Opiates and psychotropics: Pharmacokinetics for practitioners

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Opiates and psychotropics: Pharmacokinetics for practitioners
Author(s)
Aaron M. Pierce, DO

 

Practice Points

• When choosing pharmacologic therapy, make sure that all medications your patient takes are documented, consider drug-drug interactions, and instruct the patient to notify you of any new medications.

• In addition to toxicity, loss of efficacy of some opiate drugs may occur as a result of metabolic inhibition or induction by psychotropic medications.

Collaborate with the physician who is prescribing the opioid if psychotropic choices are limited. The patient’s pain may be treated adequately with another analgesic that does not interact with the psychotropic that has been chosen.

As prescribed by his internist, Mr. G, age 44, takes 10 mg of methadone every 4 hours for chronic back pain secondary to a work-related injury 3 years ago. He experiences minimal sedation. Mr. G presents for psychiatric evaluation with complaints of increasing irritability, poor focus, low energy, and lack of interest in usual activities. The psychiatrist diagnoses him with depressive disorder not otherwise specified, and prescribes fluoxetine, 20 mg/d. Three weeks later, Mr. G’s wife contacts the psychiatrist reporting that her husband seems “overmedicated” and describes excess drowsiness and slowed thought processing.

After discussion with Mr. G’s internist and pharmacist, the psychiatrist decides that this oversedation may represent a drug-drug interaction between methadone and fluoxetine resulting in higher-than-expected methadone serum levels. Mr. G is instructed to stop fluoxetine with no taper, and his methadone dose is lowered with good results. Over the next 2 weeks Mr. G is titrated back to his original methadone dose and is re-evaluated by the psychiatrist to discuss medication options to address his depression.

Psychiatrists commonly encounter patients who receive opiate medications for chronic pain. Being aware of potential drug-drug interactions between opiate medications and psychotropics can help avoid adverse effects and combinations that may affect the efficacy of either drug. Pharmacokinetic interactions may affect your choice of psychiatric medication and should be taken into account when addressing adverse effects in any patient who takes opiates and psychotropics.

Metabolic pathways

The primary metabolic pathways for opiate metabolism are the cytochrome P450 (CYP) 2D6 and 3A4 isoenzymes. Depending on the agent used, prescribers may need to consider interactions for both pathways (Table 11,2 and Table 21). For example, oxycodone is metabolized via 2D6 and 3A4 isoenzymes and is a potent analgesic with oxymorphone and noroxycodone as its active metabolites. These metabolites, however, make a negligible contribution to oxycodone’s analgesic effect.3,4 Metabolism by the 3A4 isoenzyme is the principal oxidative pathway and the 2D6 site accounts for approximately 10% of oxycodone metabolism. A randomized, placebo-controlled, crossover study showed that 2D6 inhibition by paroxetine had no significant effect on oxycodone levels; however, a combination of paroxetine and itraconazole, a potent 3A4 inhibitor, resulted in substantial increases in oxycodone plasma levels.5 Remain vigilant for possible opiate toxicity when administering oxycodone with 3A4 inhibitors.

 

Clinical Point

Remain vigilant for possible opiate toxicity when administering oxycodone with

Methadone and meperidine also involve dual pathways. Methadone is metabolized primarily by 3A4 and 2B6, with 2D6 playing a smaller role.6 CYP2D6 seems to play an important part in metabolizing the R-enantiomer of methadone, which is largely responsible for the drug’s opiate effects, such as analgesia and respiratory depression.7,8 Induction of the 3A4 isoenzyme may result in methadone withdrawal, and inhibition may cause methadone toxicity.9 Inducers of 3A4, such as carbamazepine, and inhibitors, such as fluoxetine and fluvoxamine, should be avoided or used very cautiously in patients taking methadone. The 2B6 and 2D6 isoenzymes also may increase or decrease methadone levels and should be treated similarly. In Mr. G’s case, fluoxetine inhibited all 3 isoenzymes that are primarily responsible for methadone metabolism. A better antidepressant choice for Mr. G may have been venlafaxine, which is known to only mildly inhibit 2D6, or mirtazapine, which does not seem to inhibit the major CYP isoforms to an appreciable degree.10

Although the full scope of meperidine metabolism has not been identified,9 an in vitro test demonstrated that 2B6 and 3A4 play important roles in metabolizing meperidine to normeperidine, its major metabolite.11 Normeperidine does not provide analgesia and is associated with neurotoxicity, including anxiety, tremor, muscle twitching, and seizure.12 Agents that induce 3A4—such as carbamazepine or St. John’s wort—may contribute to neurotoxicity.9 Inhibition of these isoenzymes may increase meperidine levels and lead to anticholinergic toxicity or respiratory and central nervous system depression.13,14

Opiates metabolized by the 2D6 isoenzyme include codeine, hydrocodone, and tramadol. The analgesic effect of codeine seems dependent on 2D6 metabolism. Via this pathway, codeine is converted into morphine, which has a 300-times stronger affinity for the μ opioid receptor compared with codeine. 2D6 poor metabolizers have shown codeine intolerance and toxicity.3 Psychotropics known to strongly inhibit 2D6 isoenzyme processes—such as paroxetine, fluoxetine, and bupropion—should be avoided in patients taking codeine to prevent adverse effects and potential loss of efficacy. Better antidepressant choices include citalopram or venlafaxine, which inhibit 2D6 to a lesser degree.

