Timoptic Ocumeter

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Timoptic Ocumeter

Classes

Beta-blockers, Ophthalmic, Plain
Non-Selective Beta-Blockers

Administration
Oral Administration

•Timolol may be administered orally without regard to meals.

Ophthalmic Administration

For ophthalmic use only. Apply topically only to the eye.
Instruct patient on proper instillation of eye solution.
Avoid contamination of the eye solution; do not touch the tip of the eye dropper to the eye, fingertips, or other surface.
Wash hands before and after use.
Tilt the head back slightly and pull the lower eyelid down with the index finger to form a pouch. Squeeze the prescribed amount of drops into the pouch. Close eye to spread drops.
To avoid excessive systemic absorption, apply finger pressure on the lacrimal sac for 1 to 2 minutes following application to the eye.
If more than one topical ophthalmic drug product is being used, administer the drugs at least 5 to 10 minutes apart; follow the instructions from the manufacturer.
For multidose containers, to avoid contamination or the spread of infection, do not use dropper for more than one person.
For preservative-free containers, the individual use product should be used immediately after opening and discarded immediately after use.

Adverse Reactions
Severe

bradycardia / Rapid / 5.0-9.1
heart failure / Delayed / 8.0-8.0
pulmonary edema / Early / 2.0-2.0
arrhythmia exacerbation / Early / 1.1-1.1
agranulocytosis / Delayed / 0-1.0
bronchospasm / Rapid / 0.6-0.6
cardiac arrest / Early / Incidence not known
AV block / Early / Incidence not known
angioedema / Rapid / Incidence not known
anaphylactoid reactions / Rapid / Incidence not known
exfoliative dermatitis / Delayed / Incidence not known
laryngospasm / Rapid / Incidence not known

Moderate

blurred vision / Early / 33.0-33.0
conjunctivitis / Delayed / 1.0-5.0
hypotension / Rapid / 3.0-3.0
dyspnea / Early / 1.7-1.7
chest pain (unspecified) / Early / 0.6-0.6
palpitations / Early / Incidence not known
angina / Early / Incidence not known
edema / Delayed / Incidence not known
myasthenia / Delayed / Incidence not known
confusion / Early / Incidence not known
hallucinations / Early / Incidence not known
memory impairment / Delayed / Incidence not known
depression / Delayed / Incidence not known
hepatomegaly / Delayed / Incidence not known
hyperglycemia / Delayed / Incidence not known
diabetes mellitus / Delayed / Incidence not known
hypoglycemia / Early / Incidence not known
hypertriglyceridemia / Delayed / Incidence not known
elevated hepatic enzymes / Delayed / Incidence not known
penile fibrosis / Delayed / Incidence not known
impotence (erectile dysfunction) / Delayed / Incidence not known
psoriasis / Delayed / Incidence not known
withdrawal / Early / Incidence not known

Mild

ocular irritation / Rapid / 12.5-12.5
nausea / Early / 0.6-8.0
dizziness / Early / 2.3-6.0
fatigue / Early / 3.4-5.0
asthenia / Delayed / 0.6-5.0
ocular pruritus / Rapid / 1.0-5.0
ocular discharge / Delayed / 1.0-5.0
foreign body sensation / Rapid / 1.0-5.0
lacrimation / Early / 1.0-5.0
ocular pain / Early / 1.0-5.0
pruritus / Rapid / 1.1-1.1
purpura / Delayed / 0-1.0
syncope / Early / 0.6-0.6
vertigo / Early / 0.6-0.6
paresthesias / Delayed / 0.6-0.6
libido decrease / Delayed / 0.6-0.6
insomnia / Early / Incidence not known
emotional lability / Early / Incidence not known
ptosis / Delayed / Incidence not known
nightmares / Early / Incidence not known
weakness / Early / Incidence not known
drowsiness / Early / Incidence not known
diplopia / Early / Incidence not known
dyspepsia / Early / Incidence not known
diarrhea / Early / Incidence not known
vomiting / Early / Incidence not known
cough / Delayed / Incidence not known
myalgia / Early / Incidence not known
arthralgia / Delayed / Incidence not known
musculoskeletal pain / Early / Incidence not known
Peyronie's disease / Delayed / Incidence not known
urticaria / Rapid / Incidence not known
rash / Early / Incidence not known
alopecia / Delayed / Incidence not known
xerosis / Delayed / Incidence not known
hyperhidrosis / Delayed / Incidence not known
skin hyperpigmentation / Delayed / Incidence not known
fever / Early / Incidence not known
skin irritation / Early / Incidence not known

Boxed Warning
Abrupt discontinuation

Abrupt discontinuation of any beta-adrenergic blocking agent, including timolol, can result in the development of myocardial ischemia, myocardial infarction, ventricular arrhythmias, or severe hypertension, particularly in patients with preexisting cardiovascular disease.

Common Brand Names

Betimol, Blocadren, Istalol, Timoptic, Timoptic Ocudose, Timoptic Ocumeter, Timoptic-XE

Dea Class

Rx

Description

Nonselective, beta-blocker similar to propranolol and nadolol
Lacks appreciable intrinsic sympathomimetic or membrane-stabilizing activities; relatively high lipid solubility; primarily metabolized
Available for oral and ophthalmic use.

Dosage And Indications
For the treatment of hypertension. Oral dosage Adults

Initially, 10 mg PO twice daily, alone or with a diuretic. Dosage may be increased at a minimum of weekly intervals to obtain satisfactory reduction in blood pressure. The usual dose is 10 to 20 mg PO twice daily. Maximum dose is 60 mg/day, divided in 2 doses. For geriatric patients, consider lower doses.

For reduction of cardiovascular mortality and to reduce the risk of reinfarction (i.e., myocardial infarction prophylaxis) after an acute myocardial infarction in patients who are clinically stable. Oral dosage Adults

10 mg PO twice daily. Clinical practice guidelines state oral beta blockers should be initiated in the first 24 hours in patients with STEMI who do not have signs of heart failure, evidence of low output, increased risk for cardiogenic shock, or other contraindications for beta blocker use.

For migraine prophylaxis. Oral dosage Adults

10 mg PO twice daily, initially. May increase or decrease the dose as needed based on clinical response and tolerability. Dose range: 10 to 30 mg/day. May administer doses of 10 or 20 mg/day as a single dose during maintenance therapy. Max: 30 mg/day in divided doses. Discontinue if adequate results not achieved within 4 to 6 weeks. Guidelines classify timolol as having established efficacy for migraine prophylaxis.[57981]

For the treatment of elevated intraocular pressure in patients with open-angle glaucoma or ocular hypertension. Ophthalmic dosage (Timoptic, timolol maleate ophthalmic solution) Adults

Instill 1 drop of a 0.25% solution in affected eye(s) twice daily. Dosage may be increased to 1 drop of a 0.5% solution twice daily, if necessary for adequate reduction of intraocular pressure. Dosage may be reduced to 1 drop once daily of effective strength to maintain reduced pressure.

Children and Adolescents 2 years and older

Instill 1 drop of a 0.25% solution in affected eye(s) twice daily. Dosage may be increased to 1 drop of a 0.5% solution twice daily, if necessary for adequate reduction of intraocular pressure. Dosage may be reduced to 1 drop once daily of effective strength to maintain reduced pressure.

Ophthalmic dosage (Istalol, timolol maleate ophthalmic solution) Adults

Instill 1 drop of a 0.5% solution in affected eye(s) once daily in the morning. If the IOP is not controlled on this regimen, concomitant therapy with other agent(s) for lowering IOP can be instituted.

Ophthalmic dosage (Betimol, timolol hemihydrate ophthalmic solution) Adults

Instill 1 drop of a 0.25% solution in affected eye(s) twice daily. Dosage may be increased to 1 drop of a 0.5% solution twice daily, if necessary for adequate reduction of intraocular pressure. Dosage may be reduced to 1 drop once daily of effective strength to maintain reduced pressure.

Ophthalmic dosage (Timoptic-XE gel forming ophthalmic solution) Adults

Instill 1 drop of a 0.25% solution in affected eye(s) once daily. Dosage may be increased to 1 drop of a 0.5% solution once daily, if necessary for adequate reduction of intraocular pressure. Doses greater than 1 drop of the 0.5% solution once daily have not been studied.

Children and Adolescents 2 years and older

Instill 1 drop of a 0.25% solution in affected eye(s) once daily. Dosage may be increased to 1 drop of a 0.5% solution once daily, if necessary for adequate reduction of intraocular pressure. Doses greater than 1 drop of the 0.5% solution once daily have not been studied.

For the management of chronic stable angina†. Oral dosage Adults

Initially 10 mg PO twice daily, titrated up to 30 mg twice daily, to attain clinical goals. In most angina clinical trials, the dosage ranged from 10 to 60 mg/day PO. Some patients require more frequent dosing intervals.

For the treatment of essential tremor†. Oral dosage Adults

10 mg PO once daily.

†Indicates off-label use

Dosing Considerations
Hepatic Impairment

Since timolol is primarily metabolized by the liver, dosage reductions may be necessary in patients with hepatic impairment.

Renal Impairment

CrCl < 10 ml/min: Adjust dosage based on clinical response; monitor blood pressure closely. Although timolol is only 15% excreted renally, marked hypotensive responses have occurred in renal failure patients undergoing dialysis after receiving a maintenance dose of 20 mg/day PO.
 
Intermittent hemodialysis
Monitor patients undergoing hemodialysis cautiously; marked hypotensive responses have occurred in renal failure patients undergoing dialysis after receiving a maintenance dose of 20 mg/day PO. Timolol is removed by hemodialysis when tested in vitro; however, a study of patients with renal failure has shown that timolol does not dialyze readily.

