Comparison of MR perfusion imaging and microsphere measurements of regional cerebral blood flow in a rat model of middle cerebral artery occlusion

Abstract

The purpose of this investigation was to correlate magnetic resonance (MR) perfusion measurements with absolute regional cerebral blood flow (rCBF) in a rat model of focal ischemia. The MR perfusion measurements were made using dynamic first-pass bolus tracking of a susceptibility contrast agent, whereas rCBF was measured using radioactive microspheres. Two simple MR perfusion parameters, the maximum change in R 2 ∗ ( m ΔR 2 ∗ ) and time delay to m ΔR 2 ∗ ( t ΔR 2 ∗ ), were derived from the signal intensity versus time curves on a pixel-to-pixel basis, without applying curve-fitting procedures or tracer kinetic theory. In each hemisphere, m ΔR 2 ∗ and t ΔR 2 ∗ were compared with the rCBF measurements in four selected regions of interest. Sixteen MR bolus tracking series were performed in 12 rats with occlusion of the middle cerebral artery. In all of the individual series there was a significant correlation (.0001 ≤ p ≤ .02) between m ΔR 2 ∗ and the microsphere rCBF measurements, with correlation coefficients ranging from .784 to .983. Pooling the m ΔR 2 ∗ data resulted in a correlation coefficient of .809 ( p = .0001). There was a nonlinear correlation between the t ΔR 2 ∗ and rCBF. For both parameters there was considerable variation between different measurements regarding both the slope of the regression line and its intercept with the y-axis. Our results justify the use of m ΔR 2 ∗ as a relative measure of perfusion during acute cerebral ischemia. Because of the interindividual variation, calibration of MR perfusion measurements for the estimation of absolute flow values must be considered unreliable. The t ΔR 2 ∗ may have physiological relevance as a marker of collateral flow.