In vivo electrochemical detection of 5-hydroxyindole within the trigeminal nucleus caudalis of freely moving rats: the effect of morphine

Acute morphine administration increases extracellular DA levels in the rat lateral septum by decreasing the GABAergic inhibitory tone in the ventral tegmental area

We studied the effect of an acute systemic administration of morphine and of a local intra-ventral tegmental area (VTA) infusion of the same drug on extracellular levels of dopamine (DA) in the lateral septum (LS) by in vivo microdialysis in anesthetized rats. The extracellular levels of 5-hydroxytryptamine (5-HT) were also measured in all dialysate samples. The acute systemic administration of morphine dose-dependently increased extracellular levels of DA but not of 5-HT in the LS, in the absence or presence of fluoxetine. This morphine effect was antagonized by the previous administration of naloxone, a specific opioid antagonist. The local infusion of morphine in the VTA also induced a significant increase of the extracellular levels of DA in the LS, concomitantly with a decrease of gamma-aminobutyric acid (GABA) extracellular levels in the VTA itself. Intriguingly, the LS extracellular levels of DA returned to basal values before the VTA GABA extracellular levels recovered. Our results show for the first time that an acute administration of morphine increases DA extracellular levels in the LS. The results also suggest that DA cells in the VTA and innervating the LS are under an inhibitory GABAergic tone sensitive to morphine. Taken together, our neurochemical data and previous studies involving LS DA in stress-related behavior support the hypothesis that DA in the LS plays a significant role in addictive behavior. The participation of LS DA and 5-HT systems in stress-induced relapse to drug seeking should be studied further.

Effect of chronic analgesic exposure on the central serotonin system: a possible mechanism of analgesic abuse headache

OBJECTIVE

To investigate the effects of chronic analgesic exposure on the central serotonin system and the relationship between the serotonin system and the analgesic efficacy of nonnarcotic analgesics.

METHODS

Paracetamol was administered daily to adult male Wistar rats for a period of 15 or 30 days. Analgesic efficacy was measured by the tail flick test. After completion of the treatment protocol, the rats were humanely killed, and the frontal cortex and brain stem were isolated. Characteristics of the specific binding of the 5-HT2A serotonin receptor and the serotonin transporter were studied using a radioligand binding technique. Platelet serotonin was determined by high-performance liquid chromatography.

RESULTS

Chronic paracetamol administration resulted in a significant decrease in the maximum number of 5-HT2A binding sites and an increase in the maximum number of 5-HT transporter binding sites in frontal cortical membrane (P<.001). Changes in the central 5-HT system were associated with a rise in platelet 5-HT levels. The degree of receptor downregulation, as well as transporter upregulation, became less evident after more prolonged drug administration. Readaptation of serotonin receptors and transporters coincided with the decrease in the analgesic efficacy of paracetamol, as well as a fall in platelet 5-HT levels.

CONCLUSIONS

These findings provide further evidence in support of an involvement of the 5-HT system in the antinociceptive activity of simple nonnarcotic analgesics. Plasticity of this neurotransmitter system after chronic analgesic exposure may lead to the loss of analgesic efficacy and, in its more extreme form, may produce analgesic-related painful conditions, for example, analgesic abuse headache.

Opioids suppress spontaneous and NMDA-induced inhibitory postsynaptic currents in the dorsal raphe nucleus of the rat in vitro

Recently, local injection of morphine in the dorsal raphe nucleus (DRN) has been shown to increase serotonin release in the forebrain of unanesthetized rats. This study investigated the site of action of opioids in rat brain slices containing the DRN. Postsynaptic currents (PSCs), measured intracellularly under voltage clamp, were induced in serotonergic neurons with bath and microiontophoretic applications of NMDA to activate local neurons. Met-enkephalin (ENK) suppressed spontaneous and NMDA-induced GABAergic inhibitory PSCs. This effect, which was mimicked by the mu agonist DAMGO but not the kappa-agonist U50488 or the delta-agonist DPDPE, was reversed by the mu antagonist CTOP. ENK also suppressed spontaneous and NMDA-induced glutamatergic excitatory PSCs. By searching with focal microiontophoretic NMDA applications, GABAergic and glutamatergic cells projecting on serotonergic neurons were found in the DRN and the adjacent periaqueductal gray. Consistent with the reduction in PSCs, ENK inhibited/hyperpolarized the great majority (81%) of non-serotonergic neurons recorded extra- and intracellularly in the DRN; the ENK effect reversed polarity at -99 +/- 9 mV, close to the potassium reversal potential. In contrast, ENK inhibited/hyperpolarized only 28% of serotonergic neurons; in the affected cells, the ENK effect, blocked by CTOP, had its reversal potential shifted with change of extracellular potassium in agreement with the value predicted by the Nernst equation for a potassium conductance; serotonin occluded the ENK inhibition. Taken together, these results indicate that opioids inhibit both local GABAergic and glutamatergic cells projecting onto DRN serotonergic neurons.

