affinity for opioid receptors or its discriminative stimulus properties.     

Is there an opiate receptor in the snail Megalobulimus sanctipauli? Action of morphine and naloxone

The effects of morphine sulfate (10, 15 and 20 mg/kg) or saline control (5 mg/kg) on the latency of the anterior body-lifting response to heat (avoidance response) were determined in four groups of snails Megalobulimus sanctipauli (n = 6) individually placed on a metal plate mounted on the surface of a water bath at 52 ± 1°C. The effects of pre-treatment with naloxone hydrochloride (5 mg/kg) or saline (2.5 ml/kg) control on the responses to morphine (15 mg/kg) were determined in two different groups of animals (n = 6). Administration of morphine resulted in an increase in the avoidance behavior latency with maximum effects occuring at 15 mg/kg, 10–15 min after injection. The effects of morphine disappeared within 90–120 min. Saline treatment had no detectable effects on the latency of the response to an aversive stimulus. Naloxone significantly blocked (P < 0.05, Student paired t-test) the increase in avoidance behavior latency. The present results indicate that: 1. morphine has an antinociceptive effect on the response of Megalobulimus sanctipauli to an aversive thermal stimulus; and 2. the morphine-induced “analgesia” may be caused by the stimulation of μ opiate receptors.     

Tolerance to the anti-avoidance properties of cholecystokinin-octapeptide

Previous investigations have suggested a neuroleptic-like action of cholecystokinin-octapeptide (CCK8) on conditioned-avoidance behavior. This study was initiated to test tolerance to this effect. Rats were trained to avoid electric shock in a shuttle box under a free-operant (Sidman) avoidance paradigm. Each shuttle response postponed a 0.2 sec, 1 mA shock for 20 sec. If the rat failed to respond, shock was delivered every 5 sec until a response occurred. After avoidance training, half of the rats received two daily injections of CCK8 (0.320 mg/kg, IP) and half received saline for 7 days. Rats were then tested on the Sidman avoidance 1 min after receiving CCK8 (0.640 mg/kg, IP) or saline. CCK8 depressed avoidance responding if rats received saline for 7 days prior to the test. Rats pretreated with CCK8 for 7 days were not significantly affected by CCK8 during the avoidance test. Thus, repeated injections of CCK8 result in tolerance to its anti-avoidance properties.     

Discriminative effects of morphine administered intracerabrally in the rat

Rats were trained in a two-choice discrete trial avoidance paradigm to discriminate between saline and 3.0 mg/kg of morphine administered S.C. The microinjection of 0.3–3.0 μg of morphine into the lateral ventricle produced discriminative effects equivalent to those of the systemic training dose as measured by responding on the morphine-appropriate choice lever. Discriminative effects equivalent to those of the morphine training dose were not consistently produced by administration of morphine into the periaqueductal gray, lateral septum or dorsomedial thalamus in doses as high as 10 μg. However, the discriminative effects of systematically administered morphine were blocked by 10–30 μg of naloxone administered intracerebrally at all of the brain sites tested. Thus, the primary site at which morphine acts to produce discriminative effects in the rat is central, although the specific brain areas mediating these effects remain unidentified. The actions of naloxone could be the result of diffusion of the drug into the ventricular system or into the systemic circulation.     

D-amphetamine-induced hypothermia and hypermotility in rats: Changes after systemic administration of beta-endorphin

Systemically administered beta-endorphin was tested in rats for its ability to modify the hypothermia and hypermotility induced by d-amphetamine. Colonic temperature and motor activity were measured in a cold (4°C) ambient temperature in animals given IP injections of beta-endorphin (0.1, 1.0, or 3.0 mg/kg), naloxone (10 mg/kg), or morphine (30 mg/kg). The same measurements were taken in animals given beta-endorphin (1.0 mg/kg) in combination with naloxone or saline pretreatment and d-amphetamine (15 mg/kg) or saline post-treatment. Morphine alone had a biphasic effect on thermoregulation, but did not affect d-amphetamine-induced hypothermia. Activity scores were decreased by morphine, in both d-amphetamine and saline treated animals. The thermal response of rats to beta-endorphin alone was variable, depending on dosage, but all 3 dosages partially blocked the hypothermic effect of d-amphetamine. Naloxone blocked the thermal effects of both beta-endorphin and d-amphetamine. Motor activity tended to be decreased by naloxone, regardless of amphetamine treatment, but beta-endorphin tended to increase activity in amphetamine-treated animals and reduce it in saline-treated controls. In their actions on both thermoregulation and activity, naloxone and beta-endorphin appeared to interact independently with d-amphetamine, often producing effects in the same direction, but in combination, they tended to be mutually inhibitory.     

