The local cerebral metabolic effects of morphine in rats exposed to escapable footshock

Activation of cerebral cortex during acoustic challenge or acute foot-shock in freely moving, nontethered rats

Most brain mapping techniques require immobilization of the subject, which extinguishes all but the simplest behaviors. We applied in freely moving rats an implantable microbolus infusion pump (MIP) which can be triggered by remote activation for the injection of the cerebral blood flow tracer [(14)C]iodoantipyrine during behavioral activation. Consistent with previous electrophysiological, metabolic and brain anatomic studies, CBF-related tissue radioactivity (CBF-TR) increased in acoustic cortex during a 1000 Hz/8000 Hz alternating tone. In response to an acute foot-shock, CBF-TR increased in visual cortex, parietal association cortex, and extended into primary motor cortex, and primary somatosensory cortex mapping the trunk. These results support the utility of implantable pumps as adjunct tools for studying cerebral activation during behavioral challenges in nontethered, nonrestrained animals.

A quantitative method for assessing of the affective component of the pain: conditioned response associated with CO2 laser-induced nocifensive reaction

Sensory and affective components are included in the overall behavioral manifestation in a nocifensive reaction. We have developed a behavioral model using classical conditioning to differentiate the affective component from the sensory responses following a thermal noxious stimulus. In laser-pain conditioning, free moving rats were trained to associate a tone (conditioned stimulus, CS) and short CO2 laser pulsation (unconditioned stimulus, US). A monotonous tone (800 Hz, 0.6 s) was delivered through a loudspeaker as the CS. CO(2) laser pulses (5 W at 100 ms in duration) applied to the hind paw were adopted as the US. The CS-US interval was 0.5 s. The conditioned responses as quantitatively measured by their body movement were developed over a period of 40 CS-US pairings. These conditioned responses were found retained when the rats were tested by presenting CS alone, immediate to and 24 h subsequent to training. The conditioned responses however diminished significantly following both morphine and buspirone treatment. This method demonstrated that neutral auditory stimuli could form association with unlearned nocifensive responses evoked by noxious CO2 laser pulses stimuli. Thus, the assessment of conditioned response may be a valuable tool for the measurement of the affective component of nociception.

Contribution of the anterior cingulate cortex to laser-pain conditioning in rats

The emotional component of nociception is seldom distinguished from pain behavioral testing. The aim of the present study was to develop a behavioral test that indicates the emotional pain responses using the classical conditioning paradigm. The role of the anterior cingulate cortex (ACC) in the process of this pain conditioning response was also evaluated. In laser-pain conditioning, free moving rats were trained to associate a tone (conditioned stimulus, CS) and short CO(2) laser pulsation (unconditioned stimulus, US). Monotonous tone (800 Hz, 0.6 s) was delivered through a loud-speaker as CS. CO(2) laser pulses (5 W at 50 or 100 ms in duration) applied to the hind paw was adopted as US. The CS-US interval was 0.5 s. Laser-pain conditioning was developed during 40 CS-US pairings. CS and US pairing with 100-ms laser pulse stimuli was more effective in establishing conditioning responses than that of 50-ms stimuli. The conditioning responses remained, tested by presenting CS alone, immediate to and 24 h subsequent to training. The performance of laser-pain conditioning was significantly reduced after bilateral lesioning of the ACC. Similar results were also obtained by bilateral lesions of the amygdala. The conditioning responses were also diminished following morphine treatment. The association between a neutral stimulus and a noxious stimulus could be demonstrated in a Pavlovian conditioning test in free moving rats. Thus, the conditioned response may be employed as a measure of the emotional component of the nociception. It is also suggested that the ACC may play an important role in mediating this conditioning effect.

The effects of the medial and cortical amygdala lesions on post-stress analgesia in rats

The role of the medial, and cortical nuclei of amygdala was studied in 54 Möll-Wistar rats under two modes of foot-shock analgesia. In all but control animals bilateral electrolytic lesions were performed. Pre- and post-stress pain reactivity were measured in the hot-plate and the tail-flick tests. The damage of the medial nucleus decreases animals' primordial pain reactivity. Four minutes of continuous foot-shock produced post-stress analgesia in all control and lesioned rats, but 20 min of regularly intermittent foot-shock failed to evoke analgesia in the lesioned rats, especially in subjects with the dorsal part of the medial nucleus injuries. The results indicate that the medial and cortical nuclei are important in regulation of the post-stress antinociceptive processes evoked only by prolonged intermittent shock action. It has been previously shown that the behaviour evoked by this stressor is related to opioid mechanisms, and modulated by the hypothalamic-pituitary-adrenocortical system. Present finding is in agreement with our concept of the dorsomedial amygdala involvement in painful and stressful stimuli processing.

Persistent increases in basal cerebral metabolic activity induced by morphine sensitization

To characterize the underlying neuroanatomic substrate of morphine (MS) sensitization, changes in the local cerebral metabolic rate for glucose (LCMRglu) were examined in 95 brain regions of male F-344 rats using the 2-deoxy-D-[1-14C]glucose method. The results of these experiments demonstrate that MS-induced sensitization is manifested by increases in basal metabolic activity that last for at least 6 days. Although changes in basal metabolic rate were found to be more extensive in the presence of conditioned cues, the increases in LCMRglu in nonconditioned sensitized rats indicate a basic underlying pharmacologic effect of MS sensitization on basal brain activity. Regions in which MS sensitization had a lasting pharmacologic effect include the shell of the nucleus accumbens, the prelimbic area of the prefrontal cortex, and the dorsolateral prefrontal cortex. Interestingly, the core of the nucleus accumbens and regions of the caudate were found to have an increased LCMRglu only in the presence of conditioned cues, indicating conditioned brain activity without observable changes in behavior. The previous administration of an MS-sensitizing treatment was also found to alter the cerebral metabolic response to a subsequent acute MS challenge (0.5 mg/kg, subcutaneously), most notably in forebrain systems. The more widespread activation of brain structures in the basal state in the presence of conditioned cues suggests that these MS-sensitized rats may model an altered brain state related to craving in the abstinent opiate addict.