Effects of electrical stimulation and morphine microinjection into periaqueductal gray on 5-hydroxyindole oxidation current in spinal cord of cats

1. The effects of electrical stimulation and microinjection of morphine into the periaqueductal gray (PAG) on the 5-hydroxyindole oxidation current (280-300 mV) in laminae I-VI (800-2500 microns) of the spinal cord were examined using in vivo voltammetry in anesthetized cats. 2. Electrical stimulation of the PAG (PAG-S) both enhanced and attenuated the current. PAG-S increased the signal by 13.3 +/- 3.7% (laminae I-II: 800-1200 microns) or 19.0 +/- 3.6% (laminae V-VI: 1700-2500 microns) in comparison to control values. Attenuation by PAG-S decreased the signal by 15.3 +/- 2.6% (laminae I-II) or 13.3 +/- 2.0% (laminae V-VI) of control values. Naloxone antagonized signal enhancement by PAG-S. 3. Morphine (10 micrograms/microliter) microinjected into the PAG significantly increased the height of the signal (laminae I-II: 15.0 +/- 3.4%, laminae V-VI: 12.2 +/- 1.5%). Enhancement by microinjected morphine was antagonized by naloxone. In contrast, microinjected morphine also significantly decreased the signal by 10.4 +/- 2.7% (laminae I-II) and by 10.3 +/- 1.3% (laminae V-VI) of control values. 4. Microinjection of morphine and electrical stimulation of the PAG was observed both to enhance and attenuate the oxidation current of 5-hydroxyindole in the superficial and deeper dorsal horn. PAG may function to regulate the RVM-spinal serotonergic pathway, which modulates the transmission of nociceptive messages at the spinal cord.

Relationship between analgesia and extracellular morphine in brain and spinal cord in awake rats

Extracellular concentrations of morphine from the dorsal spinal cord, the periaqueductal gray (PAG) including the dorsal raphé, and the lateral hypothalamus were measured by microdialysis in awake rats after intraperitoneal (i.p.) administration of 2.5, 5.0 and 10 mg/kg morphine. Morphine concentrations in all areas showed similar time courses: morphine was detected in the first dialysate sample (13-15 min) and maximal concentrations were reached at 45 min after injection. When in vivo recoveries of morphine from the spinal cord and brain areas were taken into account, no significant differences between morphine concentrations in the various areas were found. The relationship between extracellular morphine concentrations and morphine-induced analgesic behavior was investigated by simultaneously measuring morphine in the dialysate and its analgesic effect in the paw-withdrawal and tail-flick tests. In all areas sampled, the extracellular concentrations of morphine at different times after i.p. injection, significantly correlated with the magnitude of behavioral analgesia assessed by either test. The highest correlation was obtained between extracellular concentrations of morphine in the spinal cord and PAG and behavioral analgesia assessed in the paw-withdrawal test. Our data indicate that, after systemic injection, morphine is evenly distributed throughout the spinal cord and brain including potential anatomical sites of morphine's analgesic action. We estimate that the minimal extracellular morphine concentration in spinal cord that is required to produced a significant increase in nociceptive threshold is approximately 100 pg/25 microl, which corresponds to a tissue concentration of about 100 mg/g of morphine.

High sensitivity measurement of brain catechols and indoles in vivo using electrochemically treated carbon-fiber electrodes

The combination of electrochemically treated carbon-fiber electrodes with DPV, DNPV or DPA represents a wide range of possibilities. As shown in this review, the choice of treatment and measurement technique depends on the purpose. As regards in vivo monitoring of 5-HIAA or DOPAC from very small brain nuclei, electrochemically treated carbon-fiber electrodes appear very potent and inexpensive. The main limitation of the established electrochemical techniques, including those discussed here, is that the unequivocal measurement of the basal extracellular neurotransmitter level cannot be achieved unless animals are treated with pargyline. On the other hand, this monitoring is feasible with in vivo dialysis. Therefore, electrochemical techniques, on the one hand, and in vivo dialysis, on the other hand, present different advantages. The former are much more potent than the latter in two respects. First, due to the much smaller size of the sensor, electrochemical techniques are more suitable for studying small brain nuclei. Second, since electrochemical techniques exhibit a better temporal resolution, they are recommended for investigating the relationship between impulse flow and neurotransmitter release. However, when high anatomical or temporal resolution is not required, in vivo dialysis is more suitable for recording the basal monoamine release.

