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A pacemaker patient’s electrical dilemma

CASE: Relapsing depression

Mrs. A, age 41, presents with worsening depression and suicidal ideation with a plan to take an overdose of her medications. She describes herself as “tense, anxious, and worrying all the time.” She reports worsening mood, loss of interest in previously pleasurable activities, lack of energy and drive, and difficulties performing routine household tasks. She also endorses a combination of initial and middle insomnia. According to her husband, the patient has been slow in movement and speech and has not been taking adequate care of herself.

Mrs. A denies auditory or visual hallucinations, thought insertion, thought withdrawal, thought broadcast, ideas of reference, or paranoid ideation. She also denies recent or past symptoms of mania or hypomania.

Mrs. A has a history of alcohol abuse and major depressive disorder. For her first depressive episode 5 years ago, she was treated with paroxetine, 20 to 80 mg/d, with good results. Following a depressive relapse, she was switched to fluoxetine, 80 mg/d, which improved her depressive symptoms. Approximately 2 years later, she experienced another depressive relapse that resulted in hospitalization. During hospitalization and subsequent outpatient visits, she was treated with citalopram, 20 mg/d, ziprasidone, 80 mg bid, and lorazepam, 1 mg tid. Her depressive symptoms were in partial remission for 2 years until her current relapse.

Her medical history includes syncope of unexplained origin, for which she received an implanted cardiac pacemaker 3 years ago. She takes sertraline, 150 mg/d, methylphenidate, 15 mg/d, and trazodone, 200 mg at night. Laboratory testing is unremarkable.

On mental status examination, Mrs. A’s mood is sad and her affect constricted. Her speech is fluent but slow, and she speaks only when spoken to. We note that Mrs. A has thought blocking but no hallucinations or delusions. She is alert and oriented, but her attention and concentration are impaired. Her insight is fair, and judgment is poor.

The authors’ observations

Somatic therapy for severe major depressive disorders has been limited principally to pharmacotherapy. Despite the availability of effective antidepressants and aggressive treatment, for many patients—such as Mrs. A—the course of depression is characterized by relapse, recurrence, and chronicity.1,2

Because Mrs. A has treatment-refractory depression, we decide to treat her with ECT. ECT has few contraindications and typically is well tolerated. It commonly is used to treat depression in patients with cardiac conditions and generally is quite safe in this population.3,4

ECT in patients with cardiac pacemakers in situ theoretically presents an increased risk of complications, however.5 Specific concerns of administering ECT to pacemaker patients include electrical interference from ECT stimulus and pacemaker sensing of:

  • myopotentials that originate from succinylcholine-induced fasciculation (muscular twitching of contiguous groups of muscle fibers)
  • muscle contractions that result in incomplete muscle paralysis
  • dysrhythmias during the seizure.

Interference caused by electrical stimulation during ECT may vary by pacemaker manufacturer and model. Each model requires different specifications and software. For all pacemakers, skeletal muscle potentials that occur during ECT may fall within the range of the pacemaker sensing circuit and inhibit or trigger pacemaker activity.

Skeletal muscle can generate significant electrical potentials that are well within the sensing capabilities of most newer pulse generators. This happens most frequently in some dual-chamber pacemakers that can automatically perform mode switching or adapt their sensing and pacing thresholds to new situations, which might make them more sensitive to interference by ECT.

Similar concerns apply to administering ECT to patients receiving vagus nerve stimulation (VNS) therapy, as both VNS pulse generators and cardiac pacemakers are battery-powered, electrical signal-producing mechanisms housed in a metal case. The safety of concurrent ECT and VNS therapy is unknown (Box).6,7

Box

Concomitant use of ECT and vagus nerve stimulation

Although vagus nerve stimulation (VNS) and electroconvulsive therapy (ECT) are not mutually exclusive, the safety of concurrent use of these 2 therapies is uncertain.6 The manufacturer of the VNS device recommends turning off the VNS pulse generator before administering ECT. In at least 1 case report, however, ECT was administered safely without the VNS pulse generator turned off.7

No case reports describe the safety of VNS in patients with an implanted device such as a pacemaker or automatic cardioverter defibrillator. According to the manufacturer, the VNS system may affect the operation of other devices. For VNS patients who require an implantable pacemaker, defibrillator therapy, or other types of stimulators, the VNS manufacturer advises careful programming of each system and implanting the 2 stimulators at least 10 centimeters (4 inches) apart to avoid communication interference.

