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Drug Interactions between Bel-Phen-Ergot and ozanimod

This report displays the potential drug interactions for the following 2 drugs:

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Major

PHENobarbital ozanimod

Applies to: Bel-Phen-Ergot (belladonna / ergotamine / phenobarbital) and ozanimod

GENERALLY AVOID: Coadministration of ozanimod with strong CYP450 2C8 inducers may decrease the exposure (AUC) of the major active metabolites of ozanimod which may lead to loss of efficacy. The proposed mechanism is induction of CYP450 2C8-mediated metabolism of ozanimod, which has been shown to be metabolized by this isoenzyme. Coadministration with rifampin (600 mg once daily), a moderate inducer of CYP450 2C8, at steady state with a single 0.92 mg dose of ozanimod decreased the AUC for ozanimod and the active metabolites CC112273 and CC1084037 by approximately 24%, 60%, and 55%, respectively.

MANAGEMENT: Coadministration of ozanimod with strong CYP450 2C8 inducers should be avoided due to the potential for reduced efficacy.

References

  1. (2020) "Product Information. Zeposia (ozanimod)." Celgene Corporation

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Moderate

ergotamine PHENobarbital

Applies to: Bel-Phen-Ergot (belladonna / ergotamine / phenobarbital) and Bel-Phen-Ergot (belladonna / ergotamine / phenobarbital)

MONITOR: Coadministration with inducers of CYP450 3A4 may decrease the plasma concentrations of ergot alkaloids, which are substrates of the isoenzyme.

MANAGEMENT: The potential for diminished pharmacologic effects of ergot alkaloids should be considered during coadministration with CYP450 3A4 inducers. Alternative treatments may be required if an interaction is suspected.

References

  1. Cerner Multum, Inc. "UK Summary of Product Characteristics."
  2. Cerner Multum, Inc. "Australian Product Information."
  3. (2010) "Product Information. Methergine (methylergonovine)." Novartis Pharmaceuticals

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Moderate

ergotamine ozanimod

Applies to: Bel-Phen-Ergot (belladonna / ergotamine / phenobarbital) and ozanimod

GENERALLY AVOID: Coadministration of serotonergic agents (e.g., selective serotonin reuptake inhibitors (SSRIs), 5-HT1 receptor agonists (triptans), ergot alkaloids, buspirone, dextromethorphan, St. John's wort) with drugs that possess monoamine oxidase inhibition (MAOI) activity may potentiate the risk of serotonin syndrome, which is a rare but serious and potentially fatal condition thought to result from hyperstimulation of brainstem 5-HT1A and 2A receptors. Symptoms of the serotonin syndrome may include mental status changes such as irritability, altered consciousness, confusion, hallucinations, and coma; autonomic dysfunction such as tachycardia, hyperthermia, diaphoresis, shivering, blood pressure lability, and mydriasis; neuromuscular abnormalities such as hyperreflexia, myoclonus, tremor, rigidity, and ataxia; and gastrointestinal symptoms such as abdominal cramping, nausea, vomiting, and diarrhea. Because an active metabolite of ozanimod inhibits MAO-B in vitro, the interaction may theoretically occur with ozanimod. In clinical trials, a small number of patients treated with ozanimod were concomitantly exposed to serotonergic medications; however, this exposure was not adequate to rule out the possibility of an adverse reaction from coadministration.

MANAGEMENT: Until more information is available, concomitant use of ozanimod with serotonergic agents should be avoided when possible. Blood pressure and other vitals should be monitored if coadministration is required.

