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Cardioversion

Cardioversion is a designed to restore a normal heart rhythm, known as , in patients experiencing certain s, such as , , , or unstable . It can be performed electively to manage symptoms or emergently in hemodynamically unstable cases, and it differs from , which is used for life-threatening rhythms without a pulse. There are two primary types of cardioversion: electrical and pharmacological. Electrical cardioversion involves delivering synchronized low-energy electric shocks to the heart through electrodes placed on the chest, timed with the R-wave of the heartbeat to avoid inducing ventricular fibrillation. This method is typically performed in a hospital setting under sedation, starting with energies of 120-200 joules for atrial fibrillation using biphasic waveforms, and is highly effective for terminating tachycardias caused by conditions like coronary artery disease or re-entrant circuits. In contrast, pharmacological cardioversion uses intravenous medications, such as adenosine for supraventricular tachycardia, amiodarone or procainamide for atrial fibrillation, or magnesium for torsades de pointes, to chemically reset the rhythm without shocks. This approach is preferred for stable patients, avoids sedation, and is suitable for outpatient use when the arrhythmia duration is less than 48 hours. Indications for cardioversion include symptomatic or unstable arrhythmias that impair , with being the most common target, affecting millions worldwide and increasing risk if untreated. Prior to the procedure, patients often undergo preparation such as for 8 hours, transesophageal to rule out atrial clots, and anticoagulation therapy (e.g., blood thinners for 3-4 weeks) to prevent embolic events like , especially if the has persisted beyond 48 hours. The procedure itself is brief, often allowing same-day discharge after monitoring, though post-procedure anticoagulation may continue for up to 4 weeks. While generally safe and effective, cardioversion carries risks including dislodgement of blood clots leading to (mitigated by pre-procedure screening), induction of new s, skin burns from shocks, or proarrhythmic effects from drugs (occurring in about 2% of cases with certain agents). Success rates are high, particularly for recent-onset arrhythmias, but recurrence is common, often necessitating lifestyle modifications, ongoing medications, or repeat procedures.

Background and Indications

Definition and Mechanism

Cardioversion is a therapeutic designed to restore normal in patients with abnormal heart rhythms, known as arrhythmias, by either delivering a synchronized electrical shock or administering specific medications. This intervention targets tachycardias or other dysrhythmias that compromise hemodynamic stability, converting them to a coordinated electrical activity originating from the . The electrical form of cardioversion, first described in 1962 by Lown et al., involves the synchronized delivery of a low-energy transthoracic shock timed to the R wave of the on the electrocardiogram. This timing prevents the risk of inducing by avoiding the vulnerable phase (R-on-T phenomenon). The shock depolarizes a of myocardial cells, simultaneously extinguishing re-entrant wavefronts or ectopic foci that sustain the , thereby allowing the to reestablish dominance and propagate normal impulses through the atrioventricular conduction system. In pharmacological cardioversion, antiarrhythmic agents achieve rhythm restoration by modulating cardiac channels—such as sodium, , or calcium channels—or by influencing autonomic tone to disrupt re-entrant circuits. These drugs prolong duration, slow conduction velocity, or suppress in arrhythmogenic tissues, facilitating the termination of abnormal electrical loops without the need for external energy delivery. At the physiological level, the underpins these mechanisms: phase 0 , driven by rapid sodium influx, initiates myocardial contraction, while subsequent phases restore excitability. Arrhythmias often perpetuate via re-entrant circuits where excitable gaps allow sustained wavefronts; cardioversion interrupts this by inducing widespread, simultaneous , rendering tissues temporarily refractory and resetting the heart's electrical synchrony to prevent reinitiation.

