Echocardiography Shows Promise for Infarct Size Quantification

By MedImaging International staff writers
Posted on 03 Jan 2012
Speckle tracking echocardiography (STE) is a relatively new noninvasive echocardiography technique designed to quantify infarct size.

STE works by tracking the movement of natural acoustic markers or “speckles,” which are present on conventional gray ultrasound tissue images. With the use of wall motion tracking software, speckle movement, and therefore, myocardial tissue movement, can be visualized during the cardiac cycle.

Image: Representation of 2D-strain (speckle tracking) of the left ventricle in the apical long axis view in a patient with systolic heart failure (Photo courtesy of SPL).

Speckle tracking can be used to evaluate myocardial strain, which describes the myocardial deformation throughout the cardiac cycle. Reductions in measurement of strain have been found to show direct relationships to the size of the infarct. “Up until now, infarct size has only been measured as part of clinical studies and not in routine clinical practice. The reason being that the reference method of gadolinium-based contrast agents in MRI [magnetic resonance imaging] is expensive, takes a great deal of time to perform, and can only be undertaken by imaging specialists,” explained Dr. Luigi Badano, from the University of Padua (Italy). “The advantages of STE over MRI is that it’s far quicker to use, cheaper, and can be used by cardiologists at the bedside with portable machines, and repeated serially whenever needed.”

Moreover, STE can be applied even in patients with contraindications for MRI, such as metallic devices, claustrophobia, and severe renal failure that preclude use of contrast infusions. “The studies presented here open the way for every patient who is admitted to hospital with STEMI [ST elevation MI (myocardial infarction)] to undergo assessment of infarct size with echocardiography prior to discharge,” said Dr. Badano.

Infarct size matters for determining how well patients will recover from STEMI. Statistics suggest that individuals who suffer damage to more than 30% of the left ventricle are twice as likely to die within one year of the event than people who suffer less damage. “It’s well known that patients with larger infarcts are more likely to undergo alterations in the structure [dimensions, mass, and shape] of the left ventricle, known as cardiac remodeling, which leads to heart failure,” noted Dr. Badano.

Evidence is increasing, Dr. Badano noted, that screening for patients with larger infract sizes enables identification of patients with a worse prognosis who benefit from more aggressive therapy and more frequent follow-up visits. “Nowadays many more options exist for STEMI patients deemed at high risk of adverse events, including prescription of ACE [angiotensin-converting enzyme] inhibitors and insertion of devices like CRT [cardiac resynchronization therapy] or ICDs [implantable cardioverter defibrillators],” stated Dr. Badano.

Measuring circumferential strain with 3D speckle tracking provides a good predictor of infarct size after STEMI, according to an Italian study. In the study, which presents the first data on use of three-dimensional (3D) speckle tracking in measuring infarct size, Dr. Denisa Muraru and colleagues from the University of Padua (Italy) estimated infarct size and necrosis transmurality in patients with recent STEMI, who had undergone successful treatment with primary PCI.

One of the advantages of 3D speckle tracking over 2D, according to the researchers, is that it allows the assessment of longitudinal (apex-to-base shortening), circumferential (shortening in the circumferential direction); radial strain (myocardialwall thickening towards LV cavity center) and area strain (a deformation parameter combining longitudinal and circumferential strain) at the same time.

In the study, 49 patients with recent STEMI, successfully reperfused with primary PCI were assessed by 3D speckle tracking, and the obtained LV strain parameters were compared with peak troponin I levels, as an estimate of the extent of myocardial cell injury. In a multivariable analysis, results showed that only circumferential strain emerged as a significant independent predictor of infarct size. Furthermore, in the subgroup of 27 patients who underwent additional assessment with delayed-enhancement MRI within 24 hours from the echocardiographic study, circumferential strain again showed the closest correlation with infarct size and the best predictive power to identify LV segments with transmural necrosis among all strain components.
“Our preliminary study demonstrates that 3D circumferential strain could be used as an accurate and reproducible marker for infarct size estimation by ultrasound in STEMI patients,” stated Dr. Muraru. Long-term follow-up, she added, will be needed to verify if 3D strain parameters improve the predictive prognostic value of conventional parameters after STEMI.

Longitudinal strain measured early after reperfusion with 2D speckle tracking may predict infarct size and LV remodeling, concluded a Bulgarian study. In the study, Dr. Krasimira Hristova and colleagues, from the University National Heart Hospital (Sofia, Bulgaria) investigated the ability of speckle-tracking echocardiography using the vector velocity imaging technique (which measures both the amount of strain and the direction of strain) to determine infarct size.

In the study 30 patients who had percutaneous coronary intervention (PCI) for an acute myocardial infarction (MI) within 24 hours and 20 normal volunteers (who had not experienced an event) were assessed with both vector velocity speckle-tracking and intracoronary electrocardiography. The later technique is an established procedure that maps areas of ischemia with guide wires during percutaneous procedures, providing the exact location and size of residual ischemia.

The findings revealed that in patients who had suffered STEMI radial and circumferential strain decreased in the infarct area, perinfarct area (immediate area around the infarct), and remote regions acutely in comparison with controls; but that longitudinal strain was only decreased in the actual infarct area and not in the perinfarct and remote regions.

“While longitudinal strain shows the best relationship to infarct size, we believe that radial and circumferential strain may be useful to predict the later development of adverse LV remodeling,” stated Dr. Hristova. In the next phase of the study, she added, they hope to be able to compare their preliminary findings for longitudinal, radial, and circumferential strain with the longer-term effects on left ventricular remodeling.

Related Links:
University of Padua
University [Bulgarian] National Heart Hospital



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