Discriminative stimulus effects of caffeine: tolerance and cross-tolerance with methylphenidate

Twice daily injection of caffeine (30 mg/kg) for 3-1/2 days shifted the caffeine stimulus generalization curve to the right by 3-fold in rats trained to discriminate saline from 30 mg/kg of caffeine, and by 4-fold in rats trained to discriminate saline from 10 mg/kg of caffeine. The latter group was also tested for cross-tolerance with methylphenidate, a drug that generalizes completely with caffeine. Twice daily injection of caffeine (30 mg/kg) for 3-1/2 days increased the ED50 of methylphenidate for caffeine-appropriate responding from 1.5 to 5.5 mg/kg. Conversely, injections of methylphenidate (3.0 mg/kg) increased the ED50 of caffeine from 5.2 to 15 mg/kg. The development of symmetrical cross-tolerance to the discriminative effects of caffeine and to the caffeine-like discriminative effects of methylphenidate supports previous observations suggesting commonalities in the cellular bases of the stimulus properties of these drugs.     

Specifics of participation of dopaminergic and serotoninergic systems of the brain in latent inhibition based on pharmacological models

Single intraperitoneal injections of haloperidol (0.5 mg/kg) or sertralin (5 mg/kg) or 20 preexpositions of conditional stimulus before conditioning induced similar changes of passive avoidance reactions of rats. The combinative application of drugs (sertralin 1h and bupropion 30 min before conditioning) simultaneously enhancing activity of serotonin and dopamine in brain did not produce changes of passive avoidance reaction comparing with intact control. The results obtained showed that high selective drugs and analysis of latent inhibition of some parameters enable creation of pharmacological models and their use as instrument at experimental study of neurochemical mechanisms of attention.     

Effects of posttrial hormone injections on memory processes

This experiment examined the effect on memory of posttrial injections of epinephrine, norepinephrine, ACTH, growth hormone, vasopressin and corticosterone. Rats were trained with a weak footshock (0.7 mA, 0.35 sec) in a one-trial inhibitory (passive) avoidance task. The animals received subcutaneous injections of one of the above hormones or saline immediately after training. On a retention test 24 hr after training, animals which received ACTH (0.03 or 0.3 IU/rat), epinephrine (0.1 mg/kg) or norepinephrine (0.1, 0.3 or 1.0 mg/kg) had retention performance which was significantly better than that of saline control animals. A higher posttrial ACTH dose (3.0 I.U./animal) impaired later retention performance. ACTH (0.3 I.U./animal) and norepinephrine (0.3 mg/kg) injections administered 2 hr after training had no significant effect on retention. Immediate posttrial injections of vasopressin (dose range 0.001–1.0 I.U./animal), growth hormone (0.5–1.0 mg/kg), or corticosterone (0.01–4 mg/kg) did not significantly enhance retention. These findings indicate that epinephrine, norepinephrine, and ACTH injections can enhance memory processes if the hormones are injected shortly after training. Such results are consistent with the view that hormonal consequences of an experience, particularly epinephrine, norepinephrine and ACTH release, may normally have a modulatory influence on memory processes in untreated animals. In addition, it is therefore possible that other posttrial treatments which enhance or impair later retention performance may act through hormonal mechanisms.     

Selective interaction of drugs with a discriminable stimulus associated with narcotic actions

Rats were trained to bar press on either one of two levers depending on whether they received an injection of morphine (10 mg/kg) or saline. The rats responded on the morphine-correct lever when injected with another narcotic, fentanyl, but responded on the saline-correct lever when injected with a narcotic antagonist or another CNS active, but non-narcotic, drug (e.g., amphetamine, apomorphine). The narcotic antagonist, naloxone, prevented the occurrence of the narcotic discriminable stimulus, but the rats responded on the morphine-correct lever when injected with morphine plus any of a number of potent CNS active, but non-narcotic compounds. These results are discussed with reference to the specificity of this procedure for detecting drugs with narcotic agonist or antagonist properties.     

