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There are a wide variety of devices available for ambulatory cardiac monitoring. The primary purpose of ambulatory electrocardiography (AECG) monitoring is the evaluation of suspected arrhythmias that have not been detected in office- or hospital-based monitoring, generally while the individual is engaged in daily activities, including sleep. These devices differ in the types of monitoring leads used, the duration and continuity of monitoring, the ability to detect arrhythmias without individual intervention, and the mechanism of delivery or information from the individual to the clinician. Traditionally, these devices may be used for the evaluation of symptoms suggestive of arrhythmias such as syncope or palpitations. Other common clinical uses include the detection of atrial fibrillation (AF) in individuals who have undergone cardiac ablation of AF, or who have a history of cryptogenic stroke; the assessment of treatment response to antiarrhythmic therapy; the assessment of pacemaker and implantable cardioverter defibrillator (ICD) function; the evaluation of idiopathic hypertrophic cardiomyopathy; or the evaluation for suspected myocardial ischemia.

CONTINUOUS AMBULATORY ELECTROCARDIOGRAPHY (AECG) MONITORING (HOLTER MONITORING)

Continuous AECG monitoring (Holter monitoring) is a noninvasive test in which the electrocardiogram (ECG) is continuously recorded over an extended period of time, typically 24 to 48 hours, to evaluate fairly frequent symptoms (e.g., palpitations, dizziness, syncope) suggestive of cardiac arrhythmias. A Holter monitor is about the size of a large deck of cards. It can be clipped to a belt or carried in a pocket. Wires connect the device to electrodes that are placed on specified areas of the chest using sticky patches. These electrodes (sensors) detect the heart's electrical signals, and the monitor records heart rhythm. The heart's activity is recorded rather than transmitted. Holter monitoring, however, may be ineffective in detecting arrhythmias if an individual experiences infrequent symptoms. Therefore, the sensitivity of Holter monitoring is low for the detection of arrhythmias that are intermittent.

POST-EVENT CARDIAC DETECTION MONITORING

A cardiac event detection monitor can be either a hand-held device or worn on a wrist. When the individual feels a symptom or irregular heartbeat, the monitor is placed on the chest and a recording button is activated. The back of this device has small metal discs that function as the electrodes. If the monitor is worn on a wrist, a button is pressed to record. Some of these types of cardiac event detection monitors typically only record the rhythm that occurs with an individual's perceived symptoms and not those events that are asymptomatic. These monitors, referred to as postevent monitors, are of limited utility, as they do not include a memory loop, so they have no memory to allow recording of the rhythm before the device is activated. The device transmits ECG data telephonically to a central monitoring center and then is uploaded to a secured computer for analysis.

For example, in September 2011, the US Food and Drug Administration (FDA) gave 510(k) approval to the REKA E100™ system, a noncontinuous single-lead cardiac event detection monitor. This device is the size of a hockey puck and weighs no more than a few ounces. There are two options depending on the individual's circulation: a zero-lead device that is separate from the body and may be carried in a purse or coat pocket; or, if an individual's circulation is determined to be inadequate, a single electrode lead that the individual connects to the device at the time of an event. The zero-lead device records an event by individual activation and can record and store up to 2000 readings. The individual has the choice of sending stored event information to the monitoring center across a phone application or the Internet on their computer. The monitoring center provides the EGG data to the referring professional provider for evaluation.

EXTERNAL CARDIAC EVENT DETECTION MONITORING (EXTERNAL LOOP MONITORING)

External cardiac event detection monitoring (external loop monitoring) typically involves long-term (30 days or more) monitoring of the heart rhythm of an individual with significant, but very infrequent, symptoms that are suggestive of transient cardiac arrhythmia. The infrequency of the arrhythmia makes it difficult to identify on a 24- or 48-hour continuous Holter monitor.

