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Bisoprolol: Drug information

Bisoprolol: Drug information
(For additional information see "Bisoprolol: Patient drug information")

For abbreviations, symbols, and age group definitions used in Lexicomp (show table)
Brand Names: Canada
  • AG-Bisoprolol;
  • APO-Bisoprolol;
  • JAMP-Bisoprolol;
  • MINT-Bisoprolol;
  • PMS-Bisoprolol;
  • PRO-Bisoprolol-10;
  • PRO-Bisoprolol-5;
  • RIVA-Bisoprolol [DSC];
  • SANDOZ Bisoprolol;
  • TEVA-Bisoprolol
Pharmacologic Category
  • Antihypertensive;
  • Beta-Blocker, Beta-1 Selective
Dosing: Adult
Angina

Angina (off-label use):

Note: For vasospastic angina, beta-blockers are not recommended; calcium channel blockers and nitrates are preferred. For nonvasospastic angina, guidelines recommend titrating dose to a resting heart rate of 55 to 60 beats per minute (ACCF/AHA [Fihn 2012]).

Oral: Initial: 5 to 10 mg once daily; may increase dose after ≥1 week to achieve the desired effect to a maximum dose of 20 mg once daily (de Muinck 1992; Maisch 1989; von Arnim 1995).

Atrial fibrillation/flutter, maintenance of ventricular rate control

Atrial fibrillation/flutter, maintenance of ventricular rate control (off-label use):

Note: Initiate cautiously in patients with concomitant heart failure. Avoid initiating or up-titrating therapy in patients with decompensated heart failure; for unstable patients, electrical cardioversion is preferred (AHA/ACC/HRS [January 2014]; AHA [Panchal 2020]).

Oral: Initial: 2.5 to 5 mg once daily; increase dose gradually as tolerated to achieve ventricular rate control up to 20 mg once daily (AHA/ACC/HRS [January 2014]; ESC [Hindricks 2020]; Muresan 2022).

Heart failure with reduced ejection fraction

Heart failure with reduced ejection fraction (off-label use):

Note: Initiate only in stable, euvolemic patients. In hospitalized patients, volume status should be optimized and IV diuretics, IV vasodilators, and IV inotropic agents successfully discontinued prior to initiation of therapy. Use caution when initiating in patients with NYHA class IV symptoms or recent heart failure exacerbation (particularly if inotropes were required during hospital course) (AHA/ACC/HFSA [Heidenreich 2022]).

Oral: Initial: 1.25 mg once daily; up-titrate gradually (eg, doubling the dose every ≥1 to 2 weeks) to a target dose of 10 mg once daily while monitoring for signs and symptoms of heart failure (AHA/ACC/HFSA [Heidenreich 2022]; CIBIS-II Investigators and Committees 1999). Note: A dose of 1.25 mg requires splitting a round 5 mg tablet into quarters in the United States and Canada, which may result in inaccurate dosing. Smaller tablet strengths are available in other countries.

Hypertension

Hypertension (alternative agent):

Note: Not recommended in the absence of specific comorbidities (eg, ischemic heart disease, heart failure with reduced ejection fraction, arrhythmia) (ACC/AHA [Whelton 2018]).

Oral: Initial: 2.5 to 5 mg once daily; titrate at weekly (or longer) intervals as needed based on patient response; usual dosage range: 2.5 to 10 mg once daily; maximum dose: 20 mg/day (ACC/AHA [Whelton 2018]).

Ventricular arrhythmias

Ventricular arrhythmias (off- label use):

Oral: Initial: 2.5 mg once daily; titrate dose as needed based on response and tolerability up to a maximum dose of 10 mg once daily (AHA/ACC/HRS [Al-Khatib 2017]).

Dosage adjustment for concomitant therapy: Significant drug interactions exist, requiring dose/frequency adjustment or avoidance. Consult drug interactions database for more information.

Dosing: Kidney Impairment: Adult

The renal dosing recommendations are based upon the best available evidence and clinical expertise. Senior Editorial Team: Bruce Mueller, PharmD, FCCP, FASN, FNKF; Jason A. Roberts, PhD, BPharm (Hons), B App Sc, FSHP, FISAC; Michael Heung, MD, MS.

Note: Bisoprolol has renal and hepatic clearance; total clearance in patients with severe kidney dysfunction (eg, CrCl <20 mL/minute/1.73 m2) is decreased ~50% compared to those with normal kidney function (Grevel 1989; Kirch 1987; Payton 1987).

Altered kidney function:

CrCl ≥20 mL/minute/1.73 m2: No dosage adjustment necessary (Kirch 1987; Payton 1987).

CrCl <20 mL/minute/1.73 m2: Start with low initial doses (eg, 1.25 to 2.5 mg daily, depending on indication); consider a reduced maximum dose of 10 mg daily (Kirch 1987; Payton 1987; expert opinion).

Hemodialysis, intermittent (thrice weekly): Moderately dialyzable (25% to 35%) (Kanegae 1999): Initial: 1.25 to 2.5 mg daily, depending on indication; consider a reduced maximum dose of 10 mg daily (Payton 1987; expert opinion). When scheduled dose falls on a hemodialysis day, administer dose after hemodialysis (expert opinion).

