Cardiac stress test

From Self-sufficiency
Revision as of 10:07, 11 August 2010 by SmackBot (Talk) (Date maintenance tags and general fixes: build 443:)

(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Jump to: navigation, search
File:Stress test.jpg
A male patient walks on a stress test treadmill to have his heart's function checked

A cardiac stress test is a diagnostic test used in cardiology in which the ability of the heart to respond to stress, either actually induced by physical exercise or stimulated by pharmacologic maneuvers, is measured in a controlled clinical setting. Cardiac stress tests attempt to compare the coronary circulation at rest with that observed during near-maximal physical exertion, with the objective of detecting any exertion-induced imbalances of blood flow to the myocardium. The results may also be interpreted as a reflection on a person's overall physical fitness. These tests are typically included in the initial evaluation of suspected ischemic heart disease, and as a prognostic indicator after myocardial infarction.[1] The first standardized cardiac stress test was developed in 1929 by Arthur Master, a doctor at Mount Sinai Hospital in New York City.[2]

Test overview

The patient either walks on a treadmill or is given an intravenous (IV) medication that simulates exercise while connected to an electrocardiogram (ECG) machine, usually with the standard 10 connections used to record a 12-lead ECG. The level of exercise is increased in 3-minute stages of progressively increased grade (% incline) and speed (mph, km/h, etc.). The patient's symptoms and blood pressure response are repeatedly checked. When using ECG and blood pressure monitoring alone the test is variously called a cardiac stress test, exercise stress test, exercise treadmill test, exercise tolerance test, stress test or exercise ECG test.

A radiotracer (typically, technetium-99m sestamibi or thallium-201) may be injected prior to the exercise portion. If radioactive nuclides are used it is usually called a nuclear stress test. After a suitable waiting period to permit circulation of the radiotracer, pictures are taken with a gamma camera to capture resting images of the blood flow. Then, pictures are captured after exercise to compare with the patient's resting images in order to assess the status of the patient's coronary arteries. Given the ability to visualize the relative amounts of radioisotope within the heart muscle, nuclear stress tests are more accurate in detecting regional areas of decreased blood flow. However, diffuse global ischemia (decreased blood flow that is evenly spread out) may not be recognized because absolute blood flow is not quantitatively measured, only regional variations.

Some patients with abnormal resting ECGs or those who are unable to walk safely can be "exercised" pharmacologically instead of by walking on a treadmill. The patient will typically receive a pharmaceutical such as dipyridamole or adenosine (both vasodilators) or dobutamine (which stimulates heart rate and pumping force) while a radiologist, nuclear medicine physician, cardiologist, nurse or physician assistant reviews the ECG tracing and checks blood pressure periodically. Again, a radiotracer may be injected during the simulated exercise portion.

Purpose

The American Heart Association recommends ECG treadmill testing as the first choice for patients with medium risk of coronary heart disease based on the risk factors of smoking, family history of coronary stenosis, hypertension, diabetes, and high cholesterol.

Perfusion (sestamibi) stress testing is appropriate for select patients, especially those with an abnormal resting EKG.

Angiogram or intracoronary ultrasound (preferably in a hospital capable of percutaneous coronary intervention (PCI) with stenting) can provide even greater information, but at the risk of complications associated with cardiac catheterization.

Diagnostic value

The joint Guideline for Exercise Testing from the American College of Cardiology and American Heart Association[3] states:

Treadmill test: sensitivity of 67%, specificity of 70% (of advanced lumen narrowing)
Nuclear test: sensitivity of 81%, specificity of 85-95% (of advanced lumen narrowing)

However, these numbers reference detection of advanced artery luminal narrowing as assessed by stress methods compared with angiography as the "gold standard". Because this is not the predominant basis of most heart attacks, actual clinical cardiology experience demonstrates that the actual sensitivity and specificity values for detecting likelihood of future heart attack, as opposed to lumen narrowing, are much lower than stated above.