 

 

What the evidence says

In evidence-based medicine, we tend to say: “In God we trust; all the others have to bring their data.” Unfortunately, it is difficult to conduct a trial of patients with multiple medical issues. Based on anecdotal reports, it appears that ECT use in patients with an implanted cardiac device such as a pacemaker or automatic internal cardioverter-defibrillator (AICD) generally is safe.8-12

One case report describes successful administration of ECT in a treatment-refractory depressed patient with an AICD. The AICD was deactivated during ECT and re-activated immediately upon completion of each treatment. The case report’s authors concluded that the presence of an AICD should not be a contraindication to ECT.13

A chart review of 3 patients with ICDs who received concurrent ECT found treatment was generally uneventful.12 One patient developed tachycardia with a rate-dependent left bundle branch block and hypotension in the recovery room, which responded promptly to esmolol. She did not experience similar events after subsequent ECT treatments.

Minimizing risk

In the absence of controlled data about the use of ECT in patients with implanted cardiac devices, crucial therapeutic decisions depend on the physician’s skill and judgment. Risk strategies can minimize complications (Algorithm).12 An internist or cardiologist experienced in pacemaker management should conduct a device interrogation—evaluating thresholds, lead impedance, and battery voltage and reviewing histograms, mode switch episodes, and stored electrograms—before the first ECT session and after the final one.

Most modern implantable pacemakers work in the synchronous (demand), rate-adaptive mode. In a patient in whom non-cardiac electrical signals cause bradycardia or asystole during ECT, the pacemaker can be reprogrammed to be less sensitive by placing a magnet over the pulse generator, which converts the pacemaker to an asynchronous (fixed), non-sensing mode. It is important to keep in mind that magnet application will not “turn off” a pacemaker; although each pacemaker is programmed to respond to a magnet in a specific fashion, the main response is asynchronous pacing.

Reprogramming the pacemaker to diminish its sensitivity also may be prudent for patients in whom succinylcholine causes fasciculation that inhibits pacemaker output. Such patients can be switched to a nondepolarizing muscle relaxant such as altacurium for future ECT treatments.

Careful cardiac monitoring during ECT is essential (Table). The cardiologist or internist should be available during the first few ECT sessions to monitor for potential pacemaker interference or malfunction. This physician should be familiar with the pacemaker model and type of lead system so he or she can deactivate, reactivate, or reprogram the device.

Algorithm

Reducing risk when administering ECT to cardiac pacemaker patients

Step 1 
Evaluate the patient to ensure medical suitability for ECT and associated anesthesia
Step 2
Conduct pacemaker interrogation (evaluating thresholds, lead impedance, and battery voltage and reviewing histograms, mode switch episodes, and stored electrograms) prior to first ECT treatment and after completion of full ECT course
Step 3
Perform cardiac monitoring during and immediately after administering ECT
Step 4
Have a magnet available to reprogram the pacemaker in the event of pacemaker inhibition or symptomatic bradycardia during ECT
Step 5
Check that all monitoring devices are properly grounded, insulate the patient’s stretcher, and ensure that the patient does not touch anyone who is in contact with the ground during presentation of the ECT electrical stimulus
ECT: electroconvulsive therapy
Source: Reference 12
Table

Guidelines for monitoring cardiac pacemaker patients during ECT

Use multilead ECG monitoring
Have equipment available to rapidly obtain central access (if vasoactive medications or transvenous pacing is needed)
Assess the plethysmography tracing of the pulse oximeter (a useful surrogate if the patient experiences dysrhythmias)
Have ready an external defibrillator

TREATMENT: Successful ECT

We seek a medical consultation before initiating ECT. An internist performs device interrogation before the first ECT treatment and is present in the ECT treatment suite to ensure proper pacemaker conversion and to monitor for cardiac complications. The internist conducts another device interrogation after the acute series of ECT treatments.

Mrs. A tolerates the ECT sessions without cardiac complications. Her depressive symptoms respond well to 12 ECT sessions. She is more interactive and reports better attention and concentration. Although Mrs. A still has middle and initial insomnia, she denies thoughts of harming herself or anyone else.

Related resources

Drug brand names

  • Atracurium • Tracrium
  • Citalopram • Celexa
  • Esmolol • Brevibloc
  • Fluoxetine • Prozac
  • Lorazepam • Ativan
  • Methylphenidate • Ritalin, Concerta, others
  • Nortriptyline • Aventyl, Pamelor, others
  • Paroxetine • Paxil
  • Sertraline • Zoloft
  • Succinylcholine • Anectine
  • Trazodone • Desyrel
  • Venlafaxine • Effexor
  • Ziprasidone • Geodon
Disclosure

Dr. Romanowicz reports no financial relationship with any company whose products are mentioned in this article or with manufacturers of competing products.

