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Drug Interactions between insulin glargine / lixisenatide and Ximino

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

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Moderate

minocycline insulin glargine

Applies to: Ximino (minocycline) and insulin glargine / lixisenatide

MONITOR: Tetracyclines may enhance the hypoglycemic effects of insulin and insulin secretagogues (e.g., sulfonylureas, meglitinides). The exact mechanism is unknown; however, proposed mechanisms include increasing the sensitivity of insulin, increasing the half-life of insulin via inhibition of insulin degradation in the liver, interference with epinephrine-induced hyperglycemia via inhibition of glycogenolysis, and tetracycline-induced hepatotoxicity. The authors of one study suggest that tetracycline may also be able to inhibit alpha-amylase and/or alpha-glucosidase, as substrates for these enzymes have similar functional groups to those found in tetracycline. There are case reports available documenting hypoglycemia for patients on doxycycline and one case report demonstrating improved insulin sensitivity in a patient on minocycline. It is possible that other tetracyclines may possess similar abilities to lower glucose levels.

MANAGEMENT: Blood glucose should be monitored more closely during therapy with a tetracycline antibiotic. As the effects of the antibiotic may persist beyond the last dose, it is possible that patients may need to be monitored more closely until the antibiotic is fully eliminated from their body, which will differ depending on the half-life of the antibiotic involved. Insulin and insulin secretagogues may require dosage adjustments if an interaction is suspected. Patients should be apprised of the signs and symptoms of hypoglycemia (e.g., headache, dizziness, drowsiness, nausea, hunger, tremor, weakness, sweating, palpitations), how to treat it, and to contact their doctor if it occurs unexpectedly. Conversely, patients should be observed for loss of glycemic control following completion of tetracycline therapy.

References (12)
  1. Dalpe-Scott M, Heick HM, Begin-Heick N (1983) "Insulin secretion in the obese (ob/ob) mouse: the effect of oxytetracycline on insulin release." Diabetes, 32, p. 932-7
  2. Dalpe-Scott M, Begin-Heick N (1982) "Oxytetracycline treatment improves the response to insulin in the spontaneously diabetic (BB) rat." Diabetes, 31, p. 53-9
  3. Begin-Heick N, Heick HM, Norman MG (1979) "Regranulation of Islets of Langerhans and normalization of in vivo insulin secretion in ob/ob mice treated with oxytetracycline." Diabetes, 28, p. 65-70
  4. Phillips PJ, Easterbrook G (1977) "Phenformin, tetracycline and lactic acidosis." Ann Intern Med, 86, p. 111
  5. Miller JB (1966) "Hypoglycaemic effect of oxytetracycline." BMJ, 2, p. 1007
  6. Hiatt N, Bonorris G (1970) "Insulin response in pancreatectomized dogs treated with oxytetracycline." Diabetes, 19, p. 307-11
  7. Amiri B, Hosseini NS, Taktaz F, et al. (2019) "Inhibitory effects of selected antibiotics on the activities of alpha-amylase and alpha-glucosidase: In-vitro, in-vivo and theoretical studies" Eur J Pharm Sci, 138, p. 1-16
  8. Kennedy KE, Teng C, Patek TM, Frei CR (2020) "Hypoglycemia associated with antibiotics alone and in combination with sulfonylureas and meglitinides: an epidemiologic surveillance study of the FDA adverse event reporting system (FAERS)." Drug Saf, 43, p. 363-9
  9. Ashraf S, Saberinia H, Desimone M (2018) "Doxycycline induced hypoglycemia in an adult without diabetes." J Basic Clin Pharma, 9, p. 115-7
  10. Douglas Y, grant mb, Moshiree B (2023) Case report open access minocycline attenuates severe hyperglycemia in patient with lipodystrophy. https://www.omicsonline.org/open-access/minocycline-attenuates-severe-hyperglycemia-in-patient-with-lipodystrophy-ijm-1000136.php?aid=76310
  11. Ijete E, Hosni M, Dadey E, Nikookam K, Rehmani H, Mlawa G (2022) "Uncommon side effect of a common drug: doxycyline induced hypoglycemia." Endocrine Abstracts, 81, P347
  12. (2020) "Product Information. Tetracycline (tetracycline)." Sigma Pharmaceuticals Australia Pty Ltd
Moderate

