Skip to main content

Drug Interactions between dexamethasone / lidocaine and licorice

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

Edit list (add/remove drugs)

Interactions between your drugs

Moderate

dexAMETHasone licorice

Applies to: dexamethasone / lidocaine and licorice

GENERALLY AVOID: Licorice may potentiate the effects of corticosteroids. Licorice use has been associated with hypertension as well as sodium and water retention. Glycyrrhizic acid, a component of licorice, is hydrolyzed in the intestine to a metabolite (glycyrrhetinic acid) that causes mineralocorticoid and renin-suppressing effects. In one study, licorice was found to increase blood pressure in a dose-dependent manner. Healthy volunteers who consumed licorice 50 to 200 g/day (corresponding to 75 to 540 mg/day of glycyrrhetinic acid) for two to four weeks had a 3.1 to 14.4 mmHg increase in their systolic blood pressure. Even the lowest dosage demonstrated a significant effect. In another study, plasma potassium levels decreased by 0.3 to 1.5 mEq/L in 12 out of 14 healthy volunteers who ingested licorice 100 or 200 g/day (equivalent to 700 to 1400 mg/day of glycyrrhizic acid) for one to four weeks, including four who had to be withdrawn from the study because of hypokalemia. Two more subjects were withdrawn due to edema of the face, hands, and ankles. Other side effects reported include mild, transient generalized edema; headache; sodium retention; and weight gain (1 to 4 kg, mean 1.5 kg). Signs of renin-angiotensin-aldosterone suppression were observed in all subjects, especially plasma renin activity and urinary aldosterone concentrations, which fell to subnormal or undetectable levels in the majority of subjects. There have been various published case reports of refractory hypertension, severe hypokalemia (life-threatening hypokalemic paralysis, myopathy, arrhythmia, or cardiac arrest), and hypertensive encephalopathy in association with licorice intoxication. Hypertension and hypokalemia have also been reported with moderate doses of licorice in the form of licorice-flavored chewing gum or candy, chewing tobacco, or licorice-based foods and beverages consumed on a chronic basis. Prolonged use of licorice has led to a hypermineralocorticoid (pseudohyperaldosteronism) syndrome characterized by hypertension, hypernatremia, hypokalemia, metabolic alkalosis, renin-angiotensin-aldosterone suppression, and edema. In studies and case reports, licorice toxicity has generally been completely reversible within one to several weeks of licorice discontinuation. However, renin-angiotensin-aldosterone axis may be suppressed for up to several months.

MANAGEMENT: Patients receiving prolonged corticosteroid therapy should avoid or limit the consumption of licorice-containing products. Even relatively moderate doses of licorice may be problematic in susceptible patients when ingested regularly for prolonged periods.