 

 

Dr. Ramaswamy receives research support from Bristol-Myers Squibb, Shire, and Forest Pharmaceuticals and is a consultant to Dainippon Sumitomo Pharma.

References

1. American Psychiatric Association Committee on ECT. The practice of electroconvulsive therapy: recommendations for treatment, training, and privileging. 2nd ed. Washington, D.C: American Psychiatric Association; 2001.

2. Russell JC, Rasmussen KG, O’Connor MK, et al. Long-term maintenance ECT: a retrospective review of efficacy and cognitive outcome. J ECT. 2003;19(1):4-9.

3. Alexopoulos GS, Shamoian CJ, Lucas J, et al. Medical problems of geriatric psychiatric patients and younger controls during electroconvulsive therapy. J Am Geriatr Soc. 1984;32(9):651-654.

4. Rasmussen KG, Rummans TA, Richardson JR. Electroconvulsive therapy in the medically ill. Psychiatric Clin North Am. 2002;25:177-193.

5. MacPherson RD, Loo CK, Barrett N. Electroconvulsive therapy in patients with cardiac pacemakers. Anaesth Intensive Care. 2006;34(4):470-474.

6. Burke MJ, Husain MM. Concomitant use of vagus nerve stimulation and electroconvulsive therapy for treatment-resistant depression. J ECT. 2006;22(3):218-222.

7. Husain MM, Montgomery JH, Fernandes P, et al. Safety of vagus nerve stimulation with ECT. Am J Psychiatry. 2002;159:1243.-

8. Alexopoulos GS, Frances RJ. ECT and cardiac patients with pacemakers. Am J Psychiatry. 1980;137(9):1111-1112.

9. Stone KR, McPherson CA. Assessment and management of patients with pacemakers and implantable cardioverter defibrillators. Crit Care Med. 2004;32(4 suppl):S155-S165.

10. Maisel WH, Sweeney MO, Stevenson WG, et al. Recalls and safety alerts involving pacemakers and implantable cardioverter-defibrillator generators. JAMA. 2001;286(7):793-799.

11. Gibson TC, Leaman DM, Devors J, et al. Pacemaker function in relation to electroconvulsive therapy. Chest. 1973;63(6):1025-1027.

12. Dolenc TJ, Barnes RD, Hayes DL, et al. Electroconvulsive therapy in patients with cardiac pacemakers and implantable cardioverter defibrillators. Pacing Clin Electrophysiol. 2004;27(9):1257-1263.

13. Lapid MI, Rummans TA, Hofmann VE, et al. ECT and automatic internal cardioverter-defibrillator. J ECT. 2001;17(2):146-148.

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Magdalena Romanowicz, MD;
Sriram Ramaswamy, MD
Dr. Romanowicz is a first-year psychiatry resident, Mayo Clinic, Rochester, MN. Dr. Ramaswamy is assistant professor of psychiatry, Creighton University, Omaha, NE.

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Current Psychiatry - 08(01)
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pacemaker; implanted cardiac pacemaker; depression; electroconvulsive therapy; ECT; vagus nerve stimulation; VNS; Magdalena Romanowicz; Sriram Ramaswamy
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Magdalena Romanowicz, MD;
Sriram Ramaswamy, MD
Dr. Romanowicz is a first-year psychiatry resident, Mayo Clinic, Rochester, MN. Dr. Ramaswamy is assistant professor of psychiatry, Creighton University, Omaha, NE.

Author and Disclosure Information

Magdalena Romanowicz, MD;
Sriram Ramaswamy, MD
Dr. Romanowicz is a first-year psychiatry resident, Mayo Clinic, Rochester, MN. Dr. Ramaswamy is assistant professor of psychiatry, Creighton University, Omaha, NE.

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CASE: Relapsing depression

Mrs. A, age 41, presents with worsening depression and suicidal ideation with a plan to take an overdose of her medications. She describes herself as “tense, anxious, and worrying all the time.” She reports worsening mood, loss of interest in previously pleasurable activities, lack of energy and drive, and difficulties performing routine household tasks. She also endorses a combination of initial and middle insomnia. According to her husband, the patient has been slow in movement and speech and has not been taking adequate care of herself.

Mrs. A denies auditory or visual hallucinations, thought insertion, thought withdrawal, thought broadcast, ideas of reference, or paranoid ideation. She also denies recent or past symptoms of mania or hypomania.

Mrs. A has a history of alcohol abuse and major depressive disorder. For her first depressive episode 5 years ago, she was treated with paroxetine, 20 to 80 mg/d, with good results. Following a depressive relapse, she was switched to fluoxetine, 80 mg/d, which improved her depressive symptoms. Approximately 2 years later, she experienced another depressive relapse that resulted in hospitalization. During hospitalization and subsequent outpatient visits, she was treated with citalopram, 20 mg/d, ziprasidone, 80 mg bid, and lorazepam, 1 mg tid. Her depressive symptoms were in partial remission for 2 years until her current relapse.