 

 

 

Clinical Point

Agents that inhibit 3A4 could increase fentanyl plasma concentration, leading to respiratory depression

Hydrocodone may be a viable option for patients taking 2D6 inhibitors. Hydrocodone is metabolized by 2D6 into hydromorphone, which is 7 to 33 times more potent than hydrocodone.15 Unlike codeine, 2D6 inhibition may have little effect on hydrocodone’s analgesic properties. Animal studies have shown that inhibition of the CYP analog to 2D6 does not affect analgesic response. In humans, 2D6 inhibition does not seem to affect hydrocodone’s abuse liability.16 Two case reports describe known 2D6 poor metabolizers who showed at least a partial response to hydrocodone.15,16

Tramadol’s analgesic properties may be related to serotonin and norepinephrine reuptake inhibition. It is less potent than codeine but is metabolized via the 2D6 isoenzyme into 0-desmethyltramadol, which is up to 200 times stronger than its parent compound.17 Clinicians should be aware that tramadol’s efficacy may be decreased when coadministered with 2D6 inhibitors. In a randomized, placebo-controlled trial, paroxetine, a potent 2D6 inhibitor, was shown to lessen the analgesic effect of tramadol.18

 

Clinical Point

Use of SSRIs or tricyclic antidepressants with tramadol may increase risk for serotonin syndrome

The 3A4 site is the primary pathway for fentanyl metabolism. Agents that inhibit 3A4 could increase fentanyl plasma concentration, leading to respiratory depression.19 Examples of 3A4 inhibitors include fluoxetine and fluvoxamine.

Psychotropics may inhibit or induce P450 isoenzymes to varying degrees. For example, paroxetine and citalopram are known to inhibit 2D6 but paroxetine is a stronger inhibitor; therefore, a significant drug-drug interaction is more likely with paroxetine and a 2D6 substrate than the same substrate administered with citalopram.

Table 1

Cytochrome P450 isoenzymes inhibited and induced by psychotropics

 

IsoenzymePotencyPsychotropic(s)
2B6 inducerModerateCarbamazepine
2B6 inhibitorsMild to moderateFluoxetine, fluvoxamine
ModerateSertraline
PotentParoxetine
2D6 inhibitorsMildVenlafaxine
Mild to moderateCitalopram, escitalopram, fluvoxamine, risperidone
ModerateDuloxetine
Moderate to potentBupropion
PotentFluoxetine, haloperidol, paroxetine
Dose-dependentSertraline
3A4 inducerPotentCarbamazepine
3A4 inhibitorsMildSertraline
Mild to moderateFluoxetine, fluvoxamine
Source: References 1,2

Table 2

Cytochrome P450 isoenzymes inhibiting and inducing opiate metabolism

 

IsoenzymeOpiates
2B6 inducerMethadone
2B6 inhibitorsMeperidine, methadone
2D6 inhibitorsCodeine (may involve loss of efficacy as well as
toxicity), methadone, tramadol (may involve loss of efficacy)
3A4 inducerMeperidine, methadone
3A4 inhibitorsFentanyl, oxycodone, meperidine, methadone
Source: Reference 1

Other considerations

In addition to pharmacokinetic interactions, it is important to consider synergistic effects of some opiates and psychotropics. Examples include:

 

  • additive effect on respiratory depression by benzodiazepines and opiates
  • increased risk of serotonin syndrome and seizure when using tramadol with selective serotonin reuptake inhibitors or tricyclic antidepressants
  • additive prolongation of the QTc interval by methadone when used with psychotropics known to prolong the QTc, such as ziprasidone.9,17,20

Careful attention to these interactions and collaboration among providers can ensure the best outcome for our patients. In Mr. G’s case, collaboration with his internist would be in order, particularly if antidepressant choices are limited. In consultation with the psychiatrist, the internist might choose another opiate to treat Mr. G’s pain that would not interact with fluoxetine. If Mr. G and his physician have struggled to manage his pain and if he is stable on the current regimen, selecting a different antidepressant may be warranted.

Related Resources

 

  • Indiana University School of Medicine drug interactions: cytochrome P450 drug interaction table. http://medicine.iupui.edu/clinpharm/ddis/table.asp.
  • Ferrando SJ, Levenson JL, Owen JA, eds. Clinical manual of psychopharmacology in the medically ill. Arlington, VA: American Psychiatric Publishing, Inc; 2010.

Drug Brand Names

 

  • Bupropion • Wellbutrin, Zyban
  • Carbamazepine • Tegretol
  • Citalopram • Celexa
  • Duloxetine • Cymbalta
  • Escitalopram • Lexapro
  • Fentanyl • Duragesic, Actiq
  • Fluoxetine • Prozac
  • Fluvoxamine • Luvox
  • Haloperidol • Haldol
  • Hydrocodone • Lortab, Vicodin, others
  • Itraconazole • Sporanox
  • Meperidine • Demerol
  • Methadone • Dolophine, Methadose
  • Mirtazapine • Remeron
  • Morphine • Avinza, Duramorph, others
  • Oxycodone • OxyContin, Roxicodone
  • Paroxetine • Paxil
  • Risperidone • Risperdal
  • Sertraline • Zoloft
  • Tramadol • Ultram
  • Venlafaxine • Effexor
  • Ziprasidone • Geodon

Disclosure

The authors report no financial relationship with any company whose products are mentioned in this article or with manufacturers of competing products.

References

 

1. Sandson NB, Armstrong SC, Cozza KL. An overview of psychotropic drug-drug interactions. Psychosomatics. 2005;46:464-494.

2. Faucette SR, Wang H, Hamilton GA. Regulation of CYP2B6 in primary human hepatocytes by prototypical inducers. Drug Metab Dispos. 2004;32(3):348-358.

3. Smith HS. Opioid metabolism. Mayo Clin Proc. 2009;84:613-624.

4. Armstrong SC, Cozza KL. Pharmacokinetic drug interactions of morphine codeine, and their derivatives: theory and clinical reality, part II. Psychosomatics. 2003;44:515-520.