Peritoneal dialysis: Slightly dialyzable (Payton 1987): Initial 1.25 to 2.5 mg daily, depending on indication; consider a reduced maximum dose of 10 mg daily (Payton 1987; expert opinion).

CRRT: Initial 1.25 to 2.5 mg daily, depending on indication; consider a reduced maximum dose of 10 mg daily (expert opinion).

PIRRT (eg, sustained, low-efficiency diafiltration): Initial 1.25 to 2.5 mg daily, depending on indication; consider a reduced maximum dose of 10 mg daily (expert opinion).

Dosing: Hepatic Impairment: Adult

Hepatitis or cirrhosis: Initial: 2.5 mg once daily; increase cautiously.

Dosing: Older Adult

Refer to adult dosing.

Dosage Forms: US

Excipient information presented when available (limited, particularly for generics); consult specific product labeling.

Tablet, Oral, as fumarate:

Generic: 5 mg, 10 mg

Generic Equivalent Available: US

Yes

Dosage Forms: Canada

Excipient information presented when available (limited, particularly for generics); consult specific product labeling.

Tablet, Oral, as fumarate:

Generic: 5 mg, 10 mg

Administration: Adult

Oral: May be administered without regard to meals. The smallest tablet size available in the United States and Canada is 5 mg. A dose of 1.25 mg for heart failure with reduced ejection fraction would require splitting a round tablet into quarters.

Use: Labeled Indications

Hypertension: Management of hypertension. Note: Beta-blockers are not recommended as first-line therapy (ACC/AHA [Whelton 2018]).

Use: Off-Label: Adult

Angina; Atrial fibrillation/flutter, maintenance of ventricular rate control; Heart failure with reduced ejection fraction; Ventricular arrhythmias

Medication Safety Issues
Sound-alike/look-alike issues:

Zebeta may be confused with DiaBeta, Zetia

Adverse Reactions (Significant): Considerations
Bradyarrhythmias

Beta-blockers may cause first degree atrioventricular (AV) block, second degree atrioventricular block, or complete atrioventricular block (Ref). At maintenance dosing, second- or third-degree AV block are less likely (Ref). Beta-blocking agents with intrinsic sympathomimetic activity (eg, pindolol) may cause fewer AV conduction abnormalities than those without intrinsic sympathomimetic activity (eg, bisoprolol) due to their partial agonist effects (Ref). In most cases (up to 72%), AV block associated with a beta-blocker will resolve upon discontinuation; however, there are reported cases of recurrent AV block and nearly 50% of patients with more severe AV block may require a permanent pacemaker (Ref).

Mechanism: Dose-related; related to the pharmacologic action. Blockade of cardiac beta-1 adrenergic receptors results in slowed conduction and prolongation in the refractory period of the AV node. Slowing of AV conduction can lead to AV block (Ref).

Onset: Varied; one study included patients who were on beta-blocker for more than one month (Ref); however, other studies noted prolongation of the PR interval or AV nodal refractory period occurring anywhere from one dose to several days following treatment initiation (Ref).

Risk factors:

• Impaired AV node or sinus node dysfunction (Ref)

• Concurrent use of other agents that impair AV nodal conduction (eg, nondihydropyridine calcium channel blockers, digoxin, ivabradine, select antiarrhythmic agents) (Ref)

• Older patients (Ref)

Bronchospasm

Selective beta-blockers (eg, bisoprolol) have a lower risk of bronchospasm compared to noncardioselective beta-blockers (Ref). Specifically, patients with moderate to severe asthma or COPD have a higher risk of symptoms or exacerbation leading to hospitalization even with selective beta-blocker use (Ref). Concurrent use of inhaled bronchodilators and/or corticosteroids are protective against beta-blocker-induced bronchospasm in patients with COPD or asthma (Ref). Bronchospasm is reversible upon discontinuation or use of bronchodilators (Ref).

Mechanism: Dose-related; related to pharmacologic action. Beta-blocking agents can lead to airway smooth muscle constriction by antagonism of beta-2 receptors (Ref).

Onset: Rapid; reports suggest that single doses or acute use are more likely to cause changes in FEV1 compared to chronic use (Ref)

Risk factors:

• Acute use (Ref)

CNS effects

Beta-blockers may cause reversible CNS effects such as fatigue, insomnia, vivid dreams, memory impairment, and sexual disorder (Ref). Sexual disorders may occur; however, patients who require beta-blocker therapy have risk factors for erectile dysfunction (eg, coronary artery disease, heart failure) (Ref). In addition, there may be a psychosomatic component (Ref). Lipophilic beta-blockers (such as bisoprolol, which is moderately lipophilic) penetrate the blood-brain barrier to a greater extent than hydrophilic beta-blockers, possibly leading to a greater incidence of CNS effects; however, other studies have refuted this theory (Ref). CNS effects generally resolve with dose reduction or discontinuation (Ref).