Her medical history includes syncope of unexplained origin, for which she received an implanted cardiac pacemaker 3 years ago. She takes sertraline, 150 mg/d, methylphenidate, 15 mg/d, and trazodone, 200 mg at night. Laboratory testing is unremarkable.

On mental status examination, Mrs. A’s mood is sad and her affect constricted. Her speech is fluent but slow, and she speaks only when spoken to. We note that Mrs. A has thought blocking but no hallucinations or delusions. She is alert and oriented, but her attention and concentration are impaired. Her insight is fair, and judgment is poor.

The authors’ observations

Somatic therapy for severe major depressive disorders has been limited principally to pharmacotherapy. Despite the availability of effective antidepressants and aggressive treatment, for many patients—such as Mrs. A—the course of depression is characterized by relapse, recurrence, and chronicity.1,2

Because Mrs. A has treatment-refractory depression, we decide to treat her with ECT. ECT has few contraindications and typically is well tolerated. It commonly is used to treat depression in patients with cardiac conditions and generally is quite safe in this population.3,4

ECT in patients with cardiac pacemakers in situ theoretically presents an increased risk of complications, however.5 Specific concerns of administering ECT to pacemaker patients include electrical interference from ECT stimulus and pacemaker sensing of:

  • myopotentials that originate from succinylcholine-induced fasciculation (muscular twitching of contiguous groups of muscle fibers)
  • muscle contractions that result in incomplete muscle paralysis
  • dysrhythmias during the seizure.

Interference caused by electrical stimulation during ECT may vary by pacemaker manufacturer and model. Each model requires different specifications and software. For all pacemakers, skeletal muscle potentials that occur during ECT may fall within the range of the pacemaker sensing circuit and inhibit or trigger pacemaker activity.

Skeletal muscle can generate significant electrical potentials that are well within the sensing capabilities of most newer pulse generators. This happens most frequently in some dual-chamber pacemakers that can automatically perform mode switching or adapt their sensing and pacing thresholds to new situations, which might make them more sensitive to interference by ECT.

Similar concerns apply to administering ECT to patients receiving vagus nerve stimulation (VNS) therapy, as both VNS pulse generators and cardiac pacemakers are battery-powered, electrical signal-producing mechanisms housed in a metal case. The safety of concurrent ECT and VNS therapy is unknown (Box).6,7

Box

Concomitant use of ECT and vagus nerve stimulation

Although vagus nerve stimulation (VNS) and electroconvulsive therapy (ECT) are not mutually exclusive, the safety of concurrent use of these 2 therapies is uncertain.6 The manufacturer of the VNS device recommends turning off the VNS pulse generator before administering ECT. In at least 1 case report, however, ECT was administered safely without the VNS pulse generator turned off.7

No case reports describe the safety of VNS in patients with an implanted device such as a pacemaker or automatic cardioverter defibrillator. According to the manufacturer, the VNS system may affect the operation of other devices. For VNS patients who require an implantable pacemaker, defibrillator therapy, or other types of stimulators, the VNS manufacturer advises careful programming of each system and implanting the 2 stimulators at least 10 centimeters (4 inches) apart to avoid communication interference.

 

 

What the evidence says

In evidence-based medicine, we tend to say: “In God we trust; all the others have to bring their data.” Unfortunately, it is difficult to conduct a trial of patients with multiple medical issues. Based on anecdotal reports, it appears that ECT use in patients with an implanted cardiac device such as a pacemaker or automatic internal cardioverter-defibrillator (AICD) generally is safe.8-12

One case report describes successful administration of ECT in a treatment-refractory depressed patient with an AICD. The AICD was deactivated during ECT and re-activated immediately upon completion of each treatment. The case report’s authors concluded that the presence of an AICD should not be a contraindication to ECT.13

A chart review of 3 patients with ICDs who received concurrent ECT found treatment was generally uneventful.12 One patient developed tachycardia with a rate-dependent left bundle branch block and hypotension in the recovery room, which responded promptly to esmolol. She did not experience similar events after subsequent ECT treatments.

Minimizing risk

In the absence of controlled data about the use of ECT in patients with implanted cardiac devices, crucial therapeutic decisions depend on the physician’s skill and judgment. Risk strategies can minimize complications (Algorithm).12 An internist or cardiologist experienced in pacemaker management should conduct a device interrogation—evaluating thresholds, lead impedance, and battery voltage and reviewing histograms, mode switch episodes, and stored electrograms—before the first ECT session and after the final one.