Whatever the actual numbers, the value of stress tests has increasingly been recognized as limited. Atherosclerosis, which typically begins in later childhood, predominantly produces artery wall thickening and artery enlargement, not lumen narrowing. Lumen narrowing typically occurs as part of healing responses after vulnerable plaque ruptures, most of these ruptures being clinically silent. Thus lumen narrowing represents only a symptom of very advanced disease, a state which typically requires several decades to develop. Additionally, no stress methods quantitatively measure actual or needed blood flow to the heart muscle. They only detect imbalances of blood flow between regions of the left ventricular muscle which are beyond the capabilities of the arterioles in the downstream vascular bed to fully compensate.

According to American Heart Association data, published 2004, for about 65% of men and 47% of women, the first symptom of cardiovascular disease is heart attack or sudden death (death within one hour of symptom onset). Yet the evidence is that stress tests, even if they were performed shortly prior to these events, would not detect that these events were about to happen for most of the individuals who were about to have events.

Over the last couple of decades, other methods have been developed as ways to better detect atherosclerotic disease before it becomes symptomatic. These have included both (a) anatomic detection methods and (b) physiologic measurement methods.

Examples of anatomic methods include: (1) coronary calcium scoring by computed tomography, (2) carotid IMT (intimal medial thickness) measurement by ultrasound, e.g. IntiMaTe, and (3) IVUS.

Examples of physiologic methods include: (1) lipoprotein subclass analysis, (2) HbA1c, (3) hs-CRP, and (4) homocysteine.

The example of the metabolic syndrome combines both anatomic (abdominal girth) and physiologic (blood pressure, elevated blood glucose) methods.

Advantages: The anatomic methods directly measure some aspect of the actual atherosclerotic disease process itself and thus offer potential for earlier detection. The physiologic methods are often less expensive and safer.

Disadvantages: The anatomic methods are generally more expensive and several are invasive, such as IVUS. The physiologic methods do not quantify the current state of the disease or directly track progression. For both, clinicians and third party payers have been slow to accept the usefulness of these newer approaches.

Risks

Absolute contraindications to cardiac stress testing include acute myocardial infarction within 48 hours, unstable angina not yet stabilized with medical therapy, uncontrolled cardiac arrhythmia, which may have significant hemodynamic responses (for example ventricular tachycardia), symptomatic severe aortic stenosis, aortic dissection, pulmonary embolism, and pericarditis.

Major side effects from cardiac stress testing can include palpitation, chest pain, shortness of breath, headache, nausea, or fatigue. Adenosine and dipyridamole can cause mild drug-induced hypotension. However, hypotension caused by exercise stress testing or dobutamine is almost always abnormal and should raise suspicion for severe coronary disease.

Stress tests using radiological agents confer low long-term risk of cancer, but patients undergoing such examinations often receive little or inaccurate information about these risks. A sestamibi scan is approximately 12 mSv. A thallium scan is approximately 25 mSv.(For comparison, the annual background radiation per annum a person receives is approximately 3 mSv.) A thallium scan corresponds to the dose of 250 chest x rays, or an extra cancer risk of about 1 in 16000 exposed patients (A. de González). The lifetime risk of fatal cancer development is 4%/Sv or 0.004%/mSv or about 0.1% for a thallium scan. Therefore, frequent usage of these tests has to balance the benefits against the risks of radiation.

Another major risk of stress testing, whether by exercise or pharmacological agents, is the possibility of inducing an MI, especially in patients with severe multi-vessel coronary artery disease. This risk, however, is substantially lower than the risk of major complications (such as inducing a heart attack, stroke, peripheral artery clot and embolism) from cardiac catheterization (about 1%).

The choice of pharmacologic stress agent to be used (dobutamine, adenosine, dipyridamole) depends on factors such as concurrent medications and diseases. Dobutamine is usually used when a patient has asthma or severe COPD, takes the medication theophylline or has ingested coffee or chocolate (anything with caffeine), or has 2nd or 3rd degree AV block (a type of heart block). Adenosine or dipyridamole is generally used when a patient has poorly controlled hypertension, glaucoma, or has left bundle branch block (LBBB, another type of heart block). It is well known that patients with LBBB can have false positive septal ischemia if dobutamine is used as a pharmacologic agent in nuclear stress test. The adverse effects associated with the use of pharmacologic stress test agents can be reversed upon completion of the test. For drugs that promote adenosine (including dipyrimadole or adenosine itself), adenosine antagonists that constrict blood vessels such as theophylline or caffeine can be given. The adverse effects of beta-agonists like dobutamine can be reversed with the administration of a beta-blocking agent such as propranolol.