Mechanism: Dose-related; exact mechanism is not fully understood. Proposed mechanisms include presence of beta receptors in the brain, affinity and in some instances, inhibition of beta-blocking agents towards serotonin (5-HT) receptors in the brain (affecting mood and sleep), and beta-blocker-induced decreases in central sympathetic output (Ref). Beta-1 blockade may also impact sleep by blocking sympathetic signaling to the pineal gland, resulting in suppression of nighttime levels of melatonin (Ref). Beta-blockers may cause erectile dysfunction through decreased sympathetic nervous system output and subsequent decreases in luteinizing hormone secretion and testosterone stimulation (Ref).

Onset: Intermediate; CNS effects often occur within the first few weeks of treatment (Ref).

Risk factors:

• Higher starting doses (Ref)

• Older patients (Ref)

Potentiation/masking of hypoglycemia

Beta-blockers may worsen, prolong, or cause hypoglycemia (Ref). Additionally, beta-blockers may mask symptoms of hypoglycemia (tremor, irritability, palpitations), making diaphoresis the only symptom unaffected by beta-blockers (Ref). It is unclear if nonselective or selective beta-blockers are more likely to cause hypoglycemia as data are conflicting. One study suggests bisoprolol has no effect on blood glucose (Ref).

Mechanism: Dose-related; related to the pharmacologic action. Beta-blockers inhibit hepatic gluconeogenesis and glycogenolysis (Ref). Beta-blockers also reduce activation of the sympathetic nervous system; therefore, masking hypoglycemic symptoms that are catecholamine-mediated (Ref).

Onset: Varied. Data are limited for bisoprolol; suggested that bisoprolol does not affect blood glucose (Ref). Onset is extrapolated from other beta-blocking agents. Blood glucose recovery was significantly reduced following one dose or one day of therapy (Ref). In another study, episodes of severe hypoglycemia were reported over the course of 4 years (Ref).

Risk factors:

• Insulin-dependent diabetes (Ref)

• Type 2 diabetes mellitus (Ref)

• Hospitalized patients not requiring basal insulin (Ref)

Withdrawal

Beta-blocker therapy should not be withdrawn abruptly, but gradually tapered to avoid acute tachycardia, hypertension, and/or ischemia in patients with underlying cardiovascular disease (Ref). Some studies have found an increase in propensity-adjusted mortality and cardiovascular events; however, one study did not find changes in infarct size and left ventricular function when beta-blocker was abruptly withdrawn in patients with myocardial infarction (Ref).

Mechanism: Dose-dependent; related to the pharmacologic action. Beta blockade causes upregulation of beta-receptors, enhanced receptor sensitivity, and decreased sympathetic nervous system response (Ref). Abrupt withdrawal leads to a transient sympathetic hyper-response (Ref). Another proposed mechanism involves increased platelet aggregability to epinephrine and thrombin (Ref).

Onset: Rapid/varied and transient; increases in heart rate and blood pressure appear 24 hours after abrupt withdrawal, peak after 48 hours, and subside after 7 days (Ref). Anginal symptoms reported to begin 12 to 24 hours after discontinuation (Ref). Development of adverse reactions also reported to occur 1 to 21 days after withdrawal (Ref).

Risk factors:

• Abrupt withdrawal in chronic users (Ref)

• Past medical history of coronary artery disease (including chronic stable angina) (Ref)

• Past medical history of hypertension (Ref)

Adverse Reactions

The following adverse drug reactions and incidences are derived from product labeling unless otherwise specified.

1% to 10%:

Cardiovascular: Chest pain (1%)

Gastrointestinal: Diarrhea (3%), vomiting (1%)

Nervous system: Fatigue (7%) (table 1), hypoesthesia (1%)

Bisoprolol: Adverse Reaction: Fatigue

Drug (Bisoprolol)

Placebo

Dose

Number of Patients (Bisoprolol)

Number of Patients (Placebo)

7%

2%

5 mg to 20 mg

273

132

Respiratory: Dyspnea (1%), upper respiratory tract infection (5%)

<1%:

Cardiovascular: Bradycardia

Neuromuscular & skeletal: Asthenia

Frequency not defined:

Cardiovascular: Cardiac arrhythmia, claudication, cold extremity, edema, flushing, heart failure, hypotension, orthostatic hypotension, palpitations

Dermatologic: Alopecia, diaphoresis, eczema, pruritus, purpuric rash, skin irritation, skin rash

Endocrine & metabolic: Decreased libido, increased serum glucose, increased serum phosphate, increased serum potassium, increased serum triglycerides, increased uric acid, weight gain

Gastrointestinal: Abdominal pain, constipation, dysgeusia, dyspepsia, epigastric pain, gastritis, nausea, peptic ulcer, stomach pain, xerostomia

Genitourinary: Cystitis, sexual disorder

Hematologic & oncologic: Decreased white blood cell count, positive ANA titer, thrombocytopenia

Hepatic: Increased serum alanine aminotransferase, increased serum aspartate aminotransferase