Most modern implantable pacemakers work in the synchronous (demand), rate-adaptive mode. In a patient in whom non-cardiac electrical signals cause bradycardia or asystole during ECT, the pacemaker can be reprogrammed to be less sensitive by placing a magnet over the pulse generator, which converts the pacemaker to an asynchronous (fixed), non-sensing mode. It is important to keep in mind that magnet application will not “turn off” a pacemaker; although each pacemaker is programmed to respond to a magnet in a specific fashion, the main response is asynchronous pacing.

Reprogramming the pacemaker to diminish its sensitivity also may be prudent for patients in whom succinylcholine causes fasciculation that inhibits pacemaker output. Such patients can be switched to a nondepolarizing muscle relaxant such as altacurium for future ECT treatments.

Careful cardiac monitoring during ECT is essential (Table). The cardiologist or internist should be available during the first few ECT sessions to monitor for potential pacemaker interference or malfunction. This physician should be familiar with the pacemaker model and type of lead system so he or she can deactivate, reactivate, or reprogram the device.

Algorithm

Reducing risk when administering ECT to cardiac pacemaker patients

Step 1 
Evaluate the patient to ensure medical suitability for ECT and associated anesthesia
Step 2
Conduct pacemaker interrogation (evaluating thresholds, lead impedance, and battery voltage and reviewing histograms, mode switch episodes, and stored electrograms) prior to first ECT treatment and after completion of full ECT course
Step 3
Perform cardiac monitoring during and immediately after administering ECT
Step 4
Have a magnet available to reprogram the pacemaker in the event of pacemaker inhibition or symptomatic bradycardia during ECT
Step 5
Check that all monitoring devices are properly grounded, insulate the patient’s stretcher, and ensure that the patient does not touch anyone who is in contact with the ground during presentation of the ECT electrical stimulus
ECT: electroconvulsive therapy
Source: Reference 12
Table

Guidelines for monitoring cardiac pacemaker patients during ECT

Use multilead ECG monitoring
Have equipment available to rapidly obtain central access (if vasoactive medications or transvenous pacing is needed)
Assess the plethysmography tracing of the pulse oximeter (a useful surrogate if the patient experiences dysrhythmias)
Have ready an external defibrillator

TREATMENT: Successful ECT

We seek a medical consultation before initiating ECT. An internist performs device interrogation before the first ECT treatment and is present in the ECT treatment suite to ensure proper pacemaker conversion and to monitor for cardiac complications. The internist conducts another device interrogation after the acute series of ECT treatments.

Mrs. A tolerates the ECT sessions without cardiac complications. Her depressive symptoms respond well to 12 ECT sessions. She is more interactive and reports better attention and concentration. Although Mrs. A still has middle and initial insomnia, she denies thoughts of harming herself or anyone else.

Related resources

Drug brand names

  • Atracurium • Tracrium
  • Citalopram • Celexa
  • Esmolol • Brevibloc
  • Fluoxetine • Prozac
  • Lorazepam • Ativan
  • Methylphenidate • Ritalin, Concerta, others
  • Nortriptyline • Aventyl, Pamelor, others
  • Paroxetine • Paxil
  • Sertraline • Zoloft
  • Succinylcholine • Anectine
  • Trazodone • Desyrel
  • Venlafaxine • Effexor
  • Ziprasidone • Geodon
Disclosure

Dr. Romanowicz reports no financial relationship with any company whose products are mentioned in this article or with manufacturers of competing products.

 

 

Dr. Ramaswamy receives research support from Bristol-Myers Squibb, Shire, and Forest Pharmaceuticals and is a consultant to Dainippon Sumitomo Pharma.

CASE: Relapsing depression

Mrs. A, age 41, presents with worsening depression and suicidal ideation with a plan to take an overdose of her medications. She describes herself as “tense, anxious, and worrying all the time.” She reports worsening mood, loss of interest in previously pleasurable activities, lack of energy and drive, and difficulties performing routine household tasks. She also endorses a combination of initial and middle insomnia. According to her husband, the patient has been slow in movement and speech and has not been taking adequate care of herself.

Mrs. A denies auditory or visual hallucinations, thought insertion, thought withdrawal, thought broadcast, ideas of reference, or paranoid ideation. She also denies recent or past symptoms of mania or hypomania.

Mrs. A has a history of alcohol abuse and major depressive disorder. For her first depressive episode 5 years ago, she was treated with paroxetine, 20 to 80 mg/d, with good results. Following a depressive relapse, she was switched to fluoxetine, 80 mg/d, which improved her depressive symptoms. Approximately 2 years later, she experienced another depressive relapse that resulted in hospitalization. During hospitalization and subsequent outpatient visits, she was treated with citalopram, 20 mg/d, ziprasidone, 80 mg bid, and lorazepam, 1 mg tid. Her depressive symptoms were in partial remission for 2 years until her current relapse.

