Stress Echocardiography

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Stress echocardiography constitutes the combination of two-dimensional echocardiography with physical, pharmacological, or less commonly, electrical pacing. In some patients, stress may increase ischemia or lead to new or worsened wall motion abnormalities. Stress echocardiography plays an important role in identifying wall motion abnormalities in the assessment of ischemic heart disease. It is also used for evaluation of systolic and diastolic heart failure, valvular pathologies, nonischemic cardiomyopathy, pulmonary hypertension, and congenital heart disease. This activity reviews stress echocardiography, its indications, and the role of the interprofessional team in evaluating patients with heart disease.

Objectives:

  • Identify the indications for stress echocardiography.
  • Describe the techniques for performing stress echocardiography.
  • Review the clinical relevance of stress echocardiography.
  • Explain the importance of improving care coordination among the interprofessional team to enhance the delivery of care for patients undergoing stress echocardiography.

Introduction

Stress echocardiography combines two-dimensional echocardiography with a physical, pharmacological, or less commonly, electrical stress with atrial pacing. [1] Stress-induced ischemia generates new or worsening wall motion abnormalities in the segment supplied by the stenosed coronary artery.[2] Stress echocardiography plays an important role in identifying these wall motion abnormalities in the assessment of ischemic heart disease, and also plays a vital role in the evaluation of systolic or diastolic heart failure, valvular pathologies, nonischemic cardiomyopathy, pulmonary hypertension, and congenital heart disease. [3]

Anatomy and Physiology

Anatomy involves studying the various wall motion abnormalities and understanding the vascular territories associated with various segments. The segments are studied in six views: the parasternal long axis, the parasternal short axis at the levels of the mitral valve, papillary muscles, and apex, apical four chambers, apical two chambers. The scoring system is based on if the wall motion is normal, hypokinetic, akinetic, or dyskinetic. Based on the wall motion, a score of 1 to 4 is assigned. The American Society of Echocardiography uses a 17-segment model for wall motion abnormalities. [4]

Parasternal long axis (PLAX) view

Segments seen in parasternal long-axis view:

  1. Basal anteroseptal and mid anteroseptal on the septum: supplied by the left anterior descending artery
  2. Basal inferolateral and mid inferolateral: supplied by the right coronary artery or left circumflex artery

Apical four chambers (A4C) view

Segments seen in apical four-chamber view:

  1. Apical cap: supplied by left anterior descending artery, left circumflex artery
  2. The apical septum, mid inferoseptal: supplied by the left anterior descending artery
  3. Basal inferoseptal: supplied by right coronary artery
  4. Apical lateral, mid anterolateral, basal anterolateral: supplied by left circumflex artery

Apical two chambers (A2C) view

Segments saw in apical two-chamber view:

  1. Basal inferior, mid inferior: supplied by right coronary artery
  2. Apical anterior: supplied by a right coronary artery or left anterior descending artery
  3. Apical inferior, basal anterior, mid anterior: supplied by the left anterior descending artery

Parasternal short-axis (SAX) view

Segments seen in parasternal short-axis view at the papillary muscle level:

  1. Mid anteroseptal, mid anterior supplied by the left anterior descending artery
  2. Mid inferoseptal: supplied by right coronary artery
  3. Mid anterolateral, mid inferolateral: supplied by left circumflex artery
  4. Mid inferior: supplied by right coronary artery

Indications

  • The following are indications for stress echocardiography: [5], [6], [7][8]
  • Coronary artery disease diagnosis
  • To assess adequacy before and after revascularization
  • Risk stratification in known coronary diseases
  • Identifying the location of ischemia
  • Preoperative risk assessment
  • Evaluation for cardiac etiology of exertional dyspnea
  • To assess valve disease
  • Left bundle branch block

Contraindications

Contraindications to exercise/pharmacologic stress echocardiography:  [9][10]

 Absolute

  • Acute myocardial infarction within 48 hours
  • Acute pericarditis/Myocarditis
  • Symptomatic severe aortic stenosis
  • Uncontrolled Arrhythmias causing symptoms or instability
  • Acute aortic dissection
  • High-risk Unstable Angina
  • Decompensated or unstable heart failure with left ventricle ejection fraction (LVEF) less than 35%
  • Acute pulmonary embolism or pulmonary infarction

 Relative

  •  Left main coronary artery stenosis
  •  High degree atrioventricular (AV) block
  •  Severe hypertension (greater than 180/100mm Hg)
  •  Electrolyte abnormalities
  •  Mental or physical disability
  •  Tachycardia or bradyarrhythmia
  •  Moderate stenotic valvular heart disease 

Specific contraindications to dipyridamole (or adenosine) and dobutamine stress echocardiography include severe conduction abnormalities (high-degree AV block without pacemaker), active bronchospasm, Sick sinus syndrome without a pacemaker, systolic blood pressure less than 90 mmHg, and tachyarrhythmias such as atrial fibrillation.