Hypersensitivity: Hypersensitivity angiitis

Nervous system: Anxiety, depression, dizziness, drowsiness, headache, hyperesthesia, lack of concentration, malaise, memory impairment, paresthesia, restlessness, tremor, twitching, vertigo, vivid dream

Neuromuscular & skeletal: Back pain, gout, muscle cramps, myalgia, neck pain

Ophthalmic: Abnormal lacrimation, eye pain, sensation of eye pressure, visual disturbance

Otic: Otalgia, tinnitus

Renal: Increased blood urea nitrogen, increased serum creatinine, polyuria, renal colic

Respiratory: Asthma, bronchitis, bronchospasm, cough, dyspnea on exertion, pharyngitis, rhinitis, sinusitis

Postmarketing:

Cardiovascular: Complete atrioventricular block (Zeltser 2004), first-degree atrioventricular block (Zeltser 2004), second-degree atrioventricular block (Zeltser 2004), syncope

Dermatologic: Dermatitis, exacerbation of psoriasis (Waqar 2009), exfoliative dermatitis

Genitourinary: Peyronie disease

Hypersensitivity: Angioedema

Nervous system: Insomnia (Chang 2013), sleep disturbance, unsteadiness

Neuromuscular & skeletal: Arthralgia

Otic: Auditory impairment

Contraindications

Cardiogenic shock; overt cardiac failure; marked sinus bradycardia or heart block greater than first-degree (except in patients with a functioning artificial pacemaker).

Canadian labeling: Additional contraindications (not in US labeling): Hypersensitivity to bisoprolol or any component of the formulation; overt cardiac failure requiring IV inotropic therapy; sick sinus syndrome or sinoatrial block; hypotension (systolic BP <100 mm Hg); severe bronchial asthma or chronic obstructive pulmonary disease; peripheral arterial occlusive disease (late stages); Raynaud syndrome; pheochromocytoma (untreated); metabolic acidosis.

Documentation of allergenic cross-reactivity for beta-blockers is limited. However, because of similarities in chemical structure and/or pharmacologic actions, the possibility of cross-sensitivity cannot be ruled out with certainty.

Warnings/Precautions

Disease-related concerns:

• Anaphylaxis reactions: Beta-blockers are unlikely to cause anaphylaxis; however, in susceptible patients, beta-blockers have been associated with an increase in the severity of anaphylaxis. Anaphylaxis in the presence of a beta-blocker may be severe, protracted, and resistant to conventional treatment (Lang 2008; Toogood 1987). This is due to beta-2-adrenergic blockade and the resulting diminution of endogenous catecholamine effect.

• Heart failure with reduced ejection fraction: Stabilize patients on heart failure regimen prior to initiation or titration of beta-blocker. Beta-blocker therapy should be initiated at very low doses with gradual and careful titration. Worsening heart failure or fluid retention may occur during upward titration; dose reduction and/or slower titration may be necessary. Adjustment of other medications (ACE inhibitors and/or diuretics) may be required.

• Hepatic impairment: Use with caution in patients with hepatic impairment; dosage adjustment may be required.

• Kidney impairment: Use with caution in patients with kidney impairment; dosage adjustment may be required.

• Myasthenia gravis: Use with caution in patients with myasthenia gravis.

• Peripheral vascular disease (PVD) and Raynaud disease: Can precipitate or aggravate symptoms of arterial insufficiency in patients with PVD and Raynaud disease. Use with caution and monitor for progression of arterial obstruction.

• Pheochromocytoma (untreated): Adequate alpha-blockade is required prior to use of any beta-blocker.

• Psoriasis: Beta-blocker use has been associated with induction or exacerbation of psoriasis, but cause and effect have not been firmly established.

• Thyroid disease: May mask signs of hyperthyroidism (eg, tachycardia). If hyperthyroidism is suspected, carefully manage and monitor; abrupt withdrawal may precipitate thyroid storm.

• Vasospastic angina: Beta-blockers without alpha1-adrenergic receptor blocking activity should be avoided in patients with vasospastic angina since unopposed alpha1-adrenergic receptors mediate coronary vasoconstriction and can worsen anginal symptoms (Mayer 1998).

Special populations:

• Older adult: Dosage reductions may be necessary.

Other warnings/precautions:

• Abrupt withdrawal: Beta-blocker therapy should not be withdrawn abruptly (particularly in patients with CAD), but gradually tapered to avoid acute tachycardia, hypertension, and/or ischemia.

• Major surgery: Chronic beta-blocker therapy should not be routinely withdrawn prior to major surgery.

Metabolism/Transport Effects

Substrate of CYP2D6 (minor), CYP3A4 (minor); Note: Assignment of Major/Minor substrate status based on clinically relevant drug interaction potential

Drug Interactions

Note: Interacting drugs may not be individually listed below if they are part of a group interaction (eg, individual drugs within “CYP3A4 Inducers [Strong]” are NOT listed). For a complete list of drug interactions by individual drug name and detailed management recommendations, use the Lexicomp drug interactions program by clicking on the “Launch drug interactions program” link above.

