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Drug Interactions between amoxicillin / clarithromycin / lansoprazole and cyclosporine

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

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Interactions between your drugs

Major

cycloSPORINE clarithromycin

Applies to: cyclosporine and amoxicillin / clarithromycin / lansoprazole

MONITOR CLOSELY: Coadministration with macrolide antibiotics that are potent inhibitors of CYP450 3A4 may significantly increase the blood concentrations of cyclosporine, which is primarily metabolized by the isoenzyme. The risk of nephro- and neurotoxicity associated with cyclosporine may be increased. There have been numerous reports of significant increases in cyclosporine peak concentration (Cmax) and systemic exposure (AUC) and decreases in its clearance during concomitant administration with macrolide antibiotics, especially erythromycin and clarithromycin. Macrolides that may significantly inhibit CYP450 3A4 include troleandomycin, erythromycin, and clarithromycin. Azithromycin and dirithromycin are generally believed to have little effect, if any, on CYP450 3A4, although azithromycin was implicated in a single case report.

MANAGEMENT: Caution is advised if cyclosporine is used with macrolide antibiotics that are potent inhibitors of CYP450 3A4. Cyclosporine blood levels and renal function should be checked frequently and the dosage adjusted accordingly, particularly following initiation or discontinuation of macrolide therapy in patients who are stabilized on their cyclosporine regimen. Patients should be advised to notify their doctor if they experience possible signs of cyclosporine toxicity such as nausea, vomiting, diarrhea, abdominal pain, dizziness, fatigue, headache, tremors, and convulsions. Alternative antibiotics that do not interfere with cyclosporine metabolism should be considered whenever possible.

References (24)
  1. Ptachcinski RJ, Carpenter BJ, Burckart GJ, Venkataramanan R, Rosenthal J (1985) "Effect of erythromycin on cyclosporine levels." N Engl J Med, 313, p. 1416-7
  2. Grino JM, Sabate I, Castelao AM, et al. (1986) "Erythromycin and cyclosporine." Ann Intern Med, 105, p. 467-8
  3. Wadhwa NK, Schroeder TJ, O'Flaherty E, et al. (1987) "Interaction between erythromycin and cyclosporine in a kidney and pancreas allograft recipient." Ther Drug Monit, 9, p. 123-5
  4. Kessler M, Louis J, Renoult E, et al. (1986) "Interaction between cyclosporin and erythromycin in a kidney transplant patient." Eur J Clin Pharmacol, 30, p. 633-4
  5. Kohan DE (1986) "Possible interaction between cyclosporine and erythromycin." N Engl J Med, 314, p. 448
  6. Freeman DJ, Martell R, Carruthers SG, et al. (1987) "Cyclosporin-erythromycin interaction in normal subjects." Br J Clin Pharmacol, 23, p. 776-8
  7. Murray BM, Edwards L, Morse GD, et al. (1987) "Clinically important interaction of cyclosporine and erythromycin." Transplantation, 43, p. 602-4
  8. Cockburn IT, Krupp P (1989) "An appraisal of drug interactions with sandimmun." Transplant Proc, 21, p. 3845-50
  9. Fabre I, Fabre G, Maurel P, et al. (1988) "Metabolism of cyclosporin A. Interaction of the macrolide antibiotic, erythromycin, using rabbit hepatocytes and microsomal fractions." Drug Metab Dispos, 16, p. 296-301
  10. Yee GC, McGuire TR (1990) "Pharmacokinetic drug interactions with cyclosporin (Part I)." Clin Pharmacokinet, 19, p. 319-32
  11. Gupta SK, Bakran A, Johnson RW, Rowland M (1989) "Cyclosporin-erythromycin interaction in renal transplant patients." Br J Clin Pharmacol, 27, p. 475-81
  12. (2022) "Product Information. SandIMMUNE (cycloSPORINE)." Apothecon Inc
  13. Jensen CW, Flechner SM, Van Buren CT, et al. (1987) "Exacerbation of cyclosporin toxicity by concomitant administration of erythromycin." Transplantation, 43, p. 263-70
  14. Gersema LM, Porter CB, Russell EH (1994) "Suspected drug interaction between cyclosporine and clarithromycin." J Heart Lung Transplant, 13, p. 343-5
  15. Ferrari SL, Goffin E, Mourad M, Wallemacq P, Squifflet JP, Pirson Y (1994) "The interaction between clarithromycin and cyclosporine in kidney transplant recipients." Transplantation, 58, p. 725-7
  16. Zylber-Katz E (1995) "Multiple drug interactions with cyclosporine in a heart transplant patient." Ann Pharmacother, 29, p. 127-31
  17. Ljutic D, Rumboldt Z (1995) "Possible interaction between azithromycin and cyclosporin: a case report." Nephron, 70, p. 130
  18. Amsden GW (1995) "Macrolides versus azalides: a drug interaction update." Ann Pharmacother, 29, p. 906-17
  19. Sketris IS, Wright MR, West ML (1996) "Possible role of the intestinal p-450 enzyme system in a cyclosporine clarithromycin interaction." Pharmacotherapy, 16, p. 301-5
  20. Nahata M (1996) "Drug interactions with azithromycin and the macrolides: an overview." J Antimicrob Chemother, 37 ( Suppl, p. 133-42
  21. Gomez E, Sanchez JE, Aguado S, Grande JA (1996) "Interaction between azithromycin and cyclosporin?" Nephron, 73, p. 724
  22. Spicer ST, Liddle C, Chapman JR, Barclay P, Nankivell BJ, Thomas P, O'Connell PJ (1997) "The mechanism of cyclosporine toxicity induced by clarithromycin." Br J Clin Pharmacol, 43, p. 194-6
  23. Knower MT, LabellaWalker K, McFadden PM, Kantrow SP, Valentine VG (2000) "Clarithromycin for safe and cost-effective reduction of cyclosporine doses in lung allograft recipients." South Med J, 93, p. 1087-92
  24. Homma S, Takahashi KI, Nihei S, Kato F, Sugihara S, Nunoda S (2014) "The successful management of respiratory complications with long-term, low-dose macrolide administration in pediatric heart transplant recipients." Int Heart J
Moderate