Environmental and intraperitoneal ethanol influences morphine antinociceptive effect in mice

The ability of acute environmental or intraperitoneal (i.p.) ethanol to influence morphine antinociceptive effect was studied in mice. In order to induce tolerance to morphine analgesia, mice received daily injections of 10 mg/Kg morphine over a period of 10 days. Mice were divided into three groups: i.p. ethanol (E), environmental ethanol (E*), and control saline (M). During the induction of tolerance these groups were treated identically except on days 1 and 11. On these days, 10 minutes prior to morphine injection, mice received either i.p. ethanol (1g/Kg), environmental ethanol (a bottle of 10% ethanol placed next to the animals cage during the experiments), or an equivalent volume of saline. Analgesia was assessed using a standard hot plate protocol and dose-response cumulative curves for morphine analgesia were obtained on days 1 and 11. On day 1, both the i.p. and environmental administration of ethanol showed similar morphine-potentiation effects [Mean Effective Dose: ED50 (M1)=4.5 mg/kg; ED50 (E1)=2.4 mg/kg; ED50 (E*1)=2.1 mg/kg]. On day 11, control group mice showed a reduction of morphine analgesia at test [ED50 (M11)=14.1 mg/kg]. Mice receiving i.p. and environmental ethanol again showed a leftward shift in dose-response cumulative curves for morphine antinociception with respect to controls [ED50 (E11)=9.1 mg/kg; ED50 (E*11)=4.7 mg/kg]. I.p. ethanol administration at non-antinociceptive doses enhances the morphine antinociception effect similarly in tolerant and non-tolerant (naive) mice. The presence of environmental ethanol can also induce a similar pattern of increase in morphine antinociception effect.     

Experimental study of the effects of amiridin and tacrine on learning and memory

The authors studied the influence of amiridin and tacrine on learning and memory in mice and rat by passive avoidance conditioning test at norm and under scopolamine induced amnesia as well as of their effect on acetylcholine esterase (AChE) activity in brain cortex homogenates. Amiridin in doses 0.1 and 0.2 mg/kg showed a beneficial action on conditioning in untreated animals, its effect being comparable with that of piracetam. Tacrine was ineffective. In scopolamine treated animals amiridin and tacrine showed anti-amnestic action at dose of 0.1 mg/kg which was found ineffective with respect to AChE activity. The data suggests that the ameliorating effect of amiridin and tacrine on cognitive abilities in patients with senile dementia is not related their anticholinesterase properties.     

Short-term tolerance to morphine: Effects of indomethacin

Short-term tolerance to opiates has been demonstrated in as little as three hours after priming with a single dose of morphine in naive animals. Tail-flick latency in mice and changes in plasma corticosterone in rats were the indicators tested in these experiments. Rats primed with either saline or morphine, 10 mg/kg, were injected 3 hrs. subsequently with morphine, 5 mg/kg. Those primed with saline showed the characteristic plasma corticosterone elevation following morphine, when serial blood samples were examined, whereas those previously treated with morphine did not. Mice were primed with saline or either of two doses of morphine, 30 or 100 mg/kg, 3.5 hrs. prior to estimation of tail-flick latency and ED 50 determinations. Mice primed with either dose of morphine had significantly higher ED50's than those primed with saline. The effects of indomethacin, 5 or 10 mg/kg, were examined on both systems. Rats and mice were pretreated with indomethacin at 2.25 or 3 hrs., respectively, before morphine-priming. In all cases, indomethacin did not produce alterations in responses previously observed in correspondently treated controls.     