Acetylcholinesterase Inhibitors: May enhance the bradycardic effect of Beta-Blockers. Risk C: Monitor therapy

Alfuzosin: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

Alpha1-Blockers: Beta-Blockers may enhance the orthostatic hypotensive effect of Alpha1-Blockers. The risk associated with ophthalmic products is probably less than systemic products. Risk C: Monitor therapy

Alpha2-Agonists: May enhance the AV-blocking effect of Beta-Blockers. Sinus node dysfunction may also be enhanced. Beta-Blockers may enhance the rebound hypertensive effect of Alpha2-Agonists. This effect can occur when the Alpha2-Agonist is abruptly withdrawn. Management: Closely monitor heart rate during treatment with a beta blocker and clonidine. Withdraw beta blockers several days before clonidine withdrawal when possible, and monitor blood pressure closely. Recommendations for other alpha2-agonists are unavailable. Risk D: Consider therapy modification

Amifostine: Blood Pressure Lowering Agents may enhance the hypotensive effect of Amifostine. Management: When used at chemotherapy doses, hold blood pressure lowering medications for 24 hours before amifostine administration. If blood pressure lowering therapy cannot be held, do not administer amifostine. Use caution with radiotherapy doses of amifostine. Risk D: Consider therapy modification

Amiodarone: May enhance the bradycardic effect of Beta-Blockers. Possibly to the point of cardiac arrest. Amiodarone may increase the serum concentration of Beta-Blockers. Risk C: Monitor therapy

Amphetamines: May diminish the antihypertensive effect of Antihypertensive Agents. Risk C: Monitor therapy

Antidiabetic Agents: Beta-Blockers (Beta1 Selective) may enhance the hypoglycemic effect of Antidiabetic Agents. Risk C: Monitor therapy

Antipsychotic Agents (Phenothiazines): May enhance the hypotensive effect of Beta-Blockers. Beta-Blockers may decrease the metabolism of Antipsychotic Agents (Phenothiazines). Antipsychotic Agents (Phenothiazines) may decrease the metabolism of Beta-Blockers. Risk C: Monitor therapy

Antipsychotic Agents (Second Generation [Atypical]): Blood Pressure Lowering Agents may enhance the hypotensive effect of Antipsychotic Agents (Second Generation [Atypical]). Risk C: Monitor therapy

Barbiturates: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

Benperidol: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

Beta2-Agonists: Beta-Blockers (Beta1 Selective) may diminish the bronchodilatory effect of Beta2-Agonists. Of particular concern with nonselective beta-blockers or higher doses of the beta1 selective beta-blockers. Risk C: Monitor therapy

Bradycardia-Causing Agents: May enhance the bradycardic effect of other Bradycardia-Causing Agents. Risk C: Monitor therapy

Brigatinib: May diminish the antihypertensive effect of Antihypertensive Agents. Brigatinib may enhance the bradycardic effect of Antihypertensive Agents. Risk C: Monitor therapy

Brimonidine (Topical): May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

Bromperidol: May diminish the hypotensive effect of Blood Pressure Lowering Agents. Blood Pressure Lowering Agents may enhance the hypotensive effect of Bromperidol. Risk X: Avoid combination

Bupivacaine: Beta-Blockers may increase the serum concentration of Bupivacaine. Risk C: Monitor therapy

Cannabis: Beta-Blockers may enhance the adverse/toxic effect of Cannabis. Specifically, the risk of hypoglycemia may be increased. Risk C: Monitor therapy

Ceritinib: Bradycardia-Causing Agents may enhance the bradycardic effect of Ceritinib. Management: If this combination cannot be avoided, monitor patients for evidence of symptomatic bradycardia, and closely monitor blood pressure and heart rate during therapy. Risk D: Consider therapy modification

Cholinergic Agonists: Beta-Blockers may enhance the adverse/toxic effect of Cholinergic Agonists. Of particular concern are the potential for cardiac conduction abnormalities and bronchoconstriction. Risk C: Monitor therapy

CYP3A4 Inducers (Strong): May decrease the serum concentration of Bisoprolol. Risk C: Monitor therapy

Dabigatran Etexilate: Bisoprolol may increase the serum concentration of Dabigatran Etexilate. Risk C: Monitor therapy

Dexmethylphenidate: May diminish the therapeutic effect of Antihypertensive Agents. Risk C: Monitor therapy

Diazoxide: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

Dipyridamole: May enhance the bradycardic effect of Beta-Blockers. Risk C: Monitor therapy

Disopyramide: May enhance the bradycardic effect of Beta-Blockers. Beta-Blockers may enhance the negative inotropic effect of Disopyramide. Risk C: Monitor therapy

DOBUTamine: Beta-Blockers may diminish the therapeutic effect of DOBUTamine. Risk C: Monitor therapy

Dronedarone: May enhance the bradycardic effect of Beta-Blockers. Dronedarone may increase the serum concentration of Beta-Blockers. This likely applies only to those agents that are metabolized by CYP2D6. Management: Use lower initial beta-blocker doses; adequate tolerance of the combination, based on ECG findings, should be confirmed prior to any increase in beta-blocker dose. Increase monitoring for clinical response and adverse effects. Risk D: Consider therapy modification