5. Grönlund J, Saari TI, Hagelberg NM, et al. Exposure to oral oxycodone is increased by concomitant inhibition of CYP2D6 and 3A4 pathways, but not by inhibition of CYP2D6 alone. Br J Clin Pharmacol. 2010;70:78-87.

6. Leavitt SB. Methadone-drug* interactions. (*medications illicit drugs, and other substances). 3rd ed. Mundelein, IL: Addiction Treatment Forum; 2005.

7. Pérez de los Cobos J, Siñol N, Trujols J, et al. Association of CYP2D6 ultrarapid metabolizer genotype with deficient patient satisfaction regarding methadone maintenance treatment. Drug Alcohol Depend. 2007;89:190-194.

8. Kristensen K, Christensen CB, Christrup LL. The mu1 mu2, delta, kappa opioid receptor binding profiles of methadone stereoisomers and morphine. Life Sci. 1995;56:PL45-50.

9. Armstrong SC, Wynn GH, Sandson NB. Pharmacokinetic drug interactions of synthetic opiate analgesics. Psychosomatics. 2009;50:169-176.

10. Spina E, Santoro V, D’Arrigo C. Clinically relevant pharmacokinetic drug interactions with second-generation antidepressants: an update. Clin Ther. 2008;30:1206-1227.

11. Ramírez J, Innocenti F, Schuetz EG, et al. CYP2B6, CYP3A4, and CYP2C19 are responsible for the in vitro N-demethylation of meperidine in human liver microsomes. Drug Metab Dispos. 2004;32:930-936.

12. Kaiko RF, Foley KM, Grabinski PY, et al. Central nervous system excitatory effects of meperidine in cancer patients. Ann Neurol. 1983;13:180-185.

13. Chalverus C. Clinically important meperidine toxicities. Journal of Pharmaceutical Care in Pain and Symptom Control. 2001;9:37-55.

14. Beckwith MC, Fox ER, Chandramouli J. Removing meperidine from the health-system formulary—frequently asked questions. J Pain Palliat Care Pharmacother. 2002;16:45-59.

15. Foster A, Mobley E, Wang Z. Complicated pain management in a CYP450 2D6 poor metabolizer. Pain Pract. 2007;7:352-356.

16. Susce MT, Murray-Carmichael E, de Leon J. Response to hydrocodone codeine and oxycodone in a CYP2D6 poor metabolizer. Prog Neuropsychopharmacol Biol Psychiatry. 2006;30:1356-1358.

17. Sansone RA, Sansone LA. Tramadol: seizures serotonin syndrome, and coadministered antidepressants. Psychiatry (Edgmont). 2009;6:17-21.

18. Laugesen S, Enggaard TP, Pedersen RS, et al. Paroxetine, a cytochrome P450 2D6 inhibitor, diminishes the stereoselective O-demethylation and reduces the hypoalgesic effect of tramadol. Clin Pharmacol Ther. 2005;77:312-323.

19. Duragesic [package insert]. Raritan NJ: Ortho-McNeil-Janssen Pharmaceuticals, Inc; 2009.

20. Caplehorn JR, Drummer OH. Fatal methadone toxicity: signs and circumstances and the role of benzodiazepines. Aust N Z J Public Health. 2002;26:358-362;discussion 362–363.

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Aaron M. Pierce, DO
Dr. Pierce is Medical Director, Psychiatry Clinic, Assistant Professor, Department of Psychiatry, University of Oklahoma School of Community Medicine, Tulsa, OK.

Nancy C. Brahm, PharmD, MS, BCPP
Dr. Brahm is Clinical Associate Professor, Department of Pharmacy Practice: Clinical and Administrative Sciences-Tulsa, University of Oklahoma College of Pharmacy, Tulsa, OK.

Vicki L. Ellingrod, PharmD, BCPP, FCCP
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Aaron M. Pierce, DO
Dr. Pierce is Medical Director, Psychiatry Clinic, Assistant Professor, Department of Psychiatry, University of Oklahoma School of Community Medicine, Tulsa, OK.

Nancy C. Brahm, PharmD, MS, BCPP
Dr. Brahm is Clinical Associate Professor, Department of Pharmacy Practice: Clinical and Administrative Sciences-Tulsa, University of Oklahoma College of Pharmacy, Tulsa, OK.

Vicki L. Ellingrod, PharmD, BCPP, FCCP
Series Editor

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Aaron M. Pierce, DO
Dr. Pierce is Medical Director, Psychiatry Clinic, Assistant Professor, Department of Psychiatry, University of Oklahoma School of Community Medicine, Tulsa, OK.

Nancy C. Brahm, PharmD, MS, BCPP
Dr. Brahm is Clinical Associate Professor, Department of Pharmacy Practice: Clinical and Administrative Sciences-Tulsa, University of Oklahoma College of Pharmacy, Tulsa, OK.

Vicki L. Ellingrod, PharmD, BCPP, FCCP
Series Editor

Article PDF
1006CP_Savvy.pdf
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1006CP_Savvy.pdf

 

Practice Points

• When choosing pharmacologic therapy, make sure that all medications your patient takes are documented, consider drug-drug interactions, and instruct the patient to notify you of any new medications.

• In addition to toxicity, loss of efficacy of some opiate drugs may occur as a result of metabolic inhibition or induction by psychotropic medications.

Collaborate with the physician who is prescribing the opioid if psychotropic choices are limited. The patient’s pain may be treated adequately with another analgesic that does not interact with the psychotropic that has been chosen.

