Subcutaneous implantable defibrillator

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S-ICD lead and generator position S-ICD.jpg
S-ICD lead and generator position

Subcutaneous implantable cardioverter defibrillator, or S-ICD, is an implantable medical device for detecting and terminating ventricular tachycardia and ventricular fibrillation in patients at risk of sudden cardiac arrest. [1] It is a type of implantable cardioverter defibrillator but unlike the transvenous ICD, the S-ICD lead is placed just under the skin, leaving the heart and veins untouched.

Contents

The S-ICD was developed to reduce the risk of complications associated with transvenous leads. [2] Potential complications, such as infections in the bloodstream and the need to remove or replace the leads in the heart, are minimised or entirely eliminated with the S-ICD system.

Transvenous ICD (leads in the heart)

Pros

The generator is smaller than the S-ICD generator, which may result in a less visible implanted device. This could improve the time needed to get used to the implantable device, although this is subjective. The procedure can usually be done under local anesthesia and light sedation. The transvenous ICD is capable of pacing for bradycardia and delivering antitachycardia pacing (ATP). However, device-related complications were numerically more frequent in patients with transvenous ICDs, inappropriate shocks are less frequent that in those with subcutaneous ICDs. [3]

Cons

The leads go into the vein and heart and will grow into the heart wall over time. This may increase the chance of complications if the leads need to be removed or replaced, as the procedure to extract an intracardiac leads can be a challenge. Because the leads need to go into the heart they need to be relatively thin and flexible, since they have to pass through (and remain in) the heart valve(s) and need to flex with every heartbeat. This makes the leads more vulnerable to lead fracture (and therefore complications). It has been demonstrated that device-related complications were numerically more frequent in patients with transvenous ICDs. [3] Due to the position of the pulse generator under the collarbone, it can be more visible with clothing with low neckline.

Patient selection

Patients who are relatively older, who need ICD for secondary prevention, or who have concomitant bradycardia requiring pacing, or heart failure requiring cardiac resynchronisation therapy are more suitable for transvenous ICD implantation. An older patient with ischemic cardiomyopathy and documented symptomatic ventricular tachycardia is a typical example. [4]

Subcutaneous ICD (lead under the skin)

Pros

The lead does not go into the heart, which means it leaves the veins and the heart completely intact. This reduces chance of complications (e.g. systemic infections). Because the lead does not go into the heart it can be thicker and more robust. This minimizes / reduces the chance of lead fracture. In the event the system needs to be explanted, the procedure is a relatively simple surgical procedure.

Cons

The pulse generator is larger than most transvenous ICD pulse generators. This could result in a longer time needed to get used to it, although this is subjective. Depending on the physique of a person, the S-ICD may be more visible with bare chest. The procedure usually requires deep sedation or general anaesthesia, as creating a larger pocket between the muscles and tunnelling the lead over the sternum, as well as performing defibrillation threshold testing, can be quite painful. The S-ICD can deliver only temporary post-shock pacing, but cannot otherwise address bradycardia and cannot deliver anti-tachycardia pacing. Inappropriate shocks were numerically more frequent in those with subcutaneous ICDs. [3] Defibrillation testing has traditionally been considered mandatory in patients with subcutaneous implantable cardioverter–defibrillator to confirm appropriate ventricular fibrillation detection. [5] However, PRAETORIAN-DFT randomised clinical trial is aiming to demonstrate non-inferiority of omitting DFT in patients undergoing S-ICD implantation in which the S-ICD system components are optimally positioned by calculated PRAETORIAN score. [6]

Patient selection

Patients who are relatively younger, who need ICD for primary prevention, and who do not require pacing or cardiac resynchronisation therapy, are more suitable for S-ICD implantation. A young survivor of aborted sudden cardiac death is a typical example.

Transvenous vs subcutaneous ICD implantation procedure

Transvenous ICD implant procedureSubcutaneous ICD implant procedure
A transvenous ICD is typically implanted in the left shoulder area, near the collarbone. Occasionally the right side is preferred for certain patients or other specific reasons.In contrast to a transvenous ICD, the pulse generator is implanted on the left side of the chest next to the rib cage, just under the arm, and the lead is implanted just under the skin above the breastbone.
Using X-ray imaging (fluoroscopy), the leads are fed through a vein into the heart and through the heart valve(s) into the heart.Guided by anatomical landmarks and/or an X-ray image, the subcutaneous ICD electrode is tunneled under the skin. The subcutaneous ICD delivers therapy without the need for wires implanted in the heart.
Depending on heart condition, 1, 2 or 3 leads will be placed in the heart. Once the leads are put in place, they are attached to the heart wall for optimal connectivity.The subcutaneous ICD leaves the heart and blood vessels untouched and intact.