Her medical history includes syncope of unexplained origin, for which she received an implanted cardiac pacemaker 3 years ago. She takes sertraline, 150 mg/d, methylphenidate, 15 mg/d, and trazodone, 200 mg at night. Laboratory testing is unremarkable.

On mental status examination, Mrs. A’s mood is sad and her affect constricted. Her speech is fluent but slow, and she speaks only when spoken to. We note that Mrs. A has thought blocking but no hallucinations or delusions. She is alert and oriented, but her attention and concentration are impaired. Her insight is fair, and judgment is poor.

The authors’ observations

Somatic therapy for severe major depressive disorders has been limited principally to pharmacotherapy. Despite the availability of effective antidepressants and aggressive treatment, for many patients—such as Mrs. A—the course of depression is characterized by relapse, recurrence, and chronicity.1,2

Because Mrs. A has treatment-refractory depression, we decide to treat her with ECT. ECT has few contraindications and typically is well tolerated. It commonly is used to treat depression in patients with cardiac conditions and generally is quite safe in this population.3,4

ECT in patients with cardiac pacemakers in situ theoretically presents an increased risk of complications, however.5 Specific concerns of administering ECT to pacemaker patients include electrical interference from ECT stimulus and pacemaker sensing of:

  • myopotentials that originate from succinylcholine-induced fasciculation (muscular twitching of contiguous groups of muscle fibers)
  • muscle contractions that result in incomplete muscle paralysis
  • dysrhythmias during the seizure.

Interference caused by electrical stimulation during ECT may vary by pacemaker manufacturer and model. Each model requires different specifications and software. For all pacemakers, skeletal muscle potentials that occur during ECT may fall within the range of the pacemaker sensing circuit and inhibit or trigger pacemaker activity.

Skeletal muscle can generate significant electrical potentials that are well within the sensing capabilities of most newer pulse generators. This happens most frequently in some dual-chamber pacemakers that can automatically perform mode switching or adapt their sensing and pacing thresholds to new situations, which might make them more sensitive to interference by ECT.

Similar concerns apply to administering ECT to patients receiving vagus nerve stimulation (VNS) therapy, as both VNS pulse generators and cardiac pacemakers are battery-powered, electrical signal-producing mechanisms housed in a metal case. The safety of concurrent ECT and VNS therapy is unknown (Box).6,7

Box

Concomitant use of ECT and vagus nerve stimulation

Although vagus nerve stimulation (VNS) and electroconvulsive therapy (ECT) are not mutually exclusive, the safety of concurrent use of these 2 therapies is uncertain.6 The manufacturer of the VNS device recommends turning off the VNS pulse generator before administering ECT. In at least 1 case report, however, ECT was administered safely without the VNS pulse generator turned off.7

No case reports describe the safety of VNS in patients with an implanted device such as a pacemaker or automatic cardioverter defibrillator. According to the manufacturer, the VNS system may affect the operation of other devices. For VNS patients who require an implantable pacemaker, defibrillator therapy, or other types of stimulators, the VNS manufacturer advises careful programming of each system and implanting the 2 stimulators at least 10 centimeters (4 inches) apart to avoid communication interference.

 

 

What the evidence says

In evidence-based medicine, we tend to say: “In God we trust; all the others have to bring their data.” Unfortunately, it is difficult to conduct a trial of patients with multiple medical issues. Based on anecdotal reports, it appears that ECT use in patients with an implanted cardiac device such as a pacemaker or automatic internal cardioverter-defibrillator (AICD) generally is safe.8-12

One case report describes successful administration of ECT in a treatment-refractory depressed patient with an AICD. The AICD was deactivated during ECT and re-activated immediately upon completion of each treatment. The case report’s authors concluded that the presence of an AICD should not be a contraindication to ECT.13

A chart review of 3 patients with ICDs who received concurrent ECT found treatment was generally uneventful.12 One patient developed tachycardia with a rate-dependent left bundle branch block and hypotension in the recovery room, which responded promptly to esmolol. She did not experience similar events after subsequent ECT treatments.

Minimizing risk

In the absence of controlled data about the use of ECT in patients with implanted cardiac devices, crucial therapeutic decisions depend on the physician’s skill and judgment. Risk strategies can minimize complications (Algorithm).12 An internist or cardiologist experienced in pacemaker management should conduct a device interrogation—evaluating thresholds, lead impedance, and battery voltage and reviewing histograms, mode switch episodes, and stored electrograms—before the first ECT session and after the final one.