Opposite changes in the expression of enkephalin in the amygdala and hypothalamus after lesions of the bed nucleus of the stria terminalis in the rat

The expression of enkephalin in neurons of the rat forebrain was studied by in situ hybridization and immunohistochemistry after unilateral injections of ibotenic acid into the bed nucleus of the stria terminalis. Initially, we observed that the destruction of nerve cell bodies in this nucleus resulted in a prominent bilateral increase in the number of neuronal perikarya immunoreactive for [Met]enkephalin in the lateral/basolateral amygdaloid complex-especially in the anterior division of the latter nucleus-as compared with NaCl-injected rats. In a separate set of experiments, this effect was associated with a significant (two times) enhancement of the number of nerve cell bodies containing preproenkephalin A messenger RNAs in the same amygdaloid nucleus ipsilateral to the injection, as compared with controls. In the hypothalamus of both experimental and control rats, the nerve cell bodies immunoreactive for [Met]enkephalin were few since the animals were not pretreated with colchicine, and the effects of the lesion were difficult to appreciate. However, using in situ hybridization, numerous nerve cell bodies containing preproenkephalin A messenger RNAs were detected bilaterally in the perifornical area, the paraventricular (parvocellular division) and the ventromedial nuclei of the hypothalamus. In the latter nucleus, the lesion of the bed nucleus of the stria terminalis resulted in a strong decrease (about two times) in the number of labelled cell bodies as compared with the controls, whereas no significant changes were found bilaterally in the paraventricular nucleus. In agreement with some data of the literature, our results indicate that the bed nucleus of the stria terminalis plays an important role in the regulation of neuropeptide genes expression in certain regions of the limbic system. Such a role is often exerted by nerve fibres afferents to the nerve cell bodies considered. However, from numerous neuroanatomical data of the literature, it appears more probable that the induction or inhibition of the expression of enkephalin in presynaptic neurons is due to the disappearance of their postsynaptic target in the bed nucleus of the stria terminalis.

Naloxone alters the local metabolic rate for glucose in discrete brain regions associated with opiate withdrawal

The current 2-deoxy-D-[1-14C]glucose investigation was performed to test the hypothesis that endogenous opioids influence basal synaptic activity within discrete brain regions. To examine this hypothesis, the effects of naloxone (1.0 mg/kg s.c.) on local cerebral metabolic rate for glucose (LCMRglu) in 84 brain regions were compared to saline controls. The specificity of naloxone's effects for opioid receptors was assessed by the coadministration of the opiate agonist morphine in a separate group. In naloxone-treated rats, there was a significant decrease in LCMRglu in the locus coeruleus (LC) and an increase in the central nucleus of the amygdala (CAMY), supporting a tonic influence of endogenous opioids on these regions. These metabolic changes were reversed by coadministered morphine, indicating that naloxone's metabolic actions are specific for opioid receptors. Based on the role of the LC and CAMY in opiate withdrawal, the present results suggest a subthreshold naloxone precipitated withdrawal from endogenous opioids. Although morphine administered alone significantly reduced LCMRglu in 16 brain regions, these did not include the LC or the CAMY. These results identify brain regions in which synaptic activity is under tonic modulation by endogenous opioids.

Chronic escapable footshock causes a reduced response to morphine in rats as assessed by local cerebral metabolic rates

The 2-deoxy-D-[14C]glucose (2-DG) method was used to examine the effects of morphine sulfate (MS) on local cerebral metabolic rates for glucose (LCMRglu) in male F-344 rats required to turn a wheel manipulandum in order to escape from nociceptive footshock. This nociceptive stimulus was identical with that utilized in a previous 2-DG study from this laboratory [15] except that animals were exposed to 15 daily 30 min sessions of footshock prior to the 2-DG testing day rather than a single footshock exposure. This allows a direct comparison of the effects of morphine in chronic and acute pain. Unlike the acute footshock study, morphine in chronic footshock rats did not have a significant effect compared with chronic footshock alone in any of the 73 measured brain structures, including limbic and midline thalamic structures previously shown to be important in morphine-induced analgesia during acute pain [15]. Whereas 93% of measured cerebral structures showed decreases in LCMRglu following morphine administration in the acute footshock rats, morphine given to chronic footshock rats caused decreases in only 56% of the structures as compared with chronic footshock plus saline. It is hypothesized that these differential effects of morphine are due in part to a habituation to the chronic stressor such that chronic footshock rats are less stressed than acute footshock rats. Additionally, it is suggested that chronic exposure to pain produces a constant elevation of opioid peptides leading to opioid receptor downregulation and consequently morphine tolerance. These results demonstrate that, even in the presence of the same nociceptive stimulus, morphine can have widely disparate effects on brain metabolism if there are differences in the pain history of the animal.