Brain research
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Opioid-adenosine interactions have been demonstrated at both cellular and behavioral levels. Short-term morphine treatment has been shown to enhance adenosine release in brain and spinal tissues. Since adenosine uptake and release is regulated by a nitrobenzylthioinosine-sensitive adenosine transporter, we examined the effects of morphine treatment on this transporter-binding site. ⋯ In behavioral studies, mice receiving this same chronic morphine or vehicle treatment were given saline or morphine injections (40 or 50 mg/kg i.p.) followed by ambulatory activity monitoring. In the chronic vehicle treatment group, morphine injections significantly stimulated ambulatory activity while in the chronic morphine treatment group there was no such stimulation by acute morphine, suggestive of opiate tolerance. Morphine-induced up-regulation of striatal and hypothalamic adenosine transporter sites could potentially alter extracellular adenosine release and adenosine receptor activation and mediate aspects of opiate tolerance and dependence.
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A dual-probe microdialysis technique was applied to the locus coeruleus (LC) and prefrontal cortex (PFC) of the brain of conscious rats. One probe was implanted close to the LC and was used to apply receptor-specific compounds by retrograde microdialysis. The effects of the LC infusions were recorded by a sampling noradrenaline by a second probe that was implanted in the ipsilateral prefrontal cortex. ⋯ These results also provide evidence for localization of cholinergic-, NMDA-, non-NMDA-receptor on noradrenergic neurons in the LC. Finally it is concluded that dual-probe microdialysis is a useful method to further investigate the pharmacology of LC-noradrenergic neurons. Carbachol and clonidine are suitable tools for a rapid and reversible stimulation or inhibition, respectively, of noradrenergic LC neurons.
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Microinjections of excitatory amino acids made into the ventrolateral midbrain periaqueductal gray of the rat have revealed that neurons in this region integrate a reaction characterised by quiescence, hyporeactivity, hypotension and bradycardia. Microinjections of both excitatory amino acids and opioids into the ventrolateral periaqueductal gray have shown also that it is a key central site mediating analgesia. The effects of injections of opioids into the ventrolateral periaqueductal gray on arterial pressure and heart rate or behaviour are unknown. ⋯ In contrast to the effects of excitatory amino acid injections, microinjections of the mu-opioid agonist ([D-Ala2,N-Me-Phe4,Gly-ol5]enkephalin) evoked hypertension and tachycardia at approximately 50% of sites. Similar to excitatory amino acid injections, microinjections of both the delta-opioid agonist ([D-Pen2,D-Pen5]enkephalin), and the kappa-opioid agonist ((5,7,8)-(+)-N-Methyl-N-[7-(1-pyrrolidinyl)-1-oxaspiro[4.5]dec-8-y l]-benzeneacetamide) evoked either a hypotension and bradycardia, or had no effect. These results indicate that different opiate receptor subtypes are present on a distinct population of ventrolateral periaqueductal gray neurons, or at different ventrolateral periaqueductal gray synaptic locations (pre- or post-synaptic).
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Previous reports have documented spatial navigational deficits following experimental traumatic brain injury (TBI), although the majority of the work to date has involved assessment at acute intervals following TBI, and has focused on tasks sensitive to hippocampal dysfunction. The present experiments were designed to investigate the chronic consequences of TBI, and the possible contribution of extrahippocampal dysfunction to TBI-induced spatial navigational deficits, in a moderate parasagittal fluid percussion TBI model. In Experiment 1, animals were pre-trained in a water maze, subjected to TBI or sham procedures, and re-evaluated in the water maze 48 h following the insult. ⋯ Injured animals exhibited deficits in both tasks which gradually diminished over the course of testing. The results of these experiments indicate that moderate TBI is accompanied by both retention and acquisition deficits, and that some of the navigational deficits observed in the water maze can be attributed to extrahippocampal damage. The possible recovery of spatial navigational ability following parasagittal TBI at moderate intensities is also discussed.