As prescribed by his internist, Mr. G, age 44, takes 10 mg of methadone every 4 hours for chronic back pain secondary to a work-related injury 3 years ago. He experiences minimal sedation. Mr. G presents for psychiatric evaluation with complaints of increasing irritability, poor focus, low energy, and lack of interest in usual activities. The psychiatrist diagnoses him with depressive disorder not otherwise specified, and prescribes fluoxetine, 20 mg/d. Three weeks later, Mr. G’s wife contacts the psychiatrist reporting that her husband seems “overmedicated” and describes excess drowsiness and slowed thought processing.

After discussion with Mr. G’s internist and pharmacist, the psychiatrist decides that this oversedation may represent a drug-drug interaction between methadone and fluoxetine resulting in higher-than-expected methadone serum levels. Mr. G is instructed to stop fluoxetine with no taper, and his methadone dose is lowered with good results. Over the next 2 weeks Mr. G is titrated back to his original methadone dose and is re-evaluated by the psychiatrist to discuss medication options to address his depression.

Psychiatrists commonly encounter patients who receive opiate medications for chronic pain. Being aware of potential drug-drug interactions between opiate medications and psychotropics can help avoid adverse effects and combinations that may affect the efficacy of either drug. Pharmacokinetic interactions may affect your choice of psychiatric medication and should be taken into account when addressing adverse effects in any patient who takes opiates and psychotropics.

Metabolic pathways

The primary metabolic pathways for opiate metabolism are the cytochrome P450 (CYP) 2D6 and 3A4 isoenzymes. Depending on the agent used, prescribers may need to consider interactions for both pathways (Table 11,2 and Table 21). For example, oxycodone is metabolized via 2D6 and 3A4 isoenzymes and is a potent analgesic with oxymorphone and noroxycodone as its active metabolites. These metabolites, however, make a negligible contribution to oxycodone’s analgesic effect.3,4 Metabolism by the 3A4 isoenzyme is the principal oxidative pathway and the 2D6 site accounts for approximately 10% of oxycodone metabolism. A randomized, placebo-controlled, crossover study showed that 2D6 inhibition by paroxetine had no significant effect on oxycodone levels; however, a combination of paroxetine and itraconazole, a potent 3A4 inhibitor, resulted in substantial increases in oxycodone plasma levels.5 Remain vigilant for possible opiate toxicity when administering oxycodone with 3A4 inhibitors.

 

Clinical Point

Remain vigilant for possible opiate toxicity when administering oxycodone with

Methadone and meperidine also involve dual pathways. Methadone is metabolized primarily by 3A4 and 2B6, with 2D6 playing a smaller role.6 CYP2D6 seems to play an important part in metabolizing the R-enantiomer of methadone, which is largely responsible for the drug’s opiate effects, such as analgesia and respiratory depression.7,8 Induction of the 3A4 isoenzyme may result in methadone withdrawal, and inhibition may cause methadone toxicity.9 Inducers of 3A4, such as carbamazepine, and inhibitors, such as fluoxetine and fluvoxamine, should be avoided or used very cautiously in patients taking methadone. The 2B6 and 2D6 isoenzymes also may increase or decrease methadone levels and should be treated similarly. In Mr. G’s case, fluoxetine inhibited all 3 isoenzymes that are primarily responsible for methadone metabolism. A better antidepressant choice for Mr. G may have been venlafaxine, which is known to only mildly inhibit 2D6, or mirtazapine, which does not seem to inhibit the major CYP isoforms to an appreciable degree.10

Although the full scope of meperidine metabolism has not been identified,9 an in vitro test demonstrated that 2B6 and 3A4 play important roles in metabolizing meperidine to normeperidine, its major metabolite.11 Normeperidine does not provide analgesia and is associated with neurotoxicity, including anxiety, tremor, muscle twitching, and seizure.12 Agents that induce 3A4—such as carbamazepine or St. John’s wort—may contribute to neurotoxicity.9 Inhibition of these isoenzymes may increase meperidine levels and lead to anticholinergic toxicity or respiratory and central nervous system depression.13,14

Opiates metabolized by the 2D6 isoenzyme include codeine, hydrocodone, and tramadol. The analgesic effect of codeine seems dependent on 2D6 metabolism. Via this pathway, codeine is converted into morphine, which has a 300-times stronger affinity for the μ opioid receptor compared with codeine. 2D6 poor metabolizers have shown codeine intolerance and toxicity.3 Psychotropics known to strongly inhibit 2D6 isoenzyme processes—such as paroxetine, fluoxetine, and bupropion—should be avoided in patients taking codeine to prevent adverse effects and potential loss of efficacy. Better antidepressant choices include citalopram or venlafaxine, which inhibit 2D6 to a lesser degree.

 

 

 

Clinical Point

Agents that inhibit 3A4 could increase fentanyl plasma concentration, leading to respiratory depression

Hydrocodone may be a viable option for patients taking 2D6 inhibitors. Hydrocodone is metabolized by 2D6 into hydromorphone, which is 7 to 33 times more potent than hydrocodone.15 Unlike codeine, 2D6 inhibition may have little effect on hydrocodone’s analgesic properties. Animal studies have shown that inhibition of the CYP analog to 2D6 does not affect analgesic response. In humans, 2D6 inhibition does not seem to affect hydrocodone’s abuse liability.16 Two case reports describe known 2D6 poor metabolizers who showed at least a partial response to hydrocodone.15,16

Tramadol’s analgesic properties may be related to serotonin and norepinephrine reuptake inhibition. It is less potent than codeine but is metabolized via the 2D6 isoenzyme into 0-desmethyltramadol, which is up to 200 times stronger than its parent compound.17 Clinicians should be aware that tramadol’s efficacy may be decreased when coadministered with 2D6 inhibitors. In a randomized, placebo-controlled trial, paroxetine, a potent 2D6 inhibitor, was shown to lessen the analgesic effect of tramadol.18

 

Clinical Point

Use of SSRIs or tricyclic antidepressants with tramadol may increase risk for serotonin syndrome

The 3A4 site is the primary pathway for fentanyl metabolism. Agents that inhibit 3A4 could increase fentanyl plasma concentration, leading to respiratory depression.19 Examples of 3A4 inhibitors include fluoxetine and fluvoxamine.