Effects of tianeptine on 5-hydroxyindoles and on the morphine-induced increase in 5-HT metabolism at the medullary dorsal horn level as measured by in vivo voltammetry in freely moving rats

The present study, by the use of in vivo electrochemical detection of 5-hydroxyindole (peak '3') in the bulbo spinal serotonergic system at the medullary dorsal horn (MDH) level, investigated the effects of the new tricyclic antidepressant (TCA) tianeptine, which has been shown to be a specific serotonin (5-HT) uptake enhancer. It was found that acutely administered tianeptine (10 mg/kg, i.p.) induced a marked significant increase in peak 3 within the dorsal horn, an in vivo observation which is in accordance with the biochemical properties of tianeptine as studied in forebrain structures. In addition, the effect of tianeptine on the morphine-induced increase in 5-HT metabolism was investigated, by comparison with the previous data obtained with the specific 5-HT uptake inhibitor femoxetine in the MDH. It was shown that tianeptine can display additive effect with morphine (10 mg/kg, i.p.) on 5-HT metabolism at the MDH level. These results are discussed in relation to the effects of classical TCAs and the particular properties of tianeptine.

Morphine induces an increase in extracellular serotonin in the rat diencephalon

The effect of systemic morphine on extracellular serotonin (5-HT) in the diencephalon of unanesthetized, unrestrained rats was investigated by in vivo microdialysis coupled to high performance liquid chromatography with electrochemical detection. Administration of morphine resulted in a dose dependent increase in extracellular 5-HT. Significant increases were first seen at a dose of 5 mg/kg, and a maximal increase occurred at 10 mg/kg. This increase was blocked by pretreatment with naltrexone, indicating that the effect of morphine on 5-HT was mediated by opiate receptors. Morphine also had a significant effect on extracellular 5-hydroxyindoleacetic acid (5-HIAA), leading to a gradual increase across a range of doses. The effect of morphine on 5-HT was compared to effects of morphine on nociception and catalepsy. Increases in 5-HT and 5-HIAA were first detected at doses that were analgesic but too low to elicit catalepsy. Consistent with many reports that opioids cause an increase in synthesis and turnover of 5-HT in the rat forebrain, the present results provide more direct evidence that 5-HT release is increased after morphine administration.

Effect of subcutaneous administration of the chemical algogen formalin, on 5-HT metabolism in the nucleus raphe magnus and the medullary dorsal horn: a voltammetric study in freely moving rats

The effect of subcutaneous administration of the chemical algogen formalin, on serotonin (5-HT) metabolism in the nucleus raphe magnus (NRM) and the medullary dorsal horn (MDH) has been investigated using in vivo 5-hydroxyindole electrochemical (peak '3') detection with treated, multi-carbon fiber electrodes and differential pulse, or normal pulse, voltammetry in freely moving rats. The subcutaneous (s.c.) injection of 50 microliters of 10% formalin in the left forepaw was followed, at the NRM level, by a significant increase in the voltammograms as compared to controls (50 microliters of saline 0.9% s.c. in left forepaw) for about 70 min after the injection, before a return to control values. At the MDH level, the formalin injection induced no significant effect on peak 3, as compared to controls, during the first 70 min. After that, the voltammograms significantly increased and remained above controls for up to 180 min. Thus, the time-courses of NRM and MDH effects appear markedly different. These findings suggest that, depending on the anatomical level (NRM or MDH) and/or the period of observation, one can measure differences in the time-course of the increase in 5-HT metabolism in the NRM-dorsal horn serotonergic system by tonic noxious stimuli, such as the formalin test.