DULoxetine: Blood Pressure Lowering Agents may enhance the hypotensive effect of DULoxetine. Risk C: Monitor therapy

EPHEDrine (Systemic): Beta-Blockers may diminish the therapeutic effect of EPHEDrine (Systemic). Risk C: Monitor therapy

EPINEPHrine (Nasal): Beta-Blockers (Beta1 Selective) may diminish the therapeutic effect of EPINEPHrine (Nasal). Risk C: Monitor therapy

EPINEPHrine (Oral Inhalation): Beta-Blockers (Beta1 Selective) may diminish the therapeutic effect of EPINEPHrine (Oral Inhalation). Risk C: Monitor therapy

Epinephrine (Racemic): Beta-Blockers (Beta1 Selective) may diminish the therapeutic effect of Epinephrine (Racemic). Risk C: Monitor therapy

EPINEPHrine (Systemic): Beta-Blockers (Beta1 Selective) may diminish the therapeutic effect of EPINEPHrine (Systemic). Risk C: Monitor therapy

Ergot Derivatives (Vasoconstrictive CYP3A4 Substrates): Beta-Blockers may enhance the vasoconstricting effect of Ergot Derivatives (Vasoconstrictive CYP3A4 Substrates). Risk C: Monitor therapy

Etilefrine: May enhance the bradycardic effect of Beta-Blockers. Beta-Blockers may diminish the therapeutic effect of Etilefrine. Risk C: Monitor therapy

Etofylline: Beta-Blockers may diminish the therapeutic effect of Etofylline. Risk X: Avoid combination

Fexinidazole: Bradycardia-Causing Agents may enhance the arrhythmogenic effect of Fexinidazole. Risk X: Avoid combination

Fingolimod: Bradycardia-Causing Agents may enhance the bradycardic effect of Fingolimod. Management: Consult with the prescriber of any bradycardia-causing agent to see if the agent could be switched to an agent that does not cause bradycardia prior to initiating fingolimod. If combined, perform continuous ECG monitoring after the first fingolimod dose. Risk D: Consider therapy modification

Flunarizine: May enhance the therapeutic effect of Antihypertensive Agents. Risk C: Monitor therapy

Grass Pollen Allergen Extract (5 Grass Extract): Beta-Blockers may enhance the adverse/toxic effect of Grass Pollen Allergen Extract (5 Grass Extract). More specifically, Beta-Blockers may inhibit the ability to effectively treat severe allergic reactions to Grass Pollen Allergen Extract (5 Grass Extract) with epinephrine. Some other effects of epinephrine may be unaffected or even enhanced (e.g., vasoconstriction) during treatment with Beta-Blockers. Management: Consider alternatives to either grass pollen allergen extract (5 grass extract) or beta-blockers in patients with indications for both agents. Canadian product labeling specifically lists this combination as contraindicated. Risk D: Consider therapy modification

Herbal Products with Blood Pressure Increasing Effects: May diminish the antihypertensive effect of Antihypertensive Agents. Risk C: Monitor therapy

Herbal Products with Blood Pressure Lowering Effects: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

Hypotension-Associated Agents: Blood Pressure Lowering Agents may enhance the hypotensive effect of Hypotension-Associated Agents. Risk C: Monitor therapy

Isoproterenol: Beta-Blockers may diminish the therapeutic effect of Isoproterenol. Risk C: Monitor therapy

Ivabradine: Bradycardia-Causing Agents may enhance the bradycardic effect of Ivabradine. Risk C: Monitor therapy

Lacosamide: Bradycardia-Causing Agents may enhance the AV-blocking effect of Lacosamide. Risk C: Monitor therapy

Levodopa-Containing Products: Blood Pressure Lowering Agents may enhance the hypotensive effect of Levodopa-Containing Products. Risk C: Monitor therapy

Lidocaine (Systemic): Beta-Blockers may increase the serum concentration of Lidocaine (Systemic). Risk C: Monitor therapy

Loop Diuretics: May enhance the hypotensive effect of Antihypertensive Agents. Risk C: Monitor therapy

Lormetazepam: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

Mavacamten: Beta-Blockers may enhance the adverse/toxic effect of Mavacamten. Specifically, negative inotropic effects may be increased. Risk C: Monitor therapy

Mepivacaine: Beta-Blockers may increase the serum concentration of Mepivacaine. Risk C: Monitor therapy

Methacholine: Beta-Blockers may enhance the adverse/toxic effect of Methacholine. Risk C: Monitor therapy

Methoxyflurane: May enhance the hypotensive effect of Beta-Blockers. Risk C: Monitor therapy

Methylphenidate: May diminish the antihypertensive effect of Antihypertensive Agents. Risk C: Monitor therapy

Midodrine: May enhance the bradycardic effect of Bradycardia-Causing Agents. Risk C: Monitor therapy

Mivacurium: Beta-Blockers may enhance the therapeutic effect of Mivacurium. Risk C: Monitor therapy