References

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  3. Kline SS, Mauro LS, Scala-Bennett DM, Zick D (1989) "Serotonin syndrome versus neuroleptic malignant death syndrome as a cause of death." Clin Pharm, 8, p. 510-4
  4. Sternbach H (1988) "Danger of MAOI therapy after fluoxetine withdrawal." Lancet, 2, p. 850-1
  5. Sovner R, Wolfe J (1988) "Interaction between dextromethorphan and monoamine oxidase inhibitor therapy with isocarboxazid ." N Engl J Med, 319, p. 1671
  6. Bem JL, Peck R (1992) "Dextromethorphan. An overview of safety issues." Drug Saf, 7, p. 190-9
  7. Nierenberg DW, Semprebon M (1993) "The central nervous system serotonin syndrome." Clin Pharmacol Ther, 53, p. 84-8
  8. Graham PM, Potter JM, Paterson J (1982) "Combination monoamine oxidase inhibitor/tricyclic antidepressants interaction." Lancet, 2, p. 440
  9. Spiker DG, Pugh DD (1976) "Combining tricyclic and monoamine oxidase inhibitor antidepressants." Arch Gen Psychiatry, 33, p. 828-30
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  13. (2002) "Product Information. D.H.E. 45 (dihydroergotamine)." Sandoz Pharmaceuticals Corporation
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  19. Graham PM, Ilett KF (1988) "Danger of MAOI therapy after fluoxetine withdrawal." Lancet, 2, p. 1255-6
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  25. (2001) "Product Information. Paxil (paroxetine)." GlaxoSmithKline
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  27. (2001) "Product Information. Imitrex (sumatriptan)." Glaxo Wellcome
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  33. Phillips SD, Ringo P (1995) "Phenelzine and venlafaxine interaction." Am J Psychiatry, 152, p. 1400-1
  34. Klysner R, Larsen JK, Sorensen P, Hyllested M, Pedersen BD (1995) "Toxic interaction of venlafaxine and isocarboxazide." Lancet, 346, p. 1298-9
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  40. Thomas JM, Rubin EH (1984) "Case report of a toxic reaction from a combination of tryptophan and phenelzine." Am J Psychiatry, 141, p. 281-3
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  46. (2001) "Product Information. Zomig (zolmitriptan)." Astra-Zeneca Pharmaceuticals
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  48. (2001) "Product Information. Maxalt (rizatriptan)." Merck & Co., Inc
  49. (2001) "Product Information. Celexa (citalopram)." Forest Pharmaceuticals
  50. Gardner DM, Lynd LD (1998) "Sumatriptan contraindications and the serotonin syndrome." Ann Pharmacother, 32, p. 33-8
  51. Mathew NT, Tietjen GE, Lucker C (1996) "Serotonin syndrome complicating migraine pharmacotherapy." Cephalalgia, 16, p. 323-7
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  53. Diamond S, Pepper BJ, Diamond ML, Freitag FG, Urban GJ, Erdemoglu AK (1998) "Serotonin syndrome induced by transitioning from phenelzine to venlafaxine: four patient reports." Neurology, 51, p. 274-6
  54. Chan BSH, Graudins A, Whyte IM, Dawson AH, Braitberg G, Duggin GG (1998) "Serotonin syndrome resulting from drug interactions." Med J Aust, 169, p. 523-5
  55. Brubacher JR, Hoffman RS, Lurin MJ (1996) "Serotonin syndrome from venlafaxine-tranylcypromine interaction." Vet Hum Toxicol, 38, p. 358-61
  56. Miller LG (1998) "Herbal medicinals: selected clinical considerations focusing on known or potential drug-herb interactions." Arch Intern Med, 158, p. 2200-11
  57. Fleishaker JC, Ryan KK, Jansat JM, et al. (2001) "Effect of MAO-A inhibition on the pharmacokinetics of almotriptan, an antimigraine agent in humans." Br J Clin Pharmacol, 51, p. 437-41
  58. (2002) "Product Information. Lexapro (escitalopram)." Forest Pharmaceuticals
  59. Martin TG (1996) "Serotonin syndrome." Ann Emerg Med, 28, p. 520-6
  60. Jacob JE, Wagner ML, Sage JI (2003) "Safety of selegiline with cold medications." Ann Pharmacother, 37, p. 438-41
  61. (2004) "Product Information. Cymbalta (duloxetine)." Lilly, Eli and Company
  62. (2005) "Product Information. Manerix (moclobemide)." Hoffmann-La Roche Limited
  63. Gillman PK (2005) "Monoamine oxidase inhibitors, opioid analgesics and serotonin toxicity." Br J Anaesth
  64. Bodner RA, Lynch T, Lewis L, Kahn D (1995) "Serotonin syndrome." Neurology, 45, p. 219-23
  65. Paruchuri P, Godkar D, Anandacoomarswamy D, Sheth K, Niranjan S (2006) "Rare case of serotonin syndrome with therapeutic doses of paroxetine." Am J Ther, 13, p. 550-552
  66. Jimenez-Genchi A (2006) "Immediate switching from moclobemide to duloxetine may induce serotonin syndrome." J Clin Psychiatry, 67, p. 1821-1822
  67. (2008) "Product Information. Pristiq (desvenlafaxine)." Wyeth Laboratories
  68. (2009) "Product Information. Savella (milnacipran)." Forest Pharmaceuticals
  69. (2011) "Product Information. Viibryd (vilazodone)." Trovis Pharmaceuticals LLC
  70. (2013) "Product Information. Fetzima (levomilnacipran)." Forest Pharmaceuticals
  71. (2013) "Product Information. Brintellix (vortioxetine)." Takeda Pharmaceuticals America
  72. (2020) "Product Information. Zeposia (ozanimod)." Celgene Corporation
View all 72 references