insulin glargine lixisenatide

Applies to: insulin glargine / lixisenatide and insulin glargine / lixisenatide

ADJUST DOSE: Coadministration of a glucagon-like peptide-1 (GLP-1) receptor agonist or dual GLP-1 and glucose-dependent insulinotropic polypeptide (GIP) receptor agonist with insulin may potentiate the risk of hypoglycemia. GLP-1 receptor agonists and dual GLP-1 and GIP receptor agonists lower blood glucose by stimulating insulin secretion and lowering glucagon secretion. An increased incidence of hypoglycemia has been observed in patients treated with a combination of basal insulin and GLP-1 or dual GLP-1 and GIP receptor agonists. Additionally, patients with diabetic retinopathy who received treatment with basal insulin and subcutaneous semaglutide in one clinical trial had an increased risk of developing diabetic retinopathy complications. Rapid improvement in glucose control has been associated with a temporary worsening of diabetic retinopathy, but other mechanisms cannot be excluded. The safety and efficacy of GLP-1 or dual GLP-1 and GIP receptor agonists in combination with non-basal insulin have not been established.

MANAGEMENT: When a GLP-1 receptor agonist or dual GLP-1 and GIP receptor agonist is used as add-on therapy to basal insulin, a lower dosage of insulin may be required. Some clinical trials have reduced the basal insulin dose by 20% in patients with a baseline hemoglobin A1c <= 8% when a GLP-1 or dual GLP-1 and GIP receptor agonist was initiated. Because diabetic ketoacidosis has been reported in insulin-dependent patients after rapid discontinuation or dose reduction of insulin, a stepwise approach to insulin dose reduction is recommended and blood glucose levels should be closely monitored. Patients should receive guidance on the recognition and management of hypoglycemia as well as precautions to take to avoid hypoglycemia, particularly while driving or operating hazardous machinery. Those with diabetic retinopathy should also be monitored for progression of the condition or complications. A rapid improvement in glucose control has been associated with a temporary worsening of diabetic retinopathy.

References (15)
  1. (2010) "Product Information. Victoza (liraglutide)." Novo Nordisk Pharmaceuticals Inc
  2. (2014) "Product Information. Tanzeum (albiglutide)." GlaxoSmithKline
  3. (2014) "Product Information. Trulicity (dulaglutide)." Eli Lilly and Company
  4. (2016) "Product Information. Adlyxin (lixisenatide)." sanofi-aventis
  5. (2022) "Product Information. Ozempic (1 mg dose) (semaglutide)." Novo Nordisk Pharmaceuticals Inc
  6. (2022) "Product Information. Mounjaro (tirzepatide)." Lilly, Eli and Company
  7. (2022) "Product Information. Wegovy (2.4 mg dose) (semaglutide)." Novo Nordisk Pharmaceuticals Inc, SUPPL-3
  8. (2023) "Product Information. Bydureon BCise (exenatide)." AstraZeneca UK Ltd
  9. (2022) "Product Information. Byetta Prefilled Pen (exenatide)." Astra-Zeneca Pharmaceuticals
  10. (2014) "Product Information. Eperzan (albiglutide)." GlaxoSmithKline UK Ltd
  11. (2023) "Product Information. Trulicity (dulaglutide)." Eli Lilly and Company Ltd
  12. (2022) "Product Information. Saxenda (liraglutide)." Novo Nordisk Ltd
  13. (2022) "Product Information. Victoza (liraglutide)." Novo Nordisk Ltd
  14. (2022) "Product Information. Lyxumia (lixisenatide)." Sanofi
  15. (2023) "Product Information. Ozempic (semaglutide)." Novo Nordisk Ltd

Drug and food/lifestyle interactions

Moderate

insulin glargine food/lifestyle

Applies to: insulin glargine / lixisenatide

GENERALLY AVOID: Alcohol may cause hypoglycemia or hyperglycemia in patients with diabetes. Hypoglycemia most frequently occurs during acute consumption of alcohol. Even modest amounts can lower blood sugar significantly, especially when the alcohol is ingested on an empty stomach or following exercise. The mechanism involves inhibition of both gluconeogenesis as well as the counter-regulatory response to hypoglycemia. Episodes of hypoglycemia may last for 8 to 12 hours after ethanol ingestion. By contrast, chronic alcohol abuse can cause impaired glucose tolerance and hyperglycemia. Moderate alcohol consumption generally does not affect blood glucose levels in patients with well controlled diabetes. A disulfiram-like reaction (e.g., flushing, headache, and nausea) to alcohol has been reported frequently with the use of chlorpropamide and very rarely with other sulfonylureas.

