Neuroscience
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Ischemia-induced selective neuronal injury to field CA1 is not attributable to selective glutamate release in field CA1 during ischemia. Excessive release of glutamate has been proposed to play a major role in ischemia-induced selective neuronal death in field CA1 of the hippocampus. It is well known that, following carotid arterial occlusion of 5 min duration in the gerbil, the pyramidal neurons in field CA1 show delayed neuronal death, whereas the neurons in field CA3 do not show any neuronal degeneration. ⋯ No significant differences were detected in the time-course of change in glutamate release and the levels of glutamate between field CA1 and field CA3. This result indicates that the increased glutamate levels do not play a pivotal part in the detrimental effect of glutamate during 5-min ischemia. Some differentiated post-synaptic organization may act as a crucial factor in the development of ischemia-induced selective neuronal death in the gerbil hippocampus.
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Comparative Study
Adenosine A2 receptors: selective localization in the human basal ganglia and alterations with disease.
Adenosine A2 receptors were labeled and visualized by autoradiography in tissue sections of the human brain using the A2-selective agonist ligand [3H](2-p-(2-carboxyethyl)phenylamino)-5'-N-carboxamidoadenosine (CGS 21680). The binding of this ligand was of high affinity, reversible, and was blocked by adenosine A2 agents. Autoradiographic mapping of adenosine A2 sites revealed them to be exclusively restricted to the caudate nucleus, putamen, nucleus accumbens, olfactory tubercle and the lateral segment of the globus pallidus. ⋯ In contrast, density values of A2 sites were dramatically decreased, compared to control values, in the basal ganglia of patients with Huntington's chorea. Similar losses of A2 receptors were observed in the guinea-pig striatum after local application of quinolinic acid while lesioning of the dopaminergic neurons was without effect. All these results taken together suggest that adenosine A2 receptors are localized on striatal output neurons which degenerate in Huntington's chorea.
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A novel mechanism for regulating dopamine activity in subcortical sites and its possible relevance to schizophrenia is proposed. This hypothesis is based on the regulation of dopamine release into subcortical regions occurring via two independent mechanisms: (1) transient or phasic dopamine release caused by dopamine neuron firing, and (2) sustained, "background" tonic dopamine release regulated by prefrontal cortical afferents. Behaviorally relevant stimuli are proposed to cause short-term activation of dopamine cell firing to trigger the phasic component of dopamine release. ⋯ In this way, tonic dopamine release would set the background level of dopamine receptor stimulation (both autoreceptor and postsynaptic) and, through homeostatic mechanisms, the responsivity of the system to dopamine in these sites. In schizophrenics, a prolonged decrease in prefrontal cortical activity is proposed to reduce tonic dopamine release. Over time, this would elicit homeostatic compensations that would increase overall dopamine responsivity and thereby cause subsequent phasic dopamine release to elicit abnormally large responses.
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The effect of capsaicin on voltage-activated calcium currents was investigated in voltage-clamped somata of cultured adult rat dorsal root ganglion neurons. About half the neurons studied were sensitive to capsaicin, which induced an inward current at negative membrane potentials accompanied by an increase in membrane conductance. In the sensitive neurons capsaicin inhibited voltage-activated calcium current to an extent that depended on the size and duration of the capsaicin-induced inward current. ⋯ Substituting Ca with Co did not prevent the prolonged block of calcium channels. It is concluded that the inhibition of voltage-activated calcium currents by capsaicin is secondary to increased intracellular Ca levels due to calcium entry through capsaicin-activated cation-specific ion channels in the plasma membrane. Long-lasting inhibition of voltage-activated calcium channels may contribute to the mechanism of the analgesic and anti-inflammatory effects of capsaicin through inhibition of neurotransmitter release from central and peripheral terminals of primary afferent nociceptive neurons.
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The organization of connections between the amygdala, prefrontal cortex and striatum was studied using anterograde and retrograde tract tracing techniques in the rat. The anterograde transport of Phaseolus vulgaris leucoagglutinin and wheat germ agglutinin conjugated to horseradish peroxidase was used to examine the striatal projections of the prefrontal cortex. These studies revealed that the prelimbic area of the medial prefrontal cortex projects mainly to the medial part of the striatum, whereas the dorsal agranular insular area of the lateral prefrontal cortex projects mainly to the ventrolateral part of the striatum. ⋯ The rostral pole and lateral portions of the basolateral nucleus project to both the lateral prefrontal cortex and its associated lateral striatal region. Many neurons in the basolateral amygdaloid nucleus, and to a lesser extent other amygdaloid nuclei, were double-labeled in these experiments, indicating that these cells send collaterals to both the prefrontal cortex and striatum. These findings indicate that discrete areas of the amygdala, and in some cases individual amygdaloid neurons, can modulate information processing in the first two links of distinct cortico-striato-pallidal systems arising in the medial and lateral prefrontal cortex.