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Drug and food interactions

Major

PHENobarbital food

Applies to: Bel-Phen-Ergot (belladonna / ergotamine / phenobarbital)

GENERALLY AVOID: Concurrent acute use of barbiturates and ethanol may result in additive CNS effects, including impaired coordination, sedation, and death. Tolerance of these agents may occur with chronic use. The mechanism is related to inhibition of microsomal enzymes acutely and induction of hepatic microsomal enzymes chronically.

MANAGEMENT: The combination of ethanol and barbiturates should be avoided.

References

  1. Gupta RC, Kofoed J (1966) "Toxological statistics for barbiturates, other sedatives, and tranquilizers in Ontario: a 10-year survey." Can Med Assoc J, 94, p. 863-5
  2. Misra PS, Lefevre A, Ishii H, Rubin E, Lieber CS (1971) "Increase of ethanol, meprobamate and pentobarbital metabolism after chronic ethanol administration in man and in rats." Am J Med, 51, p. 346-51
  3. Saario I, Linnoila M (1976) "Effect of subacute treatment with hypnotics, alone or in combination with alcohol, on psychomotor skills related to driving." Acta Pharmacol Toxicol (Copenh), 38, p. 382-92
  4. Stead AH, Moffat AC (1983) "Quantification of the interaction between barbiturates and alcohol and interpretation of fatal blood concentrations." Hum Toxicol, 2, p. 5-14
  5. Seixas FA (1979) "Drug/alcohol interactions: avert potential dangers." Geriatrics, 34, p. 89-102
View all 5 references

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Moderate

ergotamine food

Applies to: Bel-Phen-Ergot (belladonna / ergotamine / phenobarbital)

MONITOR: Grapefruit juice may increase the plasma concentrations of orally administered drugs that are substrates of the CYP450 3A4 isoenzyme. The proposed mechanism is inhibition of CYP450 3A4-mediated first-pass metabolism in the gut wall by certain compounds present in grapefruit. Because grapefruit juice inhibits primarily intestinal rather than hepatic CYP450 3A4, the magnitude of interaction is greatest for those drugs that undergo significant presystemic metabolism by CYP450 3A4 (i.e., drugs with low oral bioavailability). In general, the effect of grapefruit juice is concentration-, dose- and preparation-dependent, and can vary widely among brands. Certain preparations of grapefruit juice (e.g., high dose, double strength) have sometimes demonstrated potent inhibition of CYP450 3A4, while other preparations (e.g., low dose, single strength) have typically demonstrated moderate inhibition. Pharmacokinetic interactions involving grapefruit juice are also subject to a high degree of interpatient variability, thus the extent to which a given patient may be affected is difficult to predict.

MANAGEMENT: Patients who regularly consume grapefruit or grapefruit juice should be monitored for adverse effects and altered plasma concentrations of drugs that undergo significant presystemic metabolism by CYP450 3A4. Grapefruit and grapefruit juice should be avoided if an interaction is suspected. Orange juice is not expected to interact with these drugs.

