Home Random Page


CATEGORIES:

BiologyChemistryConstructionCultureEcologyEconomyElectronicsFinanceGeographyHistoryInformaticsLawMathematicsMechanicsMedicineOtherPedagogyPhilosophyPhysicsPolicyPsychologySociologySportTourism






ACUTE CORONARY SYNDROME

The initial diagnosis of acute coronary syndrome (ACS) is based on history, risk factors, and, to a lesser extent, ECG findings. The symptoms are due to myocardial ischemia, the underlying cause of which is an imbalance between supply and demand of myocardial oxygen.

Patients with ACS include those whose clinical presentations cover the following range of diagnoses: unstable angina, non–ST-elevation myocardial infarction (NSTEMI), and ST-elevation myocardial infarction (STEMI). This ACS spectrum concept is a useful framework for developing therapeutic strategies.

History

  • Typically, angina is a symptom of myocardial ischemia that appears in circumstances of increased oxygen demand. It is usually described as a sensation of chest pressure or heaviness, which is reproduced by activities or conditions that increase myocardial oxygen demand.
  • Not all patients experience chest pain. Some present with only neck, jaw, ear, arm, or epigastric discomfort.
  • Other symptoms, such as shortness of breath or severe weakness, may represent anginal equivalents.
  • A patient may present to the ED because of a change in pattern or severity of symptoms. A new case of angina is more difficult to diagnose because symptoms are often vague and similar to those caused by other conditions (eg, indigestion, anxiety).
  • Patients may have no pain and may only complain of episodic shortness of breath, weakness, lightheadedness, diaphoresis, or nausea and vomiting.
  • Patients may complain of the following:

·

    • Palpitations
    • Pain, which is usually described as pressure, squeezing, or a burning sensation across the precordium and may radiate to the neck, shoulder, jaw, back, upper abdomen, or either arm
    • Exertional dyspnea that resolves with pain or rest
    • Diaphoresis from sympathetic discharge
    • Nausea from vagal stimulation
    • Decreased exercise tolerance
    • Patients with diabetes and elderly patients are more likely to have atypical presentations and offer only vague complaints, such as weakness, dyspnea, lightheadedness, and nausea.
  • Stable angina
    • Involves episodic pain lasting 5-15 minutes
    • Provoked by exertion
    • Relieved by rest or nitroglycerin
  • Unstable angina: Patients have increased risk for adverse cardiac events, such as MI or death. Three clinically distinct forms exist, as follows:
    • New-onset exertional angina
    • Angina of increasing frequency or duration or refractory to nitroglycerin
    • Angina at rest
  • Variant angina (Prinzmetal angina)
    • Occurs primarily at rest
    • Triggered by smoking
    • Thought to be due to coronary vasospasm
  • Elderly persons and those with diabetes may have particularly subtle presentations and may complain of fatigue, syncope, or weakness. Elderly persons may also present with only altered mental status. Those with preexisting altered mental status or dementia may have no recollection of recent symptoms and may have no complaints whatsoever.
  • As many as half of cases of ACS are clinically silent in that they do not cause the classic symptoms described above and consequently go unrecognized by the patient. Maintain a high index of suspicion for ACS especially when evaluating women, patients with diabetes, older patients, patients with dementia, and those with a history of heart failure.

Physical



  • Physical examination results are frequently normal. If chest pain is ongoing, the patient will usually lie quietly in bed and may appear anxious, diaphoretic, and pale.
  • Hypertension may precipitate angina or reflect elevated catecholamine levels due to either anxiety or exogenous sympathomimetic stimulation.
  • Hypotension indicates ventricular dysfunction due to myocardial ischemia, infarction, or acute valvular dysfunction.
  • Congestive heart failure (CHF)
  • Jugular venous distention
    • Third heart sound (S3) may be present.
    • A new murmur may reflect papillary muscle dysfunction.
    • Rales on pulmonary examination may suggest left ventricular (LV) dysfunction or mitral regurgitation.
    • Presence of a fourth heart sound (S4) is a common finding in patients with poor ventricular compliance due to preexisting ischemic heart disease or hypertension.

Causes

  • Atherosclerotic plaque is the predominant cause. Coronary artery vasospasm is less common.
  • Alternative causes of angina include the following:
    • Ventricular hypertrophy due to hypertension, valvular disease, or cardiomyopathy
    • Embolic occlusion of the coronary arteries
    • Hypoxia, as in carbon monoxide poisoning or acute pulmonary disorders
    • Cocaine and amphetamines, which increase myocardial oxygen demand and may cause coronary vasospasm
    • Underlying coronary artery disease, which may be unmasked by severe anemia
    • Inflammation of epicardial arteries
    • Coronary artery dissection
  • Risk factors for ACS should be documented and include the following:
    • Male gender
    • Diabetes mellitus (DM)
    • Smoking history
    • Hypertension
    • Increased age
    • Hypercholesterolemia
    • Hyperlipidemia
    • Prior cerebrovascular accident (CVA) - These patients constitute 7.5% of patients with ACS and have high-risk features.
    • Inherited metabolic disorders
    • Methamphetamine use
    • Occupational stress
    • Connective tissue disease