Most physicians support the population-wide reduction of risk factors which cause heart attack. These risk factors are contained in the well-known cardiac Framingham Risk Score. Physicians typically take a history, perform a physical and then obtain baseline bloodwork and a resting ECG. Stress testing is the established method of investigating moderate-risk patients for coronary artery disease as well as obtaining prognostic information for the patient.

Limitations

Stress tests do not detect atheromata (lipid deposits within the walls, not lumens, of arteries) or vulnerable plaques, which cause most heart attacks, or myocardial infarctions. Recent (late 1990s) clinical studies have shown that the vulnerable plaques are commonly present within many regions of the coronary arteries, yet are typically relatively flat and do not protrude into the arterial lumen sufficiently to produce enough stenosis (usually less than 50%, average 20% by some IVUS studies) to be detectable by stress test methods. Thus, over the last 20 years or so, newer approaches in both research and clinical assessment/management have increasingly focused on measuring coronary calcification, intima-media thickness (IMT), or using intravascular ultrasound, along with (or in place of) the longer used techniques of coronary angiography, to detect plaque within the walls of arteries at earlier stages of progression, before the arterial lumen becomes more severely compromised.

The major limitation of the stress test approach is that it requires high-grade stenosis to indicate heart attack risk. And high-grade stenosis, while a good indicator of advanced arterial disease, is not the major cause of myocardial infarctions. This issue is also reflected in the results of the COURAGE trial[4], which demonstrated that "intensive pharmacologic therapy and lifestyle intervention" produced better survival and quality of life than invasive interventions such as angioplasty.

Like all tests, stress testing has problems with both falsely positive and falsely negative results compared with other clinical tests.

Preparation

Prior to a stress test one should not eat or drink for a couple of hours. You should however be very well hydrated before you begin. One may also be asked to refrain from smoking prior to the test. If you are undergoing some kind of medical treatments take all your medications prior to a stress test, unless told otherwise by the physician in charge [5]. All individuals who use heart medications and inhalers for their asthma should bring them to the stress test center. Let the doctor know if you have diabetes; since exercise can lower blood sugar, he or she may want to check your blood sugar level before the test begins.

Comfortable loose clothes for exercising and running shoes are the best clothing items to wear for such a test.[6].It is also recommended that you do warm up and extension exercises before you begin a cardiac stress test or any type of exercise routine. This will help prevent any cramping up of the muscles being used.

After the test

Once the stress test has been completed, you will be asked to walk for a while and cool down. Then you will also be asked to lie down and recover. All this still with the monitors in place. Only after the readings have returned to baseline normal will you be discharged and sent home. Once the test has been completed, you can resume your daily living activities closely following any indications that the doctor (s) give you. The best cool-down after the test or any exercise activity is to slowly decrease the intensity of your activity. You may also do some of the same stretching activities you did in the warm-up phase.[7]

As opposed to exploratory surgery, these tests are much less expensive and also involve a much lower risk towards the patient. What is even better is that there is no recovery time involved in the case of these cardiac tests. Once you have been cleared by the doctors to leave is time to go home.[8]

Conclusion and subjects for further research

The increased spatial resolution allows for more sensitive detection of ischemia, which initially starts at the thin subendocardial layer, due to stenotic epicardial supply vessels. First-pass stress perfusion cardiac MR imaging is performed using a rapid bolus injection of gadolinium based contrast and rapidly obtaining T1 weighted images of the myocardium at every R-R interval after pharmacologic stress induced with adenosine. The stress and resting first-pass perfusion MRI data can then be analyzed using a convolution model (such as the Marquard-Levenberg least-squares algorithm) to determine the quantitative global myocardial perfusion reserve (Michael Jerosch-Herold). Delayed hyper-enhancement imaging can be done after 10–15 minutes of contrast injection to evaluate for regions of infarction or fibrosis which has increased signal due to the slower washout of contrast from these areas (Thomson LE). Stress cardiac MRI perfusion testing thus is sensitive enough to detect subtle ischemia and myocardial infarctions even if they are limited only to the subendocardial level. The major problem again is that they still do not detect the "vulnerable plaques" which is the major cause of most heart attacks.