Clinical Indications and Patient Selection

Cardioversion is primarily indicated for patients with symptomatic (AF) or (AFL) as part of a rhythm control strategy to restore and alleviate symptoms such as , , or . In hemodynamically unstable patients with AF, electrical cardioversion is the treatment of choice to rapidly restore normal rhythm and stabilize , including cases of , , or acute . For (SVT), including atrioventricular nodal reentrant tachycardia (AVNRT) and (AVRT), cardioversion is recommended when the arrhythmia causes hemodynamic instability, such as altered mental status or signs of , and initial maneuvers like vagal stimulation or fail. Similarly, in sustained monomorphic (VT) with a , cardioversion is indicated for patients exhibiting hemodynamic compromise, including , syncope, or , particularly after unsuccessful pharmacological attempts in stable cases. These interventions are classified as Class I recommendations with moderate-quality evidence from nonrandomized studies, emphasizing urgent application in unstable scenarios versus elective use for persistent symptoms in stable patients. Patient selection for cardioversion prioritizes those with recent-onset arrhythmias to minimize risks, such as AF or AFL of documented duration <48 hours, where therapeutic anticoagulation (with an oral anticoagulant) can be deferred until after successful cardioversion if no evidence of an atrial thrombus is identified by transesophageal echocardiography (TEE) (Class 2a recommendation), particularly when the CHA₂DS₂-VASc score is low (0 in males, 0-1 in females), with the incidence of thromboembolism estimated at under 1% in such low-risk cases. For arrhythmias exceeding 48 hours or of unknown duration, therapeutic anticoagulation for at least 3 weeks prior and 4 weeks post-procedure is mandatory, with direct oral anticoagulants preferred over warfarin in eligible patients to achieve stroke prevention rates comparable to long-term therapy. Underlying heart conditions, such as structural heart disease or heart failure, influence selection, favoring early rhythm control in symptomatic individuals to improve outcomes, while excluding those with stable chronic AF where rate control with medications like beta-blockers is sufficient and preferred to avoid procedural risks. In SVT and VT, selection emphasizes hemodynamic stability; stable patients may undergo elective cardioversion if drugs are ineffective or contraindicated, but urgent intervention is reserved for instability, with sedation required to ensure safety. The 2023 ACC/AHA/ACCP/HRS guidelines underscore these criteria, recommending rhythm control via cardioversion for AF in patients with reduced ejection fraction or recent onset to enhance quality of life and reduce hospitalization rates.

Types of Cardioversion

Electrical Cardioversion

Electrical cardioversion employs a () defibrillator operating in synchronized mode to deliver timed electrical shocks that the myocardium and restore normal in patients with tachyarrhythmias. The synchronization feature tracks the R-wave of the on the ECG, ensuring the shock is delivered during the absolute refractory period to avoid the vulnerable phase of the T-wave, thereby minimizing the risk of precipitating . Contemporary devices utilize biphasic waveforms, which involve an initial positive current followed by a reversal to negative , enhancing efficacy by allowing more uniform myocardial compared to unidirectional shocks. The primary equipment for electrical cardioversion consists of external defibrillators, with biphasic models supplanting older monophasic ones due to superior performance. Monophasic defibrillators deliver current in a single direction, often requiring higher energies and yielding lower success rates, whereas biphasic defibrillators achieve cardioversion in up to 90% of cases for with reduced energy delivery, decreasing the potential for myocardial injury. These devices incorporate self-adhesive pads or paddles for transthoracic application and integrate ECG monitoring for precise timing. This method provides rapid and high efficacy for terminating acute arrhythmias, making it particularly advantageous in hemodynamically unstable patients where immediate rhythm restoration can be life-saving. In contrast to pharmacological approaches that modulate channels chemically, electrical cardioversion offers an instantaneous intervention suitable for urgent scenarios. However, it necessitates procedural to mitigate patient discomfort and carries risks such as , which mandates anticoagulation for episodes exceeding 48 hours to prevent clot dislodgement during rhythm conversion. Energy selection for typically begins at 100-200 joules using biphasic waveforms, with escalation in increments (e.g., doubling to 200-360 J) if initial attempts fail, balancing efficacy against tissue damage; specific protocols are further detailed in procedural guidelines.

