Rj. Kim et al., Relationship of elevated Na-23 magnetic resonance image intensity to infarct size after acute reperfused myocardial infarction, CIRCULATION, 100(2), 1999, pp. 185-192
Citations number
35
Categorie Soggetti
Cardiovascular & Respiratory Systems","Cardiovascular & Hematology Research
Background-Elevated Na-23 MR image intensity after acute myocardial infarct
ion has previously been shown to correspond to high tissue [Na+] and loss o
f myocardial viability. In this study, we explored the potential of in vivo
Na-23 MRI to assess infarct size and investigated possible mechanisms for
elevated Na-23 image intensity.
Methods and Results-Thirteen dogs and 8 rabbits underwent in situ coronary
artery occlusion and reperfusion and were imaged by Na-23 MRI. For anatomic
ally matched left ventricular short-axis cross sections (n=46), infarct siz
e measured by in vivo Na-23 MRI correlated well with triphenyltetrazolium c
hloride staining (r=0.87, y=0.92x+3.37, P<0.001). Elevated Na-23 image inte
nsity was observed in infarcted myocardium (206+/-37% of remote in dogs, P<
0.001; 215+/-58% in rabbits, P<0.002) but was not observed after severe but
reversible ischemic injury (101+/-11% of baseline, P=NS). High-resolution
ex vivo imaging revealed that regions of elevated Na-23 image intensity app
eared to be identical to those of infarcted regions (r=0.97, y=0.92x+1.52,
P<0.001). In infarcted regions, total tissue [Na+] was elevated (89+/-12 ve
rsus 37+/-9 mmol/L in control tissue, 156+/-60% increase, P<0.001) and was
associated with increased intracellular sodium (254+/-68% of control, P<0.0
05) and an increased intracellular sodium/potassium ratio (868+/-512% of co
ntrol, P<0.002). Morphometric analysis demonstrated only a minor increase i
n extracellular volume (17+/-8% versus 14+/-5%, P<0.05) in the infarcted te
rritory.
Conclusions-Elevated Na-23 MR image intensity in vivo measures infarct size
after reperfused infarction in both a large and a small animal model. The
mechanism of elevated Na-23 image intensity is probably intracellular sodiu
m accumulation secondary to loss of myocyte ionic homeostasis.