Psychotropics may inhibit or induce P450 isoenzymes to varying degrees. For example, paroxetine and citalopram are known to inhibit 2D6 but paroxetine is a stronger inhibitor; therefore, a significant drug-drug interaction is more likely with paroxetine and a 2D6 substrate than the same substrate administered with citalopram.

Table 1

Cytochrome P450 isoenzymes inhibited and induced by psychotropics

 

IsoenzymePotencyPsychotropic(s)
2B6 inducerModerateCarbamazepine
2B6 inhibitorsMild to moderateFluoxetine, fluvoxamine
ModerateSertraline
PotentParoxetine
2D6 inhibitorsMildVenlafaxine
Mild to moderateCitalopram, escitalopram, fluvoxamine, risperidone
ModerateDuloxetine
Moderate to potentBupropion
PotentFluoxetine, haloperidol, paroxetine
Dose-dependentSertraline
3A4 inducerPotentCarbamazepine
3A4 inhibitorsMildSertraline
Mild to moderateFluoxetine, fluvoxamine
Source: References 1,2

Table 2

Cytochrome P450 isoenzymes inhibiting and inducing opiate metabolism

 

IsoenzymeOpiates
2B6 inducerMethadone
2B6 inhibitorsMeperidine, methadone
2D6 inhibitorsCodeine (may involve loss of efficacy as well as
toxicity), methadone, tramadol (may involve loss of efficacy)
3A4 inducerMeperidine, methadone
3A4 inhibitorsFentanyl, oxycodone, meperidine, methadone
Source: Reference 1

Other considerations

In addition to pharmacokinetic interactions, it is important to consider synergistic effects of some opiates and psychotropics. Examples include:

 

  • additive effect on respiratory depression by benzodiazepines and opiates
  • increased risk of serotonin syndrome and seizure when using tramadol with selective serotonin reuptake inhibitors or tricyclic antidepressants
  • additive prolongation of the QTc interval by methadone when used with psychotropics known to prolong the QTc, such as ziprasidone.9,17,20

Careful attention to these interactions and collaboration among providers can ensure the best outcome for our patients. In Mr. G’s case, collaboration with his internist would be in order, particularly if antidepressant choices are limited. In consultation with the psychiatrist, the internist might choose another opiate to treat Mr. G’s pain that would not interact with fluoxetine. If Mr. G and his physician have struggled to manage his pain and if he is stable on the current regimen, selecting a different antidepressant may be warranted.

Related Resources

 

  • Indiana University School of Medicine drug interactions: cytochrome P450 drug interaction table. http://medicine.iupui.edu/clinpharm/ddis/table.asp.
  • Ferrando SJ, Levenson JL, Owen JA, eds. Clinical manual of psychopharmacology in the medically ill. Arlington, VA: American Psychiatric Publishing, Inc; 2010.

Drug Brand Names

 

  • Bupropion • Wellbutrin, Zyban
  • Carbamazepine • Tegretol
  • Citalopram • Celexa
  • Duloxetine • Cymbalta
  • Escitalopram • Lexapro
  • Fentanyl • Duragesic, Actiq
  • Fluoxetine • Prozac
  • Fluvoxamine • Luvox
  • Haloperidol • Haldol
  • Hydrocodone • Lortab, Vicodin, others
  • Itraconazole • Sporanox
  • Meperidine • Demerol
  • Methadone • Dolophine, Methadose
  • Mirtazapine • Remeron
  • Morphine • Avinza, Duramorph, others
  • Oxycodone • OxyContin, Roxicodone
  • Paroxetine • Paxil
  • Risperidone • Risperdal
  • Sertraline • Zoloft
  • Tramadol • Ultram
  • Venlafaxine • Effexor
  • Ziprasidone • Geodon

Disclosure

The authors report no financial relationship with any company whose products are mentioned in this article or with manufacturers of competing products.

 

Practice Points

• When choosing pharmacologic therapy, make sure that all medications your patient takes are documented, consider drug-drug interactions, and instruct the patient to notify you of any new medications.

• In addition to toxicity, loss of efficacy of some opiate drugs may occur as a result of metabolic inhibition or induction by psychotropic medications.

Collaborate with the physician who is prescribing the opioid if psychotropic choices are limited. The patient’s pain may be treated adequately with another analgesic that does not interact with the psychotropic that has been chosen.

As prescribed by his internist, Mr. G, age 44, takes 10 mg of methadone every 4 hours for chronic back pain secondary to a work-related injury 3 years ago. He experiences minimal sedation. Mr. G presents for psychiatric evaluation with complaints of increasing irritability, poor focus, low energy, and lack of interest in usual activities. The psychiatrist diagnoses him with depressive disorder not otherwise specified, and prescribes fluoxetine, 20 mg/d. Three weeks later, Mr. G’s wife contacts the psychiatrist reporting that her husband seems “overmedicated” and describes excess drowsiness and slowed thought processing.

After discussion with Mr. G’s internist and pharmacist, the psychiatrist decides that this oversedation may represent a drug-drug interaction between methadone and fluoxetine resulting in higher-than-expected methadone serum levels. Mr. G is instructed to stop fluoxetine with no taper, and his methadone dose is lowered with good results. Over the next 2 weeks Mr. G is titrated back to his original methadone dose and is re-evaluated by the psychiatrist to discuss medication options to address his depression.