Pharmacological Cardioversion

Pharmacological cardioversion involves the administration of antiarrhythmic drugs to restore normal in patients with (AF) or other supraventricular s, serving as a non-invasive to electrical methods. For supraventricular tachycardia (SVT), is a common first-line agent for pharmacological cardioversion. These agents work by targeting cardiac ion channels, such as and sodium channels, to prolong the refractory period, slow conduction velocity, or directly terminate re-entrant circuits and ectopic foci that sustain the . By altering the heart's electrical properties, the drugs facilitate organized atrial activity and resumption of without the need for external energy delivery. Key drug classes used for pharmacological cardioversion of AF include Class Ia agents, such as , which block sodium channels to depress phase 0 of the action potential, and Class III agents, like intravenous or oral , which primarily inhibit the rapid component of the delayed rectifier potassium current (IKr) to extend . Intravenous formulations, such as and , are typically employed for acute settings to achieve faster onset, with success often observed within hours for recent-onset AF (duration less than 7 days), while oral agents like facilitate conversion over 24-72 hours. Overall success rates range from 50% to 70%, though diminishes with longer AF duration due to progressive atrial remodeling. This approach offers advantages such as being non-invasive and amenable to outpatient use in select stable patients, avoiding the and procedural risks associated with electrical cardioversion. However, it has a slower onset compared to electrical methods and carries proarrhythmic risks, including from QT prolongation, particularly with Class III drugs. Pharmacological cardioversion is preferred for hemodynamically stable patients with recent-onset or when electrical cardioversion is contraindicated, such as in cases of severe or .

Electrical Cardioversion Procedure

Preoperative Preparation

Preoperative preparation for electrical cardioversion begins with a thorough assessment to confirm the and evaluate risks. An electrocardiogram (ECG) is performed to verify the presence of the target , such as (), and to assess for any contraindicating features like digitalis toxicity or prolonged . Laboratory tests are essential, including electrolyte levels (particularly and magnesium) to prevent arrhythmogenic imbalances, coagulation studies to confirm anticoagulation status, and renal function tests to guide medication dosing. If has persisted for more than 48 hours or the duration is unknown, transesophageal echocardiography (TEE) is recommended to exclude left atrial , with a reported detection rate of 0% to 38% in such cases. Anticoagulation management is a critical component to mitigate thromboembolic risk. For patients with lasting more than 48 hours, therapeutic oral anticoagulation (OAC) is required for at least 3 weeks prior to the procedure, using either (target international normalized ratio [INR] of 2 to 3) or direct oral anticoagulants (DOACs) at standard therapeutic doses, and continued for at least 4 weeks postoperatively due to atrial stunning. In cases where prior anticoagulation has been inadequate (less than 3 weeks), TEE-guided cardioversion is preferred as an alternative strategy. Anticoagulation may be omitted for of less than 12 hours in low-risk patients (CHA₂DS₂-VASc score of 0 or 1), where thromboembolic risk is approximately 0.3% to 0.4%. Uninterrupted OAC is maintained perioperatively. Sedation and anesthesia preparation ensures patient comfort and safety during the brief . Conscious or general is administered using short-acting agents such as , with monitoring for respiratory and hemodynamic stability. Patients must fast for at least 6 to 8 hours preoperatively to reduce risk, though usual medications (except anticoagulants if interrupted) are continued unless otherwise directed. Informed consent is obtained after shared , discussing procedure benefits, risks (including and recurrence), and alternatives. The multidisciplinary team typically includes a cardiologist for management, an anesthesiologist for oversight, and staff for , all coordinated to optimize procedural .