Stress testing, even if done in time, will detect only some of these people before symptoms, debility or death. Stress testing methods, though more effective than a resting ECG, only detect medium to high-grade flow limitations; this assuming the testing is fully and aggressively performed. However, most acute artery flow disrupting events leading to heart attacks are due to rupture of "vulnerable plaques". Most of the "vulnerable plaques" cause less than 40% lumen narrowing, a degree of stenosis which is usually too minimal to cause a reduction in maximal coronary blood flow that is required for detection by stress testing methods.

Historically, through the mid-1980s, it was believed that detecting these high-grade stenoses was the key to recognizing people who would have heart attacks in the future. However, there was also long-standing experience that some people could exercise all the way to maximum predicted heart rate, have no abnormal symptoms and completely normal stress test results, only to die of a massive heart attack within a few days to weeks. While anecdotal and not quantitative, these observations have long demonstrated the unreliability of the stress test approach as a means of diagnosing arterial disease before serious health problems occur. From the 1960s to 1990s, despite the success of stress testing identifying many who were at high risk for heart attack, its failure to correctly identify many others was a conundrum, discussed in medical circles but unexplained.

The high grade stenoses which are detected by stress test methods are often, though not always, responsible for recurring symptoms of angina. Cardiac stress tests do detect some individuals who already have with very advanced coronary arterial disease and stenosis, some of whom did not recognize that they had advanced disease. However, stress test results (especially stress perfusion cardiac MRI which can detect subtle diffuse subendocardial decreased perfusion due to microvascular disease) are also sometimes abnormal in some people who do not have high grade narrowings of their coronary arteries as visualized by coronary angiography, which provides more accurate information of the coronary artery lumen. This was long viewed as a false positive result, with some of these individuals diagnosed as having Syndrome X, i.e. meaning clear recurring signs of angina, though with smooth open coronary artery lumens on coronary angiography. The actual underlying issues responsible for this apparent conundrum are now better understood, see atheroma and microvascular disease.

In the 1950s, heart attacks were commonly attributed to coronary thrombosis, a clot closure of a coronary artery, based on post mortem examination findings. In the late 1950s to early 1960s, this concept became replaced by the concept of stenosis based on the angiographic view of the lumens of the coronary arteries. In turn the angiographic view led to promotion of cardiac stress testing to detect stenoses, i.e. the severe ones more commonly present in people experiencing recurrent angina with physical exertion.

By the early to mid-1990s, it became more widely recognized that rupture of more rapidly evolving and unstable atheroma, hidden within the walls of the coronary arteries, called "vulnerable plaques", even though they often produce little or no stenosis of the coronary lumen, is the primary event which produces most heart attacks; thus back to the coronary thrombosis view, though with more sophistication of understanding some of the complexities. Two clinical trials published in the late 1990s, focusing on the relation between plaque structure, lumen stenosis and myocardial infarction, in which each individuals coronary anatomy was tracked with both angiography and IVUS found that 75% or greater stenotic areas were responsible for only about 14% of heart attacks. The typical heart attack occurred at an artery location with extensive, eccentric plaque within the wall but a luminal stenosis of only 20%. This finding added further evidence to the importance of the concept of vulnerable plaques. The detection of these vulnerable plaques using high resolution CT, MRI, IVUS, OCT (Optical Coherence Tomography), and molecular imaging is currently hotly researched. For CT, as of 2005, 64-slice multidetector machines are providing the best artery and lumen images, yet still do not clearly reveal which plaques are vulnerable. It is hoped that perhaps with better resolution and ability to characterize the content of the plaques that an imaging modality may in the future be able to indicate which plaques are "vulnerable" as it is clear that detecting a stenosis itself, however subtle, is not enough.