External cardiac event detection monitoring (external loop monitoring) is initiated in either the office or the home setting. The device is an ECG recording monitor with a continuous loop that attaches to the chest with electrodes, and is typically worn up to 1 month or longer. The device records the ECG in a continuous manner, but stores only a brief period of ECG recording in memory. When the event marker is activated at the time of a symptom, the device's looping memory is individually programmed to record an ECG 30 to 90 seconds prior to activation, and the next minute or so after activation. In addition to patient-activated monitoring, autotriggering monitoring is available. Autotriggering loop monitors have the capability to be automatically activated in the case of a predefined arrhythmia, such as asystole of greater than 3 seconds, and/or other variable rate and rhythm intervals. Autotriggering loop monitors do not rely on an individual's ability to activate and, as a result, are able to capture asymptomatic, in addition to symptomatic, events.

Information may be stored in the device and later reviewed or transmitted from the monitoring device to a receiving monitoring center where the data are reviewed. The transmission ranges from the simple, analog dial-in transtelephonic system, to a cellular phone link, or a wireless link or Internet-based in-home computer that captures and stores ECG data. Currently, no one system is proven to be superior to another.

A representative example of a patient-activated external looping monitor includes Zio® Event Card (iRhythm Technologies, Inc., San Francisco, CA). In June 2008, the FDA gave 510(k) approval to a noncontinuous real-time recording device, Zio® Event Card (iRhythm Technologies, Inc., San Francisco, CA), that can be worn up to 30 days. This device can be worn under clothing (including during sleep), as it weighs less than 2 ounces and is similar in size to a standard credit card. Upon activation by the individual, the card is able to record the previous 45 seconds of ECG activity into memory plus the first 15 seconds after the button is pushed. This is made possible because this device continuously scans for ECG activity but only records upon symptom activation. After the device is activated, the individual is responsible for calling the iRhythm National Clinical Center (NCC), which then instructs the individual on sending the event over the phone line.

Other devices for external loop monitoring include King of Hearts Express® AF (Istromedix®, San Diego, CA), Looping Multi-Event Monitor (CardioNet Inc., Conshohocken, PA), and LifeStar AF Express (Life Watch, Buffalo Grove, IL).

CONTINUOUS AMBULATORY ELECTROCARDIOGRAPHY MONITORING (AECG) FOR PERIODS GREATER THAN 48 HOURS

Despite the clinical utility of 24- or 48-hour continuous Holter monitoring in clinical cardiology, issues such as diagnostic yield and individual compliance have prompted the development of ultra-portable devices for extended monitoring, referred to as ECG patch monitors. For example, the FDA approved the Zio® Patch, Model Z100 and the Zio® Patch (iRhythm Technologies Inc., San Francisco, CA) in May 2009 and February 2012, respectively. Both approvals carry the same indication for use as a prescription-only, single-use, continuous recording ECG monitor that can be worn for up to 14 days. It is indicated for use on individuals who experience transient symptoms such as syncope, palpitations, shortness of breath, or chest pains. The Zio® Patch system is most analogous to a 24- or 48-hour continuous Holter monitor that records and stores information. The available published peer-reviewed literature suggests that Zio® Patch typically detects a greater number of arrhythmias during extended follow-up than 24- or 48-hour Holter monitor. This system consists of a patch worn over the left pectoral region of the body that records continuously for up to 14 days, while the individual keeps a symptom log. At the end of the recording period, the individual mails back the recorder in a prepaid envelope to a central center where the ECG data are analyzed via a proprietary algorithm using the Zio ECG Utilization Service (ZEUS) System. A full report is provided to the referring professional provider for interpretation and clinical management.

Other similar continuous AECG monitoring devices with recording periods greater than 48 hours include CAM™ (BardyDx, Vashon Island, WA),​ myPatch® (Dms-Service Llc., Santa Monica, CA) and Stealth™ Monitor (Cardiac Insight Inc., Bellevue, WA).

MOBILE CARDIAC OUTPATIENT TELEMETRY (MCOT) MONITORING​

Although many monitors have automatic activation capability and allow the individual to transmit data to a monitoring center, they do not automatically transmit the data at the time of occurrence to an attended monitoring center. An MCOT is an automatically activated device that requires no active intervention to capture or transmit an arrhythmia when it occurs, although data can also be recorded through patient activation. MCOT is the real-time transmission of the individual's cardiac activity to a receiving monitoring center that converts this electronic transmission into a visible image that is constantly and continuously displayed on a monitor in the receiving monitoring center, so that qualified technicians located in the receiving monitoring center can provide immediate and accurate surveillance of the individual's cardiac activity 24 hours a day, 7 days a week. The individual's referring professional provider is made aware of arrhythmias based on predetermined notification criteria specific to that individual. The ability to respond immediately when clinically important arrhythmias occur is the major advantage of real-time MCOT monitoring.