cycloSPORINE lansoprazole

Applies to: cyclosporine and amoxicillin / clarithromycin / lansoprazole

MONITOR: Chronic use of proton pump inhibitors (PPIs) may induce hypomagnesemia, and the risk may be increased during concomitant use of diuretics or other agents that can cause magnesium loss. The mechanism via which hypomagnesemia may occur during long-term PPI use is unknown, although changes in intestinal absorption of magnesium may be involved. Hypomagnesemia has been reported rarely in patients treated with PPIs for at least three months, but in most cases, after a year or more. Serious adverse events include tetany, seizures, tremor, carpopedal spasm, atrial fibrillation, supraventricular tachycardia, and abnormal QT interval; however, patients do not always exhibit these symptoms. Hypomagnesemia can also cause impaired parathyroid hormone secretion, which may lead to hypocalcemia. In approximately 25% of the cases of PPI-associated hypomagnesemia reviewed by the FDA, the condition did not resolve with magnesium supplementation alone but also required discontinuation of the PPI. Both positive dechallenge as well as positive rechallenge (i.e., resolution of hypomagnesemia with PPI cessation and recurrence with PPI resumption) were reported in some cases. After discontinuing the PPI, the median time required for magnesium levels to normalize was one week. After restarting the PPI, the median time for hypomagnesemia to recur was two weeks.

MANAGEMENT: Monitoring of serum magnesium levels is recommended prior to initiation of therapy and periodically thereafter if prolonged treatment with a proton pump inhibitor is anticipated or when combined with other agents that can cause hypomagnesemia such as diuretics, aminoglycosides, cation exchange resins, amphotericin B, cetuximab, cisplatin, cyclosporine, foscarnet, panitumumab, pentamidine, and tacrolimus. Patients should be advised to seek immediate medical attention if they develop potential signs and symptoms of hypomagnesemia such as palpitations, arrhythmia, muscle spasm, tremor, or convulsions. In children, abnormal heart rates may cause fatigue, upset stomach, dizziness, and lightheadedness. Magnesium replacement as well as discontinuation of the PPI may be required in some patients.

References (1)
  1. FDA. U.S. Food and Drug Administration (2011) FDA Drug Safety Communication: Low magnesium levels can be associated with long-term use of proton pump inhibitor drugs (PPIs). http://www.fda.gov/Drugs/DrugSafety/ucm245011.htm
Moderate

clarithromycin lansoprazole

Applies to: amoxicillin / clarithromycin / lansoprazole and amoxicillin / clarithromycin / lansoprazole