Drug Interactions

Acetaminophen; Aspirin, ASA; Caffeine: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Acetaminophen; Aspirin: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Acetaminophen; Aspirin; Diphenhydramine: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Adenosine: (Moderate) Use adenosine with caution in the presence of beta blockers due to the potential for additive or synergistic depressant effects on the sinoatrial and atrioventricular nodes.
Aldesleukin, IL-2: (Moderate) Beta blockers may potentiate the hypotension seen with aldesleukin, IL 2.
Alemtuzumab: (Moderate) Alemtuzumab may cause hypotension. Careful monitoring of blood pressure and hypotensive symptoms is recommended especially in patients with ischemic heart disease and in patients on antihypertensive agents.
Alfentanil: (Moderate) Alfentanil may cause bradycardia. The risk of significant hypotension and/or bradycardia during therapy with alfentanil is increased in patients receiving beta-blockers.
Alfuzosin: (Moderate) The manufacturer warns that the combination of alfuzosin with antihypertensive agents has the potential to cause hypotension in some patients. Alfuzosin (2.5 mg, immediate-release) potentiated the hypotensive effects of atenolol (100 mg) in eight healthy young male volunteers. The Cmax and AUC of alfuzosin was increased by 28% and 21%, respectively. Alfuzosin increased the Cmax and AUC of atenolol by 26% and 14%, respectively. Significant reductions in mean blood pressure and in mean heart rate were reported with the combination.
Alogliptin; Metformin: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Alpha-blockers: (Moderate) Orthostatic hypotension may be more likely if beta-blockers are coadministered with alpha-blockers.
Alpha-glucosidase Inhibitors: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Alprostadil: (Minor) The concomitant use of systemic alprostadil injection and antihypertensive agents, such as beta-clockers, may cause additive hypotension. Caution is advised with this combination. Systemic drug interactions with the urethral suppository (MUSE) or alprostadil intracavernous injection are unlikely in most patients because low or undetectable amounts of the drug are found in the peripheral venous circulation following administration. In those men with significant corpora cavernosa venous leakage, hypotension might be more likely. Use caution with in-clinic dosing for erectile dysfunction (ED) and monitor for the effects on blood pressure. In addition, the presence of medications in the circulation that attenuate erectile function may influence the response to alprostadil. However, in clinical trials with alprostadil intracavernous injection, anti-hypertensive agents had no apparent effect on the safety and efficacy of alprostadil.
Amifostine: (Major) Patients receiving beta-blockers should be closely monitored during amifostine infusions due to additive effects. Patients receiving amifostine at doses recommended for chemotherapy should have antihypertensive therapy interrupted 24 hours preceding administration of amifostine. If the antihypertensive cannot be stopped, patients should not receive amifostine.
Amiodarone: (Moderate) Concomitant administration of timolol with amiodarone may cause additive electrophysiologic effects (slow sinus rate or worsen AV block), resulting in symptomatic bradycardia, sinus arrest, and atrioventricular block. This is particularly likely in patients with preexisting partial AV block or sinus node dysfunction. Because amiodarone is an inhibitor of CYP2D6, decreased clearance of timolol, which is a CYP2D6 substrate, is also possible. Caution and close monitoring are recommended during coadministration; a dose reduction of one or both drugs may be needed based on response. It should be noted that post-hoc analysis of amiodarone therapy in patients after acute myocardial infarction in two clinical trials revealed that amiodarone in addition to a beta-blocker significantly lowered the incidence of cardiac and arrhythmic death or resuscitated cardiac arrest when compared with amiodarone or beta-blocker therapy alone.
Amlodipine: (Moderate) Coadministration of amlodipine and beta-blockers can reduce angina and improve exercise tolerance. When these drugs are given together, however, hypotension and impaired cardiac performance can occur, especially in patients with left ventricular dysfunction, cardiac arrhythmias, or aortic stenosis.
Amlodipine; Atorvastatin: (Moderate) Coadministration of amlodipine and beta-blockers can reduce angina and improve exercise tolerance. When these drugs are given together, however, hypotension and impaired cardiac performance can occur, especially in patients with left ventricular dysfunction, cardiac arrhythmias, or aortic stenosis.
Amlodipine; Benazepril: (Moderate) Coadministration of amlodipine and beta-blockers can reduce angina and improve exercise tolerance. When these drugs are given together, however, hypotension and impaired cardiac performance can occur, especially in patients with left ventricular dysfunction, cardiac arrhythmias, or aortic stenosis.
Amlodipine; Celecoxib: (Moderate) Coadministration of amlodipine and beta-blockers can reduce angina and improve exercise tolerance. When these drugs are given together, however, hypotension and impaired cardiac performance can occur, especially in patients with left ventricular dysfunction, cardiac arrhythmias, or aortic stenosis.
Amlodipine; Olmesartan: (Moderate) Coadministration of amlodipine and beta-blockers can reduce angina and improve exercise tolerance. When these drugs are given together, however, hypotension and impaired cardiac performance can occur, especially in patients with left ventricular dysfunction, cardiac arrhythmias, or aortic stenosis.
Amlodipine; Valsartan: (Moderate) Coadministration of amlodipine and beta-blockers can reduce angina and improve exercise tolerance. When these drugs are given together, however, hypotension and impaired cardiac performance can occur, especially in patients with left ventricular dysfunction, cardiac arrhythmias, or aortic stenosis.
Amlodipine; Valsartan; Hydrochlorothiazide, HCTZ: (Moderate) Coadministration of amlodipine and beta-blockers can reduce angina and improve exercise tolerance. When these drugs are given together, however, hypotension and impaired cardiac performance can occur, especially in patients with left ventricular dysfunction, cardiac arrhythmias, or aortic stenosis.
Amobarbital: (Moderate) Although concurrent use of amobarbital with antihypertensive agents may lead to hypotension, barbiturates, as a class, can enhance the hepatic metabolism of beta-blockers that are significantly metabolized by the liver. Beta-blockers that may be affected include betaxolol, labetalol, metoprolol, pindolol, propranolol, and timolol. Clinicians should closely monitor patients blood pressure during times of coadministration.
Antithyroid agents: (Minor) Hyperthyroidism may cause increased clearance of beta blockers that possess a high extraction ratio. A dose reduction of some beta-blockers may be needed when a hyperthyroid patient treated with methimazole becomes euthyroid.
Apomorphine: (Moderate) Use of beta blockers and apomorphine together can increase the hypotensive effects of apomorphine. Monitor blood pressure regularly during use of this combination.
Apraclonidine: (Minor) Theoretically, additive blood pressure reductions could occur when apraclonidine is combined with antihypertensive agents.
Aripiprazole: (Minor) Aripiprazole may enhance the hypotensive effects of antihypertensive agents. It may be advisable to monitor blood pressure when these medications are coadministered.
Artemether; Lumefantrine: (Moderate) Lumefantrine is an inhibitor and timolol is a substrate/inhibitor of the CYP2D6 isoenzyme; therefore, coadministration may lead to increased timolol concentrations. Concomitant use warrants caution due to the potential for increased side effects.
Articaine; Epinephrine: (Moderate) Local anesthetics may cause additive hypotension in combination with antihypertensive agents. Thus, patients receiving antihypertensive agents may experience additive hypotensive effects.
Asenapine: (Moderate) Secondary to alpha-blockade, asenapine can produce vasodilation that may result in additive effects during concurrent use of timolol. The potential reduction in blood pressure can precipitate orthostatic hypotension and associated dizziness, tachycardia, and syncope. If concurrent use is necessary, patients should be counseled on measures to prevent orthostatic hypotension, such as sitting on the edge of the bed for several minutes prior to standing in the morning and rising slowly from a seated position. Close monitoring of blood pressure is recommended until the full effects of the combination therapy are known; the timolol dosage may need to be adjusted.
Aspirin, ASA: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Aspirin, ASA; Butalbital; Caffeine: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Aspirin, ASA; Caffeine: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Aspirin, ASA; Caffeine; Orphenadrine: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Aspirin, ASA; Carisoprodol: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Aspirin, ASA; Carisoprodol; Codeine: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Aspirin, ASA; Citric Acid; Sodium Bicarbonate: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Aspirin, ASA; Dipyridamole: (Major) Beta-blockers should generally be withheld before dipyridamole-stress testing. Monitor the heart rate carefully following the dipyridamole injection. (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Aspirin, ASA; Omeprazole: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Aspirin, ASA; Oxycodone: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Atazanavir: (Moderate) Atazanavir can prolong the PR interval. Coadministration with other agents that prolong the PR interval, like beta blockers, may result in elevated risk of conduction disturbances and atrioventricular block.
Atazanavir; Cobicistat: (Moderate) Atazanavir can prolong the PR interval. Coadministration with other agents that prolong the PR interval, like beta blockers, may result in elevated risk of conduction disturbances and atrioventricular block. (Moderate) Coadministration of cobicistat (a CYP2D6 inhibitor) with beta-blockers metabolized by CYP2D6, such as timolol, may result in elevated beta-blocker serum concentrations. If used concurrently, close clinical monitoring with appropriate beta-blocker dose reductions are advised.
Baclofen: (Moderate) Baclofen has been associated with hypotension. Concurrent use with baclofen and antihypertensive agents may result in additive hypotension. Dosage adjustments of the antihypertensive medication may be required.
Beta-agonists: (Moderate) Beta-blockers will block the pulmonary effects of inhaled beta-agonists, and in some cases may exacerbate bronchospasm in patients with reactive airways. Beta-agonists can sometimes increase heart rate or have other cardiovascular effects, particularly when used in high doses or if hypokalemia is present. Use of a beta-1-selective (cardioselective) beta blocker is recommended whenever possible when this combination of drugs must be used together. Monitor the patient's lung and cardiovascular status closely. Beta-agonists and beta-blockers are pharmacologic opposites and will counteract each other to some extent when given concomitantly, especially when non-cardioselective beta blockers are used.
Bismuth Subsalicylate: (Moderate) Concurrent use of beta-blockers with bismuth subsalicylate and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Bismuth Subsalicylate; Metronidazole; Tetracycline: (Moderate) Concurrent use of beta-blockers with bismuth subsalicylate and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Bretylium: (Moderate) Bretylium and beta-blockers may have an additive effect when used concomitantly; monitor for hypotension or marked bradycardia, which may produce vertigo, syncope, or postural hypotension.
Brexpiprazole: (Moderate) Due to brexpiprazole's antagonism at alpha 1-adrenergic receptors, the drug may enhance the hypotensive effects of alpha-blockers and other antihypertensive agents.
Bupivacaine Liposomal: (Moderate) Local anesthetics may cause additive hypotension in combination with antihypertensive agents. Use extreme caution with the concomitant use of bupivacaine and antihypertensive agents. Peripheral vasodilation may occur after use of bupivacaine. Thus, patients receiving antihypertensive agents may experience additive hypotensive effects. Blood concentrations of local anesthetics achieved after therapeutic doses are associated with minimal change in peripheral vascular resistance. Higher blood concentrations of local anesthetics may occur due to inadvertent intravascular administration or repeated doses.
Bupivacaine: (Moderate) Local anesthetics may cause additive hypotension in combination with antihypertensive agents. Use extreme caution with the concomitant use of bupivacaine and antihypertensive agents. Peripheral vasodilation may occur after use of bupivacaine. Thus, patients receiving antihypertensive agents may experience additive hypotensive effects. Blood concentrations of local anesthetics achieved after therapeutic doses are associated with minimal change in peripheral vascular resistance. Higher blood concentrations of local anesthetics may occur due to inadvertent intravascular administration or repeated doses.