Molsidomine: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

Naftopidil: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

Nicergoline: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

Nicorandil: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

NIFEdipine: May enhance the hypotensive effect of Beta-Blockers. NIFEdipine may enhance the negative inotropic effect of Beta-Blockers. Risk C: Monitor therapy

Nitroprusside: Blood Pressure Lowering Agents may enhance the hypotensive effect of Nitroprusside. Risk C: Monitor therapy

Nonsteroidal Anti-Inflammatory Agents: May diminish the antihypertensive effect of Beta-Blockers. Risk C: Monitor therapy

Nonsteroidal Anti-Inflammatory Agents (Topical): May diminish the therapeutic effect of Beta-Blockers. Risk C: Monitor therapy

Obinutuzumab: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Management: Consider temporarily withholding blood pressure lowering medications beginning 12 hours prior to obinutuzumab infusion and continuing until 1 hour after the end of the infusion. Risk D: Consider therapy modification

Ozanimod: May enhance the bradycardic effect of Bradycardia-Causing Agents. Risk C: Monitor therapy

Pentoxifylline: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

Pholcodine: Blood Pressure Lowering Agents may enhance the hypotensive effect of Pholcodine. Risk C: Monitor therapy

Phosphodiesterase 5 Inhibitors: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

Ponesimod: Bradycardia-Causing Agents may enhance the bradycardic effect of Ponesimod. Management: Avoid coadministration of ponesimod with drugs that may cause bradycardia when possible. If combined, monitor heart rate closely and consider obtaining a cardiology consult. Do not initiate ponesimod in patients on beta-blockers if HR is less than 55 bpm. Risk D: Consider therapy modification

Prostacyclin Analogues: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

Quinagolide: May enhance the hypotensive effect of Blood Pressure Lowering Agents. Risk C: Monitor therapy

Reserpine: May enhance the hypotensive effect of Beta-Blockers. Risk C: Monitor therapy

Rivastigmine: May enhance the bradycardic effect of Beta-Blockers. Risk X: Avoid combination

Siponimod: Bradycardia-Causing Agents may enhance the bradycardic effect of Siponimod. Management: Avoid coadministration of siponimod with drugs that may cause bradycardia. If combined, consider obtaining a cardiology consult regarding patient monitoring. Risk D: Consider therapy modification

Succinylcholine: Beta-Blockers may enhance the neuromuscular-blocking effect of Succinylcholine. Risk C: Monitor therapy

Sulfonylureas: Beta-Blockers may enhance the hypoglycemic effect of Sulfonylureas. Cardioselective beta-blockers (eg, acebutolol, atenolol, metoprolol, and penbutolol) may be safer than nonselective beta-blockers. All beta-blockers appear to mask tachycardia as an initial symptom of hypoglycemia. Ophthalmic beta-blockers are probably associated with lower risk than systemic agents. Risk C: Monitor therapy

Tasimelteon: Beta-Blockers may diminish the therapeutic effect of Tasimelteon. Management: Consider avoiding nighttime administration of beta-blockers during tasimelteon therapy due to the potential for reduced tasimelteon efficacy. Risk D: Consider therapy modification

Theophylline Derivatives: Beta-Blockers (Beta1 Selective) may diminish the bronchodilatory effect of Theophylline Derivatives. Risk C: Monitor therapy

Tofacitinib: May enhance the bradycardic effect of Bradycardia-Causing Agents. Risk C: Monitor therapy

White Birch Allergen Extract: Beta-Blockers may enhance the adverse/toxic effect of White Birch Allergen Extract. Specifically, beta-blockers may reduce the effectiveness of beta-agonists that may be required to treat systemic reactions to white birch allergen extract. Risk X: Avoid combination

Pregnancy Considerations

Exposure to beta-blockers during pregnancy may increase the risk for adverse events in the neonate. If maternal use of a beta-blocker is needed, fetal growth should be monitored during pregnancy and the newborn should be monitored for 48 hours after delivery for bradycardia, hypoglycemia, and respiratory depression (ESC [Regitz-Zagrosek 2018]).

Chronic maternal hypertension is also associated with adverse events in the fetus/infant. Chronic maternal hypertension may increase the risk of birth defects, low birth weight, premature delivery, stillbirth, and neonatal death. Actual fetal/neonatal risks may be related to duration and severity of maternal hypertension. Untreated chronic hypertension may also increase the risks of adverse maternal outcomes, including gestational diabetes, preeclampsia, delivery complications, stroke, and myocardial infarction (ACOG 203 2019).

When treatment of chronic hypertension in pregnancy is indicated, agents other than bisoprolol are preferred (ACOG 203 2019; ESC [Regitz-Zagrosek 2018]; Magee 2014). Females with preexisting hypertension may continue their medication during pregnancy unless contraindications exist (ESC [Regitz-Zagrosek 2018]).

Breastfeeding Considerations

It is not known if bisoprolol is present in breast milk.

The manufacturer recommends that caution be exercised when administering bisoprolol to breastfeeding women. Use of a beta-blocker other than bisoprolol may be preferred in a lactating female (Anderson 2017; Ito 2000).