References

  1. Edgar B, Bailey D, Bergstrand R, et al. (1992) "Acute effects of drinking grapefruit juice on the pharmacokinetics and dynamics on felodipine and its potential clinical relevance." Eur J Clin Pharmacol, 42, p. 313-7
  2. Jonkman JH, Sollie FA, Sauter R, Steinijans VW (1991) "The influence of caffeine on the steady-state pharmacokinetics of theophylline." Clin Pharmacol Ther, 49, p. 248-55
  3. Bailey DG, Arnold JM, Munoz C, Spence JD (1993) "Grapefruit juice--felodipine interaction: mechanism, predictability, and effect of naringin." Clin Pharmacol Ther, 53, p. 637-42
  4. Bailey DG, Arnold JMO, Spence JD (1994) "Grapefruit juice and drugs - how significant is the interaction." Clin Pharmacokinet, 26, p. 91-8
  5. Sigusch H, Hippius M, Henschel L, Kaufmann K, Hoffmann A (1994) "Influence of grapefruit juice on the pharmacokinetics of a slow release nifedipine formulation." Pharmazie, 49, p. 522-4
  6. Bailey DG, Arnold JM, Strong HA, Munoz C, Spence JD (1993) "Effect of grapefruit juice and naringin on nisoldipine pharmacokinetics." Clin Pharmacol Ther, 54, p. 589-94
  7. Yamreudeewong W, Henann NE, Fazio A, Lower DL, Cassidy TG (1995) "Drug-food interactions in clinical practice." J Fam Pract, 40, p. 376-84
  8. (1995) "Grapefruit juice interactions with drugs." Med Lett Drugs Ther, 37, p. 73-4
  9. Hukkinen SK, Varhe A, Olkkola KT, Neuvonen PJ (1995) "Plasma concentrations of triazolam are increased by concomitant ingestion of grapefruit juice." Clin Pharmacol Ther, 58, p. 127-31
  10. Min DI, Ku YM, Geraets DR, Lee HC (1996) "Effect of grapefruit juice on the pharmacokinetics and pharmacodynamics of quinidine in healthy volunteers." J Clin Pharmacol, 36, p. 469-76
  11. Majeed A, Kareem A (1996) "Effect of grapefruit juice on cyclosporine pharmacokinetics." Pediatr Nephrol, 10, p. 395
  12. Clifford CP, Adams DA, Murray S, Taylor GW, Wilkins MR, Boobis AR, Davies DS (1996) "Pharmacokinetic and cardiac effects of terfenadine after inhibition of its metabolism by grapefruit juice." Br J Clin Pharmacol, 42, p662
  13. Josefsson M, Zackrisson AL, Ahlner J (1996) "Effect of grapefruit juice on the pharmacokinetics of amlodipine in healthy volunteers." Eur J Clin Pharmacol, 51, p. 189-93
  14. Kantola T, Kivisto KT, Neuvonen PJ (1998) "Grapefruit juice greatly increases serum concentrations of lovastatin and lovastatin acid." Clin Pharmacol Ther, 63, p. 397-402
  15. Ozdemir M, Aktan Y, Boydag BS, Cingi MI, Musmul A (1998) "Interaction between grapefruit juice and diazepam in humans." Eur J Drug Metab Pharmacokinet, 23, p. 55-9
  16. Bailey DG, Malcolm J, Arnold O, Spence JD (1998) "Grapefruit juice-drug interactions." Br J Clin Pharmacol, 46, p. 101-10
  17. Bailey DG, Kreeft JH, Munoz C, Freeman DJ, Bend JR (1998) "Grapefruit juice felodipine interaction: Effect of naringin and 6',7'-dihydroxybergamottin in humans." Clin Pharmacol Ther, 64, p. 248-56
  18. Garg SK, Kumar N, Bhargava VK, Prabhakar SK (1998) "Effect of grapefruit juice on carbamazepine bioavailability in patients with epilepsy." Clin Pharmacol Ther, 64, p. 286-8
  19. Lilja JJ, Kivisto KT, Neuvonen PJ (1998) "Grapefruit juice-simvastatin interaction: Effect on serum concentrations of simvastatin, simvastatin acid, and HMG-CoA reductase inhibitors." Clin Pharmacol Ther, 64, p. 477-83
  20. Fuhr U, Maier-Bruggemann A, Blume H, et al. (1998) "Grapefruit juice increases oral nimodipine bioavailability." Int J Clin Pharmacol Ther, 36, p. 126-32
  21. Lilja JJ, Kivisto KT, Neuvonen PJ (1999) "Grapefruit juice increases serum concentrations of atorvastatin and has no effect on pravastatin." Clin Pharmacol Ther, 66, p. 118-27
  22. Eagling VA, Profit L, Back DJ (1999) "Inhibition of the CYP3A4-mediated metabolism and P-glycoprotein-mediated transport of the HIV-I protease inhibitor saquinavir by grapefruit juice components." Br J Clin Pharmacol, 48, p. 543-52
  23. Damkier P, Hansen LL, Brosen K (1999) "Effect of diclofenac, disulfiram, itraconazole, grapefruit juice and erythromycin on the pharmacokinetics of quinidine." Br J Clin Pharmacol, 48, p. 829-38
  24. Lee AJ, Chan WK, Harralson AF, Buffum J, Bui BCC (1999) "The effects of grapefruit juice on sertraline metabolism: An in vitro and in vivo study." Clin Ther, 21, p. 1890-9
  25. Dresser GK, Spence JD, Bailey DG (2000) "Pharmacokinetic-pharmacodynamic consequences and clinical relevance of cytochrome P450 3A4 inhibition." Clin Pharmacokinet, 38, p. 41-57
  26. Gunston GD, Mehta U (2000) "Potentially serious drug interactions with grapefruit juice." S Afr Med J, 90, p. 41
  27. Takanaga H, Ohnishi A, Maatsuo H, et al. (2000) "Pharmacokinetic analysis of felodipine-grapefruit juice interaction based on an irreversible enzyme inhibition model." Br J Clin Pharmacol, 49, p. 49-58
  28. Libersa CC, Brique SA, Motte KB, et al. (2000) "Dramatic inhibition of amiodarone metabolism induced by grapefruit juice." Br J Clin Pharmacol, 49, p. 373-8
  29. Bailey DG, Dresser GR, Kreeft JH, Munoz C, Freeman DJ, Bend JR (2000) "Grapefruit-felodipine interaction: Effect of unprocessed fruit and probable active ingredients." Clin Pharmacol Ther, 68, p. 468-77
  30. Zaidenstein R, Soback S, Gips M, Avni B, Dishi V, Weissgarten Y, Golik A, Scapa E (2001) "Effect of grapefruit juice on the pharmacokinetics of losartan and its active metabolite E3174 in healthy volunteers." Ther Drug Monit, 23, p. 369-73
  31. Sato J, Nakata H, Owada E, Kikuta T, Umetsu M, Ito K (1993) "Influence of usual intake of dietary caffeine on single-dose kinetics of theophylline in healthy human subjects." Eur J Clin Pharmacol, 44, p. 295-8
  32. Flanagan D (2005) "Understanding the grapefruit-drug interaction." Gen Dent, 53, 282-5; quiz 286
View all 32 references