Bupivacaine; Epinephrine: (Moderate) Local anesthetics may cause additive hypotension in combination with antihypertensive agents. Use extreme caution with the concomitant use of bupivacaine and antihypertensive agents. Peripheral vasodilation may occur after use of bupivacaine. Thus, patients receiving antihypertensive agents may experience additive hypotensive effects. Blood concentrations of local anesthetics achieved after therapeutic doses are associated with minimal change in peripheral vascular resistance. Higher blood concentrations of local anesthetics may occur due to inadvertent intravascular administration or repeated doses.
Bupivacaine; Lidocaine: (Major) Drugs such as beta-blockers that decrease cardiac output reduce hepatic blood flow and thereby decrease lidocaine hepatic clearance. Also, opposing effects on conduction exist between lidocaine and beta-blockers while their effects to decrease automaticity may be additive. Propranolol has been shown to decrease lidocaine clearance and symptoms of lidocaine toxicity have been seen as a result of this interaction. This interaction is possible with other beta-blocking agents since most decrease hepatic blood flow. Monitoring of lidocaine concentrations is recommended during concomitant therapy with beta-blockers. (Moderate) Local anesthetics may cause additive hypotension in combination with antihypertensive agents. Use extreme caution with the concomitant use of bupivacaine and antihypertensive agents. Peripheral vasodilation may occur after use of bupivacaine. Thus, patients receiving antihypertensive agents may experience additive hypotensive effects. Blood concentrations of local anesthetics achieved after therapeutic doses are associated with minimal change in peripheral vascular resistance. Higher blood concentrations of local anesthetics may occur due to inadvertent intravascular administration or repeated doses.
Bupivacaine; Meloxicam: (Moderate) Local anesthetics may cause additive hypotension in combination with antihypertensive agents. Use extreme caution with the concomitant use of bupivacaine and antihypertensive agents. Peripheral vasodilation may occur after use of bupivacaine. Thus, patients receiving antihypertensive agents may experience additive hypotensive effects. Blood concentrations of local anesthetics achieved after therapeutic doses are associated with minimal change in peripheral vascular resistance. Higher blood concentrations of local anesthetics may occur due to inadvertent intravascular administration or repeated doses.
Bupropion: (Minor) Monitor for an increased incidence of timolol-related adverse effects if bupropion and timolol are used concomitantly. Coadministration of bupropion and timolol may result in increased plasma concentrations of timolol. Bupropion and hydroxybupropion, the major active metabolite, are inhibitors of CYP2D6 in vitro. Timolol is a CYP2D6 substrate.
Bupropion; Naltrexone: (Minor) Monitor for an increased incidence of timolol-related adverse effects if bupropion and timolol are used concomitantly. Coadministration of bupropion and timolol may result in increased plasma concentrations of timolol. Bupropion and hydroxybupropion, the major active metabolite, are inhibitors of CYP2D6 in vitro. Timolol is a CYP2D6 substrate.
Butalbital; Aspirin; Caffeine; Codeine: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Cabergoline: (Moderate) Cabergoline should be used cautiously with antihypertensive agents, including beta-blockers. Cabergoline has been associated with hypotension. Initial doses of cabergoline higher than 1 mg may produce orthostatic hypotension. It may be advisable to monitor blood pressure.
Canagliflozin; Metformin: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Carbidopa; Levodopa: (Moderate) Concomitant use of beta-blockers with levodopa can result in additive hypotensive effects.
Carbidopa; Levodopa; Entacapone: (Moderate) Concomitant use of beta-blockers with levodopa can result in additive hypotensive effects.
Cariprazine: (Moderate) Orthostatic vital signs should be monitored in patients who are at risk for hypotension, such as those receiving cariprazine in combination with antihypertensive agents. Atypical antipsychotics may cause orthostatic hypotension and syncope, most commonly during treatment initiation and dosage increases. Patients should be informed about measures to prevent orthostatic hypotension, such as sitting on the edge of the bed for several minutes prior to standing in the morning, or rising slowly from a seated position. Consider a cariprazine dose reduction if hypotension occurs.
Ceritinib: (Major) Avoid concomitant use of ceritinib with timolol if possible due to the risk of additive bradycardia. Both ceritinib and timolol can cause bradycardia. An interruption of ceritinib therapy, dose reduction, or discontinuation of therapy may be necessary if bradycardia occurs.
Cevimeline: (Major) Cevimeline should be administered with caution to patients taking beta adrenergic antagonists, because of the possibility of conduction disturbances. Cevimeline can potentially alter cardiac conduction and/or heart rate. Patients with significant cardiovascular disease treated with beta-blockers may potentially be unable to compensate for transient changes in hemodynamics or rhythm induced by cevimeline. If use of these drugs together cannot be avoided, close monitoring of blood pressure, heart rate and cardiac function is advised.
Chloroprocaine: (Moderate) Local anesthetics may cause additive hypotension in combination with antihypertensive agents.
Chlorthalidone; Clonidine: (Moderate) Monitor heart rate in patients receiving concomitant clonidine and agents known to affect sinus node function or AV nodal conduction (e.g., beta-blockers). Severe bradycardia resulting in hospitalization and pacemaker insertion has been reported during combination therapy with clonidine and other sympatholytic agents. Concomitant use of clonidine with beta-blockers can also cause additive hypotension. Beta-blockers should not be substituted for clonidine when modifications are made in a patient's antihypertensive regimen because beta-blocker administration during clonidine withdrawal can augment clonidine withdrawal, which may lead to a hypertensive crisis. If a beta-blocker is to be substituted for clonidine, clonidine should be gradually tapered and the beta-blocker should be gradually increased over several days to avoid the possibility of rebound hypertension; administration of beta-blockers during withdrawal of clonidine can precipitate severe increases in blood pressure as a result of unopposed alpha stimulation.
Choline Salicylate; Magnesium Salicylate: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Citalopram: (Minor) Citalopram mildly inhibits the hepatic CYP2D6 isoenzyme at therapeutic doses. This can result in increased concentrations of drugs metabolized via the same pathway, including timolol.
Clevidipine: (Moderate) Use clevidipine and timolol with caution due to risk for additive negative effects on heart rate, AV conduction, and/or cardiac contractility.
Clonidine: (Moderate) Monitor heart rate in patients receiving concomitant clonidine and agents known to affect sinus node function or AV nodal conduction (e.g., beta-blockers). Severe bradycardia resulting in hospitalization and pacemaker insertion has been reported during combination therapy with clonidine and other sympatholytic agents. Concomitant use of clonidine with beta-blockers can also cause additive hypotension. Beta-blockers should not be substituted for clonidine when modifications are made in a patient's antihypertensive regimen because beta-blocker administration during clonidine withdrawal can augment clonidine withdrawal, which may lead to a hypertensive crisis. If a beta-blocker is to be substituted for clonidine, clonidine should be gradually tapered and the beta-blocker should be gradually increased over several days to avoid the possibility of rebound hypertension; administration of beta-blockers during withdrawal of clonidine can precipitate severe increases in blood pressure as a result of unopposed alpha stimulation.
Clozapine: (Moderate) Clozapine used concomitantly with the antihypertensive agents can increase the risk and severity of hypotension by potentiating the effect of the antihypertensive drug.
Cobicistat: (Moderate) Coadministration of cobicistat (a CYP2D6 inhibitor) with beta-blockers metabolized by CYP2D6, such as timolol, may result in elevated beta-blocker serum concentrations. If used concurrently, close clinical monitoring with appropriate beta-blocker dose reductions are advised.
Cocaine: (Major) Although beta-blockers are indicated to reduce cocaine-induced tachycardia, myocardial ischemia, and arrhythmias, concomitant use of cocaine and non-selective beta-adrenergic blocking agents, including ophthalmic preparations, can cause unopposed alpha-adrenergic activity, resulting in heart block, excessive bradycardia, or hypertension. In theory, the use of alpha-blocker and beta-blocker combinations or selective beta-blockers in low doses may not cause unopposed alpha stimulation in this situation. Labetalol, a beta-blocker with some alpha-blocking activity, has been used successfully to treat cocaine-induced hypertension. In addition, cocaine can reduce the therapeutic effects of beta-blockers.
Co-Enzyme Q10, Ubiquinone: (Moderate) Co-enzyme Q10, ubiquinone (CoQ10) may lower blood pressure. CoQ10 use in combination with antihypertensive agents may lead to additional reductions in blood pressure in some individuals. Patients who choose to take CoQ10 concurrently with antihypertensive medications should receive periodic blood pressure monitoring. Patients should be advised to inform their prescriber of their use of CoQ10.
Colesevelam: (Moderate) Colesevelam may decrease the absorption of timolol. To minimize potential for interactions, consider administering timolol at least 1 hour before or at least 4 hours after colesevelam.
Crizotinib: (Major) Avoid coadministration of crizotinib with agents known to cause bradycardia, such as beta-blockers, to the extent possible due to the risk of additive bradycardia. If concomitant use is unavoidable, monitor heart rate and blood pressure regularly. An interruption of crizotinib therapy or dose adjustment may be necessary if bradycardia occurs.
Dapagliflozin; Metformin: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Darunavir: (Moderate) A dose decrease may be needed for timolol when administered with darunavir/ritonavir as serum concentrations for timolol may be increased. Caution is warranted and clinical monitoring is recommended.
Darunavir; Cobicistat: (Moderate) A dose decrease may be needed for timolol when administered with darunavir/ritonavir as serum concentrations for timolol may be increased. Caution is warranted and clinical monitoring is recommended. (Moderate) Coadministration of cobicistat (a CYP2D6 inhibitor) with beta-blockers metabolized by CYP2D6, such as timolol, may result in elevated beta-blocker serum concentrations. If used concurrently, close clinical monitoring with appropriate beta-blocker dose reductions are advised.
Darunavir; Cobicistat; Emtricitabine; Tenofovir alafenamide: (Moderate) A dose decrease may be needed for timolol when administered with darunavir/ritonavir as serum concentrations for timolol may be increased. Caution is warranted and clinical monitoring is recommended. (Moderate) Coadministration of cobicistat (a CYP2D6 inhibitor) with beta-blockers metabolized by CYP2D6, such as timolol, may result in elevated beta-blocker serum concentrations. If used concurrently, close clinical monitoring with appropriate beta-blocker dose reductions are advised.
Dasiglucagon: (Minor) A temporary increase in both blood pressure and pulse rate may occur following the administration of glucagon. Patients taking beta-blockers might be expected to have a greater increase in both pulse and blood pressure. Glucagon exerts positive inotropic and chronotropic effects and may, therefore, cause tachycardia and hypertension in some patients. The increase in blood pressure and pulse rate may require therapy in some patients with coronary artery disease.
Delavirdine: (Moderate) Delavirdine is a potent inhibitor of cytochrome P450 2D6 and might decrease the hepatic metabolism of timolol. This interaction may be more pronounced in extensive metabolizers. Clinicians should be alert to exaggerated beta-blocker effects if the timolol is given with delavirdine.
Desflurane: (Moderate) Concurrent use of beta-blockers with desflurane may result in exaggerated cardiovascular effects (e.g., hypotension and negative inotropic effects). Beta-blockers may be continued during general anesthesia as long as the patient is monitored for cardiac depressant and hypotensive effects. Withdrawal of a beta-blocker perioperatively may be detrimental to the patient's clinical status and is not recommended. Caution is advised if these drugs are administered together.
Dexmedetomidine: (Moderate) Monitor blood pressure and heart rate during concomitant use of dexmedetomidine and beta-blockers due to the risk of additive bradycardia and hypotensive effects.
Dextromethorphan; Bupropion: (Minor) Monitor for an increased incidence of timolol-related adverse effects if bupropion and timolol are used concomitantly. Coadministration of bupropion and timolol may result in increased plasma concentrations of timolol. Bupropion and hydroxybupropion, the major active metabolite, are inhibitors of CYP2D6 in vitro. Timolol is a CYP2D6 substrate.