For example, CardioNet® Inc. (Conshohocken, PA) offers MCOT monitoring. In this system, the individual wears a three-lead sensor, which constantly communicates with the CardioNet® monitor, a lightweight unit that can be carried in a pocket or a purse. When an arrhythmia is detected according to preset parameters, the ECG is automatically transmitted to a central CardioNet® service center, where the ECG is immediately interpreted, with results sent to the referring professional provider. The referring professional provider can request the level and timing of response, ranging from daily reports to stat results. Other systems for MCOT monitoring include the HEARTLink II™ system (Cardiac Telecom Corp., Greensburg, PA), the Vital Signs Transmitter (VST™; Biowatch Medical, Columbia, SC), and the LifeStar™ Ambulatory Cardiac Telemetry (ACT) system (Card Guard Scientific Survival Ltd., Israel).

In February 2014, the FDA gave 510(k) approval to the Nuvant Mobile Cardiac Telemetry (MCT) System, now known as SEEQ™​ MCT (Medtronic, Inc. Minneapolis, MN). SEEQ MCT is a one-time use, wearable adhesive cardiac sensor that can be worn up to 30 days. SEEQ​ MCT is intended to continuously measure, record, and periodically transmit physiological data. The wearable, wireless-enabled sensor continuously monitors the heart and automatically transmits rhythm abnormalities to the cardiographic technicians at the Medtronic Monitoring Center. Individuals can also trigger transmission of ECGs when they experience cardiac symptoms by using the trigger button. Reports are provided to the referring professional providers for review and analysis. This system is indicated for those individuals who require monitoring for the detection of nonlethal cardiac arrhythmias such as, but not limited to, supraventricular tachycardias (SVTs) (e.g., AF, atrial flutter, paroxysmal SVTs), ventricular ectopy, bradyarrhythmias, and conduction disorders.

In August 2012, the FDA gave 510(k) clearance to the BodyGuardian Remote Monitoring System™ (Price® Inc., Minneapolis, MN). The monitoring system continuously detects and records a variety of physiologic data including ECG tracing, respiratory rate, and activity level for up to 30 days. The data are delivered securely from the BodyGuardian Control Unit to the BodyGuardian Connect smartphone device. In turn, the individual data are wirelessly delivered to the Price® CarePlatform, a cloud-based mHealth platform that collects real-time data from devices and delivers information to the referring professional providers.

In November 2011, the FDA gave 510(k) clearance to the VectraplexECG™ System (VectraCor Inc., Totowa, NJ, and Maple Grove, MN). This device is a real-time continuous MCOT device to measure ischemic ECG changes that can be indicative of a myocardial infarction (MI). This device uses the Internet to communicate real-time ECG changes to the professional provider. The individual is hooked up to a minitablet by either five electrodes, which communicate 15-lead ECG data, or 10 electrodes that communicate 12-lead ECG data. Although this system is primarily intended to monitor for ischemia, the continuous ECG monitoring would presumably detect rhythm disturbances, as well as ischemic changes.

CARDIAC EVENT DETECTION MONITORING (IMPLANTABLE LOOP MONITORING)

A cardiac event detection monitor (implantable loop monitor) is an implantable device that is inserted subcutaneously, usually in a left pectoral or mammary location. The electrodes that sense the heart's activity are on the surface of the device, so no transvenous leads are necessary. Prior to the device insertion, the monitor may be initially programmed. For a patient-activated monitoring system, when symptoms occur, the individual uses a hand-held activator to store a segment of the ECG in the device's memory. Autotriggering technology can be adapted to the implantable cardiac loop monitoring devices. For example, implantable autotrigger loop monitors have the capability to be automatically activated in the case of a predefined arrhythmia such as asystole of greater than 3 seconds, and/or other variable rate and rhythm intervals. The device's looping memory is individually programmed to record an ECG 30 to 90 seconds prior to activation. The newest generations of these devices allow remote transmission of data, and have a projected longevity of the device's battery for up to 3 years. The professional provider utilizes a programmer to retrieve, display, and print stored data. Implantable cardiac loop monitors have the capacity to record cardiac events for approximately 3 years and to store many separate events.

