Cannabidiol and endogenous opioid peptide-mediated mechanisms modulate antinociception induced by transcutaneous electrostimulation of the peripheral nervous system.

Transcutaneous electrical nerve stimulation (TENS) is a non-pharmacological therapy for the treatment of pain. The present work investigated the effect of cannabidiol, naloxone and diazepam in combination with 10 Hz and 150 Hz TENS. Male Wistar rats were submitted to the tail-flick test (baseline), and each rodent received an acute administration (intraperitoneal) of naloxone (3.0mg/kg), diazepam (1.5mg/kg) or cannabidiol (0.75 mg/kg, 1.5mg/kg, 3.0mg/kg, 4.5mg/kg, 6.0mg/kg and 12.0mg/kg); 10 min after the acute administration, 10 Hz or 150 Hz TENS or a sham procedure was performed for 30 min. Subsequently, tail-flick measures were recorded over a 90-min period, at 5-min intervals. 10 Hz TENS increased the nociceptive threshold during the 90-min period. This antinociceptive effect was reversed by naloxone pre-treatment, was not altered by diazepam pre-treatment and was abolished by cannabidiol pre-treatment (1.5mg/kg). Moreover, 150 Hz TENS increased tail-flick latencies by 35 min post-treatment, which was partially inhibited by naloxone pre-treatment and totally inhibited by cannabidiol (1.5mg/kg). These data suggest the involvement of the endogenous opioid system and the cannabinoid-mediated neuromodulation of the antinociception induced by transcutaneous electrostimulation at 10 Hz and 150 Hz TENS.

Early exposure to chronic variable stress facilitates the occurrence of anhedonia and enhanced emotional reactions to novel stressors: reversal by naltrexone pretreatment.

The present research studied the influence of an early chronic variable stress (CVS) paradigm - an animal model of depression - on behavioral responses to subsequent environmental challenges suggested to model anhedonia and emotional reactions such as anxiety and fear. In order to explore a potential involvement of an endogenous opiate mechanism - presumably activated during CVS exposure - in the development of such behavioral reactions, in all experiments rats were administered naltrexone (NAL, 2 mg/kg, i.p.) or vehicle (VH) prior to each daily stressor of the CVS procedure. Animals were exposed to CVS and 1 week later tested for sucrose preference (1%) in a free choice paradigm after the presentation or not of a 90-min restraint period. Only CVS treated animals that were later exposed to restraint showed a reduction of sucrose preference, this reduction was absent when CVS rats were pretreated previously with NAL. Moreover, CVS rats were one week later tested on the elevated plus maze (EPM) and in their conditioned and unconditioned freezing response to a single shock session. Early chronic stress resulted in an anxiogenic behavior in the EPM and in an enhanced conditioned and unconditioned freezing which were all abolished by NAL pretreatment. These behavioral findings suggest that the potential activation of an endogenous opiate mechanism during CVS participates in the development of anhedonia and exaggerated emotional reactions in response to subsequent stressful experiences.

Zinc and water intake in rats: investigation of adrenergic and opiatergic central mechanisms.

We have demonstrated that central administration of zinc in minute amounts induces a significant antidipsogenic action in dehydrated rats as well as in rats under central cholinergic and angiotensinergic stimulation. Here we show that acute third ventricle injections of zinc also block water intake induced by central ss-adrenergic stimulation in Wistar rats (190-250 g). Central inhibition of opioid pathways by naloxone reverses the zinc-induced antidipsogenic effect in dehydrated rats. After 120 min, rats receiving third ventricle injections of isoproterenol (160 nmol/rat) exhibited a significant increase in water intake (5.78 +/- 0.54 ml/100 g body weight) compared to saline-treated controls (0.15 +/- 0.07 ml/100 g body weight). Pretreatment with zinc (3.0, 30.0 and 300.0 pmol/rat, 45 min before isoproterenol injection) blocked water intake in a dose-dependent way. At the highest dose employed a complete blockade was demonstrable (0.54 +/- 0.2 ml/100 g body weight). After 120 min, control (NaAc-treated) dehydrated rats, as expected, exhibited a high water intake (7.36 +/- 0.39 ml/100 g body weight). Central administration of zinc blocked this response (2.5 +/- 0.77 ml/100 g body weight). Naloxone pretreatment (82.5 nmol/rat, 30 min before zinc administration) reverted the water intake to the high levels observed in zinc-free dehydrated animals (7.04 +/- 0.56 ml/100 g body weight). These data indicate that zinc is able to block water intake induced by central ss-adrenergic stimulation and that zinc-induced blockade of water intake in dehydrated rats may be, at least in part, due to stimulation of central opioid peptides.