MONITOR: Coadministration with clarithromycin may increase the plasma concentrations of lansoprazole. The proposed mechanism is clarithromycin inhibition of intestinal (first-pass) and hepatic metabolism of lansoprazole via CYP450 3A4. Although lansoprazole is primarily metabolized by CYP450 2C19 in the liver, 3A4-mediated metabolism is the predominant pathway in individuals who are 2C19-deficient (approximately 3% to 5% of the Caucasian and 17% to 20% of the Asian population). Additionally, inhibition of P-glycoprotein intestinal efflux transporter by clarithromycin may also contribute to the interaction, resulting in increased bioavailability of lansoprazole. In 18 healthy volunteers--six each of homozygous extensive metabolizers (EMs), heterozygous EMs, and poor metabolizers (PMs) of CYP450 2C19--clarithromycin (400 mg orally twice a day for 6 days) increased the peak plasma concentration (Cmax) of a single 60 mg oral dose of lansoprazole by 1.47, 1.71- and 1.52-fold, respectively, and area under the concentration-time curve (AUC) by 1.55-, 1.74- and 1.80-fold, respectively, in each of these groups compared to placebo. The AUC ratio of lansoprazole to lansoprazole sulphone, which is considered an index of CYP450 3A4 activity, was significantly increased by clarithromycin in all three groups. However, elimination half-life of lansoprazole was prolonged by 1.54-fold only in PMs. Mild diarrhea was reported in two subjects and mild abdominal disturbance in six subjects during clarithromycin coadministration. These side effects continued until day 6 and ameliorated the day after discontinuation of clarithromycin, whereas no adverse events were reported during placebo administration or after lansoprazole plus placebo. In another study, clarithromycin induced dose-dependent increases in the plasma concentration of lansoprazole in a group of 20 patients receiving treatment for H. pylori eradication. Mean 3-hour plasma lansoprazole concentration was 385 ng/mL for the control subjects who received lansoprazole 30 mg and amoxicillin 750 mg twice a day for 7 days; 696 ng/mL for patients coadministered clarithromycin 200 mg twice a day; and 947 ng/mL for patients coadministered clarithromycin 400 mg twice a day.

MANAGEMENT: Although lansoprazole is generally well tolerated, caution may be advised during coadministration with clarithromycin, particularly if higher dosages of one or both drugs are used. Dosage adjustment may be necessary in patients who experience excessive adverse effects of lansoprazole.

References (3)
  1. Ushiama H, Echizen H, Nachi S, Ohnishi A (2002) "Dose-dependent inhibition of CYP3A activity by clarithromycin during Helicobacter pylori eradication therapy assessed by changes in plasma lansoprazole levels and partial cortisol clearance to 6beta-hydroxycortisol." Clin Pharmacol Ther, 72, p. 33-43
  2. Saito M, Yasui-Furukori N, Uno T, et al. (2005) "Effects of clarithromycin on lansoprazole pharmacokinetics between CYP2C19 genotypes." Br J Clin Pharmacol, 59, p. 302-9
  3. Miura M, Tada H, Yasui-Furukori N, et al. (2005) "Effect of clarithromycin on the enantioselective disposition of lansoprazole in relation to CYP2C19 genotypes." Chirality, 17, p. 338-344
Minor

amoxicillin clarithromycin

Applies to: amoxicillin / clarithromycin / lansoprazole and amoxicillin / clarithromycin / lansoprazole

Although some in vitro data indicate synergism between macrolide antibiotics and penicillins, other in vitro data indicate antagonism. When these drugs are given together, neither has predictable therapeutic efficacy. Data are available for erythromycin, although theoretically this interaction could occur with any macrolide. Except for monitoring of the effectiveness of antibiotic therapy, no special precautions appear to be necessary.

References (3)
  1. Strom J (1961) "Penicillin and erythromycin singly and in combination in scarlatina therapy and the interference between them." Antibiot Chemother, 11, p. 694-7
  2. Cohn JR, Jungkind DL, Baker JS (1980) "In vitro antagonism by erythromycin of the bactericidal action of antimicrobial agents against common respiratory pathogens." Antimicrob Agents Chemother, 18, p. 872-6
  3. Penn RL, Ward TT, Steigbigel RT (1982) "Effects of erythromycin in combination with penicillin, ampicillin, or gentamicin on the growth of listeria monocytogenes." Antimicrob Agents Chemother, 22, p. 289-94

Drug and food interactions

Moderate

cycloSPORINE food

Applies to: cyclosporine

GENERALLY AVOID: Administration with grapefruit juice (compared to water or orange juice) has been shown to increase blood concentrations of cyclosporine with a relatively high degree of interpatient variability. The mechanism is inhibition of CYP450 3A4-mediated first-pass metabolism in the gut wall by certain compounds present in grapefruits.

GENERALLY AVOID: Administration with red wine or purple grape juice may decrease blood concentrations of cyclosporine. In 12 healthy volunteers, 12 ounces total of a merlot consumed 15 minutes prior to and during cyclosporine administration (single 8 mg/kg dose of Sandimmune) decreased cyclosporine peak blood concentration (Cmax) and systemic exposure (AUC) by 38% and 30%, respectively, compared to water. The time to reach peak concentration (Tmax) doubled, and oral clearance increased 50%. Similarly, one study were 12 healthy patients were administered purple grape juice and a single dose of cyclosporine showed a 30% and a 36% decrease in cyclosporine systemic exposure (AUC) and peak blood concentration (Cmax), respectively. The exact mechanism of interaction is unknown but may involve decreased cyclosporine absorption.