Nicotine improves morphine-induced impairment of memory: possible involvement of N-methyl-D-aspartate receptors in the nucleus accumbens

The possible involvement of N-methyl-D-aspartate (NMDA) receptors in the nucleus accumbens (NAc) in nicotine's effect on impairment of memory by morphine was investigated. A passive avoidance task was used for memory assessment in male Wistar rats. Subcutaneous (s.c.) administration of morphine (5 and 10 mg/kg) after training impaired memory performance in the animals when tested 24 h later. Pretest administration of the same doses of morphine reversed impairment of memory because of post-training administration of the opioid. Moreover, administration of nicotine (0.2 and 0.4 mg/kg, s.c.) before the test prevented impairment of memory by morphine (5 mg/kg) given after training. Impairment of memory performance in the animals because of post-training administration of morphine (5 mg/kg) was also prevented by pretest administration of a noncompetitive NMDA receptor antagonist, MK-801 (0.75 and 1 microg/rat). Interestingly, an ineffective dose of MK-801 (0.5 microg/rat) in combination with low doses (0.075 and 0.1 mg/kg) of nicotine, which had no effects alone, synergistically improved memory performance impaired by morphine given after training. On the other hand, pretest administration of NMDA (0.1 and 0.5 microg/rat), which had no effect alone, in combination with an effective dose (0.4 mg/kg, s.c.) of nicotine prevented the improving effect of nicotine on memory impaired by pretreatment morphine. The results suggest a possible role for NMDA receptors of the NAc in the improving effect of nicotine on the morphine-induced amnesia.     

Discriminative stimulus,antagonist, and rate-decreasing effects of cyclorphan: Multiple modes of action

The discriminative effects of cyclorphan were studied in pigeons trained to discriminate 0.32 mg/kg ethylketazocine, 1.8 mg/kg cyclazocine, or 32 mg/kg naltrexone from saline. A fourth group of pigeons was administered 100 mg/kg/day morphine and trained to discriminate 0.1 mg/kg naltrexone from saline. Cyclorphan produced dose-related ethylketazocine-appropriate responding that reached a maximum of 83% of the total session responses at 0.3 mg/kg. Higher cyclorphan doses produced less ethylketazocine-appropriate responding. In pigeons trained to discriminate cyclazocine from saline, maximum drug-appropriate responding of greater than 90% occured at 5.6–10.0 mg/kg cyclorphan. In narcotic-naive pigeons trained to discriminate 32 mg/kg naltrexone from saline, cyclorphan produced a maximum of less than 50% drug-appropriate responding. In contrast, in pigeons chronically administered morphine and trained to discriminate 0.1 mg/kg naltrexone from saline, 1.0 mg/kg cyclorphan resulted in 100% drug-appropriate responding. In pigeons responding under a multiple fixed-interval, fixed-ratio schedule of food delivery, cyclorphan produced a complete dose-related reversal of the rate-decreasing effects of 10 mg/kg morphine, the maximally effective antagonist doses being 1.0–3.2 mg/kg. Higher cyclorphan doses (10 mg/kg) resulted in response rate decreases that were not reversed by naloxone (1 mg/kg). Thus, cyclorphan has discriminative effects that are similar to those of both ethylketazocine and, at 20-fold higher doses, cyclazocine. In addition, in morphine-treated pigeons, cyclorphan, across the same range of doses that produce ethylketazocine-appropriate responding, has discriminative effects that are similar to those of naltrexone, an effect that is probably related to the antagonist action of the drug.     

Novelty-seeking behavior and stress-induced locomotion in rats of juvenile period differentially related to morphine place conditioning in their adulthood

The relationship between motor responses in a novel environment and susceptibility to place conditioning effect of psychostimulants has been reported in adult rats. However, it is in question whether this correlation could be generalized to motor activity in rats of juvenile period and place conditioning effect in their adulthood for narcotic morphine. In the present study, we tested locomotor activity in an arena open-field and the subsequent novelty-seeking behavior after adaptation process in juvenile rats (P42) and morphine (2 mg/kg) place conditioning effect 56 days later in the same rats' adulthood (P98). Our results showed that rats with high response to novelty (HRN) spent more prolonged duration in the drug-paired compartment in the place conditioning test compared with their low response counterparts (LRN), with the latter group no salient change on this measure. Moreover, rats with high response to the open-field test (HRS) expressed equally elevated duration in drug-paired side relative to their low response counterparts (LRS). The present research demonstrated that novelty-seeking behavior and locomotor activity in the open-field in rats of juvenile period differentially related to morphine place conditioning in their adulthood, with slow acquisition of morphine place conditioning effect in LRN animals.     