Lab Studies

  • Troponin I is considered the preferred biomarker for diagnosing myocardial necrosis. Troponins have the greatest sensitivity and specificity in detecting MI, and elevated serum levels are considered diagnostic of MI. They also have prognostic value.
    • For early detection of myocardial necrosis, sensitivity of troponin is superior to that of the creatine kinase–MB (CK-MB). Troponin I is detectable in serum 3-6 hours after an MI, and its level remains elevated for 14 days.
    • Troponin is a contractile protein that normally is not found in serum. It is released only when myocardial necrosis occurs.
    • Troponin should be used as the optimum biomarkers for the evaluation of patients with ACS who have coexistent skeletal muscle injury.
  • Troponin T has similar release kinetics to troponin I, and levels remains elevated for 14 days. False-positive results may occur in patients with renal failure. Minor elevations in troponin T level also identify patients at risk for subsequent cardiac events.
  • Elevated troponin levels may also point to minor myocardial injury due to other causes. Zellweger et al described 4 patients with elevated troponin levels after supraventricular tachycardia without evidence of coronary artery disease and very low risk scores for ACS.1 Similarly, Koller found that endurance athletes may show elevated serum troponin levels in the absence of ACS.2
  • CK-MB levels begin to rise within 4 hours after MI, peak at 18-24 hours, and subside over 3-4 days. A level within the reference range does not exclude myocardial necrosis.

·

    • The upper limit of normal for CK-MB is 3-6% of total CK. A normal level in the ED does not exclude the possibility of MI. A single assay in the ED has a 34% sensitivity for MI. Serial sampling over periods of 6-9 hours increases sensitivity to approximately 90%. Serial CK-MB over 24 hours detects myocardial necrosis with a sensitivity near 100% and a specificity of 98%.
    • Occasionally, a very small infarct is missed by CK-MB; therefore, troponin levels should be measured for patients suspected to have MI who have negative results from serial CK-MB tests.
    • One study looked at using the 2-hour delta (increase or decrease) of cardiac markers as 1 of 6 criteria in making the diagnosis of ACS and MI. According to one of the Erlanger criteria, an increase in the CK-MB level of 1.5 ng/mL or greater or an increase of the cardiac troponin I level of 0.2 ng/mL or greater over 2 hours in itself would allow one to make the provisional diagnosis of ACS with a high degree of sensitivity and specificity, even if the total levels were within the normal range. Patients with recent MI were also identified by a decreasing curve of CK-MB. Using this 2-hour delta of cardiac markers greatly reduces the number of cases of MI and ACS that are overlooked in patients who are then inappropriately discharged home.
  • Myoglobin, a low-molecular-weight heme protein found in cardiac and skeletal muscle, is released more rapidly from infarcted myocardium than troponin and CK-MB and may be detected as early as 2 hours after MI. Myoglobin levels, although highly sensitive, are not cardiac specific. They may be useful for early detection of MI when performed with other studies.
  • Cardiac markers should be used liberally to evaluate patients with prolonged episodes of ischemic pain, with new changes on ECG, or with nondiagnostic or normal ECGs in whom the diagnosis of ACS or MI is being considered.
  • Complete blood count is indicated to determine if anemia is a precipitant. Transfusion with packed red blood cells may be indicated.
  • A chemistry profile is indicated. Obtain a basic metabolic profile, including a check of blood glucose level, renal function, and electrolytes levels, for patients with new-onset angina. Potassium and magnesium levels should be monitored and corrected. Creatinine levels must be considered before using an angiotensin-converting enzyme (ACE) inhibitor.
  • Other biochemical markers
    • C-reactive protein (CRP) is a marker of acute inflammation. Patients without biochemical evidence of myocardial necrosis but elevated CRP level are at increased risk of an adverse event.
    • Interleukin 6 is the major determinant of acute-phase reactant proteins in the liver, and serum amyloid A is another acute-phase reactant. Elevations of either of these can be predictive in determining increased risk of adverse outcomes in patients with unstable angina.
  • In one study, patients presenting to the ED with suspected myocardial ischemia showing higher levels of inflammatory cytokines were associated with an increased risk of a serious cardiac event during the subsequent 3 months. However, the cytokines have limited ability to predict a serious adverse cardiac event.
  • Erythrocyte sedimentation rate rises above reference range values within 3 days and may remain elevated for weeks.
  • Serum lactase dehydrogenase level rises above the reference range within 24 hours of MI, reaches a peak within 3-6 days, and returns to the baseline within 8-12 days.