Performing the Procedure

The performing of electrical cardioversion involves delivering a synchronized electrical shock to restore normal in patients with certain s. The defibrillator is first set to synchronized mode, which times the shock delivery to coincide with the R-wave of the on the electrocardiogram (ECG) to prevent the R-on-T phenomenon, a potentially life-threatening event where the shock falls on the vulnerable T-wave and induces . Electrode pads are applied to the patient's chest in a configuration such as anterior-posterior or anterior-lateral, ensuring good skin contact and conductivity. The selected energy level is based on the arrhythmia type: for (AF), an initial biphasic shock of at least 200 joules (J) is recommended, escalating to higher levels up to 360 J if the initial attempt fails; for (SVT), starting energies of 50-100 J are typically used, with escalation as needed per 2025 (AHA) guidelines. Once the device is charged to the appropriate energy, all personnel are commanded to "clear" the patient to avoid accidental shock, and the shock is then delivered while the operator maintains firm contact with the paddles or pads. Immediately following the shock, the patient's ECG is assessed to determine if has been achieved; if not, the process is repeated with increased energy after a brief pause. The active delivery phase of the procedure, under conscious sedation, generally lasts 5-10 minutes, allowing for one or more shocks as required.

Immediate Post-Procedure Care

Following electrical cardioversion, patients receive continuous electrocardiographic (ECG) monitoring for 2 to 4 hours to evaluate for immediate recurrence of or other rhythm disturbances, as well as rare hemodynamic complications. , including and , are monitored concurrently to ensure hemodynamic stability. , typically administered via short-acting intravenous agents such as or , is allowed to reverse naturally due to their brief duration, though antagonists like can be used if benzodiazepines were employed and rapid recovery is needed. Success is determined by immediate post-procedure ECG confirmation of restoration, with biphasic waveform shocks achieving this in about 92% of cases for . If is not achieved, options include repeat shocks during the same session or transition to pharmacological alternatives or further evaluation. Thromboembolic risk persists post-procedure due to potential atrial , necessitating continuation of therapeutic anticoagulation (direct oral anticoagulants preferred over antagonists unless contraindicated) for at least 4 weeks, guided by the CHA₂DS₂-VASc score to assess risk. Patients meeting discharge criteria—stable sinus rhythm, normal vital signs, no procedural complications, and adequate sedation recovery—are typically released the same day, with arrangements for transportation as driving is prohibited for 24 hours.

Electrode Placement Techniques

Anterior-Posterior Placement

The anterior-posterior electrode placement technique involves positioning one self-adhesive pad on the anterior chest wall, typically to the left of the sternal border at the second or third , and the other on the posterior chest wall below the left in the paraspinal region at approximately the level of the seventh thoracic . This configuration aligns the electrical vector to traverse the heart more directly from front to back. The primary rationale for anterior-posterior placement is its ability to direct the shock vector across the atria for arrhythmias like (AF). It may reduce transthoracic impedance by distributing the current more evenly through the . Recent meta-analyses and the 2024 guidelines indicate success rates are equivalent to anterior-lateral placement for AF cardioversion, though older studies suggested a potential advantage for persistent AF. In application, self-adhesive pads are applied with conductive gel to ensure optimal skin contact and minimize air gaps, which could otherwise elevate impedance and reduce effectiveness. Evidence from randomized trials shows high overall conversion to efficacy, around 90-96% with biphasic waveforms in various cohorts. This placement is contraindicated in patients with dermatological conditions, wounds, or infections on the posterior that impair pad adhesion or increase risk. In comparison to anterior-lateral placement, it may emphasize atrial targeting over broader ventricular coverage.

Anterior-Lateral Placement

In anterior-lateral electrode placement for electrical cardioversion, one self-adhesive pad is positioned on the anterior chest wall immediately to the right of the at the second , while the second pad is placed laterally on the left mid-axillary line at the level of the fifth , below the breast tissue. This arrangement directs the electrical current vector across the heart from front to side, facilitating effective or cardioversion. Proper preparation, including shaving if necessary and use of conductive gel or pads, is essential to ensure good contact and minimize impedance. This configuration serves as the standard approach for synchronized cardioversion of (VT), particularly in unstable patients requiring rapid intervention, and is favored when posterior access is limited, such as in scenarios, with immobile patients, or in those with that complicates back placement. Its ease of application—requiring no patient repositioning—makes it practical for general use across various arrhythmias in both elective and acute settings, aligning with advanced cardiovascular protocols. A 2022 meta-analysis of randomized controlled trials demonstrated that anterior-lateral placement yields success rates equivalent to anterior-posterior placement for direct current cardioversion of , the most common requiring the procedure, with overall efficacy around 90% for biphasic waveforms. Transthoracic impedance is generally comparable between the two positions, though anterior-lateral may exhibit slightly higher values in some patients due to greater distance from the posterior , potentially necessitating energy adjustments starting at 100-200 J for adults. For adult patients, electrode pads measuring 8 to 12 cm in diameter are recommended to achieve optimal skin contact, reduce impedance, and enhance shock delivery efficacy.