Zinc and water intake in rats: investigation of adrenergic and opiatergic central mechanisms

We have demonstrated that central administration of zinc in minute amounts induces a significant antidipsogenic action in dehydrated rats as well as in rats under central cholinergic and angiotensinergic stimulation. Here we show that acute third ventricle injections of zinc also block water intake induced by central ß-adrenergic stimulation in Wistar rats (190-250 g). Central inhibition of opioid pathways by naloxone reverses the zinc-induced antidipsogenic effect in dehydrated rats. After 120 min, rats receiving third ventricle injections of isoproterenol (160 nmol/rat) exhibited a significant increase in water intake (5.78 ± 0.54 ml/100 g body weight) compared to saline-treated controls (0.15 ± 0.07 ml/100 g body weight). Pretreatment with zinc (3.0, 30.0 and 300.0 pmol/rat, 45 min before isoproterenol injection) blocked water intake in a dose-dependent way. At the highest dose employed a complete blockade was demonstrable (0.54 ± 0.2 ml/100 g body weight). After 120 min, control (NaAc-treated) dehydrated rats, as expected, exhibited a high water intake (7.36 ± 0.39 ml/100 g body weight). Central administration of zinc blocked this response (2.5 ± 0.77 ml/100 g body weight). Naloxone pretreatment (82.5 nmol/rat, 30 min before zinc administration) reverted the water intake to the high levels observed in zinc-free dehydrated animals (7.04 ± 0.56 ml/100 g body weight). These data indicate that zinc is able to block water intake induced by central ß-adrenergic stimulation and that zinc-induced blockade of water intake in dehydrated rats may be, at least in part, due to stimulation of central opioid peptides

Mecanismos cerebrales de reforzamiento del alcohol. II. Base neuroquímicas: papel del sistema opioide / Brain reinforcement mechanisms of alcohol. II. Neurochemical basis: Role of the opioid system

Numerosas evidencias sugieren la existencia de un componente biológico en los mecanismos cerebrales de reforzamiento del alcohol. Las investigaciones en neurociencias se han centrado en el estudio de los sustratos neurales y los sistemas de neurotransmisores implicados en estos mecanismos. Varios estudios muestran que los sistemas dopaminérgico, serotoninérgico y de péptidos opioides en el cerebro juegan un papel clave en estos procesos. El alcohol aumenta la transmisión dopaminérgica y serotoninérgica en regiones cerebrales asociadas a las vía de recompensa. La administración de agonistas dopaminérgicos y serotoninérgicos reduce la ingesta de alcohol, mientras que la de antagonistas dopaminérgicos la aumenta. Algunos estudios sugieren que los receptores D2, 5HT1A y 5-HT3 participan en estas respuestas. El alcohol y los péptidos opioides comparten muchas características farmacológicas y exhiben efectos similares sobre el comportamiento en animales y en el hombre. Se ha postulado al sistema opioide como posible mediador de los efectos reforzadores positivos del alcohol. El consumo de la sustancia es alterado por la administración de péptidos opiodes exógenos, y el alcohol, a su vez, afecta la actividad del sistema opioide. El etanol modifica la síntesis y la liberación de algunos péptidos opioides, así como la actividad de los receptores opiáceos muy delta. Por otro lado, la administración de antagonistas selectivos de los receptores muy delta reduce la preferencia por alcohol y la ingesta de la sustancia en animales. Los antagonistas opiáceos como la naltrexona, reducen las propiedades reforzadoras del alcohol en bebedores sociales y disminuyen la ingesta excesiva de la sustancia. En consecuencia, es posible que la preferencia por alcohol esté asociada con una activación aumentada del sistema opioide. El desarrollo de agentes farmacológicos capaces de modificar la transmisión de los péptidos opioides, así como la de otros neurotransmisores en el cerebro, tiene un uso terapeútico potencial para el tratamiento del alcoholismo en humanos

Activación del sistema de los opiodes endógenos por dosis subconvulsivamantes de metrazol / Activation of the endogenous opioid system with metrazol subconvulsivant dosis

