Drug Interactions with Patient-Controlled Analgesia

Lötsch, Jörn; Skarke, Carsten; Tegeder, Irmgard; Geißlinger, Gerd

doi:10.2165/00003088-200241010-00004

Cited by 52 publications

(37 citation statements)

References 354 publications

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“…4) Morphine 3-glucuronide has no analgesic eŠects, but morphine 6-glucuronide is a more potent (20 times) analgesic than morphine itself. 5) Patients suŠering from cancer need continuous therapy with morphine. Anti-cancer drugs such as etoposide, irinotecan (its active metabolite is SN-38), and tamoxifen, are widely used for chemotherapy with morphine.…”

Section: Introductionmentioning

confidence: 99%

Morphine Glucuronosyltransferase Activity in Human Liver Microsomes is Inhibited by a Variety of Drugs that are Co-administered with Morphine

Hara

Nakajima

Miyamoto

et al. 2007

Drug Metabolism and Pharmacokinetics

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Summary: Morphine is an analgesic drug used for the treatment of acute and chronic pain syndromes for cancer patients. Glucuronidation is a major pathway of the elimination of morphine in humans. Morphine is metabolized to 3-glucuronide (no analgesic eŠect) and 6-glucuronide (more potently analgesic than morphine) mainly by UGT2B7. In the present study, we investigated the inhibitory eŠects of a variety of drugs on the morphine glucuronosyltransferase activities in human liver microsomes. Twenty-one drugs including anticancer drugs, immunosuppresants, analgesics, anticonvulsants, antidepressants, antipsychotic drugs were selected in this study, because they are frequently coadministered with morphine. We found that 10 out of 21 drugs, tamoxifen, tacrolimus, diclofenac, carbamazepine, imipramine, clomipramine, amitriptyline, diazepam, lorazepam and oxazepam extensively inhibited the morphine 3-and 6-glucuronosyltransferase activities. Although some of the drugs are not substrates of UGT2B7, they would be potent inhibitors of UGT2B7. If patients receive morphine and these drugs simultaneously, the drug-drug interaction may change the levels of morphine and these glucuronides, resulting in altered analgesic e‹cacy and the risk of side eŠects. The results presented here will assist clinicians in choosing the proper drugs and W or dosages, and enable them to anticipate potential drug-drug interactions.

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Section: Introductionmentioning

confidence: 99%

Morphine Glucuronosyltransferase Activity in Human Liver Microsomes is Inhibited by a Variety of Drugs that are Co-administered with Morphine

Hara

Nakajima

Miyamoto

et al. 2007

Drug Metabolism and Pharmacokinetics

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“…This has been observed in animals chronically exposed to certain P-glycoprotein substrates (Fromm et al, 1997;Lotsch et al, 2002), but the mechanism underlying the increase in transporter activity has not been identified. We recently detected expression of the ligand-activated, pregnane X receptor (PXR) in isolated rat brain capillaries .…”

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confidence: 99%

In Vivo Activation of Human Pregnane X Receptor Tightens the Blood-Brain Barrier to Methadone through P-Glycoprotein Up-Regulation

Bauer

Yang²,

Hartz³

et al. 2006

Mol Pharmacol

184

181

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The ATP-driven drug export pump, P-glycoprotein, is a primary gatekeeper of the blood-brain barrier and a major impediment to central nervous system (CNS) pharmacotherapy. Reducing P-glycoprotein activity dramatically increases penetration of many therapeutic drugs into the CNS. Previous studies in rat showed that brain capillary P-glycoprotein was transcriptionally up-regulated by the pregnane X receptor (PXR), a xenobioticactivated nuclear receptor. Here we used a transgenic mouse expressing human PXR (hPXR) to determine the consequences of increased blood-brain barrier P-glycoprotein activity. P-glycoprotein expression and transport activity in brain capillaries from transgenic mice was significantly increased when capillaries were exposed to the hPXR ligands, rifampin and hyperforin, in vitro and when the mice were dosed with rifampin in vivo. Plasma rifampin levels in induced mice were comparable with literature values for patients. We also administered methadone, a CNS-acting, P-glycoprotein substrate, to control and rifampin-induced transgenic mice and measured the drug's antinociceptive effect. In rifampin-induced mice, the methadone effect was reduced by approximately 70%, even though plasma methadone levels were similar to those found in transgenic controls not exposed to rifampin. Thus, hPXR activation in vivo increased P-glycoprotein activity and tightened the blood-brain barrier to methadone, reducing the drug's CNS efficacy. This is the first demonstration of the ability of bloodbrain barrier PXR to alter the efficacy of a CNS-acting drug.

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“…2 Despite a moderateto-high degree of plasma protein binding and the ability of basic drugs to displace methadone from its binding sites on alpha 1 acid glycoprotein (AAG), there are no data suggesting that these protein binding displacement interactions are clinically relevant. 10,11 Another potential confounder is cocaine, a common co-drug-of-abuse in opioid abusers. This is because cocaine suppresses the delayed rectifier potassium ion channels in cardiac myocytes (HERG current where HERG = human ether-a-go-go gene) like many other torsadogenic drugs, including methadone.…”

Section: Potential Confounders To Considermentioning

confidence: 99%

Cardiotoxicity of Oral Methadone as an Analgesic–-Recommendations for Safe Use

Guay

2009

Clinical Medicine. Therapeutics

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Once used only as third-line therapy in the management of chronic pain states, methadone is now being used as first-and second-line therapy. Most risks and the stigma associated with methadone use have been known for years. Only over the past decade or so have the unique pharmacokinetic-pharmacodynamic properties and methods for conversion from other opioids to methadone been established. Pertinent English-language literature was obtained from MEDLINE/PUBMED and EMBASE searches (1966( -June 2009. This paper provides an overview of the cardiotoxicity of oral methadone, with an emphasis on its use as an analgesic. Cardiotoxicity during its use in the maintenance of opioid addiction has also been reviewed due to the wealth of epidemiologic, risk factor, and correlative analytic data contained therein. A series of recommendations are provided to improve the cardiac safety profile of oral methadone used for analgesia. In addition, there is a discussion of settings and patient types which may impact upon these recommendations.

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Drug Interactions with Patient-Controlled Analgesia

Cited by 52 publications

References 354 publications

Morphine Glucuronosyltransferase Activity in Human Liver Microsomes is Inhibited by a Variety of Drugs that are Co-administered with Morphine

Morphine Glucuronosyltransferase Activity in Human Liver Microsomes is Inhibited by a Variety of Drugs that are Co-administered with Morphine

In Vivo Activation of Human Pregnane X Receptor Tightens the Blood-Brain Barrier to Methadone through P-Glycoprotein Up-Regulation

Cardiotoxicity of Oral Methadone as an Analgesic–-Recommendations for Safe Use

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