We have located links that may give you full text access.
The opioid oxycodone use-dependently inhibits the cardiac sodium channel Na V 1.5.
British Journal of Pharmacology 2018 July
BACKGROUND AND PURPOSE: Oxycodone is a potent semi-synthetic opioid that is commonly used for the treatment of severe acute and chronic pain. However, treatment with oxycodone can lead to cardiac electrical changes, such as long QT syndrome, potentially inducing sudden cardiac arrest. Here, we investigate whether the cardiac side effects of oxycodone can be explained by modulation of the cardiac Nav 1.5 sodium channel.
EXPERIMENTAL APPROACH: Heterologously expressed human Nav 1.5, Nav 1.7 (HEK293 cells) or Nav 1.8 channels (mouse N1E-115 cells) were used for whole-cell patch-clamp electrophysiology. A variety of voltage-clamp protocols were used to test the effect of oxycodone on different channel gating modalities. Human stem cell-derived cardiomyocytes were used to measure the effect of oxycodone on cardiomyocyte beating.
KEY RESULTS: Oxycodone inhibited Nav 1.5 channels, concentration and use-dependently, with an IC50 of 483 μM. In addition, oxycodone slows recovery of Nav 1.5 channels from fast inactivation and increases slow inactivation. At high concentrations, these effects lead to a reduced beat rate in cardiomyocytes and to arrhythmia. In contrast, no such effects could be observed on Nav 1.7 or Nav 1.8 channels.
CONCLUSIONS AND IMPLICATIONS: Oxycodone leads to an accumulation of Nav 1.5 channels in inactivated states, with a slow time course. Although the concentrations needed to elicit cardiac arrhythmias in vitro are relatively high, some patients under long-term treatment with oxycodone as well as drug abusers and addicts might suffer from severe cardiac side effects induced by the slowly developing effects of oxycodone on Nav 1.5 channels.
EXPERIMENTAL APPROACH: Heterologously expressed human Nav 1.5, Nav 1.7 (HEK293 cells) or Nav 1.8 channels (mouse N1E-115 cells) were used for whole-cell patch-clamp electrophysiology. A variety of voltage-clamp protocols were used to test the effect of oxycodone on different channel gating modalities. Human stem cell-derived cardiomyocytes were used to measure the effect of oxycodone on cardiomyocyte beating.
KEY RESULTS: Oxycodone inhibited Nav 1.5 channels, concentration and use-dependently, with an IC50 of 483 μM. In addition, oxycodone slows recovery of Nav 1.5 channels from fast inactivation and increases slow inactivation. At high concentrations, these effects lead to a reduced beat rate in cardiomyocytes and to arrhythmia. In contrast, no such effects could be observed on Nav 1.7 or Nav 1.8 channels.
CONCLUSIONS AND IMPLICATIONS: Oxycodone leads to an accumulation of Nav 1.5 channels in inactivated states, with a slow time course. Although the concentrations needed to elicit cardiac arrhythmias in vitro are relatively high, some patients under long-term treatment with oxycodone as well as drug abusers and addicts might suffer from severe cardiac side effects induced by the slowly developing effects of oxycodone on Nav 1.5 channels.
Full text links
Related Resources
Trending Papers
Executive Summary: State-of-the-Art Review: Unintended Consequences: Risk of Opportunistic Infections Associated with Long-term Glucocorticoid Therapies in Adults.Clinical Infectious Diseases 2024 April 11
Clinical practice guidelines on the management of status epilepticus in adults: A systematic review.Epilepsia 2024 April 13
Autoimmune Hemolytic Anemias: Classifications, Pathophysiology, Diagnoses and Management.International Journal of Molecular Sciences 2024 April 13
Get seemless 1-tap access through your institution/university
For the best experience, use the Read mobile app
All material on this website is protected by copyright, Copyright © 1994-2024 by WebMD LLC.
This website also contains material copyrighted by 3rd parties.
By using this service, you agree to our terms of use and privacy policy.
Your Privacy Choices
You can now claim free CME credits for this literature searchClaim now
Get seemless 1-tap access through your institution/university
For the best experience, use the Read mobile app