MANAGEMENT: Patients with diabetes should avoid consuming alcohol if their blood glucose is not well controlled, or if they have hypertriglyceridemia, neuropathy, or pancreatitis. Patients with well controlled diabetes should limit their alcohol intake to one drink daily for women and two drinks daily for men (1 drink = 5 oz wine, 12 oz beer, or 1.5 oz distilled spirits) in conjunction with their normal meal plan. Alcohol should not be consumed on an empty stomach or following exercise.

References (10)
  1. Jerntorp P, Almer LO (1981) "Chlorpropamide-alcohol flushing in relation to macroangiopathy and peripheral neuropathy in non-insulin dependent diabetes." Acta Med Scand, 656, p. 33-6
  2. Jerntorp P, Almer LO, Holin H, et al. (1983) "Plasma chlorpropamide: a critical factor in chlorpropamide-alcohol flush." Eur J Clin Pharmacol, 24, p. 237-42
  3. Barnett AH, Spiliopoulos AJ, Pyke DA, et al. (1983) "Metabolic studies in chlorpropamide-alcohol flush positive and negative type 2 (non-insulin dependent) diabetic patients with and without retinopathy." Diabetologia, 24, p. 213-5
  4. Hartling SG, Faber OK, Wegmann ML, Wahlin-Boll E, Melander A (1987) "Interaction of ethanol and glipizide in humans." Diabetes Care, 10, p. 683-6
  5. (2002) "Product Information. Diabinese (chlorpropamide)." Pfizer U.S. Pharmaceuticals
  6. (2002) "Product Information. Glucotrol (glipizide)." Pfizer U.S. Pharmaceuticals
  7. "Product Information. Diabeta (glyburide)." Hoechst Marion-Roussel Inc, Kansas City, MO.
  8. Skillman TG, Feldman JM (1981) "The pharmacology of sulfonylureas." Am J Med, 70, p. 361-72
  9. (2002) "Position Statement: evidence-based nutrition principles and recommendations for the treatment and prevention of diabetes related complications. American Diabetes Association." Diabetes Care, 25(Suppl 1), S50-S60
  10. Cerner Multum, Inc. "UK Summary of Product Characteristics."
Moderate

lixisenatide food/lifestyle

Applies to: insulin glargine / lixisenatide

ADJUST DOSING INTERVAL: Lixisenatide slows gastric emptying, which may impact the absorption of concomitantly administered oral medications. The interaction has been studied with various medications, which demonstrated primarily an effect on the rate rather than the overall extent of absorption.

Acetaminophen: When acetaminophen 1000 mg was administered 1 hour and 4 hours after lixisenatide 10 mcg injection, acetaminophen peak plasma concentration (Cmax) was decreased by 29% and 31%, respectively; and median time to peak plasma concentration (Tmax) was delayed by 2 hours and 1.75 hours, respectively. The Cmax and Tmax of acetaminophen were not significantly altered when acetaminophen was given one hour before lixisenatide injection, and systemic exposure (AUC) was not affected whether administered before or after lixisenatide administration. Based on these results, no dose adjustment for acetaminophen is required; however, it may be advisable to take acetaminophen at least one hour before lixisenatide if a rapid onset of action is required.

Oral Contraceptives: When an oral contraceptive containing ethinyl estradiol 0.03 mg and levonorgestrel 0.15 mg was administered 1 hour and 4 hours after lixisenatide 10 mcg injection, ethinyl estradiol Cmax was decreased by 52% and 39%, respectively, while levonorgestrel Cmax was decreased by 46% and 20%, respectively. Median Tmax values were delayed by 1 to 3 hours, but overall exposure (AUC) and mean terminal half-life (T1/2) of ethinyl estradiol and levonorgestrel were not significantly altered. Administration of the oral contraceptive 1 hour before or 11 hours after lixisenatide had no effect on any of the measured pharmacokinetic parameters of either ethinyl estradiol or levonorgestrel. Based on these results, no dose adjustment for oral contraceptives is required; however, some authorities recommend that oral contraceptives be administered at least 1 hour before or 11 hours after lixisenatide.