Axonal and somato-dendritic modalities of serotonin release: their involvement in sleep preparation, triggering and maintenance

That serotonin (5-HT) plays a determinant role in sleep was first suggested by the well-known PCPA-5HTP (p.chlorophenylalanine-5-hydroxytryptophan) paradigm. This involvement, however, is paradoxical since localized cooling of the nucleus raphe dorsalis (n.RD) is sleep inducing, and unitary activity of 5-HT neurons decreases during slow wave sleep (SWS) and paradoxical sleep (PS). Furthermore, on the basis of voltammetric 5-hydroxyindole (5-OHles) measurements, it appears that 5-HT could be released throughout the sleep/wake cycle according to two different modalities: by the axonal nerve endings during the waking state (W) and by the dendrites and/or the soma during sleep. The axonal release of 5-HT might participate in sleep preparation by stimulating the synthesis of hypnogenic factors within target structures like the basal hypothalamus (BH). When such a release is increased by an immobilization stress (IS) or electrical stimulation of the n.RD, a sleep rebound is induced. The somato-dendritic release of 5-HT might be primarily responsible through an auto-inhibitory process for the decrease and abolition of the 5-HT neuronal unitary activity as well as for the reduction of the axonal release of 5-HT; both phenomena being constantly observed during sleep. Finally, the hypnogenic factors might initiate and maintain sleep by influencing the n.RD sleep gating mechanisms either through the somato-dendritic release of 5-HT, or directly.

The response of the 5-hydroxyindole oxidation current to noxious stimuli in the spinal cord of anesthetized rats: modification by morphine

The effects of cutaneous noxious heating and of systemic morphine on serotonergic activity in the spinal cord were examined in anesthetized rats. An oxidation current of 5-hydroxyindole signal was seen at 280-300 mV with differential normal pulse voltammetry. Noxious heat stimuli produced a mean signal increase over control values of 15.5 +/- 3.4% at 52 degrees C, and 7.2 +/- 5.5% at 45 degrees C. These increases lasted for 5-10 min. Non-noxious stimuli (37 degrees C) did not affect the 5-hydroxyindole signal. Morphine (0.5, 2.0 and 5.0 mg/kg, i.p.) in the absence of cutaneous stimulation did not change the signal significantly. Systemic morphine alone did not significantly modify the 5-hydroxytryptamine (5-HT) metabolism, as observed in in vivo voltammetry, in the spinal cord of anesthetized rat. However, a low dose of morphine (0.5 mg/kg, i.p.) attenuated the increase in the signal modified by noxious stimuli, and high doses (2.0 or 5.0 mg/kg, i.p.) enhanced it. Both effects of morphine were antagonized by naloxone (0.5 mg/kg, i.v.). It is likely that morphine with noxious stimuli modify the sensitivity of serotonergic descending inhibitory system. It is concluded that noxious heating of the skin increases the 5-HT metabolism in the spinal cord of anesthetized rats and that systemic administration of morphine modulates this 5-HT metabolism.

Simultaneous measurement of extracellular morphine and serotonin in brain tissue and CSF by microdialysis in awake rats

In this report, we describe an HPLC with electrochemical detection assay for the simultaneous measurement of levels of morphine, serotonin, 5-hydroxyindole-3-acetic acid, and homovanillic acid in dialysates of various brain areas and CSF in the awake rat. Morphine could be detected in the dialysates after a single intraperitoneal injection, with doses as low as 1.0 mg/kg. The time course of extracellular morphine content in the lateral hypothalamus, striatum, cerebellum, periaqueductal gray, and dorsal horn of the spinal cord and in CSF, from the ventricles and cisterna magna, was similar. We detected morphine in the first 15-min sample, and levels peaked 45-60 min after injection. Maximal dialysate levels, however, varied with the type of dialysis probe used and the area sampled. The most efficient in vivo recovery was in CSF dialysates from the cisterna magna, presumably because of minimal tissue interference with the dialysis probe. For this reason, the cisterna is an ideal region for sampling CSF. Morphine had no significant effect on the extracellular concentrations of serotonin in any of the areas studied and did not modify or only slightly increased levels of tissue metabolites; however, morphine markedly increased the CSF levels of 5-hydroxyindole-3-acetic acid and homovanillic acid. Because microdialysis in freely moving animals permits assessment of the behavioral effects of morphine while continuously monitoring the drug levels in discrete brain regions, this approach will greatly facilitate future studies of the neurochemical basis of morphine's effects in the brain.

