Antidepressants, CYP2D6, and opioid metabolism

Awhile back I posted this bleg for more information about the interaction between antidepressants and codeine. Peter Nelson emailed me asking whether I had found out anything else. I hadn't, so he did some research of his own which he has kindly agreed to allow me to share.

Take it away, Peter:

[Usual disclaimer: Neither he nor I are medical professionals. Don't take this as medical advice, et cetera.]

Since emailing you I’ve been studying the research literature and it’s crystal clear that codeine will not have any analgesic properties for people either genetically lacking CYP2D6 (6-10% of caucasians, other %’s for other ethnic groups) or who are taking a drug that blocks it.
Many antidepressants, including fluoxetine, paroxetine and bupropion are strong inhibitors of it, as are many other drugs including various antiarrhythmics, antifungals, cancer drugs, etc.

The story on the other synthetic opioids doesn’t look too good either. CYP2D6 plays a critical role in the metabolism of hydrocodone, oxycodone, and tramadol but they have more complex metabolic pathways and even now there are details that remain to be elucidated.

Hydrocodone itself has little affinity for the μ opioid (pain) receptors so it has to get metabolized the main clinically-active metabolite is assumed to be hydromorphone because it’s a known painkiller with a high affinity for the μ opioid receptors. And lack of CYP2D6 blocks that process. That part is clear, but there are unanswered questions.

For example in Kaplan et al, (Inhibition of cytochrome P450 2D6 metabolism of hydrocodone to hydromorphone does not importantly affect abuse liability J Pharmacol Exp Ther. 1997 Apr;281(1):103-8) subjects’ subjective perception of the effects of hydrocodone were unrelated to hydromorphone conversion. Heiskanen et al, (Effects of blocking CYP2D6 on the pharmacokinetics and pharmacodynamics of oxycodone. Clin Pharmacol Ther. 1998 Dec;64(6):603-11. ) performed a similar experiment involving oxycodone with similar results.
But critically, neither experiment looked at pain tolerance. Also Otton et al, (CYP2D6 phenotype determines the metabolic conversion of hydrocodone to hydromorphone - SV - Clin Pharmacol Ther - 01-NOV-1993; 54(5):) performed an experiment similar to Kaplan’s but did find that subjects responded in ways consisten with hydromorphone conversion (again, no pain test).

Based on what we think we know about hydrocodone (i.e., that the active metabolite is hydromorphone), Otton’s results make more sense. But both hydrocodone and oxycodone still have work left to do elucidating the effects of some of the other metabolites that are currently thought to be inactive.

And Heiskanen’s results also make sense because oxycodone – the parent compound - actually appears to have a nontrivial affinity for μ receptors itself, and furthermore some of its other metabolites such as noroxycodone, which may be mediated by a different enzyme – CYP2C19 - may also have high binding affinity. (Lalovic et al, Quantitative contribution of CYP2D6 and CYP3A to oxycodone metabolism in human liver and intestinal microsomes. Drug Metab Dispos. 2004 Apr;32(4):447-54. )
In other words oxycodone may work fine as an analgesic for CYP2D6 impaired patients. BUT that doesn’t mean oxycodone gets us off the hook - instead it appears to have a nastier hook: The oxymorhone is far more readily cleared than the parent compound oxycodone. So without CYP2D6 oxycodone accumulates, potentially becoming toxic or fatal.
Two studies underscore that risk: Jannetto, et al, Pharmacogenomics as molecular autopsy for postmortem forensic toxicology; genotyping cytochrome P450 2D6 for oxycodone cases. J Anal Toxicol 2002; 26:438–447 and Drummer et al, A study of deaths involving oxycodone. J Forensic Sci 1994; 39:1069–1075.

The real bottom lines are these:

1. Work remains to be done in elucidating both the pharmacokinetics and clinical effects of various metabolites for all of the synthetic opioids.