Most modern implantable pacemakers work in the synchronous (demand), rate-adaptive mode. In a patient in whom non-cardiac electrical signals cause bradycardia or asystole during ECT, the pacemaker can be reprogrammed to be less sensitive by placing a magnet over the pulse generator, which converts the pacemaker to an asynchronous (fixed), non-sensing mode. It is important to keep in mind that magnet application will not “turn off” a pacemaker; although each pacemaker is programmed to respond to a magnet in a specific fashion, the main response is asynchronous pacing.

Reprogramming the pacemaker to diminish its sensitivity also may be prudent for patients in whom succinylcholine causes fasciculation that inhibits pacemaker output. Such patients can be switched to a nondepolarizing muscle relaxant such as altacurium for future ECT treatments.

Careful cardiac monitoring during ECT is essential (Table). The cardiologist or internist should be available during the first few ECT sessions to monitor for potential pacemaker interference or malfunction. This physician should be familiar with the pacemaker model and type of lead system so he or she can deactivate, reactivate, or reprogram the device.

Algorithm

Reducing risk when administering ECT to cardiac pacemaker patients

Step 1 
Evaluate the patient to ensure medical suitability for ECT and associated anesthesia
Step 2
Conduct pacemaker interrogation (evaluating thresholds, lead impedance, and battery voltage and reviewing histograms, mode switch episodes, and stored electrograms) prior to first ECT treatment and after completion of full ECT course
Step 3
Perform cardiac monitoring during and immediately after administering ECT
Step 4
Have a magnet available to reprogram the pacemaker in the event of pacemaker inhibition or symptomatic bradycardia during ECT
Step 5
Check that all monitoring devices are properly grounded, insulate the patient’s stretcher, and ensure that the patient does not touch anyone who is in contact with the ground during presentation of the ECT electrical stimulus
ECT: electroconvulsive therapy
Source: Reference 12
Table

Guidelines for monitoring cardiac pacemaker patients during ECT

Use multilead ECG monitoring
Have equipment available to rapidly obtain central access (if vasoactive medications or transvenous pacing is needed)
Assess the plethysmography tracing of the pulse oximeter (a useful surrogate if the patient experiences dysrhythmias)
Have ready an external defibrillator

TREATMENT: Successful ECT

We seek a medical consultation before initiating ECT. An internist performs device interrogation before the first ECT treatment and is present in the ECT treatment suite to ensure proper pacemaker conversion and to monitor for cardiac complications. The internist conducts another device interrogation after the acute series of ECT treatments.

Mrs. A tolerates the ECT sessions without cardiac complications. Her depressive symptoms respond well to 12 ECT sessions. She is more interactive and reports better attention and concentration. Although Mrs. A still has middle and initial insomnia, she denies thoughts of harming herself or anyone else.

Related resources

Drug brand names

  • Atracurium • Tracrium
  • Citalopram • Celexa
  • Esmolol • Brevibloc
  • Fluoxetine • Prozac
  • Lorazepam • Ativan
  • Methylphenidate • Ritalin, Concerta, others
  • Nortriptyline • Aventyl, Pamelor, others
  • Paroxetine • Paxil
  • Sertraline • Zoloft
  • Succinylcholine • Anectine
  • Trazodone • Desyrel
  • Venlafaxine • Effexor
  • Ziprasidone • Geodon
Disclosure

Dr. Romanowicz reports no financial relationship with any company whose products are mentioned in this article or with manufacturers of competing products.

 

 

Dr. Ramaswamy receives research support from Bristol-Myers Squibb, Shire, and Forest Pharmaceuticals and is a consultant to Dainippon Sumitomo Pharma.

References

1. American Psychiatric Association Committee on ECT. The practice of electroconvulsive therapy: recommendations for treatment, training, and privileging. 2nd ed. Washington, D.C: American Psychiatric Association; 2001.

2. Russell JC, Rasmussen KG, O’Connor MK, et al. Long-term maintenance ECT: a retrospective review of efficacy and cognitive outcome. J ECT. 2003;19(1):4-9.

3. Alexopoulos GS, Shamoian CJ, Lucas J, et al. Medical problems of geriatric psychiatric patients and younger controls during electroconvulsive therapy. J Am Geriatr Soc. 1984;32(9):651-654.

4. Rasmussen KG, Rummans TA, Richardson JR. Electroconvulsive therapy in the medically ill. Psychiatric Clin North Am. 2002;25:177-193.

5. MacPherson RD, Loo CK, Barrett N. Electroconvulsive therapy in patients with cardiac pacemakers. Anaesth Intensive Care. 2006;34(4):470-474.