References (20)
  1. Ishikawa S, Kato M, Tokuda T, Momoi H, Sekijima Y, Higuchi M, Yanagisawa N (1999) "Licorice-induced hypokalemic myopathy and hypokalemic renal tubular damage in anorexia nervosa." Int J Eating Disorder, 26, p. 111-4
  2. Fugh-Berman A (2000) "Herb-drug interactions." Lancet, 355, p. 134-8
  3. Cumming AM, Boddy K, Brown JJ, et al. (1980) "Severe hypokalaemia with paralysis induced by small doses of liquorice." Postgrad Med J, 56, p. 526-9
  4. Cumming A (1976) "Severe reduction of serum potassium induced by licorice." Nurs Times, 72, p. 367-70
  5. de Klerk GJ, Nieuwenhuis MG, Beutler JJ (1997) "Lesson of the week: hypokalaemia and hypertension associated with use of liquorice flavoured chewing gum." BMJ, 314, p. 731
  6. Edwards CR (1991) "Lessons from licorice." N Engl J Med, 325, p. 1242-3
  7. Stewart PM, Wallace AM, Valentino R, Burt D, Shackleton CH, Edwards CR (1987) "Mineralocorticoid activity of liquorice: 11-beta-hydroxysteroid dehydrogenase deficiency comes of age." Lancet, 2, p. 821-4
  8. Nielsen I, Pedersen RS (1984) "Life-threatening hypokalaemia caused by liquorice ingestion." Lancet, 1, p. 1305
  9. Rosseel M, Schoors D (1993) "Chewing gum and hypokalaemia." Lancet, 341, p. 175
  10. Clyburn EB, DiPette DJ (1995) "Hypertension induced by drugs and other substances." Semin Nephrol, 15, p. 72-86
  11. Farese RV, Biglieri EG, Shackleton CH, Irony I, Gomez-Fontes R (1991) "Licorice-induced hypermineralocorticoidism." N Engl J Med, 325, p. 1223-7
  12. Elinav E, Chajek-Shaul T (2003) "Licorice consumption causing severe hypokalemic paralysis." Mayo Clin Proc, 78, p. 767-8
  13. Richard CL, Jurgens TM (2005) "Effects of natural health products on blood pressure." Ann Pharmacother, 39, p. 712-20
  14. Sigurjonsdottir HA, Franzson L, Manhem K, Ragnarsson J, Sigurdsson G, Wallerstedt S (2001) "Liquorice-induced rise in blood pressure: a linear dose-response relationship." J Hum Hypertens, 15, p. 549-52
  15. Dellow EL, Unwin RJ, Honour JW (1999) "Pontefract cakes can be bad for you: refractory hypertension and liquorice excess." Nephrol Dial Transplant, 14, p. 218-20
  16. Epstein MT, Espiner EA, Donald RA, Hughes H (1977) "Effect of eating liquorice on the renin-angiotensin aldosterone axis in normal subjects." Br Med J, 1, p. 488-90
  17. Epstein MT, Espiner EA, Donald RA, Hughes H (1977) "Liquorice toxicity and the renin-angiotensin-aldosterone axis in man." Br Med J, 1, p. 209-10
  18. Cumming AM (1977) "Metabolic effects of licorice." Br Med J, 1, p. 906
  19. Bannister B, Ginsburg R, Shneerson J (1977) "Cardiac arrest due to liquorice-induced hypokalaemia." Br Med J, 2, p. 738-9
  20. Holmes AM, Young J, Marrott PK, Prentice E (1970) "Pseudohyperaldosteronism induced by habitual ingestion of liquorice." Postgrad Med J, 46, p. 625-9
Minor

lidocaine dexAMETHasone

Applies to: dexamethasone / lidocaine and dexamethasone / lidocaine

Coadministration with inducers of CYP450 1A2 and/or 3A4 may decrease the plasma concentrations of lidocaine, which is primarily metabolized by these isoenzymes. In four healthy volunteers (2 smokers and 2 nonsmokers), administration of a single 400 mg oral dose of lidocaine following pretreatment with the CYP450 inducer phenobarbital (15 mg/day for 4 weeks, followed by 30 mg/day for 4 weeks) decreased lidocaine systemic exposure (AUC) by 37% and increased its oral clearance by 56% compared to administration of lidocaine alone. In another study, the mean bioavailability of a single 750 mg oral dose of lidocaine in six patients receiving chronic antiepileptic drug therapy (consisting of one or more of the following enzyme-inducing anticonvulsants: phenobarbital, primidone, phenytoin, carbamazepine) was approximately 2.5-fold lower than that reported for six healthy control subjects, while intrinsic clearance was nearly threefold higher. By contrast, the interaction was modest for lidocaine administered intravenously, suggesting induction of primarily hepatic first-pass rather than systemic metabolism of lidocaine. When a single 100 mg dose of lidocaine was given intravenously, mean lidocaine AUC was reduced by less than 10% and serum clearance increased by just 17% in the epileptic patients compared to controls. These changes were not statistically significant. Likewise, mean lidocaine AUC decreased by approximately 11% and plasma clearance increased by 15% when a single 50 mg intravenous dose of lidocaine was administered following pretreatment with the potent CYP450 inducer rifampin (600 mg/day for six days) in ten healthy, nonsmoking male volunteers. Another pharmacokinetic study found that cigarette smoke, an inducer of CYP450 1A2, reduced the bioavailability of lidocaine when administered orally, but had only minor effects on lidocaine administered intravenously. When 4 smokers and 5 non-smokers received 2 doses of lidocaine (100 mg IV followed by 100 mg orally after a 2-day washout period), the smoker's systemic exposure (AUC) of oral lidocaine was 68% lower than non-smokers. The AUC of IV lidocaine was only 9% lower in smokers compared with non-smokers. The clinical impact of smoking on lidocaine has not been studied, however, a loss of efficacy may occur.