Atorvastatin: When atorvastatin 40 mg and lixisenatide 20 mcg were coadministered in the morning for 6 days, atorvastatin Cmax was decreased by 31% and Tmax was delayed by 3.25 hours, but AUC was not affected. When atorvastatin was administered in the evening and lixisenatide in the morning, the AUC and Cmax of atorvastatin were increased by 27% and 66%, respectively, but there was no change in Tmax. Based on these results, no dose adjustment for atorvastatin is required; however, some authorities recommend that atorvastatin be administered at least 1 hour before lixisenatide.

Warfarin: When warfarin 25 mg was coadministered with repeated dosing of lixisenatide 20 mcg, warfarin Cmax was decreased by 19% and Tmax was delayed by 7 hours, but there were no effects on AUC or International Normalized Ratio (INR). Based on these results, no dose adjustment for warfarin is required; however, closer monitoring of INR may be appropriate following initiation or discontinuation of lixisenatide treatment.

Digoxin: When digoxin 0.25 mg and lixisenatide 20 mcg were coadministered at steady state, digoxin Cmax was decreased by 26% and Tmax was delayed by 1.5 hours, but AUC was not affected. Based on these results, no dose adjustment for digoxin is required.

Ramipril: When ramipril 5 mg and lixisenatide 20 mcg were coadministered for 6 days, ramipril Cmax was decreased by 63% and AUC was increased by 21%, while Cmax and AUC of the active metabolite (ramiprilat) were not affected. The Tmax values of ramipril and ramiprilat were delayed by approximately 2.5 hours. Based on these results, no dose adjustment for ramipril is required.

MANAGEMENT: Caution is advised during concomitant use of lixisenatide with oral medications that have a narrow therapeutic index or that require careful clinical monitoring. These medications should be administered on a consistent schedule relative to lixisenatide, and blood levels and/or pharmacologic effects should be closely monitored. In addition, if they are to be administered with food, patients should be advised to take them with a meal or snack when lixisenatide is not administered. Oral medications that are particularly dependent on threshold concentrations for efficacy, such as antibiotics, or medications for which a delay in effect is undesirable, such as acetaminophen, should be administered at least 1 hour before lixisenatide. Gastro-resistant formulations containing substances sensitive to stomach degradation should be administered 1 hour before or 4 hours after lixisenatide. Patients taking oral contraceptives should be advised to take them at least 1 hour before or 11 hours after lixisenatide.

References (1)
  1. Cerner Multum, Inc. "UK Summary of Product Characteristics."
Moderate

minocycline food/lifestyle

Applies to: Ximino (minocycline)

GENERALLY AVOID: The oral bioavailability of quinolone and tetracycline antibiotics may be reduced by concurrent administration of preparations containing polyvalent cations such as aluminum, calcium, iron, magnesium, and zinc. Therapeutic failure may result. The proposed mechanism is chelation of quinolone and tetracycline antibiotics by di- and trivalent cations, forming an insoluble complex that is poorly absorbed from the gastrointestinal tract. Reduced gastrointestinal absorption of the cations should also be considered.

MANAGEMENT: Concomitant administration of oral quinolone and tetracycline antibiotics with preparations containing aluminum, calcium, iron, magnesium, and/or zinc salts should generally be avoided. Otherwise, the times of administration should be staggered by as much as possible to minimize the potential for interaction. Quinolones should typically be dosed either 2 to 4 hours before or 4 to 6 hours after polyvalent cation preparations, depending on the quinolone and formulation. Likewise, tetracyclines and polyvalent cation preparations should typically be administered 2 to 4 hours apart. The prescribing information for the antibiotic should be consulted for more specific dosing recommendations.