Dextromethorphan; Quinidine: (Major) In general, patients receiving combined therapy with quinidine and beta-blockers should be monitored for potential hypotension, orthostasis, bradycardia and/or AV block, and heart failure. Reduce the beta-blocker dosage if necessary. Quinidine may have additive effects on cardiovascular parameters when used together with beta-blockers, such as timolol. Decreased heart rate (bradycardia) has been reported during combination timolol and quinidine therapy. Additive hypotension is also possible. Additionally, quinidine is a known inhibitor of CYP2D6, and may impair the hepatic clearance of timolol (CYP2D6 substrate). Patients should be monitored for excess beta-blockade. Quinidine has been reported to potentiate timolol-induced bradycardia even after use of ophthalmic timolol.
Diazoxide: (Moderate) Additive hypotensive effects can occur with the concomitant administration of diazoxide with other antihypertensive agent. This interaction can be therapeutically advantageous, but dosages must be adjusted accordingly. The manufacturer advises that IV diazoxide should not be administered to patients within 6 hours of receiving beta-blockers.
Digoxin: (Moderate) Monitor heart rate during concomitant digoxin and timolol use due to increased risk for bradycardia. Both digoxin and timolol slow atrioventricular conduction (AV) and decrease heart rate; additive effects on AV node conduction can result in bradycardia and advanced or complete heart block.
Diltiazem: (Moderate) Monitor blood pressure and heart rate during concomitant diltiazem and timolol use; dosage adjustments may be needed. Concomitant use may result in additive effects in prolonging AV conduction and additive antihypertensive effects.
Dipeptidyl Peptidase-4 Inhibitors: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Dipyridamole: (Major) Beta-blockers should generally be withheld before dipyridamole-stress testing. Monitor the heart rate carefully following the dipyridamole injection.
Disopyramide: (Major) Disopyramide and beta-blockers, like timolol, have been used together for the treatment of ventricular arrhythmias; however, this combination should be used with caution due to the potential for additive AV blocking effects. In general, patients receiving combined therapy with disopyramide and beta-blockers should be monitored for potential bradycardia, AV block, and/or hypotension.
Donepezil: (Moderate) The increase in vagal tone induced by some cholinesterase inhibitors may produce bradycardia, hypotension, or syncope. The vagotonic effect of these drugs may be increased when given with other medications known to cause bradycardia such as beta-blockers. These interactions are pharmacodynamic in nature rather than pharmacokinetic.
Donepezil; Memantine: (Moderate) The increase in vagal tone induced by some cholinesterase inhibitors may produce bradycardia, hypotension, or syncope. The vagotonic effect of these drugs may be increased when given with other medications known to cause bradycardia such as beta-blockers. These interactions are pharmacodynamic in nature rather than pharmacokinetic.
Doxazosin: (Moderate) Orthostatic hypotension may be more likely if beta-blockers are coadministered with alpha-blockers.
Dronedarone: (Major) In dronedarone clinical trials, bradycardia was seen more frequently in patients also receiving beta blockers. If coadministration of dronedarone and a beta blocker is unavoidable, administer a low dose of the beta blocker initially and increase the dosage only after ECG verification of tolerability. Concomitant administration may decreased AV and sinus node conduction. Furthermore, dronedarone is an inhibitor of CYP2D6, and some beta blockers are substrates for CYP2D6 (e.g., metoprolol, propranolol, nebivolol, carvedilol). Coadministration of dronedarone with a single dose of propranolol and multiple doses of metoprolol increased propranolol and metoprolol exposure by 1.3- and 1.6-fold, respectively.
Dulaglutide: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Duloxetine: (Moderate) Monitor blood pressure during concomitant duloxetine and timolol use. Concomitant use increases the risk for hypotension, including orthostatic hypotension and syncope. Consider reducing the duloxetine dose or discontinuing duloxetine if symptomatic orthostatic hypotension, falls, or syncope occur during treatment.
Dutasteride; Tamsulosin: (Minor) Tamsulosin did not potentiate the hypotensive effects of atenolol. However, since the symptoms of orthostasis are reported more frequently in tamsulosin-treated vs. placebo patients, there is a potential risk of enhanced hypotensive effects when co-administered with antihypertensive agents.
Eliglustat: (Moderate) Coadministration of timolol and eliglustat may result in increased plasma concentrations of timolol. Consider reducing the dosage of oral timolol and titrating to clinical effect. Timolol is a CYP2D6 substrate; eliglustat is a CYP2D6 inhibitor.
Elvitegravir; Cobicistat; Emtricitabine; Tenofovir Alafenamide: (Moderate) Coadministration of cobicistat (a CYP2D6 inhibitor) with beta-blockers metabolized by CYP2D6, such as timolol, may result in elevated beta-blocker serum concentrations. If used concurrently, close clinical monitoring with appropriate beta-blocker dose reductions are advised.
Elvitegravir; Cobicistat; Emtricitabine; Tenofovir Disoproxil Fumarate: (Moderate) Coadministration of cobicistat (a CYP2D6 inhibitor) with beta-blockers metabolized by CYP2D6, such as timolol, may result in elevated beta-blocker serum concentrations. If used concurrently, close clinical monitoring with appropriate beta-blocker dose reductions are advised.
Empagliflozin; Linagliptin; Metformin: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Empagliflozin; Metformin: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Epoprostenol: (Moderate) Epoprostenol can have additive effects when administered with other antihypertensive agents, including beta-blockers. These effects can be used to therapeutic advantage, but dosage adjustments may be necessary.
Ertugliflozin; Metformin: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Escitalopram: (Minor) Escitalopram modestly inhibits the hepatic CYP2D6 isoenzyme. This can result in increased concentrations of drugs metabolized via the same pathway, including timolol.
Estradiol: (Minor) Estrogens can induce fluid retention and may increase blood pressure in some patients; patients who are receiving antihypertensive agents concurrently with hormonal contraceptives should be monitored for antihypertensive effectiveness.
Etomidate: (Major) General anesthetics can potentiate the antihypertensive effects of beta-blockers and can produce prolonged hypotension. Beta-blockers may be continued during general anesthesia as long as the patient is monitored for cardiac depressant and hypotensive effects.
Exenatide: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Felodipine: (Moderate) The concomitant use of felodipine and timolol can reduce angina and improve exercise tolerance. When these drugs are given together, however, hypotension and impaired cardiac performance can occur, especially in patients with left ventricular dysfunction, cardiac arrhythmias, or aortic stenosis.
Fenoldopam: (Major) Avoid concomitant use of fenoldopam with beta-blockers due to the risk of hypotension. If used together, monitor blood pressure frequently. Beta-blockers may inhibit the sympathetic reflex response to fenoldopam.
Fingolimod: (Major) If possible, do not start fingolimod in a patient who is taking a drug that slows the heart rate or atrioventricular conduction such as beta-blockers. Use of these drugs during fingolimod initiation may be associated with severe bradycardia or heart block. Seek advice from the prescribing physician regarding the possibility to switch to drugs that do not slow the heart rate or atrioventricular conduction before initiating fingolimod. After the first fingolimod dose, overnight monitoring with continuous ECG in a medical facility is advised for patients who cannot stop taking drugs that slow the heart rate or atrioventricular conduction. Experience with fingolimod in patients receiving concurrent therapy with drugs that slow the heart rate or atrioventricular conduction is limited.
Fish Oil, Omega-3 Fatty Acids (Dietary Supplements): (Moderate) High doses of fish oil supplements may produce a blood pressure lowering effect It is possible that additive reductions in blood pressure may be seen when fish oils are used in a patient already taking antihypertensive agents.
Flecainide: (Moderate) Monitor heart rate during concomitant flecainide and timolol use due to risk for additive negative inotropic effects.
Fluorescein: (Moderate) Patients on beta-blockers are at an increased risk of adverse reaction when administered fluorescein injection. It is thought that beta-blockers may worsen anaphylaxis severity by exacerbating bronchospasm or by increasing the release of anaphylaxis mediators; alternately, beta-blocker therapy may make the patient more pharmacodynamically resistance to epinephrine rescue treatment.
Fluoxetine: (Moderate) Monitor for signs of bradycardia or heart block if coadministration of timolol with fluoxetine is necessary. Concomitant use may enhance the beta-blocking properties of timolol resulting in further slowing of the heart rate or cardiac conduction. Timolol is a CYP2D6 substrate and fluoxetine is a strong CYP2D6 inhibitor.
Galantamine: (Moderate) The increase in vagal tone induced by cholinesterase inhibitors, such as galantamine, may produce bradycardia or syncope. The vagotonic effect of galantamine may theoretically be increased when given with beta-blockers.
General anesthetics: (Major) General anesthetics can potentiate the antihypertensive effects of beta-blockers and can produce prolonged hypotension. Beta-blockers may be continued during general anesthesia as long as the patient is monitored for cardiac depressant and hypotensive effects.
Ginger, Zingiber officinale: (Minor) In vitro studies have demonstrated the positive inotropic effects of certain gingerol constituents of ginger; but it is unclear if whole ginger root exhibits these effects clinically in humans. It is theoretically possible that excessive doses of ginger could affect the action of inotropes; however, no clinical data are available.
Glipizide; Metformin: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Glucagon: (Minor) A temporary increase in both blood pressure and pulse rate may occur following the administration of glucagon. Patients taking beta-blockers might be expected to have a greater increase in both pulse and blood pressure. Glucagon exerts positive inotropic and chronotropic effects and may, therefore, cause tachycardia and hypertension in some patients. The increase in blood pressure and pulse rate may require therapy in some patients with coronary artery disease.
Glyburide; Metformin: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Guanfacine: (Moderate) Guanfacine can have additive effects when administered with other antihypertensive agents, including beta-blockers. These effects can be used to therapeutic advantage, but dosage adjustments may be necessary.
Haloperidol: (Moderate) Haloperidol should be used cautiously with timolol due to the possibility of additive hypotension.
Hydralazine; Isosorbide Dinitrate, ISDN: (Moderate) Nitroglycerin can cause hypotension. This action may be additive with other agents that can cause hypotension such as antihypertensive agents or other peripheral vasodilators. Patients should be monitored more closely for hypotension if nitroglycerin, including nitroglycerin rectal ointment, is used concurrently with any beta-blockers.
Icosapent ethyl: (Moderate) Beta-blockers may exacerbate hypertriglyceridemia and should be discontinued or changed to alternate therapy, if possible, prior to initiation of icosapent ethyl.
Iloperidone: (Moderate) Secondary to alpha-blockade, iloperidone can produce vasodilation that may result in additive effects during concurrent use with antihypertensive agents. The potential reduction in blood pressure can precipitate orthostatic hypotension and associated dizziness, tachycardia, and syncope. If concurrent use of iloperidone and antihypertensive agents is necessary, patients should be counseled on measures to prevent orthostatic hypotension, such as sitting on the edge of the bed for several minutes prior to standing in the morning and rising slowly from a seated position. Close monitoring of blood pressure is recommended until the full effects of the combination therapy are known.
Iloprost: (Moderate) Additive reductions in blood pressure may occur when inhaled iloprost is administered to patients receiving other antihypertensive agents.
Imatinib: (Moderate) Imatinib is a potent inhibitor of cytochrome P450 2D6 and might decrease the hepatic metabolism of timolol. This interaction may be more pronounced in extensive metabolizers. Clinicians should be alert to exaggerated beta-blocker effects if the timolol is given with these drugs.
Incretin Mimetics: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Insulin Degludec; Liraglutide: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Insulin Glargine; Lixisenatide: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catec

holamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Insulins: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Intravenous Lipid Emulsions: (Moderate) High doses of fish oil supplements may produce a blood pressure lowering effect It is possible that additive reductions in blood pressure may be seen when fish oils are used in a patient already taking antihypertensive agents.
Iobenguane I 131: (Major) Discontinue timolol for at least 5 half-lives before the administration of the dosimetry dose or a therapeutic dose of iobenguane I-131. Do not restart timolol until at least 7 days after each iobenguane I-131 dose. Drugs that reduce catecholamine uptake or deplete catecholamine stores, such as timolol, may interfere with iobenguane I-131 uptake into cells and interfere with dosimetry calculations resulting in altered iobenguane I-131 efficacy.
Isocarboxazid: (Moderate) Additive hypotensive effects may be seen when monoamine oxidase inhibitors (MAOIs) are combined with antihypertensives. Careful monitoring of blood pressure is suggested during concurrent therapy of MAOIs with beta-blockers. Limited data suggest that bradycardia is worsened when MAOIs are administered to patients receiving beta-blockers. Although the sinus bradycardia observed was not severe, until more data are available, clinicians should use MAOIs cautiously in patients receiving beta-blockers. Patients should be instructed to rise slowly from a sitting position, and to report syncope or changes in blood pressure or heart rate to their health care provider.
Isoflurane: (Major) General anesthetics can potentiate the antihypertensive effects of beta-blockers and can produce prolonged hypotension. Beta-blockers may be continued during general anesthesia as long as the patient is monitored for cardiac depressant and hypotensive effects.
Isosorbide Dinitrate, ISDN: (Moderate) Nitroglycerin can cause hypotension. This action may be additive with other agents that can cause hypotension such as antihypertensive agents or other peripheral vasodilators. Patients should be monitored more closely for hypotension if nitroglycerin, including nitroglycerin rectal ointment, is used concurrently with any beta-blockers.
Isosorbide Mononitrate: (Moderate) Nitroglycerin can cause hypotension. This action may be additive with other agents that can cause hypotension such as antihypertensive agents or other peripheral vasodilators. Patients should be monitored more closely for hypotension if nitroglycerin, including nitroglycerin rectal ointment, is used concurrently with any beta-blockers.
Isradipine: (Moderate) Although concomitant therapy with beta-blockers and isradipine is generally well tolerated and can even be beneficial in some cases, coadministration of these agents can induce excessive bradycardia or hypotension. Isradipine when used in combination with beta-blockers, especially in heart failure patients, can result in additive negative inotropic effects. Finally, angina has been reported when beta-adrenergic blocking agents are withdrawn abruptly when isradipine therapy is initiated. A gradual downward titration of the beta-adrenergic blocking agent dosage during initiation of isradipine therapy can minimize or eliminate this potential interaction. Patients should be monitored carefully, however, for excessive bradycardia, cardiac conduction abnormalities, or hypotension when these drugs are given together. In general, these reactions are more likely to occur with other non-dihydropyridine calcium channel blockers than with isradipine.
Ivabradine: (Moderate) Monitor heart rate if ivabradine is coadministered with other negative chronotropes like beta-blockers. Most patients receiving ivabradine will receive concomitant beta-blocker therapy. Coadministration of drugs that slow heart rate increases the risk for bradycardia.
Ketamine: (Major) General anesthetics can potentiate the antihypertensive effects of beta-blockers and can produce prolonged hypotension. Beta-blockers may be continued during general anesthesia as long as the patient is monitored for cardiac depressant and hypotensive effects.
Lacosamide: (Moderate) Use lacosamide with caution in patients taking concomitant medications that affect cardiac conduction, such as beta-blockers, because of the risk of AV block, bradycardia, or ventricular tachyarrhythmia. If use together is necessary, obtain an ECG prior to lacosamide initiation and after treatment has been titrated to steady-state. In addition, monitor patients receiving lacosamide via the intravenous route closely.
Lanreotide: (Moderate) Concomitant administration of bradycardia-inducing drugs (e.g., beta-adrenergic blockers) may have an additive effect on the reduction of heart rate associated with lanreotide. Adjust the beta-blocker dose if necessary.
Lasmiditan: (Moderate) Monitor heart rate if lasmiditan is coadministered with beta-blockers as concurrent use may increase the risk for bradycardia. Lasmiditan has been associated with lowering of heart rate. In a drug interaction study, addition of a single 200 mg dose of lasmiditan to a beta-blocker (propranolol) decreased heart rate by an additional 5 beats per minute.
Levamlodipine: (Moderate) Coadministration of amlodipine and beta-blockers can reduce angina and improve exercise tolerance. When these drugs are given together, however, hypotension and impaired cardiac performance can occur, especially in patients with left ventricular dysfunction, cardiac arrhythmias, or aortic stenosis.
Levodopa: (Moderate) Concomitant use of beta-blockers with levodopa can result in additive hypotensive effects.
Levothyroxine: (Minor) Because thyroid hormones cause cardiac stimulation including increased heart rate and increased contractility, the effects of beta-blockers may be reduced by thyroid hormones. The reduction of effects may be especially evident when a patient goes from a hypothyroid to a euthyroid state or when excessive amounts of thyroid hormone is given to the patient.
Levothyroxine; Liothyronine (Porcine): (Minor) Because thyroid hormones cause cardiac stimulation including increased heart rate and increased contractility, the effects of beta-blockers may be reduced by thyroid hormones. The reduction of effects may be especially evident when a patient goes from a hypothyroid to a euthyroid state or when excessive amounts of thyroid hormone is given to the patient.
Levothyroxine; Liothyronine (Synthetic): (Minor) Because thyroid hormones cause cardiac stimulation including increased heart rate and increased contractility, the effects of beta-blockers may be reduced by thyroid hormones. The reduction of effects may be especially evident when a patient goes from a hypothyroid to a euthyroid state or when excessive amounts of thyroid hormone is given to the patient.
Lidocaine: (Major) Drugs such as beta-blockers that decrease cardiac output reduce hepatic blood flow and thereby decrease lidocaine hepatic clearance. Also, opposing effects on conduction exist between lidocaine and beta-blockers while their effects to decrease automaticity may be additive. Propranolol has been shown to decrease lidocaine clearance and symptoms of lidocaine toxicity have been seen as a result of this interaction. This interaction is possible with other beta-blocking agents since most decrease hepatic blood flow. Monitoring of lidocaine concentrations is recommended during concomitant therapy with beta-blockers.
Lidocaine; Epinephrine: (Major) Drugs such as beta-blockers that decrease cardiac output reduce hepatic blood flow and thereby decrease lidocaine hepatic clearance. Also, opposing effects on conduction exist between lidocaine and beta-blockers while their effects to decrease automaticity may be additive. Propranolol has been shown to decrease lidocaine clearance and symptoms of lidocaine toxicity have been seen as a result of this interaction. This interaction is possible with other beta-blocking agents since most decrease hepatic blood flow. Monitoring of lidocaine concentrations is recommended during concomitant therapy with beta-blockers.
Lidocaine; Prilocaine: (Major) Drugs such as beta-blockers that decrease cardiac output reduce hepatic blood flow and thereby decrease lidocaine hepatic clearance. Also, opposing effects on conduction exist between lidocaine and beta-blockers while their effects to decrease automaticity may be additive. Propranolol has been shown to decrease lidocaine clearance and symptoms of lidocaine toxicity have been seen as a result of this interaction. This interaction is possible with other beta-blocking agents since most decrease hepatic blood flow. Monitoring of lidocaine concentrations is recommended during concomitant therapy with beta-blockers. (Moderate) Local anesthetics may cause additive hypotension in combination with antihypertensive agents.
Linagliptin; Metformin: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Linezolid: (Moderate) Linezolid is an antibiotic that is also a reversible, non-selective MAO inhibitor. Bradycardia may be worsened when MAO-inhibitors are co-administered to patients receiving beta-blockers. Use linezolid cautiously in patients receiving beta-blockers.
Liothyronine: (Minor) Because thyroid hormones cause cardiac stimulation including increased heart rate and increased contractility, the effects of beta-blockers may be reduced by thyroid hormones. The reduction of effects may be especially evident when a patient goes from a hypothyroid to a euthyroid state or when excessive amounts of thyroid hormone is given to the patient.
Liraglutide: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Lixisenatide: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Lofexidine: (Major) Because both lofexidine and timolol can cause hypotension and bradycardia, concurrent use should be avoided if possible. Patients being given lofexidine in an outpatient setting should be capable of and instructed on self-monitoring for hypotension, orthostasis, bradycardia, and associated symptoms. If clinically significant or symptomatic hypotension and/or bradycardia occur, the next dose of lofexidine should be reduced in amount, delayed, or skipped.
Lopinavir; Ritonavir: (Moderate) Timolol is significantly metabolized by CYP2D6 isoenzymes. CYP2D6 inhibitors, such as ritonavir, may impair timolol metabolism; the clinical significance of such interactions is unknown.
Lurasidone: (Moderate) Due to the antagonism of lurasidone at alpha-1 adrenergic receptors, the drug may enhance the hypotensive effects of alpha-blockers and other antihypertensive agents. If concurrent use of lurasidone and antihypertensive agents is necessary, patients should be counseled on measures to prevent orthostatic hypotension, such as sitting on the edge of the bed for several minutes prior to standing in the morning and rising slowly from a seated position. Close monitoring of blood pressure is recommended until the full effects of the combination therapy are known.
Magnesium Salicylate: (Moderate) Concurrent use of beta-blockers with aspirin and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Mavacamten: (Moderate) Expect additive negative inotropic effects during concomitant use of mavacamten and beta-blockers. If concomitant therapy with beta-blockers is initiated, or if the dose is increased, monitor left ventricular ejection fraction closely until stable doses and clinical response have been achieved. Avoid concomitant use of mavacamten and a beta-blocker plus verapamil or diltiazem due to an increased risk of left ventricular systolic dysfunction and heart failure symptoms.
Mefloquine: (Major) Concurrent use of mefloquine and beta blockers can result in ECG abnormalities or cardiac arrest.
Meglitinides: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Mepivacaine: (Moderate) Local anesthetics may cause additive hypotension in combination with antihypertensive agents. Peripheral vasodilation may occur after use of mepivacaine. Thus, patients receiving antihypertensive agents may experience additive hypotensive effects. Blood concentrations of local anesthetics achieved after therapeutic doses are associated with minimal change in peripheral vascular resistance. Higher blood concentrations of local anesthetics may occur due to inadvertent intravascular administration or repeated doses.
Metformin: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Metformin; Repaglinide: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Metformin; Rosiglitazone: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Metformin; Saxagliptin: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Metformin; Sitagliptin: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Methacholine: (Moderate) Beta-blockers may impair reversal of methacholine-induced bronchoconstriction with an inhaled rapid-acting beta-agonist.
Methohexital: (Major) General anesthetics can potentiate the antihypertensive effects of beta-blockers and can produce prolonged hypotension.
Methylergonovine: (Moderate) Concurrent use of beta-blockers and ergot alkaloids should be approached with caution. Concomitant administration with beta-blockers may enhance the vasoconstrictive action of certain ergot alkaloids including dihydroergotamine, ergotamine, methylergonovine, and methysergide. The risk of peripheral ischemia, resulting in cold extremities or gangrene, has been reported to be increased when ergotamine or dihydroergotamine is coadministered with selected beta-blockers, including propranolol, a beta-blocker commonly used for migraine prophylaxis. However, the precise mechanism of these interactions remains elusive. Additionally, because of the potential to cause coronary vasospasm, these ergot alkaloids could antagonize the therapeutic effects of anti-anginal agents including beta-blockers; clinicians should keep in mind that ergot alkaloids are contraindicated for use in patients with coronary heart disease or hypertension.
Milrinone: (Moderate) Concurrent administration of antihypertensive agents could lead to additive hypotension when administered with milrinone. Titrate milrinone dosage according to hemodynamic response.
Mirabegron: (Moderate) Mirabegron is a moderate CYP2D6 inhibitor. Exposure of drugs metabolized by CYP2D6 such as timolol may be increased when co-administered with mirabegron. Therefore, appropriate monitoring and dose adjustment may be necessary.
Nefazodone: (Minor) Although relatively infrequent, nefazodone may cause orthostatic hypotension in some patients; this effect may be additive with antihypertensive agents. Blood pressure monitoring and dosage adjustments of either drug may be necessary.
Nesiritide, BNP: (Major) The potential for hypotension may be increased when coadministering nesiritide with antihypertensive agents.
Neuromuscular blockers: (Moderate) Concomitant use of neuromuscular blockers and beta-blockers may prolong neuromuscular blockade.
Niacin, Niacinamide: (Moderate) Cutaneous vasodilation induced by niacin may become problematic if high-dose niacin is used concomitantly with other antihypertensive agents. This effect is of particular concern in the setting of acute myocardial infarction, unstable angina, or other acute hemodynamic compromise.
Niacin; Simvastatin: (Moderate) Cutaneous vasodilation induced by niacin may become problematic if high-dose niacin is used concomitantly with other antihypertensive agents. This effect is of particular concern in the setting of acute myocardial infarction, unstable angina, or other acute hemodynamic compromise.
Nicardipine: (Moderate) Use nicardipine and timolol with caution due to risk for additive negative effects on heart rate, AV conduction, and/or cardiac contractility.
Nifedipine: (Moderate) In general, concomitant therapy of nifedipine with beta-blockers is well tolerated and can even be beneficial in some cases (i.e., inhibition of nifedipine-induced reflex tachycardia by beta-blockade). Negative inotropic and/or chronotropic effects can be additive when these drugs are used in combination. Finally, angina has been reported when beta-adrenergic blocking agents are withdrawn abruptly and nifedipine therapy is initiated. A gradual downward titration of the beta-adrenergic blocking agent dosage during initiation of nifedipine therapy may minimize or eliminate this potential interaction. Hypotension and impaired cardiac performance can occur during coadministration of nifedipine with beta-blockers, especially in patients with left ventricular dysfunction, cardiac arrhythmias, or aortic stenosis. Monitor clinical response during coadministration; adjustment of nifedipine dosage may be needed during concurrent beta-blocker therapy.
Nimodipine: (Moderate) Nimodipine, a selective calcium-channel blocker, can enhance the antihypertensive effects of beta-blockers. Although often used together, concurrent use of calcium-channel blockers and beta-blockers may result in additive hypotensive, negative inotropic, and/or bradycardic effects in some patients.
Nirmatrelvir; Ritonavir: (Moderate) Timolol is significantly metabolized by CYP2D6 isoenzymes. CYP2D6 inhibitors, such as ritonavir, may impair timolol metabolism; the clinical significance of such interactions is unknown.
Nisoldipine: (Moderate) Concurrent use of nisoldipine with timolol can be beneficial (i.e., inhibition of vasodilation-induced reflex tachycardia by beta-blockade); however, the additive negative inotropic and/or chronotropic effects can cause adverse effects, especially in patients with compromised ventricular function or conduction defects (e.g., sinus bradycardia or AV block).
Nitrates: (Moderate) Nitroglycerin can cause hypotension. This action may be additive with other agents that can cause hypotension such as antihypertensive agents or other peripheral vasodilators. Patients should be monitored more closely for hypotension if nitroglycerin, including nitroglycerin rectal ointment, is used concurrently with any beta-blockers.
Nitroglycerin: (Moderate) Nitroglycerin can cause hypotension. This action may be additive with other agents that can cause hypotension such as antihypertensive agents or other peripheral vasodilators. Patients should be monitored more closely for hypotension if nitroglycerin, including nitroglycerin rectal ointment, is used concurrently with any beta-blockers.
Nitroprusside: (Moderate) Additive hypotensive effects may occur when nitroprusside is used concomitantly with other antihypertensive agents. Dosages should be adjusted carefully, according to blood pressure.
Non-Ionic Contrast Media: (Moderate) Use caution when administering non-ionic contrast media to patients taking beta-blockers. Beta-blockers lower the threshold for and increase the severity of contrast reactions and reduce the responsiveness of treatment of hypersensitivity reactions with epinephrine.
Nonsteroidal antiinflammatory drugs: (Moderate) Monitor blood pressure during concomitant beta-blocker and nonsteroidal anti-inflammatory drug (NSAID) use. The antihypertensive effect of beta-blockers may be diminished by NSAIDs.