Psychiatrists commonly encounter patients who receive opiate medications for chronic pain. Being aware of potential drug-drug interactions between opiate medications and psychotropics can help avoid adverse effects and combinations that may affect the efficacy of either drug. Pharmacokinetic interactions may affect your choice of psychiatric medication and should be taken into account when addressing adverse effects in any patient who takes opiates and psychotropics.

Metabolic pathways

The primary metabolic pathways for opiate metabolism are the cytochrome P450 (CYP) 2D6 and 3A4 isoenzymes. Depending on the agent used, prescribers may need to consider interactions for both pathways (Table 11,2 and Table 21). For example, oxycodone is metabolized via 2D6 and 3A4 isoenzymes and is a potent analgesic with oxymorphone and noroxycodone as its active metabolites. These metabolites, however, make a negligible contribution to oxycodone’s analgesic effect.3,4 Metabolism by the 3A4 isoenzyme is the principal oxidative pathway and the 2D6 site accounts for approximately 10% of oxycodone metabolism. A randomized, placebo-controlled, crossover study showed that 2D6 inhibition by paroxetine had no significant effect on oxycodone levels; however, a combination of paroxetine and itraconazole, a potent 3A4 inhibitor, resulted in substantial increases in oxycodone plasma levels.5 Remain vigilant for possible opiate toxicity when administering oxycodone with 3A4 inhibitors.

 

Clinical Point

Remain vigilant for possible opiate toxicity when administering oxycodone with

Methadone and meperidine also involve dual pathways. Methadone is metabolized primarily by 3A4 and 2B6, with 2D6 playing a smaller role.6 CYP2D6 seems to play an important part in metabolizing the R-enantiomer of methadone, which is largely responsible for the drug’s opiate effects, such as analgesia and respiratory depression.7,8 Induction of the 3A4 isoenzyme may result in methadone withdrawal, and inhibition may cause methadone toxicity.9 Inducers of 3A4, such as carbamazepine, and inhibitors, such as fluoxetine and fluvoxamine, should be avoided or used very cautiously in patients taking methadone. The 2B6 and 2D6 isoenzymes also may increase or decrease methadone levels and should be treated similarly. In Mr. G’s case, fluoxetine inhibited all 3 isoenzymes that are primarily responsible for methadone metabolism. A better antidepressant choice for Mr. G may have been venlafaxine, which is known to only mildly inhibit 2D6, or mirtazapine, which does not seem to inhibit the major CYP isoforms to an appreciable degree.10

Although the full scope of meperidine metabolism has not been identified,9 an in vitro test demonstrated that 2B6 and 3A4 play important roles in metabolizing meperidine to normeperidine, its major metabolite.11 Normeperidine does not provide analgesia and is associated with neurotoxicity, including anxiety, tremor, muscle twitching, and seizure.12 Agents that induce 3A4—such as carbamazepine or St. John’s wort—may contribute to neurotoxicity.9 Inhibition of these isoenzymes may increase meperidine levels and lead to anticholinergic toxicity or respiratory and central nervous system depression.13,14

Opiates metabolized by the 2D6 isoenzyme include codeine, hydrocodone, and tramadol. The analgesic effect of codeine seems dependent on 2D6 metabolism. Via this pathway, codeine is converted into morphine, which has a 300-times stronger affinity for the μ opioid receptor compared with codeine. 2D6 poor metabolizers have shown codeine intolerance and toxicity.3 Psychotropics known to strongly inhibit 2D6 isoenzyme processes—such as paroxetine, fluoxetine, and bupropion—should be avoided in patients taking codeine to prevent adverse effects and potential loss of efficacy. Better antidepressant choices include citalopram or venlafaxine, which inhibit 2D6 to a lesser degree.

 

 

 

Clinical Point

Agents that inhibit 3A4 could increase fentanyl plasma concentration, leading to respiratory depression

Hydrocodone may be a viable option for patients taking 2D6 inhibitors. Hydrocodone is metabolized by 2D6 into hydromorphone, which is 7 to 33 times more potent than hydrocodone.15 Unlike codeine, 2D6 inhibition may have little effect on hydrocodone’s analgesic properties. Animal studies have shown that inhibition of the CYP analog to 2D6 does not affect analgesic response. In humans, 2D6 inhibition does not seem to affect hydrocodone’s abuse liability.16 Two case reports describe known 2D6 poor metabolizers who showed at least a partial response to hydrocodone.15,16

Tramadol’s analgesic properties may be related to serotonin and norepinephrine reuptake inhibition. It is less potent than codeine but is metabolized via the 2D6 isoenzyme into 0-desmethyltramadol, which is up to 200 times stronger than its parent compound.17 Clinicians should be aware that tramadol’s efficacy may be decreased when coadministered with 2D6 inhibitors. In a randomized, placebo-controlled trial, paroxetine, a potent 2D6 inhibitor, was shown to lessen the analgesic effect of tramadol.18

 

Clinical Point

Use of SSRIs or tricyclic antidepressants with tramadol may increase risk for serotonin syndrome

The 3A4 site is the primary pathway for fentanyl metabolism. Agents that inhibit 3A4 could increase fentanyl plasma concentration, leading to respiratory depression.19 Examples of 3A4 inhibitors include fluoxetine and fluvoxamine.

Psychotropics may inhibit or induce P450 isoenzymes to varying degrees. For example, paroxetine and citalopram are known to inhibit 2D6 but paroxetine is a stronger inhibitor; therefore, a significant drug-drug interaction is more likely with paroxetine and a 2D6 substrate than the same substrate administered with citalopram.

