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Effects of [mu]-opioids on neurons of the medical geniculate nucleus Ota, Takayo

Abstract

Immunohistochemical and hybridization studies have revealed the presence of μ-, but not k- and δ-opioid receptors in the medial geniculate body. Using whole-cell patch clamp techniques, I examined the effects of opioid agonists on gerbil MGB neurons (P9-P16) in vitro. The opioid effects were concentration-dependent. Opioids produced different actions on the input conductance (G[sub i]) when applied in low, compared with high concentrations. The increase in G[sub i] might be due to increase in K⁺ conductance whereas the decrease in G[sub i] might be due to l[sub H] inactivation. When Gi was increased, the reversal potential was —65 mV; this implicates opioid actions on K+ , among other ion channels. In the case of decreased G[sub i], the opioid currents did not reverse from -100 mV to -50 mV, implying the involvement of cationic channels, other than K⁺ . DAMGO, a μ-selective opioid agonist, had a reversal potential that was similar to that observed when morphine increased G[sub i], implying that opioids activate u-opioid receptors in MGB neurons. Tetrodotoxin altered the concentration-dependent action of morphine. Here, the suggestion is morphine's actions involve neurons that presynaptic to the patch clamped neuron. Morphine application blocked spike-frequency adaptation and reduced firing rates in response to depolarizing current pulse injection. Morphine application may block Ca²⁺-mediated K⁺ channels that inhibited spike-frequency adaptation. Such blockade may be expected to increase the spike frequency. However, the increased conductance due to morphine would shunt the Na⁺ current, resulting in a lower spike frequency. The results of this study have revealed that opioids have both excitatory and inhibitory effects on MGB neurons.

Item Metadata

Title	Effects of [mu]-opioids on neurons of the medical geniculate nucleus
Creator	Ota, Takayo
Publisher	University of British Columbia
Date Issued	2000
Description	Immunohistochemical and hybridization studies have revealed the presence of μ-, but not k- and δ-opioid receptors in the medial geniculate body. Using whole-cell patch clamp techniques, I examined the effects of opioid agonists on gerbil MGB neurons (P9-P16) in vitro. The opioid effects were concentration-dependent. Opioids produced different actions on the input conductance (G[sub i]) when applied in low, compared with high concentrations. The increase in G[sub i] might be due to increase in K⁺ conductance whereas the decrease in G[sub i] might be due to l[sub H] inactivation. When Gi was increased, the reversal potential was —65 mV; this implicates opioid actions on K+ , among other ion channels. In the case of decreased G[sub i], the opioid currents did not reverse from -100 mV to -50 mV, implying the involvement of cationic channels, other than K⁺ . DAMGO, a μ-selective opioid agonist, had a reversal potential that was similar to that observed when morphine increased G[sub i], implying that opioids activate u-opioid receptors in MGB neurons. Tetrodotoxin altered the concentration-dependent action of morphine. Here, the suggestion is morphine's actions involve neurons that presynaptic to the patch clamped neuron. Morphine application blocked spike-frequency adaptation and reduced firing rates in response to depolarizing current pulse injection. Morphine application may block Ca²⁺-mediated K⁺ channels that inhibited spike-frequency adaptation. Such blockade may be expected to increase the spike frequency. However, the increased conductance due to morphine would shunt the Na⁺ current, resulting in a lower spike frequency. The results of this study have revealed that opioids have both excitatory and inhibitory effects on MGB neurons.
Extent	3387871 bytes
Genre	Thesis/Dissertation
Type	Text
File Format	application/pdf
Language	eng
Date Available	2009-07-13
Provider	Vancouver : University of British Columbia Library
Rights	For non-commercial purposes only, such as research, private study and education. Additional conditions apply, see Terms of Use https://open.library.ubc.ca/terms_of_use.
DOI	10.14288/1.0089594
URI	http://hdl.handle.net/2429/10738
Degree	Master of Science - MSc
Program	Pharmacology and Therapeutics
Affiliation	Medicine, Faculty of; Anesthesiology, Pharmacology and Therapeutics, Department of
Degree Grantor	University of British Columbia
Graduation Date	2000-11
Campus	UBCV
Scholarly Level	Graduate
Aggregated Source Repository	DSpace

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For non-commercial purposes only, such as research, private study and education. Additional conditions apply, see Terms of Use https://open.library.ubc.ca/terms_of_use.