Octreotide: (Moderate) Monitor for bradycardia during concomitant use of beta-blockers and octreotide and adjust drug dosage based on response as appropriate. Both medications may cause bradycardia and concomitant use may increase bradycardia risk.
Olanzapine: (Moderate) Olanzapine may induce orthostatic hypotension and thus enhance the effects of antihypertensive agents.
Olanzapine; Fluoxetine: (Moderate) Monitor for signs of bradycardia or heart block if coadministration of timolol with fluoxetine is necessary. Concomitant use may enhance the beta-blocking properties of timolol resulting in further slowing of the heart rate or cardiac conduction. Timolol is a CYP2D6 substrate and fluoxetine is a strong CYP2D6 inhibitor. (Moderate) Olanzapine may induce orthostatic hypotension and thus enhance the effects of antihypertensive agents.
Olanzapine; Samidorphan: (Moderate) Olanzapine may induce orthostatic hypotension and thus enhance the effects of antihypertensive agents.
Olmesartan; Amlodipine; Hydrochlorothiazide, HCTZ: (Moderate) Coadministration of amlodipine and beta-blockers can reduce angina and improve exercise tolerance. When these drugs are given together, however, hypotension and impaired cardiac performance can occur, especially in patients with left ventricular dysfunction, cardiac arrhythmias, or aortic stenosis.
Oritavancin: (Moderate) Timolol is metabolized by CYP2D6; oritavancin is a weak CYP2D6 inducer. Plasma concentrations and efficacy of timolol may be reduced if these drugs are administered concurrently.
Oxymetazoline: (Major) The vasoconstricting actions of oxymetazoline, an alpha adrenergic agonist, may reduce the antihypertensive effects produced by beta-blockers. If these drugs are used together, closely monitor for changes in blood pressure.
Ozanimod: (Moderate) Ozanimod may cause bradycardia and AV-conduction delays, which may be enhanced with the concomitant use of beta-blockers. If a calcium channel blocker that slows heart rate/cardiac conduction is also prescribed with ozanimod and a beta-blocker, a cardiologist should be consulted due to the likelyhood of additive effects.
Paliperidone: (Moderate) Paliperidone may cause orthostatic hypotension, thereby enhancing the hypotensive effects of antihypertensive agents. Orthostatic vital signs should be monitored in patients receiving paliperidone and beta-adrenergic blockers who are susceptible to hypotension.
Paroxetine: (Moderate) Monitor for signs of bradycardia or heart block if coadministration of timolol with paroxetine is necessary. Concomitant use may enhance the beta-blocking properties of timolol resulting in further slowing of the heart rate or cardiac conduction. Timolol is a CYP2D6 substrate and paroxetine is a strong CYP2D6 inhibitor.
Pasireotide: (Major) Pasireotide may cause a decrease in heart rate. Closely monitor patients who are also taking drugs associated with bradycardia such as beta-blockers. Dose adjustments of beta-blockers may be necessary.
Peginterferon Alfa-2b: (Moderate) Monitor for adverse effects associated with increased exposure to timolol if peginterferon alfa-2b is coadministered. Peginterferon alfa-2b is a CYP2D6 inhibitor, while timolol is a CYP2D6 substrate.
Pentoxifylline: (Moderate) Pentoxifylline has been used concurrently with antihypertensive drugs (beta blockers, diuretics) without observed problems. Small decreases in blood pressure have been observed in some patients treated with pentoxifylline; periodic systemic blood pressure monitoring is recommended for patients receiving concomitant antihypertensives. If indicated, dosage of the antihypertensive agents should be reduced.
Perindopril; Amlodipine: (Moderate) Coadministration of amlodipine and beta-blockers can reduce angina and improve exercise tolerance. When these drugs are given together, however, hypotension and impaired cardiac performance can occur, especially in patients with left ventricular dysfunction, cardiac arrhythmias, or aortic stenosis.
Phenelzine: (Moderate) Careful monitoring of blood pressure is suggested during concurrent therapy of MAOIs with beta-blockers. Additive hypotensive effects may be seen when phenelzine is combined with antihypertensives. Limited data suggest that bradycardia is worsened when MAOIs are administered to patients receiving beta-blockers. Although the sinus bradycardia observed was not severe, until more data are available, clinicians should use MAOIs cautiously in patients receiving beta-blockers. Patients should be instructed to rise slowly from a sitting position, and to report syncope or changes in blood pressure or heart rate to their health care provider.
Phenoxybenzamine: (Moderate) Orthostatic hypotension may be more likely if beta-blockers are coadministered with alpha-blockers.
Phentolamine: (Moderate) Orthostatic hypotension may be more likely if beta-blockers are coadministered with alpha-blockers.
Pilocarpine: (Moderate) Systemically administered pilocarpine (e.g., when used for the treatment of xerostomia or xerophthalmia) should be administered with caution in patients taking beta-blockers because of the possibility of cardiac conduction disturbances. The risk of conduction disturbances with beta-blockers and ophthalmically administered pilocarpine is low.
Pioglitazone; Metformin: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Ponesimod: (Moderate) Monitor for decreases in heart rate if concomitant use of ponesimod and beta-blockers is necessary. Consider a temporary interruption in beta-blocker therapy before initiating ponesimod in patients with a resting heart rate less than or equal to 55 bpm. Beta-blocker treatment can be initiated in patients receiving stable doses of ponesimod. Concomitant use of another beta-blocker with ponesimod resulted in a mean decrease in heart rate of 12.4 bpm after the first dose of ponesimod and 7.4 bpm after beginning maintenance ponesimod.
Pramlintide: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Prazosin: (Moderate) Orthostatic hypotension may be more likely if beta-blockers are coadministered with alpha-blockers.
Prilocaine: (Moderate) Local anesthetics may cause additive hypotension in combination with antihypertensive agents.
Prilocaine; Epinephrine: (Moderate) Local anesthetics may cause additive hypotension in combination with antihypertensive agents.
Procainamide: (Major) High or toxic concentrations of procainamide may prolong AV nodal conduction time or induce AV block; these effects could be additive with the pharmacologic actions of beta-blockers, like timolol. In general, patients receiving combined therapy with procainamide and beta-blockers should be monitored for potential bradycardia, AV block, and/or hypotension.
Propafenone: (Major) Pharmacologically, beta-blockers, like timolol, cause AV nodal conduction depression and additive effects are possible when used in combination with propafenone. When used together, AV block can occur. Patients should be monitored closely and the dose should be adjusted according to clinical response.
Propofol: (Major) General anesthetics can potentiate the antihypertensive effects of beta-blockers and can produce prolonged hypotension. Beta-blockers may be continued during general anesthesia as long as the patient is monitored for cardiac depressant and hypotensive effects.
Quinidine: (Major) In general, patients receiving combined therapy with quinidine and beta-blockers should be monitored for potential hypotension, orthostasis, bradycardia and/or AV block, and heart failure. Reduce the beta-blocker dosage if necessary. Quinidine may have additive effects on cardiovascular parameters when used together with beta-blockers, such as timolol. Decreased heart rate (bradycardia) has been reported during combination timolol and quinidine therapy. Additive hypotension is also possible. Additionally, quinidine is a known inhibitor of CYP2D6, and may impair the hepatic clearance of timolol (CYP2D6 substrate). Patients should be monitored for excess beta-blockade. Quinidine has been reported to potentiate timolol-induced bradycardia even after use of ophthalmic timolol.
Quinine: (Minor) Quinine inhibits CYP2D6 and may theoretically increase concentrations of other drugs metabolized by this enzyme, including timolol.
Ranolazine: (Moderate) Timolol is metabolized by CYP2D6 isoenzymes. Ranolazine, a CYP2D6 inhibitor, could theoretically impair timolol metabolism. Lower doses of some CYP2D6 substrates than are usually prescribed may be needed during therapy with ranolazine; monitor therapeutic response during coadministration.
Rasagiline: (Moderate) Additive hypotensive effects may be seen when monoamine oxidase inhibitors (MAOIs) are combined with antihypertensives. Careful monitoring of blood pressure is suggested during concurrent therapy of MAOIs with beta-blockers. Limited data suggest that bradycardia is worsened when MAOIs are administered to patients receiving beta-blockers. Although the sinus bradycardia observed was not severe, until more data are available, clinicians should use MAOIs cautiously in patients receiving beta-blockers. Patients should be instructed to rise slowly from a sitting position, and to report syncope or changes in blood pressure or heart rate to their health care provider.
Remifentanil: (Moderate) The risk of significant hypotension and/or bradycardia during therapy with remifentanil may be increased in patients receiving beta-blockers or calcium-channel blockers due to additive hypotensive effects.
Risperidone: (Moderate) Risperidone may induce orthostatic hypotension and thus enhance the hypotensive effects of timolol. Lower initial doses or slower dose titration of risperidone may be necessary in patients receiving timolol concomitantly.
Ritonavir: (Moderate) Timolol is significantly metabolized by CYP2D6 isoenzymes. CYP2D6 inhibitors, such as ritonavir, may impair timolol metabolism; the clinical significance of such interactions is unknown.
Rivastigmine: (Moderate) The increase in vagal tone induced by some cholinesterase inhibitors may produce bradycardia, hypotension, or syncope. The vagotonic effect of these drugs may theoretically be increased when given with other medications known to cause bradycardia such as beta-blockers.
Rolapitant: (Major) Use caution if timolol and rolapitant are used concurrently, and monitor for timolol-related adverse effects. Timolol is a substrate of CYP2D6 and rolapitant is an inhibitor of CYP2D6 ; the inhibitory effect of rolapitant is expected to persist beyond 28 days for an unknown duration. Exposure to another CYP2D6 substrate, following a single dose of rolapitant increased about 3-fold on Days 8 and Day 22. The inhibition of CYP2D6 persisted on Day 28 with a 2.3-fold increase in the CYP2D6 substrate concentrations, the last time point measured.
Ropivacaine: (Moderate) Local anesthetics may cause additive hypotension in combination with antihypertensive agents.
Salsalate: (Moderate) Concurrent use of beta-blockers with salsalate and other salicylates may result in loss of antihypertensive activity due to inhibition of renal prostaglandins and thus, salt and water retention and decreased renal blood flow.
Semaglutide: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Sevoflurane: (Major) General anesthetics can potentiate the antihypertensive effects of beta-blockers and can produce prolonged hypotension. Beta-blockers may be continued during general anesthesia as long as the patient is monitored for cardiac depressant and hypotensive effects.
SGLT2 Inhibitors: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Silodosin: (Moderate) During clinical trials with silodosin, the incidence of dizziness and orthostatic hypotension was higher in patients receiving concomitant antihypertensive treatment. Thus, caution is advisable when silodosin is administered with antihypertensive agents. In addition, increased concentrations of silodosin may occur if it is coadministered with carvedilol; exercise caution. Carvedilol is a P-glycoprotein (P-gp) inhibitor and silodosin is a P-gp substrate.
Siponimod: (Moderate) Monitor for significant bradycardia with coadministration of siponimod and beta-blockers, as additive lowering effects on heart rate may occur; temporary interruption of beta-blocker treatment may be necessary prior to siponimod initiation. Beta-blocker treatment can be initiated in patients receiving stable doses of siponimod.
Sufentanil: (Moderate) The incidence and degree of bradycardia and hypotension during induction with sufentanil may be increased in patients receiving beta-blockers.
Sulfonylureas: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Sympathomimetics: (Moderate) Monitor hemodynamic parameters and for loss of efficacy during concomitant sympathomimetic agent and beta-blocker use; dosage adjustments may be necessary. Concomitant use may antagonize the cardiovascular effects of either drug.
Tamsulosin: (Minor) Tamsulosin did not potentiate the hypotensive effects of atenolol. However, since the symptoms of orthostasis are reported more frequently in tamsulosin-treated vs. placebo patients, there is a potential risk of enhanced hypotensive effects when co-administered with antihypertensive agents.
Tasimelteon: (Moderate) Advise patients to administer the beta-blocker in the morning if tasimelteon is used concomitantly. Nighttime administration of a beta-blocker may reduce the efficacy of tasimelteon by decreasing the production of melatonin via inhibition of beta1 receptors.
Telmisartan; Amlodipine: (Moderate) Coadministration of amlodipine and beta-blockers can reduce angina and improve exercise tolerance. When these drugs are given together, however, hypotension and impaired cardiac performance can occur, especially in patients with left ventricular dysfunction, cardiac arrhythmias, or aortic stenosis.
Terazosin: (Moderate) Orthostatic hypotension may be more likely if beta-blockers are coadministered with alpha-blockers.
Tetrabenazine: (Moderate) Tetrabenazine may induce orthostatic hypotension and thus enhance the hypotensive effects of antihypertensive agents. Lower initial doses or slower dose titration of tetrabenazine may be necessary in patients receiving antihypertensive agents concomitantly.
Tetracaine: (Moderate) Local anesthetics may cause additive hypotension in combination with antihypertensive agents. Use caution with the concomitant use of tetracaine and antihypertensive agents.
Thalidomide: (Moderate) Thalidomide and other agents that slow cardiac conduction such as beta-blockers should be used cautiously due to the potential for additive bradycardia.
Thiazolidinediones: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Thyroid hormones: (Minor) Because thyroid hormones cause cardiac stimulation including increased heart rate and increased contractility, the effects of beta-blockers may be reduced by thyroid hormones. The reduction of effects may be especially evident when a patient goes from a hypothyroid to a euthyroid state or when excessive amounts of thyroid hormone is given to the patient.
Tirzepatide: (Moderate) Increased frequency of blood glucose monitoring may be required when a beta blocker is given with antidiabetic agents. Since beta blockers inhibit the release of catecholamines, these medications may hide symptoms of hypoglycemia such as tremor, tachycardia, and blood pressure changes. Other symptoms, like headache, dizziness, nervousness, mood changes, or hunger are not blunted. Beta-blockers also exert complex actions on the body's ability to regulate blood glucose. Some beta-blockers, particularly non-selective beta-blockers such as propranolol, have been noted to potentiate insulin-induced hypoglycemia and a delay in recovery of blood glucose to normal levels. Hyperglycemia has been reported as well and is possibly due to beta-2 receptor blockade in the beta cells of the pancreas. A selective beta-blocker may be preferred in patients with diabetes mellitus, if appropriate for the patient's condition. Selective beta-blockers, such as atenolol or metoprolol, do not appear to potentiate insulin-induced hypoglycemia. While beta-blockers may have negative effects on glycemic control, they reduce the risk of cardiovascular disease and stroke in patients with diabetes and their use should not be avoided in patients with compelling indications for beta-blocker therapy when no other contraindications are present.
Tizanidine: (Moderate) Concurrent use of tizanidine with antihypertensive agents can result in significant hypotension. Caution is advised when tizanidine is to be used in patients receiving concurrent antihypertensive therapy.
Trandolapril; Verapamil: (Moderate) Use verapamil and timolol with caution and close monitoring due to risk for additive negative effects on heart rate, AV conduction, and/or cardiac contractility. There have been reports of excess bradycardia and AV block, including complete heart block, when beta-blockers and verapamil have been used for the treatment of hypertension.
Tranylcypromine: (Major) Avoid concomitant use of beta-blockers and tranylcypromine due to the risk of additive hypotension and/or severe bradycardia. Potential for this interaction persists for up to 10 days after discontinuation of tranylcypromine (or 4 to 5 half-lives after discontinuation of the beta-blocker). If a medication-free interval is not feasible, initiate therapy at the lowest appropriate dose and monitor blood pressure and heart rate closely.
Trazodone: (Minor) Due to additive hypotensive effects, patients receiving antihypertensive agents concurrently with trazodone may have excessive hypotension. Decreased dosage of the antihypertensive agent may be required when given with trazodone.
Vemurafenib: (Moderate) Concomitant use of vemurafenib and timolol may result in increased timolol concentrations. Vemurafenib is a weak CYP2D6 inhibitor and timolol is a CYP2D6 substrate. Patients should be monitored for toxicity.
Verapamil: (Moderate) Use verapamil and timolol with caution and close monitoring due to risk for additive negative effects on heart rate, AV conduction, and/or cardiac contractility. There have been reports of excess bradycardia and AV block, including complete heart block, when beta-blockers and verapamil have been used for the treatment of hypertension.
Viloxazine: (Moderate) Monitor for increased timolol-related adverse reactions, including bradycardia and hypotension, during coadministration with viloxazine. Concomitant use may increase timolol exposure. Timolol is a CYP2D6 substrate and viloxazine is a weak CYP2D6 inhibitor.
Ziprasidone: (Minor) Ziprasidone is a moderate antagonist of alpha-1 receptors and may cause orthostatic hypotension with or without tachycardia, dizziness, or syncope. Additive hypotensive effects are possible if ziprasidone is used concurrently with antihypertensive agents.