2. As far as I could tell, there seem to be no human studies evaluating analgesic properties of synthetic opioids for patients who either lack the gene for CYP2D6 or for whom CYP2D6 is blocked by a drug-drug interaction.

3. Drug-drug interactions of this type will become more common as the population becomes older and as we use a greater variety of drugs. As it is, bupropion. paroxetine and fluoxetine (all potent CYP2D6 blockers) accounted for roughly 50 million prescriptions in the US alone last year. Other CYP2D6 blockers account for millions more.

4. I’ve spoken to several physicians about this and they all expressed worry and concern that they feel unsure how to do pain management for CYP2D6-impaired patients, especially in postoperative or fracture cases where OTC drugs aren’t enough and the “nuclear options” like fentanyl or methadone (both of which work regardless of CYP2D6) would be overkill and dangerous.

Visit Peter's blog at http://blog.pnart.com/. Thanks again!

The day after the day after

Question: When I haven't been to judo in a few weeks, I'm more sore 48 hours after practice than I am 24 hours afterward. But after getting back in shape the soreness seems to constantly decrease with time. Other people tell me similar things with other new exercise regimes. So I don't think I'm idiosyncratic. Why does this happen?

My initial thought --and here I reveal the depth of my ignorance-- was that since the tissues have been healing, the worsening allodynia isn't due to increased prostaglandins, bradykinin, leukotrienes, etc, released by the damaged muscle. Rather it's from dorsal horn wind-up, and neurogenic inflammatory factors like substance p and neurokinins A and B. It makes sense that those would continue to increase over time.

But that wouldn't explain why this doesn't seem to happen when I'm already in shape, even when a workout is much harder than usual.

Or is it just the obvious answer that the difference between relative inactivity and a moderate workout is less than the difference between a moderate workout and a really hard one?

Ideas?

BLEG: Opiates and renal failure

Hi all,

As I mentioned, I'm suddenly in the position of helping coordinate my grandpa's palliative care. Since I'm not a clinician, I need to get up to speed on some of the pharmacology so that I can have meaningful discussions with the real doctors.

Thus I'd really appreciate it if you could point me in the right direction toward any resources on treating acute pain in patients with severe renal impairment/failure.

Here's an example of the sort of information I'm looking for:

After reading through a bunch of journals early this morning, it seems like there's pretty good reason to not give people with severe renal impairment/failure morphine or hydromorphone. Two of the metabolites don't clear very well and can build up to cause coma or respiratory failure (in fact, at least one of the dangerous metabolites --6MG I think-- doesn't really affect pain, so the danger well outlasts the analgesic effect of the dose).

Codeine is probably even worse. The evidence with oxycodone isn't entirely clear; fentanyl is probably okay. But methadone seems to be all around pretty safe.

These are just my impressions from a bunch of journal articles. But I feel like I can now intelligibly ask his doctors whether they might consider trying methadone instead of giving him morphine for breakthrough pains and then giving him nothing (occasionally APAP) for very long periods. I don't want to second-guess their judgment, but I do want to be able to understand the treatment options....

I'll appreciate anything you can recommend.

Thanks again.

[also, sorry that these posts are pretty sloppy. I'm posting from my phone outside the hospital.]

Pharmacology bleg

I have a request for any of you who know about the pharmacology of antidepressants. I have a friend who is taking Wellbutrin (bupropion) for smoking and codeine for chronic pain. I'm curious whether the combination may be attenuating the effect of the codeine and thus whether he should talk to his doctor about changing the codeine dose or switching medications.

Here's why: Codeine itself isn't really an analgesic. It is a substrate of a polymorphic P450 enzyme CYP2D6, and is metabolized to the more potent drug morphine. Some SSRI's like fluoxetine inhibit CYP2D6 activity. Thus combining prozac with codeine can attenuate its effects (see below).

What I'd like to know is whether bupropion might have the same effect on codeine metabolism. But I can't find anything directly on the topic.

