Myocardial Infarction

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Author(s) I.A.C. van der Bilt, MD
Moderator I.A.C. van der Bilt, MD
Supervisor
some notes about authorship

Ischemia occurs when part of the heartmuscle, the myocardium, is deprived form oxygen and nutrients. Common causes of ischemia are:

  • Narrowing or obstruction of a coronary artery.
  • A rapid arrhythmia, causing a disbalance in supply and demand of energy.

A short period of ischemia causes reversibele effects: The heartcells will be able to recover. When the ep[isode of ischemia lasts for a longer period of time, heartmuscle cells will die. This is called a heart attack or myocardial infarction. That is why it is critical to recognize ischemia on the ECG in an early stage.

Severe ischemia will reuslts in ECG changes within minutes. While the ischemia lasts, several ECG changes will occur and disappear again. Therefore, it may be difficult to estimate the duration of the ischemia on the ECG, which is crucial for adequate treatment.

Signs and symptoms of myocardial ischemia:

  • Crushing pain on the chest (angina pectoris), behind the sternum, often radiating to the lower jaw or the left arm
  • Fear of dying
  • Nausea
  • Shock (manifesting as paleness, low blood pressure, fast weak pulse) shock
  • Rhythm dysturbances (in particular increasing prevalnce of ventricular ectopia, ventricular tachycardia, AV block)

Risk assessment of ischemia

The narrowing of the coronary artery leading to a myocardial infarction, usually develops over several years. An increased risk of myocardial infarction can be estimated using SCORE system which is developed by the European Society of cardiology (ESC). As shown in the figue, the most important risk factors for myocardial infarction are:

  • Male sexe
  • Smoking
  • Hypertension
  • Diabetes Mellitus
  • Hypercholesterolemia

An exercise test such as a bicycle or treadmilltest, may be usefull in detecting myocardial ischemia after exercise.[1] In such a test, a continuous ECG registration is performed during exercise. The ST-segment, blood pressure asnd clinical status of the patient (i.e. chest complaints) are monitorered during and after the test.

An exercise test is positive for myocardial ischemia when the following criteria are met:

  • Horizontal or downsloping ST-depression of > 1mm, 60 or 80ms after the J-point
  • ST elevation of > 1.0 mm


Diagnosis of myocardial infarction

ST elevation is measured 60ms or 80ms after the J point

The diagnosis of acute myocardial infarction is not only based on the ECG. A myocardial is defined as:[2]

  • Elevated blood levels of cardiac enzymes (CKMB or Troponin T) AND
  • One of the following criteria are met:
    • The patient has typical complaints
    • The ECG shows ST elevation or depression
    • pathological Q waves develop on the ECG
    • A coronary intervention had been performed (such as stent placement)

So detection of elevated serum heartenzymes is more important than ECG changes. However, the heartenzymes can only be detected in the serum 5-7 hours after the onset of the myocardial infarction. So especially in the first few hours after the myocardial infarction the ECG can be crucial.

Significant ST elevation is defined as
ST elevation of more than 2mm in two chest leads or more than 1 mm in two adjacent limb leads
ST elevation is measured 60ms or 80ms after the J-point

Myocardial infarction diagnosis in left or right bundle branch block can be difficult, but is explained in these seperate chapters:


The location of the infarct

An overview of the coronary arteries. LM = 'Left Main' = mainstem; LAD = 'Left Anterior Descending' artery; RCX = Ramus Circumflexus; RCA = 'Right Coronary Artery'.
The ST elevation points at the infarct location. Inferior MI = ST elevation in red regions (lead II,III and AVF). Lateral MI = ST elevation in blue leads (lead I, AVL, V5-V6). Anterio MI: ST elevation in yellow region (V1-V4). Left main stenosis: ST elevation in gray area (AVR)
Overview of the seperate ECG leads. The lead with ST elevation 'highlights' the infarct. An infarction of the inferior wall will result in ST elevation in leads II, III and AVF. A lateral wall infarct results in ST elevation in leads I and AVL. An Anterior wall infarct results in ST-elevation in the precordial leads.

The heartmuscle itself is very limited in its capacity to extract oxygen in the blood that is being pumped. Only the inner layers (the endocardium) profit from this oxygenrich blood. The outer layers of the heart (the epicardium) are dependent on the coronary arteries for the supply of oxygen and nutrients. With aid of an ECG, the occluded coronary can be identified. This is valuable information for the clinician, because treatment and complications of for instance an anterior wall infarction is different than those of an inferior wall infarction. The anterior wall performs the main pump function, and decay of the function of this wall will lead to decrease of bloodpressure, increase of heartrate, shock and on a longer term: heart failure. An inferior wall infarction is often accompanied with a decrease in heartrate because of involvement of the sinusnode. Longterm effects of an inferior wall infarction are usually less severe than those of an anterior wall infarction.

The heart is supplied of oxygen and nutrients by the right and left coronary arteries. The left coronray artery (the Left Main or LM) divides itself in the left anterior descending artery (LAD) and the ramus circumflexus (RCX). The right coronary artery (RCA) connects to the ramus descendens posterior (RDP). With 20% of the normal population the RDP is supplied by the RCX. This called left dominance.

Below you can find several different types of myocardial infarcation. Click on the specific infarct location to see examples.


Help with the localisation of a myocardial infarct
localisation ST elevation Reciproke ST depression coronary artery
Anterior MI V1-V6 None LAD
Septal MI V1-V4, disappearance of septum Q in leads V5,V6 none LAD
Lateral MI I, aVL, V5, V6 II,III, aVF RCX or MO
Inferior MI II, III, aVF I, aVL RCA (80%) or RCX (20%)
Posterior MI V7, V8, V9 high R in V1-V3 with ST depression V1-V3 > 2mm (mirror view) RCX
Right Ventricle MI V1, V4R I, aVL RCA
Atrial MI PTa in I,V5,V6 PTa in I,II, or III RCA


The localisation of the occlusion can be adequately visualized using a coronary angiogram (CAG). On the CAG report, the place of the occlusion is often graded with a number (for example LAD(7)) using the classification of the American Heart Association.[3]

Development of the ECG during persistent ischemia

The evolution of an infarct on the ECG. ST elevation, Q wave formation, T wave inversion, normalisation with a persistent Q wave

The cardiomyocytes in the subendocardial layers are especcially vulnerable for a decreased perfusion. Subendocardial ischemia manifests as ST depression and is usually reversible. In a myocardial infarction transmural ischemia develops.

In the first hours and days after the onset of a myocardial infarction, several changes can be observed on the ECG. First, large peaked T waves (or hyperacute T waves), then ST elevation, thennegative T waves and finally pathologic Q waves develop.

Evolution of the ECG during a myocardial infarct
see figure change
minutes not in figure

b

hyperacute T waves (peaked T waves)

ST-elevation

hours c

d

ST-elevation, with terminal negative T wave

negative T wave (these can last for months)

days e Pathologic Q Waves


References

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  1. Error fetching PMID 12356646: [accexercise]
  2. Error fetching PMID 10987628: [Alpert]
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  4. Error fetching PMID 16777513: [Wung]
  5. Error fetching PMID 10653675: [Menown]
  6. Error fetching PMID 11265742: [LBTB]

All Medline abstracts: PubMed | HubMed

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