For example, the Reveal® XT ICM (Medtronic Inc., Minneapolis, MN) is an implantable memory loop device cleared for marketing by the FDA in 2008 that allows patient-activated rhythm recording, rhythm recording at prespecified time intervals, or autotriggered rhythm recording. In February 2014, the FDA cleared for marketing the Reveal LINQ™, a miniaturized implantable memory loop device with an approximate volume of 1 mL that includes autotriggered or patient-activated rhythm recording.

The current clinical use of an implantable cardiac loop monitor involves the evaluation of transient, recurrent symptoms of possible arrhythmic origin, after a trial of cardiac event detection monitoring (i.e., external loop monitoring) does not yield a definitive diagnosis, and long-term monitoring is needed.

AECG MONITORING MANAGED THROUGH MOBILE APPLICATIONS FOR SMARTPHONE AND SMARTWATCH TECHNOLOGY

The transtelephonic ECG event recorder records, stores, and transfers single-channel ECG rhythms (e.g., KardiaMobile [previously AliveCor ECG, AliveCor Heart Monitor], KardiaBand). These devices utilize the processing power of a mobile application to obtain and analyze single-channel ECG. The device is placed on the chest or held by the individual’s hands while pressing fingers from each hand onto the electrodes to provide a single-channel ECG rhythm strip. Similar to other mobile ECG devices, the devices use a proprietary method of data transmission using acoustic waves to communicate with the mobile application where the waveform is stored, displayed, and analyzed for the presence of an irregular heart rhythm. They are designed to work in conjunction with a range of mobile platforms, including iPhone, iPad, and Android devices and may be obtained without a prescription. AECG monitoring managed through mobile applications for smartphone and smartwatch technology are intended for use by healthcare professionals, individuals with known or suspected heart conditions, and health-conscious individuals. These devices provide a single-lead ECG and cannot provide the level and detail obtained by the typical 12-lead ECG performed by professional providers.

The accuracy of smartphone-based applications intended to measure heart rate varies widely. Investigators evaluated the accuracy of four randomly selected, commercially available applications intended to measure heart rate using two types of smart phones (iOS) (Coppetti et al., 2017). The applications are based on photoplethysmography, an optical technique that measures light reflectance to detect blood volume changes in the microvasculature. The two contact-based applications require individuals to place a finger on the smart phone's built-in camera. Researchers randomly recruited 108 noncritical individuals who required heart rate monitoring in a chest pain unit or emergency department. They measured heart rate simultaneously using the applications on both smartphones, conventional ECG, and pulse oximetry. The researchers found differences greater than 20 beats per minute compared to ECG in more than 20% of application measurements. Noncontact applications performed worse than contact applications, especially at higher heart rates and lower body temperatures. Noncontact applications tended to overestimate higher heart rates. Further, both contact applications performed differently. Researchers could not attribute the divergent contact application performance to camera technology, age, body temperature, or heart rate itself, suggesting the application's proprietary algorithm was the cause.

In addition, there is currently a lack of evidence to support the clinical value of AECG monitoring managed through mobile applications for smartphone and smartwatch technology. Prospective randomized controlled studies are needed to ascertain how the use of these devices would improve clinical outcomes in individuals with cardiovascular diseases/disorders.

RECOMMENDATIONS FOR AMBULATORY ELECTROCARDIOGRAPHY (AECG) TYPE

Generally, the selection of a specific AECG monitoring device is based on the frequency with which the individual’s symptoms, thought to be related to cardiac arrhythmia, occur. For example, individuals with infrequent short periods of transient symptoms recurring over longer periods of time are unlikely to be diagnosed by conventional 24- or 48-hour continuous Holter monitoring, as the likelihood of symptom-ECG correlation is very low (Brignole et al., 2009).