From this chart of the various enzymes involved, it looks like that might be the case. But then I found this in the Wikipedia entry on buproprion

As bupropion is metabolized to hydroxybupropion by CYP2B6, drug interactions with CYP2B6 inhibitors (paroxetine, sertraline, fluoxetine metabolite norfluoxetine, diazepam, clopidogrel, orphenadrine and others) are possible. The expected result is the increase of bupropion and decrease of hydroxybupropion blood concentration. The reverse effect (decrease of bupropion and increase of hydroxybupropion) can be expected with CYP2B6 inducers (carbamazepine, clotrimazole, rifampicin, ritonavir, St John's Wort and others).

Hydroxybupropion (but not bupropion) inhibits CYP2D6 and is a substrate of that enzyme. Significant increase of the concentration of some drugs metabolized by CYP2D6 (venlafaxine, desipramine and dextromethorphan, but not fluoxetine or paroxetine) when taken with bupropion has been observed.

So I need your help. Can anyone point me in the direction of studies on bupropion and codeine? Or maybe just explain this in a way I can understand?

--
For your enjoyment, here are a few studies of fluoxetine and codeine that I came across in looking for an answer.

Inhibition by fluoxetine of cytochrome P450 2D6 activity.
Otton SV, Wu D, Joffe RT, Cheung SW, Sellers EM
Clin Pharmacol Ther. 1993 Apr ; 53(4): 401-9

Potent inhibition of cytochrome P450 2D6 (CYP2D6) in human liver microsomes by fluoxetine and its major metabolite norfluoxetine was confirmed (apparent inhibition constant values, 0.2 mumol/L). Several other serotonergic agents were also found to be competitive inhibitors of this genetically polymorphic enzyme. The O-demethylation ratio of dextromethorphan that expressed CYP2D6 activity in 19 patients receiving fluoxetine fell in the region of the antimode separating the O-demethylation ratio values observed in 208 extensive metabolizers from 15 poor metabolizers of a control group of healthy subjects. Inhibition of CYP2D6 activity in patients undergoing treatment with fluoxetine or other serotonin uptake inhibitors could contribute to toxicity or attenuated response from concurrent medications that are substrates of this enzyme. Other in vitro studies indicated that CYP2D6 catalyzes the O-demethylation of oxycodone to form oxymorphone. This reaction was inhibited by fluoxetine and its normetabolite in liver microsomes from both extensive and poor metabolizer individuals, indicating that these compounds are not selective inhibitors of CYP2D6 activity.

Treatment of codeine dependence with inhibitors of cytochrome P450 2D6.
Fernandes LC, Kilicarslan T, Kaplan HL, Tyndale RF, Sellers EM, Romach MK
J Clin Psychopharmacol. 2002 Jun ; 22(3): 326-9

Codeine is O-demethylated by cytochrome P450 2D6 (CYP2D6) to form the more potent drug morphine, accounting for much of codeine's analgesic and dependence-producing properties. Because morphine production can be decreased by inhibition of CYP2D6, the authors hypothesized that CYP2D6 inhibition could be used to treat codeine dependence. A randomized, double-blind, placebo-controlled trial was conducted. All patients received brief behavioral therapy. Two weeks of baseline monitoring were followed by 8 weeks of daily treatment with fluoxetine or quinidine (two potent CYP2D6 inhibitors) or placebo. Thirty patients were assessed (all white, age 40 + 12 years using 127 + 79 mg/day of codeine [mean + SD]), and 17 entered treatment. Eight patients remained in the study by treatment week 8. Quinidine > fluoxetine > placebo inhibited CYP2D6 as reflected in the change of the O-demethylation of dextromethorphan, a specific CYP2D6 probe. At treatment week 8, placebo, quinidine, and fluoxetine reduced mean daily codeine intake by 57%, 56%, and 51% of baseline intake respectively; there was no difference among treatment groups. In this small sample, CYP2D6 inhibitors did not appear to have a useful role in the treatment of codeine dependence.