re present.
Tizanidine: (Moderate) Concurrent use of tizanidine with antihypertensive agents can result in significant hypotension. Caution is advised when tizanidine is to be used in patients receiving concurrent antihypertensive therapy.
Trandolapril; Verapamil: (Moderate) Use verapamil and timolol with caution and close monitoring due to risk for additive negative effects on heart rate, AV conduction, and/or cardiac contractility. There have been reports of excess bradycardia and AV block, including complete heart block, when beta-blockers and verapamil have been used for the treatment of hypertension.
Tranylcypromine: (Major) Avoid concomitant use of beta-blockers and tranylcypromine due to the risk of additive hypotension and/or severe bradycardia. Potential for this interaction persists for up to 10 days after discontinuation of tranylcypromine (or 4 to 5 half-lives after discontinuation of the beta-blocker). If a medication-free interval is not feasible, initiate therapy at the lowest appropriate dose and monitor blood pressure and heart rate closely.
Trazodone: (Minor) Due to additive hypotensive effects, patients receiving antihypertensive agents concurrently with trazodone may have excessive hypotension. Decreased dosage of the antihypertensive agent may be required when given with trazodone.
Vemurafenib: (Moderate) Concomitant use of vemurafenib and timolol may result in increased timolol concentrations. Vemurafenib is a weak CYP2D6 inhibitor and timolol is a CYP2D6 substrate. Patients should be monitored for toxicity.
Verapamil: (Moderate) Use verapamil and timolol with caution and close monitoring due to risk for additive negative effects on heart rate, AV conduction, and/or cardiac contractility. There have been reports of excess bradycardia and AV block, including complete heart block, when beta-blockers and verapamil have been used for the treatment of hypertension.
Viloxazine: (Moderate) Monitor for increased timolol-related adverse reactions, including bradycardia and hypotension, during coadministration with viloxazine. Concomitant use may increase timolol exposure. Timolol is a CYP2D6 substrate and viloxazine is a weak CYP2D6 inhibitor.
Ziprasidone: (Minor) Ziprasidone is a moderate antagonist of alpha-1 receptors and may cause orthostatic hypotension with or without tachycardia, dizziness, or syncope. Additive hypotensive effects are possible if ziprasidone is used concurrently with antihypertensive agents.

