A double-delay SR-MGE-SNAP sequence allowing simultaneous T1 and T2* measurement was developed for integrating arterial input function (AIF) measurement into DCE MRI. Implemented on a 4.7-T animal MR system, this technique was applied to mice with colorectal tumor xenografts. AIF, measured in the mouse heart, was modeled by a bi-exponential function, whereas tumor K(trans) and v(e) parameter maps were obtained from analysis with a two- compartment model using an individually measured AIF. AIF analysis of T2*-corrected data yielded A1 = 9.2 +/- 4.3 kg/l, A(2) = 4.2 +/- 0.8 kg/l, m1 = 2.3 +/- 1.1 min(-1), and m2 = 0.05 +/- 0.02 min(-1). The mean initial plasma concentration C ( p )(t = 0) = 8.0 +/- 2.7 mM was compatible with estimated 8.6 mM. Without T2*-correction distribution phase parameters A1, m1, and C(p)(t = 0) were underestimated. In tumors, neglect of T2* effects yielded mean K(trans) values which were reduced by 14% (P < 0.05), whereas v(e) showed only a slight non-significant reduction. Simultaneous measurement of DeltaR1 and DeltaR2* studied in highly and poorly vascularized and (pre-)necrotic tumor regions revealed complementary behavior of both parameters with respect to vascular properties. In conclusion, the presented measurement technique is a promising tool for dynamic MRI applications studied in animal models at high field strengths and/or with CA of high relaxivities, as it combines classical DCE MRI integrating AIF assessment with dynamic T2* measurement.
In this study, T2*- relaxivity contrast imaging (RCI) is proposed for new contrast generation in MRI. The method produces images of relaxivities r*2,vasc and r*2,EES caused by susceptibility gradients across the vessel walls and cell membranes, respectively. The sensitivity to noise was assessed with a simulation study, and initial results are presented for five colorectal tumor xenografts in nude mice. Simulations show that the new relaxivity parameters are at least as accurate and precise as standard parameters such as plasma volume and interstitial volume. Mean values of both relaxivities were significantly different (r*2,vasc=10.9±2.9 mM(-1) s(-1) and r*2,EES=15.6±2.6 mM(-1) s(-1)). r*2,vasc (r=0.67) and r*2,EES (r=0.52) were weakly correlated with plasma volume and interstitial volume, respectively. Images of r*2,vasc and r*2,EES reveal a different tumor structure than plasma volume and interstitial volume maps. These results suggest that relaxivity contrast imaging is practically feasible and might offer supplementary information compared to dynamic contrast-enhanced-MRI.
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