Pharmacological Cardioversion Details

Common Medications and Dosing

Pharmacological cardioversion primarily utilizes antiarrhythmic drugs to restore sinus rhythm in conditions such as atrial fibrillation (AF) and atrial flutter (AFL), with selection based on patient characteristics, arrhythmia duration, and underlying comorbidities. The 2024 European Society of Cardiology (ESC) Guidelines recommend these agents for recent-onset AF (<48 hours), emphasizing their efficacy in hemodynamically stable patients without contraindications. Ibutilide, a class III antiarrhythmic, acts by prolonging the action potential duration through blockade of delayed rectifier potassium channels, facilitating chemical cardioversion of AF or AFL episodes lasting less than 90 days. The standard intravenous (IV) dose is 1 mg administered over 10 minutes, with a potential repeat dose of the same amount after 10-20 minutes if no conversion occurs (maximum total 2 mg); for patients weighing less than 60 kg, the initial dose is reduced to 0.01 mg/kg. It carries a significant risk of QT interval prolongation and torsades de pointes, necessitating continuous ECG monitoring for at least 4 hours post-administration in a cardiac care unit. No specific dosing adjustments are required for renal or hepatic impairment, but it is contraindicated in patients with prolonged QTc, severe left ventricular hypertrophy, or low left ventricular ejection fraction. Procainamide, a class Ia antiarrhythmic, exerts its effect via blockade, which slows conduction and prolongs the action potential duration, making it suitable for cardioversion of , , or (SVT). The IV loading dose is 10-17 mg/kg infused over 30-60 minutes, followed by maintenance if needed. Caution is advised in renal impairment, where dosing should be reduced to avoid accumulation, while hepatic adjustments are not typically specified. Potential adverse effects include , widening, and proarrhythmia, requiring close electrocardiographic surveillance. Amiodarone, a class III antiarrhythmic with multichannel effects, is used for cardioversion of recent-onset AF or AFL (<90 days), including in patients with heart failure or structural heart disease. The IV dose is 300 mg over 30-60 minutes, followed by 900-1200 mg over 24 hours if needed. Dosing adjustments are recommended in hepatic or renal impairment due to potential accumulation and interactions; it is contraindicated in hyperthyroidism or severe bradycardia. Risks include bradycardia, hypotension, QT prolongation, and long-term toxicities (e.g., pulmonary, thyroid), with continuous ECG and vital sign monitoring required. Flecainide and , both class Ic antiarrhythmics, block sodium channels to slow intra-atrial conduction and are particularly effective for "pill-in-the-pocket" strategies in paroxysmal without structural heart . 's oral single dose for acute cardioversion is 200-300 mg, achieving conversion rates of up to 70% within 4-12 hours when combined with an atrioventricular node-blocking agent like a beta-blocker to prevent rapid ventricular response. For use, 1-2 mg/kg (maximum 150-200 mg) is given over 10 minutes. follows a similar profile, with an oral single dose of 450-600 mg (conversion rates 43-89% within 6 hours) or 1.5-2 mg/kg over 10-20 minutes, also requiring co-administration with an nodal blocker. Both drugs are contraindicated in severe structural heart , , or due to proarrhythmic risks; flecainide dosing should be avoided if creatinine clearance is below 35 mL/min/1.73 , and propafenone requires reduction in hepatic impairment. The pill-in-the-pocket approach must be validated in-hospital prior to outpatient use. Vernakalant, an atrial-selective antiarrhythmic, is recommended for rapid cardioversion of recent-onset (<7 days) in hemodynamically stable patients without structural heart disease. It is available in , , and some other regions but not approved by the FDA in the United States as of November 2025. The IV dose is 3 mg/kg over 10 minutes (maximum 339 mg), with a repeat dose of 2 mg/kg (maximum 226 mg) after 10-15 minutes if needed. It is contraindicated in (SBP <100 mmHg), recent , NYHA class III/ heart failure, or prolongation. Risks include and transient prolongation, requiring ECG monitoring. A 2025 randomized trial (RAFF4) demonstrated superior efficacy to for rapid conversion in acute .
MedicationClassPrimary IndicationStandard Dosing (Acute Cardioversion)Key AdjustmentsMajor Risks
III/ <90 days: 1 mg over 10 min (repeat once)None specifiedQT prolongation, torsades
Ia/, SVT: 10-17 mg/kg over 30-60 minReduce in renal impairment, QRS widening
III/ <90 days, incl. HF: 300 mg over 30-60 minCaution in hepatic/renal,
IcParoxysmal , no SHDOral: 200-300 mg single; : 1-2 mg/kg (max 150-200 mg)Avoid if CrCl <35 mL/minProarrhythmia in SHD
IcParoxysmal , no SHDOral: 450-600 mg single; : 1.5-2 mg/kgReduce in hepatic impairmentProarrhythmia in SHD/CAD
VernakalantAtrial-selectiveRecent-onset <7 days, no SHD: 3 mg/kg over 10 min (repeat 2 mg/kg)None specified, QT prolongation
(SHD: structural heart disease; CrCl: creatinine clearance)