MONITOR: Food has been found to have variable effects on the absorption of cyclosporine. There have been reports of impaired, unchanged, and enhanced absorption during administration with meals relative to the fasting state. The mechanisms are unclear. Some investigators found an association with the fat content of food. In one study, increased fat intake resulted in significantly increased cyclosporine bioavailability and clearance. However, the AUC and pharmacodynamics of cyclosporine were not significantly affected, thus clinical relevance of these findings may be minimal.

MANAGEMENT: Patients receiving cyclosporine therapy should be advised to either refrain from or avoid fluctuations in the consumption of grapefruits and grapefruit juice. Until more data are available, the consumption of red wine or purple grape juice should preferably be avoided or limited. All oral formulations of cyclosporine should be administered on a consistent schedule with regard to time of day and relation to meals so as to avoid large fluctuations in plasma drug levels.

References (13)
  1. Honcharik N, Yatscoff RW, Jeffery JR, Rush DN (1991) "The effect of meal composition on cyclosporine absorption." Transplantation, 52, p. 1087-9
  2. Ducharme MP, Provenzano R, Dehoornesmith M, Edwards DJ (1993) "Trough concentrations of cyclosporine in blood following administration with grapefruit juice." Br J Clin Pharmacol, 36, p. 457-9
  3. Bailey DG, Arnold JMO, Spence JD (1994) "Grapefruit juice and drugs - how significant is the interaction." Clin Pharmacokinet, 26, p. 91-8
  4. Hollander AAMJ, Vanrooij J, Lentjes EGWM, Arbouw F, Vanbree JB, Schoemaker RC, Vanes LA, Vanderwoude FJ, Cohen AF (1995) "The effect of grapefruit juice on cyclosporine and prednisone metabolism in transplant patients." Clin Pharmacol Ther, 57, p. 318-24
  5. (1995) "Grapefruit juice interactions with drugs." Med Lett Drugs Ther, 37, p. 73-4
  6. Tan KKC, Trull AK, Uttridge JA, Metcalfe S, Heyes CS, Facey S, Evans DB (1995) "Effect of dietary fat on the pharmacokinetics and pharmacodynamics of cyclosporine in kidney transplant recipients." Clin Pharmacol Ther, 57, p. 425-33
  7. Yee GC, Stanley DL, Pessa LJ, et al. (1995) "Effect of grrapefruit juice on blood cyclosporin concentration." Lancet, 345, p. 955-6
  8. Ducharme MP, Warbasse LH, Edwards DJ (1995) "Disposition of intravenous and oral cyclosporine after administration with grapefruit juice." Clin Pharmacol Ther, 57, p. 485-91
  9. Ioannidesdemos LL, Christophidis N, Ryan P, Angelis P, Liolios L, Mclean AJ (1997) "Dosing implications of a clinical interaction between grapefruit juice and cyclosporine and metabolite concentrations in patients with autoimmune diseases." J Rheumatol, 24, p. 49-54
  10. Min DI, Ku YM, Perry PJ, Ukah FO, Ashton K, Martin MF, Hunsicker LG (1996) "Effect of grapefruit juice on cyclosporine pharmacokinetics in renal transplant patients." Transplantation, 62, p. 123-5
  11. 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
  12. Tsunoda SM, Harris RZ, Christians U, et al. (2001) "Red wine decreases cyclosporine bioavailability." Clin Pharmacol Ther, 70, p. 462-7
  13. Oliveira-Freitas VL, Dalla Costa T, Manfro RC, Cruz LB, Schwartsmann G (2010) "Influence of purple grape juice in cyclosporine availability." J Ren Nutr, 20, p. 309-13
Minor

clarithromycin food

Applies to: amoxicillin / clarithromycin / lansoprazole

Grapefruit juice may delay the gastrointestinal absorption of clarithromycin but does not appear to affect the overall extent of absorption or inhibit the metabolism of clarithromycin. The mechanism of interaction is unknown but may be related to competition for intestinal CYP450 3A4 and/or absorptive sites. In an open-label, randomized, crossover study consisting of 12 healthy subjects, coadministration with grapefruit juice increased the time to reach peak plasma concentration (Tmax) of both clarithromycin and 14-hydroxyclarithromycin (the active metabolite) by 80% and 104%, respectively, compared to water. Other pharmacokinetic parameters were not significantly altered. This interaction is unlikely to be of clinical significance.

References (1)
  1. Cheng KL, Nafziger AN, Peloquin CA, Amsden GW (1998) "Effect of grapefruit juice on clarithromycin pharmacokinetics." Antimicrob Agents Chemother, 42, p. 927-9

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.

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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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