References (51)
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  2. Nix DE, Watson WA, Lener ME, et al. (1989) "Effects of aluminum and magnesium antacids and ranitidine on the absorption of ciprofloxacin." Clin Pharmacol Ther, 46, p. 700-5
  3. Garrelts JC, Godley PJ, Peterie JD, Gerlach EH, Yakshe CC (1990) "Sucralfate significantly reduces ciprofloxacin concentrations in serum." Antimicrob Agents Chemother, 34, p. 931-3
  4. Frost RW, Lasseter KC, Noe AJ, Shamblen EC, Lettieri JT (1992) "Effects of aluminum hydroxide and calcium carbonate antacids on the bioavailability of ciprofloxacin." Antimicrob Agents Chemother, 36, p. 830-2
  5. Yuk JH (1989) "Ciprofloxacin levels when receiving sucralfate." J Am Geriatr Soc, 262, p. 901
  6. Neuvonen PJ (1976) "Interactions with the absorption of tetracyclines." Drugs, 11, p. 45-54
  7. Deppermann KM, Lode H, Hoffken G, Tschink G, Kalz C, Koeppe P (1989) "Influence of ranitidine, pirenzepine, and aluminum magnesium hydroxide on the bioavailability of various antibiotics, including amoxicillin, cephalexin, doxycycline, and amoxicillin-clavulanic acid." Antimicrob Agents Chemother, 33, p. 1901-7
  8. Nguyen VX, Nix DE, Gillikin S, Schentag JJ (1989) "Effect of oral antacid administration on the pharmacokinetics of intravenous doxycycline." Antimicrob Agents Chemother, 33, p. 434-6
  9. Campbell NR, Kara M, Hasinoff BB, Haddara WM, McKay DW (1992) "Norfloxacin interaction with antacids and minerals." Br J Clin Pharmacol, 33, p. 115-6
  10. Parpia SH, Nix DE, Hejmanowski LG, Goldstein HR, Wilton JH, Schentag JJ (1989) "Sucralfate reduces the gastrointestinal absorption of norfloxacin." Antimicrob Agents Chemother, 33, p. 99-102
  11. Nix DE, Wilton JH, Ronald B, Distlerath L, Williams VC, Norman A (1990) "Inhibition of norfloxacin absorption by antacids." Antimicrob Agents Chemother, 34, p. 432-5
  12. Akerele JO, Okhamafe AO (1991) "Influence of oral co-administered metallic drugs on ofloxacin pharmacokinetics." J Antimicrob Chemother, 28, p. 87-94
  13. Gothoni G, Neuvonen PJ, Mattila M, Hackman R (1972) "Iron-tetracycline interaction: effect of time interval between the drugs." Acta Med Scand, 191, p. 409-11
  14. Garty M, Hurwitz A (1980) "Effect of cimetidine and antacids on gastrointestinal absorption of tetracycline." Clin Pharmacol Ther, 28, p. 203-7
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  16. McCormack JP, Reid SE, Lawson LM (1990) "Theophylline toxicity induced by tetracycline." Clin Pharm, 9, p. 546-9
  17. D'Arcy PF, McElnay JC (1987) "Drug-antacid interactions: assessment of clinical importance." Drug Intell Clin Pharm, 21, p. 607-17
  18. Wadworth AN, Goa KL (1991) "Lomefloxacin: a review of its antibacterial activity, pharmacokinetic properties and therapeutic use." Drugs, 42, p. 1018-60
  19. Shimada J, Shiba K, Oguma T, et al. (1992) "Effect of antacid on absorption of the quinolone lomefloxacin." Antimicrob Agents Chemother, 36, p. 1219-24
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  21. Venho VM, Salonen RO, Mattila MJ (1978) "Modification of the pharmacokinetics of doxycycline in man by ferrous sulphate or charcoal." Eur J Clin Pharmacol, 14, p. 277-80
  22. (2002) "Product Information. Minocin (minocycline)." Lederle Laboratories
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  35. Spivey JM, Cummings DM, Pierson NR (1996) "Failure of prostatitis treatment secondary to probable ciprofloxacin-sucralfate drug interaction." Pharmacotherapy, 16, p. 314-6
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  37. (2001) "Product Information. Raxar (grepafloxacin)." Glaxo Wellcome
  38. (2001) "Product Information. Zagam (sparfloxacin)." Rhone Poulenc Rorer
  39. (2001) "Product Information. Trovan (trovafloxacin)." Pfizer U.S. Pharmaceuticals
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  49. (2017) "Product Information. Baxdela (delafloxacin)." Melinta Therapeutics, Inc.
  50. (2018) "Product Information. Seysara (sarecycline)." Allergan Inc
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Therapeutic duplication warnings

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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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