Do opioids evoke the release of serotonin in the spinal cord? An in vivo microdialysis study of the regulation of extracellular serotonin in the rat

This study investigated the regulation of serotonin (5-HT) and its major metabolite 5-hydroxyindoleacetic acid (5-HIAA) in the dorsal spinal cord of awake, freely moving rats, using microdialysis coupled to HPLC with electrochemical detection and tested the hypothesis that opioids exert their analgesic effect in part through the increased release of 5-HT in the dorsal horn. A dialysis tube was placed transversely at the L4 segment of the dorsal spinal cord and the basal concentration of 5-HT in the dialysate was characterized by infusion of a variety of substances through the dialysis probe: tetrodotoxin (TTX), KCl, imipramine, fluoxetine and amphetamine (AMPH). To evaluate the contribution of opioids, we also studied the effects of either systemic or intracerebroventricular (i.c.v.) injection of morphine or DAMGO. Extracellular concentrations of 5-HT and 5-HIAA were partially and reversibly reduced by TTX. In the presence of KCl, imipramine, fluoxetine or AMPH, 5-HT levels significantly increased. Under these conditions, extracellular 5-HIAA levels usually decreased. By contrast, the effects of opioids on 5-HT concentrations were highly variable. Low doses of morphine administered systemically increased 5-HT concentrations in only 3 of 6 rats. This was paralleled by a decrease in 5-HIAA. Higher doses of morphine, alone or in the presence of fluoxetine, did not change 5-HT concentrations. Intracerebroventricular injection of morphine or DAMGO increased the extracellular concentrations of 5-HT in only about one third of the animals. After intracerebroventricular opioid injection, extracellular concentrations of 5-HIAA either decreased by about 20% or did not change.(ABSTRACT TRUNCATED AT 250 WORDS)

Femoxetine blocks the morphine-induced increase in 5-HT metabolism, as measured by in vivo voltammetry in the nucleus raphe magnus of freely-moving rats

Tricyclic antidepressants, when administered acutely, are known to potentiate morphine-induced antinociception. Systemic administration of morphine has been shown to increase the metabolism of serotonin (5-HT) at the level of the nucleus raphe magnus, as measured by in vivo electrochemistry, in freely-moving rats. Using a similar electrochemical detection of 5-hydroxyindole (peak "3") in the nucleus raphe magnus, the present study investigated the effect of the specific 5-HT uptake inhibitor, femoxetine, on peak 3 and on changes in the metabolism of 5-HT, induced by morphine. Acutely administered femoxetine (40 mg/kg i.p.) induced a significant decrease in peak 3 and completely abolished the effect of morphine (10 mg/kg i.p.) on the metabolism of 5-HT. These data do not support the contention that potentiation of morphine-induced analgesia, by tricyclic depressants results from an interaction between the tricyclic antidepressants and the morphine-induced increase in metabolism of 5-HT, at the level of the nucleus raphe magnus.

In vivo electrochemical evidence that the tricyclic antidepressant femoxetine potentiates the morphine-induced increase in 5-HT metabolism in the medullary dorsal horn of freely moving rats

Acute administration of tricyclic antidepressants (TCAs) is known to potentiate morphine antinociception. At the medullary dorsal horn (MDH) level systemic morphine has been shown to increase serotonin (5-HT) metabolism as measured by in vivo electrochemistry in freely moving rats. Using similar electrochemical detection of 5-hydroxyindole (peak '3') within the MDH, the present study investigated the effect of the specific 5-HT uptake inhibitor femoxetine on peak 3 and the effects of this TCA on changes in 5-HT metabolism induced by morphine. Acutely administered femoxetine (40 mg/kg i.p.) (i) induced a small but significant increase in peak 3 and (ii) strongly potentiated the effect of morphine (10 mg/kg i.p.) on 5-HT metabolism, this potentiation being opiate specific since simultaneous injection of naloxone (1 mg/kg i.p.) abolished the effect of morphine. These findings provide an in vivo neurochemical basis for the potentiation of morphine antinociception by TCAs. They further emphasize the importance of 5-HT bulbospinal descending pathways in morphine antinociception.

A comparison of the effects of morphine on 5-HT metabolism in the periaqueductal gray, ventromedial medulla and medullary dorsal horn: in vivo electrochemical studies in freely moving rats

The effect of systemic morphine on serotonin (5-HT) metabolism within the dorsal raphe nucleus (DRN) has been investigated by in vivo 5-hydroxyindole electrochemical (peak '3') detection in freely moving rats. Morphine caused a weak and delayed, but naloxone-reversible, increase in peak '3'. This increase was poorly, if at all, correlated with the morphine-induced analgesia. Finally, stress and/or noxious stimulation had no effect on this signal. These results are compared with our previous studies using the same methodological approaches and show that morphine caused a significant and specific increase in 5-HT metabolism at the levels of nucleus raphe magnus (NRM) and medullary dorsal horn. Furthermore, as shown in the present paper, there was also a good correlation between the time course of such increases and the analgesic effect of morphine. These findings are discussed with reference to the involvement of 5-HT mechanisms in the so-called DRN-NRM-dorsal horn 'intrinsic analgesic system'.