Monitoring Parameters

BP, heart rate, ECG; serum glucose (in diabetic patients); signs and symptoms of bronchospasm (in patients with preexisting bronchospastic disease).

Hypertension: The 2017 guideline for the prevention, detection, evaluation, and management of high BP in adults (ACC/AHA [Whelton 2018]):

Confirmed hypertension and known cardiovascular disease or 10-year atherosclerotic cardiovascular disease risk ≥10%: Target BP <130/80 mm Hg is recommended.

Confirmed hypertension without markers of increased atherosclerotic cardiovascular disease risk: Target BP <130/80 mm Hg may be reasonable.

Mechanism of Action

Selective inhibitor of beta1-adrenergic receptors; competitively blocks beta1-receptors, with little or no effect on beta2-receptors at doses ≤20 mg

Pharmacokinetics

Onset of action: 1 to 2 hours

Absorption: Rapid and almost complete

Distribution: Widely; highest concentrations in heart, liver, lungs, and saliva; crosses blood-brain barrier

Protein binding: ~30%

Metabolism: Extensively hepatic; significant first-pass effect (~20%)

Bioavailability: ~80%

Half-life elimination: Normal kidney function: 9 to 12 hours; CrCl <40 mL/minute: 27 to 36 hours; Hepatic cirrhosis: 8 to 22 hours

Time to peak: 2 to 4 hours

Excretion: Urine (50% as unchanged drug, remainder as inactive metabolites); feces (<2%)

Pricing: US

Tablets (Bisoprolol Fumarate Oral)

5 mg (per each): $1.40 - $2.25

10 mg (per each): $1.40 - $2.25

Disclaimer: A representative AWP (Average Wholesale Price) price or price range is provided as reference price only. A range is provided when more than one manufacturer's AWP price is available and uses the low and high price reported by the manufacturers to determine the range. The pricing data should be used for benchmarking purposes only, and as such should not be used alone to set or adjudicate any prices for reimbursement or purchasing functions or considered to be an exact price for a single product and/or manufacturer. Medi-Span expressly disclaims all warranties of any kind or nature, whether express or implied, and assumes no liability with respect to accuracy of price or price range data published in its solutions. In no event shall Medi-Span be liable for special, indirect, incidental, or consequential damages arising from use of price or price range data. Pricing data is updated monthly.

Brand Names: International
  • Adroten (MY);
  • Ancor (BD);
  • B-Beta (ID);
  • B-Cor (BH, JO, LB);
  • Beprol (AU);
  • Beta-One (ID, KR);
  • Betabis (BD);
  • Betacor (TH, TW);
  • Betapro (BD);
  • Bicard (AU);
  • Bicor (AU);
  • Bilocor (ZW);
  • Biol (CH);
  • Bipro (ID);
  • Biprolol (UA);
  • Biscor (BH, JO, QA, SA, TW);
  • Bisloc (MY, TH);
  • Biso (DE);
  • Biso 5 (TW);
  • Bisoblock (VN);
  • Bisocard (EG, UA);
  • Bisocor (LB, LK, MY);
  • Bisodac-HF (MY);
  • Bisohexal (SG);
  • Bisol (MY);
  • Bisolock (EG);
  • Bisomerck (DE);
  • Bisono Tape (JP);
  • Bisop (IE);
  • Bisopine (IE);
  • Bisostad (VN);
  • Bisosten (PH);
  • Bisoten (JO);
  • Bisotrol (ZW);
  • Bispro (AU);
  • Bistol (EG);
  • Biteven (TW);
  • Bosvate (NZ);
  • Caprol (EG);
  • Cardensiel (FR);
  • Cardex (BH);
  • Cardicor (DK, IE);
  • Cardiloc (IL);
  • Cardiosafe (QA);
  • Cobis (KR);
  • Comed 5 (TH);
  • Concor (AE, AR, AT, BG, BH, BR, BS, CH, CL, CN, CO, CR, CY, CZ, DE, DO, EC, EE, EG, GT, HK, HN, HR, HU, ID, IL, IN, IT, JM, JO, KR, KW, LB, LK, LU, LV, MX, MY, NI, NL, PA, PE, PK, PL, PT, QA, RO, RU, SA, SI, SK, SV, TH, TR, TT, TW, UA, VE, VN, ZA);
  • Concor COR (DE, HR, VN);
  • Concor-Cor (LK);
  • Concore (PH);
  • Corbis (AR);
  • Corbloc (LK);
  • Cordinorm (UA);
  • Corentel (PE, PY, UY);
  • Detensiel (FR);
  • Emconcor (BE, DK, ES, FI, NO, SE);
  • Euradal (ES);
  • Hapsen (ID);
  • Hypercor (TH);
  • Isoten (BE);
  • Jutabis (DE);
  • Kenco (TW);
  • Maintate (JP);
  • Monocor (TW);
  • Novacor (TH);
  • Pactens (GR);
  • Probis (BD);
  • Sopalol (TH);
  • Soprol (DO);
  • Soprol-5 (PH);
  • Vasoten (MY);
  • Zabesta (LK)


For country code abbreviations (show table)
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