Administration Protocols and Monitoring

Pharmacological cardioversion is typically administered in a controlled clinical environment to ensure , with protocols varying based on the patient's hemodynamic stability and the chosen agent. For hemodynamically unstable patients or those receiving intravenous agents such as , administration occurs in an setting with immediate access to equipment. In contrast, stable patients with infrequent paroxysmal may undergo outpatient oral administration using the "pill-in-the-pocket" approach, following initial validation of and to confirm and prevent adverse events. Standard protocols emphasize preparation and delivery tailored to the route of administration. Intravenous infusions, such as for ibutilide, involve a 10-minute infusion that may be repeated once after a 10-minute observation period if initial conversion fails, always under continuous supervision. Oral protocols, like those for flecainide or propafenone, require a single loading dose preceded by ambulatory Holter monitoring to assess baseline rhythm and exclude contraindications, with co-administration of an atrioventricular nodal blocking agent at least 30 minutes prior to mitigate risks of rapid ventricular response. These measures align with 2024 ESC guideline recommendations for symptomatic atrial fibrillation of recent onset (<24 hours without transesophageal echocardiography for clot exclusion), prioritizing rapid restoration of sinus rhythm while minimizing procedural complications. Monitoring during and after administration is critical to detect proarrhythmic effects and ensure timely . Continuous electrocardiographic is mandatory throughout the and for at least 4 hours post-infusion in cases involving QT-prolonging agents like , with serial assessments of the QTc interval, electrolytes (particularly and magnesium), and renal function to preempt or other arrhythmias. A defibrillator must remain on standby, and are tracked closely, especially during intravenous delivery, to address or promptly. For outpatient oral regimens, patients receive instructions for self- symptoms and immediate return if or occur, supplemented by follow-up ECG within 24-48 hours. The onset of pharmacological cardioversion generally occurs within 30 minutes to 2 hours for most intravenous agents, though it may extend to 3-6 hours for oral options, with success evaluated via ECG confirmation of . If initial attempts fail, guidelines permit repeat administration after 24 hours in stable patients, provided no contraindications have emerged and anticoagulation status remains appropriate to mitigate thromboembolic risks. This timed approach facilitates assessment of efficacy while allowing for alternative strategies, such as electrical cardioversion, if needed.