Short-term tolerance to morphine: effects of diazepam, phenobarbital, and amphetamine

Short-term tolerance to morphine, which can be demonstrated in as little as 3 hours after a single administration of the opiate, was examined in animals chronically pretreated with diazepam, phenobarbital, or amphetamine. Tail-flick latency in mice and changes in plasma corticosterone in rats were the parameters tested in these experiments. Rats primed with either saline or morphine, 10 mg/kg, were injected 3 hours subsequently with morphine, 5 mg/kg. Those primed with saline showed the characteristic plasma corticosterone elevation following morphine, when serial blood samples were examined, whereas those previously treated with morphine did not. Mice were primed with saline or either of two doses of morphine, 30 or 100 mg/kg, 3.5 hours prior to estimation of tail-flick latency and ED50 determinations. Mice primed with either dose of morphine had significantly higher ED50's than those primed with saline. Chronic treatment with diazepam or amphetamine in either species did not significantly alter short-term tolerance development by either parameter. However, with phenobarbital pretreatment, the plasma corticosterone response was attenuated and short-term tolerance to morphine's analgesic effects did not occur. Further studies in morphine-pelleted mice showed that analgesic tolerance occurred similarly in all groups. This suggests that barbiturates may delay the process.     

Parity-associated reductions in behavioral sensitivity to opiates

Behavioral and physiological responses differ between primiparous and multiparous female rodents. Specifically, multiparous females respond with the full repertoire of maternal behaviors much more rapidly and with greater intensity than their primiparous counterparts. Since opiates inhibit the expression of maternal behavior in postpartum rats and can be reversed by means of the opiate antagonist naloxone, we investigated whether multiparous females would be resistant to the inhibitory effects of opiates on maternal behavior, relative to primiparous females. In Experiment 1 we evaluated the effects of a range of doses of morphine sulfate (MS; 0.625, 1.25, 2.5, 5.0, and 10.0 mg/kg or saline) on maternal behavior in primiparous females on Days 5-6 of lactation. The 5.0 and 10.0 mg/kg doses effectively disrupted maternal behavior, whereas the lower doses were ineffective or only marginally disruptive. In Experiment 2, age-matched female rats were timed-mated and tested for maternal behavior from Day 5 to 13 of lactation, after daily injections of the 5.0 mg/kg dose of MS. On Day 5 of lactation, this morphine treatment eliminated full maternal behavior in 87% of the primiparous animals, but only 37% of the multiparous animals were affected. By Day 10 of lactation, 100% of the multiparous females displayed full maternal behavior after MS treatment, whereas only 69% of primiparous females were responsive. In Experiment 3, analgesic responses were measured both in rats experiencing their initial or second pregnancy, and in postpartum, lactating rats after MS (5.0 mg/kg) administration. Using a tail-flick apparatus to measure analgesia, we found multigravid females to be significantly less analgesic prepartum than primigravid females, suggesting less sensitivity to endogenous opioids.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cardiovascular effects of naloxone,naltrexone and morphine in the squirrel monkey

Heart rate (HR) and mean arterial blood pressure (BP) were recorded from conscious, chair-restrained squirrel monkeys surgically prepared with chronically indwelling arterial and venous catheters to determine the effects of acute intravenous injections of two opiate antagonists and an agonist. Naloxone (0.3–10.0 mg/kg) or naltrexone (0.3–10.0 mg/kg) had little effect on HR or BP during a 30-minute post-injection period. Morphine (3.0–5.6 mg/kg) produced biphasic effects comprising an initial decrease followed by an increase in HR, and an increase followed by a decrease in BP. Lower morphine doses had lesser effects during a 100-minute post-injection period. Pre-treatment with 0.03 mg/kg naloxone attenuated the depressive effect of morphine on HR and BP, but increases in HR and BP due to morphine were enhanced. Pretreatment with 0.3 mg/kg naloxone prevented morphine-induced decreases in HR and BP, yet increases in HR and BP persisted. In previous behavioral studies, morphine in combination with naloxone similarly increased rates of responding in the squirrel monkey. Together, these data suggest an effect of naloxone that goes beyond mere pharmacological antagonism of the effects of morphine.