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<span class="mw-page-title-main">Defibrillation</span> Treatment for life-threatening cardiac arrhythmias

Defibrillation is a treatment for life-threatening cardiac arrhythmias, specifically ventricular fibrillation (V-Fib) and non-perfusing ventricular tachycardia (V-Tach). A defibrillator delivers a dose of electric current to the heart. Although not fully understood, this process depolarizes a large amount of the heart muscle, ending the arrhythmia. Subsequently, the body's natural pacemaker in the sinoatrial node of the heart is able to re-establish normal sinus rhythm. A heart which is in asystole (flatline) cannot be restarted by a defibrillator; it would be treated only by cardiopulmonary resuscitation (CPR) and medication, and then by cardioversion or defibrillation if it converts into a shockable rhythm.

<span class="mw-page-title-main">Ventricular fibrillation</span> Rapid quivering of the ventricles of the heart

Ventricular fibrillation is an abnormal heart rhythm in which the ventricles of the heart quiver. It is due to disorganized electrical activity. Ventricular fibrillation results in cardiac arrest with loss of consciousness and no pulse. This is followed by sudden cardiac death in the absence of treatment. Ventricular fibrillation is initially found in about 10% of people with cardiac arrest.

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An implantable cardioverter-defibrillator (ICD) or automated implantable cardioverter defibrillator (AICD) is a device implantable inside the body, able to perform defibrillation, and depending on the type, cardioversion and pacing of the heart. The ICD is the first-line treatment and prophylactic therapy for patients at risk for sudden cardiac death due to ventricular fibrillation and ventricular tachycardia.

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Short QT syndrome (SQT) is a very rare genetic disease of the electrical system of the heart, and is associated with an increased risk of abnormal heart rhythms and sudden cardiac death. The syndrome gets its name from a characteristic feature seen on an electrocardiogram (ECG) – a shortening of the QT interval. It is caused by mutations in genes encoding ion channels that shorten the cardiac action potential, and appears to be inherited in an autosomal dominant pattern. The condition is diagnosed using a 12-lead ECG. Short QT syndrome can be treated using an implantable cardioverter-defibrillator or medications including quinidine. Short QT syndrome was first described in 2000, and the first genetic mutation associated with the condition was identified in 2004.

<span class="mw-page-title-main">Ventricular tachycardia</span> Medical condition of the heart

Ventricular tachycardia is a cardiovascular disorder in which fast heart rate occurs in the ventricles of the heart. Although a few seconds of VT may not result in permanent problems, longer periods are dangerous; and multiple episodes over a short period of time are referred to as an electrical storm. Short periods may occur without symptoms, or present with lightheadedness, palpitations, shortness of breath, chest pain, and decreased level of consciousness. Ventricular tachycardia may lead to coma and persistent vegetative state due to lack of blood and oxygen to the brain. Ventricular tachycardia may result in ventricular fibrillation (VF) and turn into cardiac arrest. This conversion of the VT into VF is called the degeneration of the VT. It is found initially in about 7% of people in cardiac arrest.

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<span class="mw-page-title-main">Arrhythmia</span> Group of medical conditions characterized by irregular heartbeat

Arrhythmias, also known as cardiac arrhythmias, are irregularities in the heartbeat, including when it is too fast or too slow. A resting heart rate that is too fast – above 100 beats per minute in adults – is called tachycardia, and a resting heart rate that is too slow – below 60 beats per minute – is called bradycardia. Some types of arrhythmias have no symptoms. Symptoms, when present, may include palpitations or feeling a pause between heartbeats. In more serious cases, there may be lightheadedness, passing out, shortness of breath, chest pain, or decreased level of consciousness. While most cases of arrhythmia are not serious, some predispose a person to complications such as stroke or heart failure. Others may result in sudden death.