Risks, Complications, and Contraindications

Potential Risks and Complications

Cardioversion, whether electrical or pharmacological, carries several potential risks and complications, though the overall complication rate remains low at approximately 1-2%. Electrical cardioversion specifically risks minor skin burns at sites, occurring in approximately 1-7% of cases, typically manifesting as or superficial injury that resolves without intervention. Another key concern is , with an incidence of 5-7% in unanticoagulated patients undergoing the procedure for lasting longer than 48 hours, primarily due to dislodgement of atrial thrombi during restoration of . , a rare bradyarrhythmic event, affects fewer than 1% of patients, often transient and linked to underlying , but it may require immediate pacing support. Additionally, atrial stunning can occur post-procedure, leading to temporary atrial dysfunction with partial recovery in 15-30 days and full resolution in 30-90 days, potentially exacerbating thromboembolic risks in vulnerable patients. Pharmacological cardioversion introduces distinct adverse effects, particularly proarrhythmia with agents like , where or arises in approximately 4% of cases, driven by prolongation and risk, necessitating continuous ECG monitoring during administration. is another common issue, reported in up to 12% of patients receiving intravenous antiarrhythmics such as , though less frequent with , and it often resolves with fluid or discontinuation of the drug. Drug interactions further heighten risks, as combined with other QT-prolonging agents (e.g., or ) amplifies proarrhythmic potential, while inhibitors can alter of related therapies. General complications applicable to both modalities include those from procedural , such as transient drowsiness or unsteadiness in about 33% of cases, with rarer respiratory depression requiring airway support, especially in patients with comorbidities like . recurrence is also prevalent, affecting approximately 50% of patients within one year post-cardioversion, underscoring the need for ongoing antiarrhythmic therapy or consideration. These risks can be mitigated through preoperative anticoagulation and protocols to minimize thromboembolic and arrhythmic events.

Contraindications and Precautions

Cardioversion, whether electrical or pharmacological, carries specific absolute s to prevent severe adverse outcomes. Electrical cardioversion is absolutely contraindicated in cases of , as it can precipitate life-threatening ventricular arrhythmias such as . Similarly, uncorrectable represents an absolute contraindication for pharmacological cardioversion, owing to the heightened risk of induced by agents like or . The presence of a known in the left atrium or left atrial appendage is also an absolute contraindication without prior adequate anticoagulation, as it substantially elevates the risk of . Relative contraindications necessitate individualized risk-benefit assessment and additional safeguards. Recent within the preceding 3 months is considered relative, particularly with pharmacological agents like Class IC drugs ( or ), due to increased mortality and complication risks. Severe warrants caution because of potential hemodynamic instability during the procedure, though it is not an absolute bar and may proceed with careful monitoring if stability is assured. For long-standing without prior anticoagulation, cardioversion is relatively contraindicated unless rules out or at least 3 weeks of therapeutic anticoagulation has been achieved. Key precautions mitigate risks across eligible patients. Bridging anticoagulation with heparin or low-molecular-weight heparin is recommended for those on vitamin K antagonists to maintain therapeutic levels peri-procedurally. Electrolyte imbalances, such as hypokalemia or hypomagnesemia, must be corrected prior to cardioversion to minimize arrhythmic complications. Pretreatment with amiodarone can reduce post-cardioversion recurrence but requires monitoring for toxicities including QT prolongation and pulmonary effects. In special populations, tailored approaches are essential. For pregnant patients, electrical cardioversion is generally safe after the first trimester if clinically indicated, with preferred over pharmacological options to avoid fetal exposure risks; anticoagulation with (≤5 mg daily) or is used instead of direct oral anticoagulants. In pediatrics, while contraindications mirror those in adults, energy levels for synchronized electrical cardioversion are adjusted lower, starting at 0.5-1 J/kg and increasing to 2 J/kg if needed, to account for smaller body size and physiology.