Equipment

Technical equipment for stress echocardiography includes:

  • Ultrasound machine
  • Probes: 3.5 MHz, 5 MHz
  • The digital image acquisition system
  • Blood pressure cuff and stethoscope
  • Echo beds, workstations, ergonomic chair for the sonographer
  • Contrast agitator machine/contrast for border delineation
  • Emergency equipment includes a portable defibrillator, oxygen mask, bag-valve-mask resuscitator, intubation equipment, code carts, suction apparatus, syringes, needles, intravenous tubing

Stress echocardiography equipment takes into consideration M-mode, two-dimensional, color, and spectral (both flow and tissue) Doppler imaging for evaluation of ischemic heart disease.

Contrast agents are used as indicated for patients in whom at least two endocardial wall territories are not well visualized.

Technique or Treatment

Tissue harmonic imaging is indicated in stress echocardiography. It improves resolution, reduces artifacts, improves signal-to-noise ratio, greater depth of penetration and improves myocardial signals. Tissue harmonic imaging increases the sensitivity of stress echocardiography as it improves endocardial delineation due to enhanced resolution.[7][11][12][13]

Intravenous contrast agents in combination with harmonic imaging increase the accuracy of the procedure. Increased number of wall segment motion abnormalities can be studied when contrast agents are used.

Stress testing methods:

Exercise stress testing: This is indicated in patients who can exercise. Either treadmill or bicycle can be used for exercise. 

  • Treadmill stress echocardiography: Bruce protocol is most commonly used for treadmill exercise echocardiography. Exercise capacity is reported in terms of estimated metabolic equivalents of task (METs). Imaging studies are performed at rest and immediately after completion of exercise and compared for evaluation of wall motion abnormalities.  
  • Bicycle stress echocardiography: Less often used in North America than treadmill stress test. Can be performed using supine or upright bicycle ergometry. Usually, bicycle protocol starts at a workload of 25 watts and increases by 25-watt increments every three minutes until an endpoint is achieved. It is quieter, permits sensitive precordial measurements without much motion artifact. Bicycle exercise offers Doppler information in addition to assessment of regional wall motion abnormalities.

Pharmacologic stress testing: This is indicated in patients who cannot exercise. Dobutamine and vasodilators are used for assessing regional wall motion abnormalities. [10][14]

  • Dobutamine echocardiography: A graded dobutamine infusion starting at 5 mcg/kg/min and increasing at three-minute intervals to 10, 20, 30, and 40 ug/kg/min is the standard for dobutamine stress testing. [8] During dobutamine echocardiography, images are obtained before the start of the infusion, at the end of each stage, and during the recovery. The importance of low dose stages plays a role in recognition of viability and ischemia in segments with abnormal function at rest, even if viability assessment is not the main objective of the test. Endpoints are the achievement of target heart rate (defined as 85% of the age-predicted maximum heart rate), new or worsening wall motion abnormalities of moderate degree, significant arrhythmias, and intolerable symptoms. To achieve the target heart rate, Atropine can be used in divided doses of 0.25 mg to 0.5 mg to a total of 2 mg. Atropine increases the sensitivity of dobutamine echocardiography in patients receiving beta-blockers and in those with single-vessel disease.
  • Vasodilator stress testing: Adenosine and Dipyridamole can be used in stress echocardiography. [15] Dipyridamole is administered at up to 0.84 mg/kg in two separate infusions: 0.56 mg/kg over four minutes, followed by four minutes of no dose and, if an adequate physiologic response is not achieved, then an additional 0.28 mg/kg is given over two minutes. [16] Atropine is used to enhance test sensitivity. Also, the addition of a handgrip at peak infusion enhances sensitivity. The duration of action of adenosine is shorter than dipyridamole. Adenosine stress is used to assess myocardial perfusion with contrast echocardiography but has not been used widely as a clinical tool.
  • Pacing stress testing: This is indicated in patients with a permanent pacemaker. The target heart rate can be achieved by increasing the pacing. This is indicated in patients who are unable to exercise. The pacing protocol consists of two-minute stages, and an increasing paced heart rate to levels of 85% and 100%, respectively, for pre-peak and peak stress information. [10] Images are obtained at rest, the first stage, and pre-peak and peak heart rate. Termination of stress test occurs with the achievement of age-predicted maximal heart rate, new or worsening moderate regional wall motion abnormalities, greater than 2 mm horizontal or downsloping S-T depression, or presence of intolerable symptoms. [10]