Table 1

Cytochrome P450 isoenzymes inhibited and induced by psychotropics

 

IsoenzymePotencyPsychotropic(s)
2B6 inducerModerateCarbamazepine
2B6 inhibitorsMild to moderateFluoxetine, fluvoxamine
ModerateSertraline
PotentParoxetine
2D6 inhibitorsMildVenlafaxine
Mild to moderateCitalopram, escitalopram, fluvoxamine, risperidone
ModerateDuloxetine
Moderate to potentBupropion
PotentFluoxetine, haloperidol, paroxetine
Dose-dependentSertraline
3A4 inducerPotentCarbamazepine
3A4 inhibitorsMildSertraline
Mild to moderateFluoxetine, fluvoxamine
Source: References 1,2

Table 2

Cytochrome P450 isoenzymes inhibiting and inducing opiate metabolism

 

IsoenzymeOpiates
2B6 inducerMethadone
2B6 inhibitorsMeperidine, methadone
2D6 inhibitorsCodeine (may involve loss of efficacy as well as
toxicity), methadone, tramadol (may involve loss of efficacy)
3A4 inducerMeperidine, methadone
3A4 inhibitorsFentanyl, oxycodone, meperidine, methadone
Source: Reference 1

Other considerations

In addition to pharmacokinetic interactions, it is important to consider synergistic effects of some opiates and psychotropics. Examples include:

 

  • additive effect on respiratory depression by benzodiazepines and opiates
  • increased risk of serotonin syndrome and seizure when using tramadol with selective serotonin reuptake inhibitors or tricyclic antidepressants
  • additive prolongation of the QTc interval by methadone when used with psychotropics known to prolong the QTc, such as ziprasidone.9,17,20

Careful attention to these interactions and collaboration among providers can ensure the best outcome for our patients. In Mr. G’s case, collaboration with his internist would be in order, particularly if antidepressant choices are limited. In consultation with the psychiatrist, the internist might choose another opiate to treat Mr. G’s pain that would not interact with fluoxetine. If Mr. G and his physician have struggled to manage his pain and if he is stable on the current regimen, selecting a different antidepressant may be warranted.

Related Resources

 

  • Indiana University School of Medicine drug interactions: cytochrome P450 drug interaction table. http://medicine.iupui.edu/clinpharm/ddis/table.asp.
  • Ferrando SJ, Levenson JL, Owen JA, eds. Clinical manual of psychopharmacology in the medically ill. Arlington, VA: American Psychiatric Publishing, Inc; 2010.

Drug Brand Names

 

  • Bupropion • Wellbutrin, Zyban
  • Carbamazepine • Tegretol
  • Citalopram • Celexa
  • Duloxetine • Cymbalta
  • Escitalopram • Lexapro
  • Fentanyl • Duragesic, Actiq
  • Fluoxetine • Prozac
  • Fluvoxamine • Luvox
  • Haloperidol • Haldol
  • Hydrocodone • Lortab, Vicodin, others
  • Itraconazole • Sporanox
  • Meperidine • Demerol
  • Methadone • Dolophine, Methadose
  • Mirtazapine • Remeron
  • Morphine • Avinza, Duramorph, others
  • Oxycodone • OxyContin, Roxicodone
  • Paroxetine • Paxil
  • Risperidone • Risperdal
  • Sertraline • Zoloft
  • Tramadol • Ultram
  • Venlafaxine • Effexor
  • Ziprasidone • Geodon

Disclosure

The authors report no financial relationship with any company whose products are mentioned in this article or with manufacturers of competing products.

References

 

1. Sandson NB, Armstrong SC, Cozza KL. An overview of psychotropic drug-drug interactions. Psychosomatics. 2005;46:464-494.

2. Faucette SR, Wang H, Hamilton GA. Regulation of CYP2B6 in primary human hepatocytes by prototypical inducers. Drug Metab Dispos. 2004;32(3):348-358.

3. Smith HS. Opioid metabolism. Mayo Clin Proc. 2009;84:613-624.

4. Armstrong SC, Cozza KL. Pharmacokinetic drug interactions of morphine codeine, and their derivatives: theory and clinical reality, part II. Psychosomatics. 2003;44:515-520.

5. Grönlund J, Saari TI, Hagelberg NM, et al. Exposure to oral oxycodone is increased by concomitant inhibition of CYP2D6 and 3A4 pathways, but not by inhibition of CYP2D6 alone. Br J Clin Pharmacol. 2010;70:78-87.

6. Leavitt SB. Methadone-drug* interactions. (*medications illicit drugs, and other substances). 3rd ed. Mundelein, IL: Addiction Treatment Forum; 2005.

7. Pérez de los Cobos J, Siñol N, Trujols J, et al. Association of CYP2D6 ultrarapid metabolizer genotype with deficient patient satisfaction regarding methadone maintenance treatment. Drug Alcohol Depend. 2007;89:190-194.

8. Kristensen K, Christensen CB, Christrup LL. The mu1 mu2, delta, kappa opioid receptor binding profiles of methadone stereoisomers and morphine. Life Sci. 1995;56:PL45-50.

9. Armstrong SC, Wynn GH, Sandson NB. Pharmacokinetic drug interactions of synthetic opiate analgesics. Psychosomatics. 2009;50:169-176.

10. Spina E, Santoro V, D’Arrigo C. Clinically relevant pharmacokinetic drug interactions with second-generation antidepressants: an update. Clin Ther. 2008;30:1206-1227.

11. Ramírez J, Innocenti F, Schuetz EG, et al. CYP2B6, CYP3A4, and CYP2C19 are responsible for the in vitro N-demethylation of meperidine in human liver microsomes. Drug Metab Dispos. 2004;32:930-936.