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Moderate

ozanimod food

Applies to: ozanimod

GENERALLY AVOID: Foods that contain large amounts of tyramine may precipitate a hypertensive crisis in patients treated with ozanimod. The proposed mechanism involves potentiation of the tyramine pressor effect due to inhibition of monoamine oxidase (MAO) by the major active metabolites of ozanimod, CC112273 and CC1084037. Monoamine oxidase in the gastrointestinal tract and liver, primarily type A (MAO-A), is the enzyme responsible for metabolizing exogenous amines such as tyramine and preventing them from being absorbed intact. Once absorbed, tyramine is metabolized to octopamine, a substance that is believed to displace norepinephrine from storage granules causing a rise in blood pressure. In vitro, CC112273 and CC1084037 inhibited MAO-B (IC50 values of 5.72 nM and 58 nM, respectively) with more than 1000-fold selectivity over MAO-A (IC50 values >10000 nM). Because of this selectivity, as well as the fact that free plasma concentrations of CC112273 and CC1084037 are less than 8% of the in vitro IC50 values for MAO-B inhibition, ozanimod is expected to have a much lower propensity to cause hypertensive crises than nonselective MAO inhibitors. However, rare cases of hypertensive crisis have occurred during clinical trials for the treatment of multiple sclerosis (MS) and ulcerative colitis (UC) and in postmarketing use. In controlled clinical trials, hypertension and blood pressure increases were reported more frequently in patients treated with ozanimod (up to 4.6% in MS patients receiving ozanimod 0.92 mg/day) than in patients treated with interferon beta-1a (MS) or placebo (UC).

Administration of ozanimod with either a high-fat, high-calorie meal (1000 calories; 50% fat) or a low-fat, low-calorie meal (300 calories; 10% fat) had no effects on ozanimod peak plasma concentration (Cmax) and systemic exposure (AUC) compared to administration under fasted conditions.