Interpretation:

Imaging obtained at resting and stress phase are compared for interpretation of left ventricular (LV) size, shape, and function. A normal response during stress involves LV size becoming smaller compared to rest, while the shape is maintained, and there is increased endocardial excursion along with systolic wall thickening.

In a patient with multiple vessel diseases, exercise echocardiography demonstrates a dilated LV cavity with changes in the shape and reduction of systolic wall thickening of the septum, anterior, and inferior walls. Prolonged systolic wall thickening may also indicate severe coronary artery disease.

The coronary arteriographic cut off of luminal diameter stenosis at which wall thickening abnormalities occur is 54% for exercise, 58% for dobutamine, and 60% for dipyridamole. The sensitivities for the detection of coronary artery disease (CAD) are 85%, 80%, and 78%, with specificities of 77%, 86%, and 91% for exercise, dobutamine, and dipyridamole stress results. [9] However, diagnostic accuracy varies according to the pretest likelihood of CAD in the patient tested.

Complications

Dobutamine stress echocardiography: The most common cardiovascular side effects associated with dobutamine are angina, hypotension, and cardiac arrhythmias. [17] Atrial fibrillation and nonsustained ventricular arrhythmias occur in about 3% of patients. [18][19] Sustained ventricular tachycardia is not common. Dobutamine can also induce left ventricular mid-cavity and outflow tract obstruction. Frequent premature atrial or ventricular contractions occur in about 10%. [20]

Vasodilator stress echocardiography: Major adverse reactions include myocardial infarction, asystole, and ventricular tachycardia. [21] Hypotension and bradycardia may occur but can be treated with aminophylline.

Pacing stress echocardiography: Wenckebach's second-degree heart block may occur, requiring atropine administration. [22]

Clinical Significance

In terms of clinical significance and diagnostic accuracy, stress echocardiography has an advantage in terms of specificity over standard exercise electrocardiography. When compared to nuclear perfusion imaging studies, stress echocardiography has similar accuracy, with a moderate sensitivity gap that is well balanced by a higher specificity. Both dipyridamole and dobutamine have overall good tolerance and feasibility. The choice of one test over the other depends on patients' clinical characteristics and the physician's preference. Diagnostic accuracy can significantly be affected by antianginal medical therapy, particularly beta-blocking agents, and therefore, it is recommended to withhold medical therapy at the time of testing to avoid a false-negative result.

Enhancing Healthcare Team Outcomes

Healthcare workers, including nurse practitioners, will frequently encounter patients with heart disease. One of the ways to investigate these patients is with stress echocardiography. Stress echocardiography is the combination of two-dimensional echocardiography with a physical, pharmacological, or less commonly, electrical stress with atrial pacing. Stress-induced ischemia generates new or worsening wall motion abnormalities in the segment supplied by the stenosed coronary artery. Stress echocardiography plays an important role in identifying these wall motion abnormalities in the assessment of ischemic heart disease, and also plays a vital role in the evaluation of systolic or diastolic heart failure, valvular pathologies, nonischemic cardiomyopathy, pulmonary hypertension, and congenital heart disease.


(Click Image to Enlarge)
Difference between exercise electrocardiographic stress test and stress echocardiography.
Difference between exercise electrocardiographic stress test and stress echocardiography.
Contributed by StatPearls

(Click Image to Enlarge)
Above images are obtained at resting phase and post stress phase which are then compared for interpretation of left ventricul
Above images are obtained at resting phase and post stress phase which are then compared for interpretation of left ventricular size, shape and function
Contributed by Ateet Kosaraju
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Ateet Kosaraju

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Vijayadershan Muppidi

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Amgad N. Makaryus

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