References (4)
  1. Heinonen J, Takki S, Jarho L (1970) "Plasma lidocaine levels in patients treated with potential inducers of microsomal enzymes." Acta Anaesthesiol Scand, 14, p. 89-95
  2. Perucca E, Richens A (1979) "Reduction of oral bioavailability of lignocaine by induction of first pass metabolism in epileptic patients." Br J Clin Pharmacol, 8, p. 21-31
  3. Perucca E, Ruprah M, Richens A, Park BK, Betteridge DJ, Hedges AM (1981) "Effect of low-dose phenobarbitone on five indirect indices of hepatic microsomal enzyme induction and plasma lipoproteins in normal subjects." Br J Clin Pharmacol, 12, p. 592-6
  4. Reichel C, Skodra T, Nacke A, Spengler U, Sauerbruch T (1998) "The lignocaine metabolite (MEGX) liver function test and P-450 induction in humans." Br J Clin Pharmacol, 46, p. 535-9

Drug and food interactions

Moderate

lidocaine food

Applies to: dexamethasone / lidocaine

MONITOR: Grapefruit and grapefruit juice may increase the plasma concentrations of lidocaine, which is primarily metabolized by the CYP450 3A4 and 1A2 isoenzymes to active metabolites (monoethylglycinexylidide (MEGX) and glycinexylidide). The proposed mechanism is inhibition of CYP450 3A4-mediated first-pass metabolism in the gut wall by certain compounds present in grapefruit. Inhibition of hepatic CYP450 3A4 may also contribute. The interaction has not been studied with grapefruit juice but has been reported with oral and/or intravenous lidocaine and potent CYP450 3A4 inhibitor, itraconazole, as well as moderate CYP450 3A4 inhibitor, erythromycin. A pharmacokinetic study of 9 healthy volunteers showed that the administration of lidocaine oral (1 mg/kg single dose) with itraconazole (200 mg daily) increased lidocaine systemic exposure (AUC) and peak plasma concentration (Cmax) by 75% and 55%, respectively. However, no changes were observed in the pharmacokinetics of the active metabolite MEGX. In the same study, when the moderate CYP450 3A4 inhibitor erythromycin (500 mg three times a day) was administered, lidocaine AUC and Cmax increased by 60% and 40%, respectively. By contrast, when intravenous lidocaine (1.5 mg/kg infusion over 60 minutes) was administered on the fourth day of treatment with itraconazole (200 mg once a day) no changes in lidocaine AUC or Cmax were observed. However, when lidocaine (1.5 mg/kg infusion over 60 minutes) was coadministered with erythromycin (500 mg three times a day) in the same study, the AUC and Cmax of the active metabolite MEGX significantly increased by 45-60% and 40%, respectively. The observed differences between oral and intravenous lidocaine when coadministered with CYP450 3A4 inhibitors may be attributed to inhibition of CYP450 3A4 in both the gastrointestinal tract and liver affecting oral lidocaine to a greater extent than intravenous lidocaine. In general, the effects of grapefruit products are concentration-, dose- and preparation-dependent, and can vary widely among brands. Certain preparations of grapefruit (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. While the clinical significance of this interaction is unknown, increased exposure to lidocaine may lead to serious and/or life-threatening reactions including respiratory depression, convulsions, bradycardia, hypotension, arrhythmias, and cardiovascular collapse.