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Defibrillation threshold indicates the minimum amount of energy needed to return normal rhythm to a heart that is beating in a cardiac dysrhythmia. Typical examples are the minimum amount of energy, expressed in joules, delivered by external defibrillator paddles or pads, required to break atrial fibrillation and restore normal sinus rhythm. Other common scenarios are restoring normal rhythm from atrial flutter, ventricular tachycardia or ventricular fibrillation. The defibrillation threshold ranking in these settings, from lowest to highest, would be, in order, ventricular tachycardia, atrial flutter, atrial fibrillation, ventricular fibrillation. The highest amount of energy that an external defibrillator can deliver at the present time is 360 joules biphasic. In clinical practice, the real threshold can be approximated but not exactly established, since the defibrillating shock can be delivered only once. Aside from that, energy isn't directly related to stimulus strength and efficiency, which is primarily determined by the delivered charge over time in mC and not power over time or energy, which are still used due to historical reasons. Charge based thresholds are more realistic parameters for shock efficacy. Usual values delivered by biphasic defibrillators lay between 50 and 300 mC. The amount of charge needed is influenced by bertain medications, in particular sotalol, tend to lower such threshold, while others, such as amiodarone, may increase it.

<span class="mw-page-title-main">Twiddler's syndrome</span> Medical condition

Twiddler's syndrome is a malfunction of a pacemaker due to manipulation of the device and the consequent dislodging of the leads from their intended location. As the leads move, they stop pacing the heart and can cause strange symptoms such as phrenic nerve stimulation resulting in abdominal pulsing or brachial plexus stimulation resulting in rhythmic arm twitching. Twiddler's syndrome in patients with an implanted defibrilator may lead to inadequate, painful defibrillation-shocks.

References

  1. Westerman, Stacy B; El-Chami, Mikhael (2018). "The subcutaneous implantable cardioverter defibrillator––review of the recent data". Journal of Geriatric Cardiology. 15 (3): 222–228. doi:10.11909/j.issn.1671-5411.2018.03.004 (inactive 2024-05-10). ISSN   1671-5411. PMC   5919810 . PMID   29721001.{{cite journal}}: CS1 maint: DOI inactive as of May 2024 (link)
  2. Baalman, S. W. E.; Quast, A. B. E.; Brouwer, T. F.; Knops, R. E. (2018). "An Overview of Clinical Outcomes in Transvenous and Subcutaneous ICD Patients". Current Cardiology Reports. 20 (9): 72. doi:10.1007/s11886-018-1021-8. ISSN   1523-3782. PMC   6061190 . PMID   29992422.
  3. Poole, Jeanne E.; Olshansky, Brian; Mark, Daniel B.; Anderson, Jill; Johnson, George; Hellkamp, Anne S.; Davidson-Ray, Linda; Fishbein, Daniel P.; Boineau, Robin E.; Anstrom, Kevin J.; Reinhall, Per G.; Packer, Douglas L.; Lee, Kerry L.; Bardy, Gust H. (2020-07-28). "Long-Term Outcomes of Implantable Cardioverter-Defibrillator Therapy in the SCD-HeFT". Journal of the American College of Cardiology. 76 (4): 405–415. doi:10.1016/j.jacc.2020.05.061. ISSN   0735-1097. PMID   32703511.
  4. Waroux, Jean-Benoit le Polain de; Ploux, Sylvain; Mondoly, Pierre; Eschalier, Romain; Strik, Marc; Houard, Laura; Pierre, Bertrand; Buliard, Samuel; Klotz, Nicolas; Ritter, Philippe; Haissaguerre, Michel (2018-05-01). "Defibrillation testing is mandatory in patients with subcutaneous implantable cardioverter–defibrillator to confirm appropriate ventricular fibrillation detection". Heart Rhythm. 15 (5): 642–650. doi: 10.1016/j.hrthm.2018.02.013 . ISSN   1547-5271. PMID   29709229.
  5. Quast, Anne-Floor B. E.; Baalman, Sarah W. E.; Betts, Tim R.; Boersma, Lucas V. A.; Bonnemeier, Hendrik; Boveda, Serge; Brouwer, Tom F.; Burke, Martin C.; Delnoy, Peter Paul H. M.; El-Chami, Mikhael; Kuschyk, Juergen (August 2019). "Rationale and design of the PRAETORIAN-DFT trial: A prospective randomized CompArative trial of SubcutanEous ImplanTable CardiOverter-DefibrillatoR ImplANtation with and without DeFibrillation testing" (PDF). American Heart Journal. 214: 167–174. doi:10.1016/j.ahj.2019.05.002. ISSN   1097-6744. PMID   31220775. S2CID   181898926.
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