12. Kaiko RF, Foley KM, Grabinski PY, et al. Central nervous system excitatory effects of meperidine in cancer patients. Ann Neurol. 1983;13:180-185.

13. Chalverus C. Clinically important meperidine toxicities. Journal of Pharmaceutical Care in Pain and Symptom Control. 2001;9:37-55.

14. Beckwith MC, Fox ER, Chandramouli J. Removing meperidine from the health-system formulary—frequently asked questions. J Pain Palliat Care Pharmacother. 2002;16:45-59.

15. Foster A, Mobley E, Wang Z. Complicated pain management in a CYP450 2D6 poor metabolizer. Pain Pract. 2007;7:352-356.

16. Susce MT, Murray-Carmichael E, de Leon J. Response to hydrocodone codeine and oxycodone in a CYP2D6 poor metabolizer. Prog Neuropsychopharmacol Biol Psychiatry. 2006;30:1356-1358.

17. Sansone RA, Sansone LA. Tramadol: seizures serotonin syndrome, and coadministered antidepressants. Psychiatry (Edgmont). 2009;6:17-21.

18. Laugesen S, Enggaard TP, Pedersen RS, et al. Paroxetine, a cytochrome P450 2D6 inhibitor, diminishes the stereoselective O-demethylation and reduces the hypoalgesic effect of tramadol. Clin Pharmacol Ther. 2005;77:312-323.

19. Duragesic [package insert]. Raritan NJ: Ortho-McNeil-Janssen Pharmaceuticals, Inc; 2009.

20. Caplehorn JR, Drummer OH. Fatal methadone toxicity: signs and circumstances and the role of benzodiazepines. Aust N Z J Public Health. 2002;26:358-362;discussion 362–363.

References

 

1. Sandson NB, Armstrong SC, Cozza KL. An overview of psychotropic drug-drug interactions. Psychosomatics. 2005;46:464-494.

2. Faucette SR, Wang H, Hamilton GA. Regulation of CYP2B6 in primary human hepatocytes by prototypical inducers. Drug Metab Dispos. 2004;32(3):348-358.

3. Smith HS. Opioid metabolism. Mayo Clin Proc. 2009;84:613-624.

4. Armstrong SC, Cozza KL. Pharmacokinetic drug interactions of morphine codeine, and their derivatives: theory and clinical reality, part II. Psychosomatics. 2003;44:515-520.

5. Grönlund J, Saari TI, Hagelberg NM, et al. Exposure to oral oxycodone is increased by concomitant inhibition of CYP2D6 and 3A4 pathways, but not by inhibition of CYP2D6 alone. Br J Clin Pharmacol. 2010;70:78-87.

6. Leavitt SB. Methadone-drug* interactions. (*medications illicit drugs, and other substances). 3rd ed. Mundelein, IL: Addiction Treatment Forum; 2005.

7. Pérez de los Cobos J, Siñol N, Trujols J, et al. Association of CYP2D6 ultrarapid metabolizer genotype with deficient patient satisfaction regarding methadone maintenance treatment. Drug Alcohol Depend. 2007;89:190-194.

8. Kristensen K, Christensen CB, Christrup LL. The mu1 mu2, delta, kappa opioid receptor binding profiles of methadone stereoisomers and morphine. Life Sci. 1995;56:PL45-50.

9. Armstrong SC, Wynn GH, Sandson NB. Pharmacokinetic drug interactions of synthetic opiate analgesics. Psychosomatics. 2009;50:169-176.

10. Spina E, Santoro V, D’Arrigo C. Clinically relevant pharmacokinetic drug interactions with second-generation antidepressants: an update. Clin Ther. 2008;30:1206-1227.

11. Ramírez J, Innocenti F, Schuetz EG, et al. CYP2B6, CYP3A4, and CYP2C19 are responsible for the in vitro N-demethylation of meperidine in human liver microsomes. Drug Metab Dispos. 2004;32:930-936.

12. Kaiko RF, Foley KM, Grabinski PY, et al. Central nervous system excitatory effects of meperidine in cancer patients. Ann Neurol. 1983;13:180-185.

13. Chalverus C. Clinically important meperidine toxicities. Journal of Pharmaceutical Care in Pain and Symptom Control. 2001;9:37-55.

14. Beckwith MC, Fox ER, Chandramouli J. Removing meperidine from the health-system formulary—frequently asked questions. J Pain Palliat Care Pharmacother. 2002;16:45-59.

15. Foster A, Mobley E, Wang Z. Complicated pain management in a CYP450 2D6 poor metabolizer. Pain Pract. 2007;7:352-356.

16. Susce MT, Murray-Carmichael E, de Leon J. Response to hydrocodone codeine and oxycodone in a CYP2D6 poor metabolizer. Prog Neuropsychopharmacol Biol Psychiatry. 2006;30:1356-1358.

17. Sansone RA, Sansone LA. Tramadol: seizures serotonin syndrome, and coadministered antidepressants. Psychiatry (Edgmont). 2009;6:17-21.

18. Laugesen S, Enggaard TP, Pedersen RS, et al. Paroxetine, a cytochrome P450 2D6 inhibitor, diminishes the stereoselective O-demethylation and reduces the hypoalgesic effect of tramadol. Clin Pharmacol Ther. 2005;77:312-323.

19. Duragesic [package insert]. Raritan NJ: Ortho-McNeil-Janssen Pharmaceuticals, Inc; 2009.

20. Caplehorn JR, Drummer OH. Fatal methadone toxicity: signs and circumstances and the role of benzodiazepines. Aust N Z J Public Health. 2002;26:358-362;discussion 362–363.

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