6. Burke MJ, Husain MM. Concomitant use of vagus nerve stimulation and electroconvulsive therapy for treatment-resistant depression. J ECT. 2006;22(3):218-222.

7. Husain MM, Montgomery JH, Fernandes P, et al. Safety of vagus nerve stimulation with ECT. Am J Psychiatry. 2002;159:1243.-

8. Alexopoulos GS, Frances RJ. ECT and cardiac patients with pacemakers. Am J Psychiatry. 1980;137(9):1111-1112.

9. Stone KR, McPherson CA. Assessment and management of patients with pacemakers and implantable cardioverter defibrillators. Crit Care Med. 2004;32(4 suppl):S155-S165.

10. Maisel WH, Sweeney MO, Stevenson WG, et al. Recalls and safety alerts involving pacemakers and implantable cardioverter-defibrillator generators. JAMA. 2001;286(7):793-799.

11. Gibson TC, Leaman DM, Devors J, et al. Pacemaker function in relation to electroconvulsive therapy. Chest. 1973;63(6):1025-1027.

12. Dolenc TJ, Barnes RD, Hayes DL, et al. Electroconvulsive therapy in patients with cardiac pacemakers and implantable cardioverter defibrillators. Pacing Clin Electrophysiol. 2004;27(9):1257-1263.

13. Lapid MI, Rummans TA, Hofmann VE, et al. ECT and automatic internal cardioverter-defibrillator. J ECT. 2001;17(2):146-148.

References

1. American Psychiatric Association Committee on ECT. The practice of electroconvulsive therapy: recommendations for treatment, training, and privileging. 2nd ed. Washington, D.C: American Psychiatric Association; 2001.

2. Russell JC, Rasmussen KG, O’Connor MK, et al. Long-term maintenance ECT: a retrospective review of efficacy and cognitive outcome. J ECT. 2003;19(1):4-9.

3. Alexopoulos GS, Shamoian CJ, Lucas J, et al. Medical problems of geriatric psychiatric patients and younger controls during electroconvulsive therapy. J Am Geriatr Soc. 1984;32(9):651-654.

4. Rasmussen KG, Rummans TA, Richardson JR. Electroconvulsive therapy in the medically ill. Psychiatric Clin North Am. 2002;25:177-193.

5. MacPherson RD, Loo CK, Barrett N. Electroconvulsive therapy in patients with cardiac pacemakers. Anaesth Intensive Care. 2006;34(4):470-474.

6. Burke MJ, Husain MM. Concomitant use of vagus nerve stimulation and electroconvulsive therapy for treatment-resistant depression. J ECT. 2006;22(3):218-222.

7. Husain MM, Montgomery JH, Fernandes P, et al. Safety of vagus nerve stimulation with ECT. Am J Psychiatry. 2002;159:1243.-

8. Alexopoulos GS, Frances RJ. ECT and cardiac patients with pacemakers. Am J Psychiatry. 1980;137(9):1111-1112.

9. Stone KR, McPherson CA. Assessment and management of patients with pacemakers and implantable cardioverter defibrillators. Crit Care Med. 2004;32(4 suppl):S155-S165.

10. Maisel WH, Sweeney MO, Stevenson WG, et al. Recalls and safety alerts involving pacemakers and implantable cardioverter-defibrillator generators. JAMA. 2001;286(7):793-799.

11. Gibson TC, Leaman DM, Devors J, et al. Pacemaker function in relation to electroconvulsive therapy. Chest. 1973;63(6):1025-1027.

12. Dolenc TJ, Barnes RD, Hayes DL, et al. Electroconvulsive therapy in patients with cardiac pacemakers and implantable cardioverter defibrillators. Pacing Clin Electrophysiol. 2004;27(9):1257-1263.

13. Lapid MI, Rummans TA, Hofmann VE, et al. ECT and automatic internal cardioverter-defibrillator. J ECT. 2001;17(2):146-148.

Issue
Current Psychiatry - 08(01)
Issue
Current Psychiatry - 08(01)
Page Number
59-63
Page Number
59-63
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A pacemaker patient’s electrical dilemma
Display Headline
A pacemaker patient’s electrical dilemma
Legacy Keywords
pacemaker; implanted cardiac pacemaker; depression; electroconvulsive therapy; ECT; vagus nerve stimulation; VNS; Magdalena Romanowicz; Sriram Ramaswamy
Legacy Keywords
pacemaker; implanted cardiac pacemaker; depression; electroconvulsive therapy; ECT; vagus nerve stimulation; VNS; Magdalena Romanowicz; Sriram Ramaswamy
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