Imaging Studies

  • Chest radiograph may demonstrate complications of ischemia, such as pulmonary edema, or it may provide clues to alternative causes of symptoms, such as thoracic aneurysm or pneumonia.
  • Echocardiogram often demonstrates wall motion abnormalities due to ischemia. It is of limited value in patients whose symptoms have resolved or in those with preexisting wall motion abnormalities. However, echocardiogram may be useful in identifying precipitants for ischemia, such as ventricular hypertrophy and valvular disease.
  • Radionuclide myocardial perfusion imaging has been shown to have favorable diagnostic and prognostic value in this setting, with an excellent early sensitivity to detect acute myocardial infarction (MI) not achieved by other testing modalities.
    • A normal resting perfusion imaging study has been shown to have a negative predictive value of more than 99% in excluding MI. Observational and randomized trials of both rest and stress imaging in the ED evaluation of patients with chest pain have demonstrated reductions in unnecessary hospitalizations and cost savings compared with routine care.
    • Perfusion imaging has also been used in risk stratification after MI and for measurement of infarct size to evaluate reperfusion therapies. Novel "hot spot" imaging radiopharmaceuticals that visualize infarction or ischemia are currently undergoing evaluation and hold promise for future imaging of ACS. (See Myocardial Ischemia - Nuclear Medicine and Risk Stratification.)
  • Recent advances include dual-source 64-slice CT scanners that can do a full scan in 10 seconds and produce high-resolution images that allow fine details of the patient's coronary arteries to be seen. This technology allows for noninvasive and early diagnosis of coronary artery disease and thus earlier treatment before the coronary arteries become more or completely occluded. It allows direct visualization of not only the lumen of the coronary arteries but also plaque within the artery. Dual-source 64-slice CT scanning is being used with intravenous contrast to determine if a stent or graft is open or closed.
  • Technetium-99m (99mTc) tetrofosmin single-photon emission computed tomography (SPECT) is a useful method to exclude high-risk patients among patients with chest pain in the emergency department.
  • Resting cardiac magnetic resonance imaging (MRI) has exhibited diagnostic operating characteristics suitable for triage of patients with chest pain in the ED. Performed urgently to evaluate chest pain, MRI accurately detected a high fraction of patients with ACS, including patients with enzyme-negative unstable angina. MRI can identify wall thinning, scar, delayed enhancement (infarction), and wall motion abnormalities (ischemia). Coronary artery assessment may be coupled with magnetic resonance (MR) angiography in the future.

Other Tests

  • ECG is the most important ED diagnostic test for angina. It may show changes during symptoms and in response to treatment, which would confirm a cardiac basis for symptoms. It also may demonstrate preexisting structural or ischemic heart disease (left ventricular hypertrophy, Q waves). A normal ECG or one that remains unchanged from the baseline does not exclude the possibility that chest pain is ischemic in origin. Changes that may be seen during anginal episodes include the following:
    • Transient ST-segment elevations (fixed changes suggest acute MI) may be observed. In patients with elevated ST segments, consider LV aneurysm, pericarditis, Prinzmetal angina, early repolarization, and Wolff-Parkinson-White syndrome as possible diagnoses.
    • Dynamic T-wave changes (inversions, normalizations, or hyperacute changes) may be observed. In patients with deep T-wave inversions, consider CNS events or drug therapy with tricyclic antidepressants or phenothiazines.
    • ST depressions may be junctional, downsloping, or horizontal.
    • Diagnostic sensitivity may be increased by performing right-sided leads (V4R), posterior leads (V8, V9), and serial recordings.

 

Prehospital Care

Generally, patients transported with chest pain should initially be managed under the assumption that the pain is ischemic in origin. Prehospital interventions should be guided by the nature of the presenting complaint, individual risk factors, and associated symptoms (eg, breathing difficulty, hemodynamic instability, appearance of ectopy). Airway, breathing, and circulation should be rapidly assessed with institution of CPR, ACLS-guided interventions, or other measures as indicated for the unstable patient.

  • Obtain intravenous access.
  • Administer supplemental oxygen.
  • Aspirin (162-325 mg) should be given in the field, chewed and swallowed.
  • Telemetry and prehospital ECG, if available, may be helpful in selected circumstances. Certain EMS systems have investigated protocols for prehospital administration of thrombolytic therapy. This has not become a trend due to unproven benefit and due to the increase in availability of percutaneous coronary intervention (PCI) in many medical centers as an alternative to thrombolysis for STEMI.
  • Perform pulse oximetry.
  • Administer sublingual or aerosolized nitroglycerin if chest pain is ongoing and is believed to be cardiac in origin.

Date: 2015-01-12; view: 808


<== previous page | next page ==>
CLINICAL | Emergency Department Care
doclecture.net - lectures - 2014-2024 year. Copyright infringement or personal data (0.007 sec.)