According to the American College of Cardiology (ACC)/American Heart Association (AHA) Clinical Competence Statement on Electrocardiography and Ambulatory Electrocardiography (2001), there are no specific guidelines that distinguish individuals for whom it is appropriate to perform continuous monitoring from those for whom intermittent monitoring is adequate. However, when monitoring is performed to evaluate the cause of intermittent symptoms, the frequency of symptoms should dictate the type of recording. However, more recently, in 2006, the AHA/American College of Cardiology Foundation (ACCF) stated that Holter monitoring is appropriate for episodes that occur at least every day, and cardiac event detection monitoring is ideal for less-frequent episodes that occur at least once a month. Implantable loop monitoring is considered the most likely technology to identify the mechanism of syncope in individuals with unexplained syncope.

PRACTICE GUIDELINES​

In 2023, the ACC/AHA/ACCP/HRS issued guidelines for the diagnosis and management of AF. These guidelines recommend initial cardiac monitoring and, if needed, extended monitoring with an implantable loop recorder for individuals with stroke or transient ischemic attack (TIA) of undetermined cause. ​​

In 2021, the ​​AHA/ASA issued guidelines for the prevention of stroke in individuals with stroke and transient ischemic attack. These guidelines recommend long-term rhythm monitoring with MCOT, implantable loop recorder, or other approach as reasonable to detect intermittent AF in individuals with cryptogenic stroke who do not have a contraindication to anticoagulation. ​

In 2020, the AHA/ACC issued guidelines for the diagnosis and treatment of hypertrophic cardiomyopathy. Class I recommendations (i.e., conditions for which there is evidence and/or general agreement that the test is useful and effective) include 24-hour continuous AECG monitoring (Holter monitoring) or event recording monitoring for specified individuals with hypertrophic cardiomyopathy.

The use of cardiac event detection monitoring postablation is addressed in a consensus document published in 2017 by the HRS/EHRA/ECAS/APHRS/SOLAECE on catheter and surgical ablation for AF. This document provides general recommendations based on literature review and expert consensus. Based on such recommendations, following ablation for AF, individuals in whom discontinuation of systemic anticoagulation is being considered should consider undergoing continuous ECG monitoring.

In 2014 the American Academy of Neurology released updated guidelines on the prevention of stroke in individuals with nonvalvular​ atrial fibrillation (NVAF). The guidelines make the following recommendations regarding the identification of individuals with occult NVAF:

• Outpatient cardiac rhythm studies may be obtained in individuals with cryptogenic stroke without known NVAF in order to identify individuals with occult NVAF.
• Cardiac rhythm studies for prolonged periods (e.g., 1 or more weeks) instead of shorter periods (e.g., 24 hours) may be obtained in individuals with cryptogenic stroke without known NVAF in order to increase the yield of identification of individuals with occult NVAF.

In the 1999 Guidelines for AECG, the ACC/AHA discuss the following as a Class I indications:

• Symptoms that may be related to disturbances of heart rhythm
• Efficacy of antiarrhythmic therapy
• Pacemaker and implantable cardioverter-defibrillator (ICD) function
• Pediatric individuals

According to the ACC/AHA Guidelines for AECG, as in adults, selection of the method of monitoring (i.e., continuous recording versus patient-activated) for the pediatric population is predicated on the frequency and symptoms of the arrhythmia. Generally, the indications for pediatric AECG monitoring include the following:

• The evaluation of symptoms that may be arrhythmia related
• Risk assessment in individuals with cardiovascular disease, with or without symptoms of an arrhythmia
• The evaluation of cardiac rhythm after an intervention such as drug therapy or device implantation​

TECHNICAL AND PROFESSIONAL COMPONENTS

Ambulatory ECG technology varies among different devices. Ambulatory ECG may include technical and professional components. The technical component comprises the portion of the procedure or service performed by the monitoring center or independent diagnostic testing facility, and the equipment used for the procedure or service.

The professional component is the portion of the procedure or service performed by a professional provider, which includes the interpretation, analysis, and a detailed signed written report of the results of the procedure or service.

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