Unfortunately, cardiac stress tests are only capable of detecting medium to high-grade limitations of blood flow to the left ventricular heart muscle, which may produce recurring angina, not the atheroma that produce heart attacks. Stress test methods do not evaluate blood flow to non-left-ventricle heart muscle. Thus stress test results are often falsely negative for many people, in terms of predicting who is at high risk for myocardial infarction due to atheroma or ruptured "vulnerable plaques".

It has become clear that stress testing recognizes most people at risk for heart attacks too late, unfortunately only after the disease and symptoms of the disease have developed. By the time, a majority of people would already have at least medium stenosis of coronary vessels with development of atheroma or have already had heart attacks or died. It is hoped that research in higher resolution imaging techniques will allow for earlier detection and characterization of subtle atheroma and to initiate lifestyle changes and optimal medical therapy in "vulnerable patients" before they develop symptoms.

See also

References

Cite error: Invalid <references> tag; parameter "group" is allowed only.

Use <references />, or <references group="..." />

Circulation, Fletcher et al. AHA Exercise Standards for Testing. 201:104:1694.

National Guideline Clearinghouse. Cardiac Stress Test Supplement. ICSI:2003Nov.26p.87.

Michael Jerosch-Herold; Seethamraju, RT; Swingen, CM; Wilke, NM; Stillman, AE (2004). "Analysis of myocardial perfusion MRI". Journal of Magnetic Resonance Imaging. 19 (6): 758–770. doi:10.1002/jmri.20065. PMID 15170782. .

Thomson LE; Kim, RJ; Judd, RM (2004). "Magnetic resonance imaging for the assessment of myocardial viability". Journal of Magnetic Resonance Imaging. 19 (6): 771–788. doi:10.1002/jmri.20075. PMID 15170783. .

A. de González (2004). "Risk of cancer from diagnostic X-rays: estimates for the UK and 14 other countries". The Lancet. 363 (9406): 345–351. doi:10.1016/S0140-6736(04)15433-0. .

Morin; Gerber, TC; McCollough, CH (2003). "Radiation Dose in Computed Tomography of the Heart". Circulation. 107 (6): 917–922. doi:10.1161/01.CIR.0000048965.56529.C2. PMID 12591765. .

External links

cs:Ergometrie

de:Ergometrie fr:Épreuve d'effort it:Test da sforzo he:ארגומטריה nl:Inspannings-ecg pl:Test wysiłkowy pt:Teste de esforço

sq:Ergometria
  1. Sabatine, Marc (February 15, 2000). Pocket Medicine. Lippincott Williams & Wilkins. pp. 256 pages. 
  2. Master AM, Oppenheimer ET (February 1929). "A simple exercise tolerance test for circulatory efficiency with standard tables for normal individuals". Am J Med Sci. 177 (2): 223–243. doi:10.1097/00000441-192902000-00010. Retrieved 6 August 2010. 
  3. Gibbons, R.; Balady, G.; Timothybricker, J.; Chaitman, B.; Fletcher, G.; Froelicher, V.; Mark, D.; McCallister, B.; Mooss, A. (2002). "ACC/AHA 2002 guideline update for exercise testing: summary articleA report of the American college of cardiology/American heart association task force on practice guidelines (committee to update the 1997 exercise testing guidelines) 1 2 3 4 5". Journal of the American College of Cardiology. 40 (8): 1531. doi:10.1016/S0735-1097(02)02164-2. PMID 12392846.  edit
  4. Lua error in package.lua at line 80: module 'Module:Citation/CS1/Suggestions' not found.
  5. Exercise Stress Test - Medline Plus - Retrieved on 2010-01-26
  6. Preparation for an Exercise Stress - Harvard Health Publications - Retrieved on 2010-01-26
  7. Exercise Stress - How to cool down properly - Retrieved on 2010-01-26
  8. Cardiac Stress - What to expect after the test - Retrieved on 2010-01-26