MANAGEMENT: Dietary restriction is not ordinarily required during ozanimod treatment with respect to most foods and beverages that contain tyramine, which usually include aged, fermented, cured, smoked, or pickled foods (e.g., air-dried and fermented meats or fish, aged cheeses, most soybean products, yeast extracts, red wine, beer, sauerkraut). However, certain foods like some of the aged cheeses (e.g., Boursault, Liederkrantz, Mycella, Stilton) and pickled herring may contain very high amounts of tyramine and could potentially cause a hypertensive reaction in patients taking ozanimod, even at recommended dosages, due to increased sensitivity to tyramine. Patients should be advised to avoid the intake of very high levels of tyramine (e.g., greater than 150 mg) and to promptly seek medical attention if they experience potential signs and symptoms of a hypertensive crisis such as severe headache, visual disturbances, confusion, stupor, seizures, chest pain, unexplained nausea or vomiting, and stroke-like symptoms. Blood pressure should be regularly monitored and managed accordingly. Because of the long elimination half-lives of the major active metabolites, these precautions may need to be observed for up to 3 months following the last ozanimod dose. Ozanimod can be administered with or without food.

References

  1. (2022) "Product Information. Zeposia (ozanimod)." Celgene Pty Ltd
  2. (2023) "Product Information. Zeposia (ozanimod)." Bristol-Myers Squibb
  3. (2023) "Product Information. Zeposia (ozanimod)." Bristol-Myers Squibb Canada Inc
  4. (2023) "Product Information. Zeposia (ozanimod)." Bristol-Myers Squibb Pharmaceuticals Ltd
  5. Choi DK, Rubin DT, Puangampai A, Cleveland N (2022) "Hypertensive emergency after initiating ozanimod: a case report." Inflamm Bowel Dis, 28, e114-5
View all 5 references

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Moderate

belladonna food

Applies to: Bel-Phen-Ergot (belladonna / ergotamine / phenobarbital)

GENERALLY AVOID: Use of anticholinergic agents with alcohol may result in sufficient impairment of attention so as to render driving and operating machinery more hazardous. In addition, the potential for abuse may be increased with the combination. The mechanism of interaction is not established but may involve additive depressant effects on the central nervous system. No effect of oral propantheline or atropine on blood alcohol levels was observed in healthy volunteers when administered before ingestion of a standard ethanol load. However, one study found impairment of attention in subjects given atropine 0.5 mg or glycopyrrolate 1 mg in combination with alcohol.

MANAGEMENT: Alcohol should generally be avoided during therapy with anticholinergic agents. Patients should be counseled to avoid activities requiring mental alertness until they know how these agents affect them.

References

  1. Linnoila M (1973) "Drug effects on psychomotor skills related to driving: interaction of atropine, glycopyrrhonium and alcohol." Eur J Clin Pharmacol, 6, p. 107-12

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Moderate

ergotamine food

Applies to: Bel-Phen-Ergot (belladonna / ergotamine / phenobarbital)

MONITOR: Nicotine may cause vasoconstriction in some patients and potentiate the ischemic response to ergot alkaloids.

MANAGEMENT: Caution may be advisable when ergot alkaloids are used in combination with nicotine products. Patients should be advised to seek immediate medical attention if they experience potential symptoms of ischemia such as coldness, pallor, cyanosis, numbness, tingling, or pain in the extremities; muscle weakness; severe or worsening headache; visual disturbances; severe abdominal pain; chest pain; and shortness of breath.

References

  1. (2001) "Product Information. Migranal (dihydroergotamine nasal)." Novartis Pharmaceuticals
  2. (2004) "Product Information. Cafergot (caffeine-ergotamine)." Novartis Pharmaceuticals
  3. Cerner Multum, Inc. "UK Summary of Product Characteristics."
  4. Cerner Multum, Inc. "Australian Product Information."
View all 4 references

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Therapeutic duplication warnings

No warnings were found for your selected drugs.

Therapeutic duplication warnings are only returned when drugs within the same group exceed the recommended therapeutic duplication maximum.

See also

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Drug Interaction Classification

These classifications are only a guideline. The relevance of a particular drug interaction to a specific individual is difficult to determine. Always consult your healthcare provider before starting or stopping any medication.
Major Highly clinically significant. Avoid combinations; the risk of the interaction outweighs the benefit.
Moderate Moderately clinically significant. Usually avoid combinations; use it only under special circumstances.
Minor Minimally clinically significant. Minimize risk; assess risk and consider an alternative drug, take steps to circumvent the interaction risk and/or institute a monitoring plan.
Unknown No interaction information available.

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