Se investigaron las alteraciones en el sistema de los opioides endógenos en el cerebro de la rata, inducidas por la administración de una dósis subconvulsivante de metrazol (PTZ) (30 mg/kg i.p.). Por medio de experimentos de microdiálisis, encontramos durante los primeros 60 min después del tratamiento, una liberación importante de opiodes endógenos en el hipocampo y la amígdala cerebral. Posteriormente, los valores regresaron a los niveles basales. Por autorradiografía se observó un decremento en los niveles de los receptores mu en varias estructuras cerebrales. Mediante el análisis de la unión a receptores las membranas cerebrales, se confirmó un decremento en el número de estos receptores, sin cambios en su afinidad. En la aplicación de la prueba de Randall-Sellito, se encontró un aumento en el umbral de respuesta a estímulos dolorosos, durante los primeros 30 min. después del PTZ. Finalmente, experimentos de hibridación in situ revelaron un incremento en los niveles de la proencefalina a las 24 hrs después del tratamiento. Nuestros resultados indican que la administración de dosis subconvulsivante de PTZ activan de manera importante al sistema de los opiodes endógenos. Estos cambios resultan relevantes para entender el proceso del epileptogénesis y los mecanismos involucrados en el mismo

Sucrose ingestion causes opioid analgesia.

The intake of saccharin solutions for relatively long periods of time causes analgesia in rats, as measured in the hot-plate test, an experimental procedure involving supraspinal components. In order to investigate the effects of sweet substance intake on pain modulation using a different model, male albino Wistar rats weighing 180-200 g received either tap water or sucrose solutions (250 g/l) for 1 day or 14 days as their only source of liquid. Each rat consumed an average of 15.6 g sucrose/day. Their tail withdrawal latencies in the tail-flick test (probably a spinal reflex) were measured immediately before and after this treatment. An analgesia index was calculated from the withdrawal latencies before and after treatment. The indexes (mean +/- SEM, N = 12) for the groups receiving tap water for 1 day or 14 days, and sucrose solution for 1 day or 14 days were 0.09 +/- 0.04, 0.10 +/- 0.05, 0.15 +/- 0.08 and 0.49 +/- 0.07, respectively. One-way ANOVA indicated a significant difference (F(3, 47) = 9.521, P < 0.001) and the Tukey multiple comparison test (P < 0.05) showed that the analgesia index of the 14-day sucrose-treated animals differed from all other groups. Naloxone-treated rats (N = 7) receiving sucrose exhibited an analgesia index of 0.20 +/- 0.10 while rats receiving only sucrose (N = 7) had an index of 0.68 +/- 0.11 (t = 0.254, 10 degrees of freedom, P < 0.03). This result indicates that the analgesic effect of sucrose depends on the time during which the solution is consumed and extends the analgesic effects of sweet substance intake, such as saccharin, to a model other than the hot-plate test, with similar results. Endogenous opioids may be involved in the central regulation of the sweet substance-produced analgesia.

Sucrose ingestion causes opioid analgesia

The intake of saccharin solutions for relatively long periods of time causes analgesia in rats, as measured in the hot-plate test, an experimental procedure involving supraspinal components. In order to investigate the effects of sweet substance intake on pain modulation using a different model, male albino Wistar rats weighing 180-200 g received either tap water or sucrose solutions (250 g/I) for 1 day or 14 days as their only source of liquid. Each rat consumed an average of 15.6 g sucrose/day. Their tail withdrawal latencies in the tail-flick test (probably a spinal reflex) were measured immediately before and after this treatment. An analgesia index was calculated from the withdrawal latencies before and after treatment. The indexes (mean + SEM,N = 12) for the groups receiving tap water for 1 day or 14 days, and sucrose solution for 1 day or 14 days were 0.09 + 0.04, 0.10 + 0.05, 0.15 + 0.08 and 0.49 + 0.07, respectively. One-way ANOVA indicated a significant difference (F(3,47) = 9.521, P<0.001) and the Tukey multiple comparison test (P<0.05) showed that the analgesia index of the 14-day sucrose-treated animals differed from all other groups. Naloxone-treated rats (N = 7) receiving sucrose exhibited an analgesia index of 0.20 + 0.10 while rats receiving only sucrose (n = 7) had an index of 0.68 + 0.11 (t=0.254, 10 degreed of freedom, P<0.03). This result indicates that the analgesic effect of sucrose depens on the time during which the solution is consumed and extends the analgesic effects of sweet substance intake, such as saccharin, to a model other than the hot-plate test, with similar results. Endogenous opioids may be involved in the central regulation of the sweet substance-produced analgesia.