Outcomes and Follow-Up

Success Rates and Factors

The success of electrical cardioversion for restoring in (AF) varies by AF duration and patient characteristics, with acute conversion rates typically ranging from 90% to 95% using biphasic waveform shocks at energies of 200 J or higher. For recent-onset AF lasting less than 48 hours, success exceeds 90%, while rates drop to 70-80% for persistent or chronic AF due to atrial remodeling. Key factors enhancing efficacy include shorter AF duration, left atrial diameter less than 50 mm, absence of significant valvular disease, and optimized electrode placement such as anterior-posterior positioning for longer-duration AF. Pretreatment with antiarrhythmic drugs like further improves outcomes by facilitating reverse electrical remodeling. Pharmacological cardioversion achieves lower success rates than electrical methods, generally 50-80% for recent-onset AF without structural heart disease, with efficacy dependent on the agent used. Class Ic drugs such as or convert 58-85% of cases within 3-8 hours in patients with normal left ventricular function, outperforming (around 30-50% within 90 minutes) or intravenous (relative risk of 1.2-1.4 for conversion by 24 hours). Success is higher with shorter AF episodes and smaller left atrial size, but declines in the presence of heart failure or electrolyte imbalances, which contraindicate certain agents due to proarrhythmic risks. Common predictors of successful rhythm conversion across both methods include younger age under 70 years, fewer comorbidities such as or , and early intervention before extensive atrial develops. Post-cardioversion reverse remodeling, characterized by recovery of atrial refractory periods and reduced conduction velocity abnormalities within 1-7 days, supports sustained and is more pronounced in paroxysmal . Recent analyses from long-term cohorts, including follow-ups to trials like AFFIRM, confirm that these factors correlate with lower recurrence at 1 year, emphasizing the role of atrial size and duration in prognostic models. In cases of failed cardioversion, anticoagulation should be continued based on CHA₂DS₂-VASc score to mitigate thromboembolic risk, with consideration of repeat attempts or alternative rhythm control strategies after addressing modifiable factors like correction.

Long-Term Management

Following successful cardioversion, long-term management focuses on maintaining and preventing (AF) recurrence through a of pharmacological and non-pharmacological strategies. Antiarrhythmic plays a central role, with and commonly used to sustain post-procedure. has demonstrated superior efficacy in maintaining compared to , with studies showing a median time to recurrence of 487 days versus 6 days with , though it carries risks such as neurological toxicity and (incidence 0.7%). is an alternative, particularly in patients without significant , but it is associated with increased all-cause mortality ( 2.23, 95% CI 1.03-4.81) and requires monitoring every 3-6 months. serves as a non-pharmacological alternative, offering higher long-term success rates than antiarrhythmic drugs alone, with recurrence rates of 30-40% after the first procedure and a 50% reduction in AF burden compared to medical . Lifestyle modifications are essential to reduce AF burden and support rhythm maintenance. Weight loss of at least 10% body weight has been shown to significantly decrease AF recurrence in overweight patients, while limiting alcohol intake to no more than 3 drinks per week lowers AF progression and symptom severity. These interventions, when combined with antiarrhythmic therapy, enhance overall outcomes by addressing modifiable risk factors. Follow-up care involves serial monitoring to detect recurrence early and guide anticoagulation decisions. Electrocardiograms (ECGs) and Holter monitoring are recommended at intervals such as 1, 3, and 6 months post-cardioversion to assess stability and AF burden. Anticoagulation therapy should be continued or initiated based on the CHA2DS2-VASc score, with direct oral anticoagulants preferred for patients at moderate-to-high risk (score ≥2 in men or ≥3 in women), reducing risk by 30% compared to . Recurrence rates after electrical cardioversion remain high, ranging from 40-60% at 1 year according to recent meta-analyses, underscoring the importance of ongoing surveillance. This approach contributes to the broader debate favoring early control over rate control, as strategies have been linked to reduced cardiovascular mortality, events, and in contemporary guidelines.