• The Korean Journal of Pharmacology
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• v.25 no.1
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• pp.13-21
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• 1989

The circadian rhythm of spontaneous motor activity was not significantly altered by $T_4$(4mg/kg, i.p. inj. once a day for 5 days: $T_4$) and PTU (fed ad lib in 0.01% drinking water for 5 weeks: PTU). The plasma thyroxine level was markedly increased by $T_4$ but reduced by PTU, and the plasma thyrotropin level was markedly increased by PTU but moderately increased by $T_4$. Clonidine slightly increased the plasma CS level, but the clonidine effect was significantly enhanced by $T_4-pretreatment$. The brain NE and MHPG contents were little affected by $T_4$ but the NE content was significantly decreased by PTU. The SS-induced increase of plasma CS level was moderately decreased by PTU but increased by $T_4$. However, clonidine significantly inhibited the SS-induced increase, and the inhibitory effect of clonidine was not significantly affected by PTU and $T_4$, respectively. The brain MHPG content and MHPG/NE ratio were significantly decreased by clonidine but increased by SS. The clonidine- and SS-induced changes of brain MHPG content and MHPG/NE ratio were not altered by $T_4$. PTU did not affect the SS-induced increase of brain NE turnover but significantly attenuated the clonidine-induced decrease. The SS-induced increases of brain MHPG content and MHPG/NE rtatio were markedly inhibited by clonidine, and the inhibitory effect of clonidine was not affected by $T_4$ and PTU, respectively. These results suggest that the responses to swim-stress is not signigicantly affected by the alteration of thyroid function and that the hypothalamo-adenohypophysis-adrenocortical stimulation in response to swim-stress seems to be mediated via hypothalamic noradrenergic activation, and the stress response may be inhibited by the agonistic activity of clonidine on the presynaptic ${\alpha}_2-adrenoceptor$.

• The Korean Journal of Pharmacology
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• v.30 no.3
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• pp.299-311
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• 1994

The present study was attempted to investigate whether pentazocine, which is known to possess both opioid agonistic and antagonistic properties, produces catecholamines (CA) secretion from the isolated perfused rat adrenal gland, and to establish the mechanism of its action, and also to compare its action with that of some opioids. Pentazocine (30 to 300 ug) injected into an adrenal vein caused a dose-dependent secretory response of CA from the rat adrenal medulla. The pentazocine-evoked secretion of CA was remarkably diminished by the preloading with chlorisondamine $(10^{-6}\;M)$, naloxone $(1.22{\times}10^{-7}\;M)$, morphine $(1.7{\times}10^{-5}\;M)$, met-enkephalin $(9.68{\times}10^{-6}\;M)$, nicardipine $(10^{-6}\;M)$ and TMB-8 $(10^{-5}\;M)$ while was not influenced by the pretreatment of pirenzepine $(2{\times}10^{-6}\;M)$. The perfusion of $Ca^{++}$-free Krebs solution for 30 min into the gland also led to the marked reduction in CA secretion evoked by pentazocine. Furthermore, the CA release evoked by ACh and/or DMPP was greatly inhibited by the pretreatment with pentazocine $(1.75{\times}10^{-4}\;M)$ for 20 min. From these experimental results, it is thought that pentazocine causes markedly the increased secretion of CA from the isolated perfused rat adrenal medulla by a calcium-dependent exocytotic mechanism. The secretory effect of pentazocine appears to be mediated through activation of opioid receptors located on adrenal chromaffin cells, which may be also associated with stimulation of cholinergic nicotinic receptors.