How Supplied

Betimol/Istalol/Timolol Hemihydrate/Timolol Maleate/Timoptic/Timoptic Ocudose/Timoptic Ocumeter Ophthalmic Sol: 0.25%, 0.5%
Blocadren/Timolol Maleate Oral Tab: 5mg, 10mg, 20mg
Timolol Maleate/Timoptic-XE Ophthalmic Sol GF ER: 0.25%, 0.5%

Maximum Dosage
Adults

60 mg/day PO for hypertension or angina; 30 mg/day PO for migraine prophylaxis; 20 mg/day PO for postmyocardial infarction or myocardial infarction prophylaxis; 1 drop per eye twice daily of Timoptic or Betimol 0.5% ophthalmic solution; 1 drop per eye per day of Timoptic-XE 0.5% gel forming ophthalmic solution or Istalol ophthalmic solution.

Geriatric

60 mg/day PO for hypertension or angina; 30 mg/day PO for migraine prophylaxis; 20 mg/day PO for postmyocardial infarction or myocardial infarction prophylaxis; 1 drop per eye twice daily of Timoptic or Betimol 0.5% ophthalmic solution; 1 drop per eye per day of Timoptic-XE 0.5% gel forming ophthalmic solution or Istalol ophthalmic solution.

Adolescents

1 drop per eye twice daily of Timoptic (timolol maleate) 0.5% ophthalmic solution; 1 drop per eye per day of Timoptic-XE (timolol maleate) 0.5% gel forming ophthalmic solution; safety and efficacy of other ophthalmic formulations and the oral formulation have not been established.

Children

Children 2 years and older: 1 drop per eye twice daily of Timoptic (timolol maleate) 0.5% ophthalmic solution; 1 drop per eye per day of Timoptic-XE (timolol maleate) 0.5% gel forming ophthalmic solution; safety and efficacy of other ophthalmic formulations and the oral formulation have not been established.
Children 1 year: Safety and efficacy have not been established.

Infants

Safety and efficacy have not been established.

Neonates

Safety and efficacy have not been established.

Mechanism Of Action

Mechanism of Action: Like other beta-adrenergic antagonists, timolol competes with adrenergic neurotransmitters (e.g., catecholamines) for binding at sympathetic receptor sites. Similar to propranolol and nadolol, timolol blocks sympathetic stimulation mediated by beta1-adrenergic receptors in the heart and vascular smooth muscle, and beta2-receptors in the bronchial and vascular smooth muscle. Pharmacodynamic consequences of beta1-receptor blockade include a decrease in both resting and exercise heart rate and cardiac output; a decrease in both systolic and diastolic blood pressure; and, possibly, a reduction in reflex orthostatic hypotension. The fall in cardiac output induced by beta1 effects is often countered by a moderate reflex increase in peripheral vascular resistance that can be magnified by timolol's beta2-blockade (unmasked alpha stimulation). As a result, nonselective beta-blocking agents can produce a more modest decrease in (diastolic) blood pressure compared with selective beta1-antagonists.Actions that make timolol useful in treating hypertension include a decrease in heart rate at rest and after exercise (negative chronotropic effect); a decrease in cardiac output (negative inotropic effect); reduction of sympathetic outflow from the CNS; and suppression of renin release from the kidneys. Thus, like other beta-blockers, timolol affects blood pressure via multiple mechanisms. In general, beta-blockers without intrinsic sympathomimetic activity (ISA) exert detrimental effects on LVH and the lipid profile, and cause sexual dysfunction.Timolol possesses numerous mechanisms that may contribute to its efficacy in preventing migraine headaches. Beta-blockade can prevent arterial dilation, inhibit renin secretion, and block catecholamine-induced lipolysis. Blocking lipolysis, decreases arachidonic acid synthesis and subsequent prostaglandin production. Inhibition of platelet aggregation is due to this decrease in prostaglandins and blockade of catecholamine-induced platelet adhesion. Other actions include increased oxygen delivery to tissues and prevention of coagulation during epinephrine release.Timolol has been used in the management of hereditary or familial essential tremor. Beta-blockade controls the involuntary, rhythmic and oscillatory movements of essential tremor. Tremor amplitude is reduced, but not the frequency of tremor.Reduction of elevated or normal intraocular pressure occurs irrespective of the presence of glaucoma. This effect is believed to be caused by a reduced production of aqueous humor, although the exact mechanism has not been elucidated. Visual acuity, pupil size, and accommodation do not appear to be affected by timolol.

Pharmacokinetics

Timolol is administered via the oral and ophthalmic routes. Binding to plasma proteins is minimal (10%). The drug is relatively lipophilic, but less than propranolol, and is distributed into breast milk. Timolol is as substrate of CYP2D6 and is extensively metabolized to inactive metabolites. Both the parent drug (15%) and metabolites are excreted in the urine. Plasma half-life is about 4 hours, which is largely unchanged by renal insufficiency. Timolol is removed by hemodialysis when tested in vitro; however, a study of patients with renal failure has shown that it does not dialyze readily.
 
Affected cytochrome P450 isoenzymes and drug transporters: CYP2D6

Oral Route

Following oral administration, timolol is rapidly and completely absorbed. There appears, however, to be considerable individual patient variation in the amount of drug reaching the systemic circulation, owing to extensive first-pass metabolism. Bioavailability is approximately 50%. After oral administration, the onset of activity is 30 minutes, with peak plasma concentrations achieved within 1—2 hours and a dose-dependent duration of activity of 12—24 hours. Food has no effect on the absorption characteristics of timolol.

Other Route(s)

Ophthalmic Route
Some systemic absorption may occur following ophthalmic administration, but data are limited. Similar to the characteristics of oral timolol, ophthalmic timolol reduces intraocular pressure within roughly 30 minutes following application, peaks 1—2 hours later, and can last 24 hours.

Pregnancy And Lactation
Pregnancy

There are no adequate and well-controlled human studies evaluating use of timolol during pregnancy. According to the manufacturer, the drug should be used during pregnancy only if the potential benefit justifies the potential risk to the fetus.

According to the manufacturer, neither oral nor ophthalmic timolol should be used during breast-feeding. The American Academy of Pediatrics (AAP) regards timolol as usually compatible with breast-feeding. Timolol has been detected in breast milk after oral administration. In 9 women taking timolol 5 mg PO three times daily, the mean milk timolol concentration was 15.9 ng/ml. The mean milk timolol concentration was 41 ng/ml in 4 women taking timolol 10 mg PO three times daily. Milk:plasma ratios for the two dosage regimens were 0.8 and 0.83, respectively. Propranolol, labetalol, and metoprolol are also regarded as usually compatible with breast-feeding by the AAP and may represent reasonable alternatives to timolol. Timolol has been detected in breast-milk after ophthalmic administration, however, the amount is reported to be below that expected to produce clinically significant effects in a nursing infant. To further minimize the amount of drug that reaches the systemic circulation and breast milk, after ophthalmic administration, apply pressure over the tear duct by the corner of the eye for 1 minute. If oral or ophthalmic timolol is administered during breast-feeding, close observation for cardiac effects in the nursing infant is recommended. Consider the benefits of breast-feeding, the risk of potential infant drug exposure, and the risk of an untreated or inadequately treated condition. If a breast-feeding infant experiences an adverse effect related to a maternally ingested drug, healthcare providers are encouraged to report the adverse effect to the FDA.