MONITOR: Certain foods and behaviors that induce CYP450 1A2 may reduce the plasma concentrations of lidocaine. The proposed mechanism is induction of hepatic CYP450 1A2, one of the isoenzymes responsible for the metabolic clearance of lidocaine. Cigarette smoking is known to be a CYP450 1A2 inducer. In one pharmacokinetic study of 4 smokers and 5 non-smokers who received 2 doses of lidocaine (100 mg IV followed by 100 mg orally after a 2-day washout period), the smokers' systemic exposure (AUC) of oral lidocaine was 68% lower than non-smokers. The AUC of IV lidocaine was only 9% lower in smokers compared with non-smokers. Other CYP450 1A2 inducers include cruciferous vegetables (e.g., broccoli, brussels sprouts) and char-grilled meat. Therefore, eating large or variable amounts of these foods could also reduce lidocaine exposure. The clinical impact of smoking and/or the ingestion of foods that induce CYP450 1A2 on lidocaine have not been studied, however, a loss of efficacy may occur.

MANAGEMENT: Caution is recommended if lidocaine is to be used in combination with grapefruit and grapefruit juice. Monitoring for lidocaine toxicity and plasma lidocaine levels may also be advised, and the lidocaine dosage adjusted as necessary. Patients who smoke and/or consume cruciferous vegetables may be monitored for reduced lidocaine efficacy.

References (7)
  1. Huet PM, LeLorier J (1980) "Effects of smoking and chronic hepatitis B on lidocaine and indocyanine green kinetics" Clin Pharmacol Ther, 28, p. 208-15
  2. (2024) "Product Information. Lidocaine Hydrochloride (lidocaine)." Hospira Inc.
  3. (2015) "Product Information. Lidocaine Hydrochloride (lidocaine)." Hospira Healthcare Corporation
  4. (2022) "Product Information. Lidocaine Hydrochloride (lidocaine)." Hameln Pharma Ltd
  5. (2022) "Product Information. Xylocaine HCl (lidocaine)." Aspen Pharmacare Australia Pty Ltd
  6. Isohanni MH, Neuvonen PJ, Olkkola KT (2024) Effect of erythromycin and itraconazole on the pharmacokinetics of oral lignocaine https://pubmed.ncbi.nlm.nih.gov/10193676/
  7. Isohanni MH, Neuvonen PJ, Olkkola KT (2024) Effect of erythromycin and itraconazole on the pharmacokinetics of intravenous lignocaine https://pubmed.ncbi.nlm.nih.gov/9832299/
Moderate

lidocaine food

Applies to: dexamethasone / lidocaine

MONITOR: Smoking cessation may lead to elevated plasma concentrations and enhanced pharmacologic effects of drugs that are substrates of CYP450 1A2 (and possibly CYP450 1A1) and/or certain drugs with a narrow therapeutic index (e.g., flecainide, pentazocine). One proposed mechanism is related to the loss of CYP450 1A2 and 1A1 induction by polycyclic aromatic hydrocarbons in tobacco smoke; when smoking cessation agents are initiated and smoking stops, the metabolism of certain drugs may decrease leading to increased plasma concentrations. The mechanism by which smoking cessation affects narrow therapeutic index drugs that are not known substrates of CYP450 1A2 or 1A1 is unknown. The clinical significance of this interaction is unknown as clinical data are lacking.

MANAGEMENT: Until more information is available, caution is advisable if smoking cessation agents are used concomitantly with drugs that are substrates of CYP450 1A2 or 1A1 and/or those with a narrow therapeutic range. Patients receiving smoking cessation agents may require periodic dose adjustments and closer clinical and laboratory monitoring of medications that are substrates of CYP450 1A2 or 1A1.

References (4)
  1. (2024) "Product Information. Cytisine (cytisinicline)." Consilient Health Ltd
  2. jeong sh, Newcombe D, sheridan j, Tingle M (2015) "Pharmacokinetics of cytisine, an a4 b2 nicotinic receptor partial agonist, in healthy smokers following a single dose." Drug Test Anal, 7, p. 475-82
  3. Vaughan DP, Beckett AH, Robbie DS (1976) "The influence of smoking on the intersubject variation in pentazocine elimination." Br J Clin Pharmacol, 3, p. 279-83
  4. Zevin S, Benowitz NL (1999) "Drug interactions with tobacco smoking: an update" Clin Pharmacokinet, 36, p. 425-38

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

Report options

Loading...
QR code containing a link to this page

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.

Further information

Always consult your healthcare provider to ensure the information displayed on this page applies to your personal circumstances.

Medical Disclaimer