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Llowing for plaque detection and vessel wall delineation (Figure 2C).Imaging of Contrast Agent UptakeThe aortic arches of ApoE2/2 mice (young and aged) were imaged with the retrospective-gated MRI protocol pre- and postinjection of a micellar T1 contrast agent. Throughout the cardiac cycle, 10 movie frames of 6 transversal slices were made (Figure 3A). Pre contrast agent injection, the plaque burden in the inner curvature of the aorta was difficult to discriminate from healthy vessel wall, with only slightly elevated CNR in the plaque (arrow in Figure 3B). After injection of Gd-containing micelles, a distinct hyperintensity was observed in the inner curvatures of the aortic arch and carotid arteries at the well-documented locations where atherosclerotic plaque is found in these ApoE2/2 mice (Figure 3C) [31]. The hyper enhancement was largest in the aged animals, but could be distinguished in the younger animals as well. The CNR values for these mice were determined after micelle injection for the images in the cardiac cycle with black blood (Figure 3A, frames 6?). Quantitative CNR values for the young and aged animals are summarized in Figure 3D. The CNR increased significantly after the injection of micelles in both groups, but both the CNR (Figure 3D1) and DCNR (Figure 3D2) of the aged animals were systematically higher than in the younger animals. We applied a similar imaging strategy to detect the contrast changes pre- and post-injection of an ultrasmall iron-oxide particle (USPIO). Because USPIOs induce large signal voids in the artery wall, the bright blood frames of the retrospective-gated CINE MRI were more suitable for CNR quantification (Figure 4A B). CNR (Figure 4C1) and DCNR (Figure 4C2) values became negative (hypointense) after injection of the contrast agent, and as for the micelles, the enhancement was more pronounced in the aged mice.HistologyAortic arches were frozen in Tissue TekH (Sakura Finetek Europe, Zoetermeer, The Netherlands) and cut into serial 5-mm sections. Sections were stained with hematoxylin and eosin for gross morphology and Oil Red O for lipid deposition as described previously [29], followed by bright-field microscopy. Lesion size was calculated from 8?0 consecutive H E stained sections of the aortic arch. Iron deposits were visualized using Perl’s Prussian blue staining. Presence of Gd-containing micelles was indirectly detected by staining of the DTPA MedChemExpress 1934-21-0 chelate present in the micelles as recently described in den Adel et al. [30]. In short, sections were incubated overnight at room I-BRD9 biological activity temperature with a rabbit polyclonal primary antibody against Gd-DTPA (1:20, BioPAL Inc). Goatanti-rabbit conjugate (1:200, DAKO) with normal goat serum diluted in PBS was incubated for 1 h at room temperature as secondary antibody. Biotin labelling was followed by development using black alkaline phosphatase (Vector Laboratories Inc., United Kingdom) and counterstaining was done with Mayer’s hematoxylin.Age Related Differences in Vessel Wall StiffnessAn increase in the diameter of the ascending aorta of the aged mice compared to the younger animals was observed both at endsystole and end-diastole (Figure 5A). A significant decrease of 46 in average maximal circumferential strain values was observed between 3 and 12-month-old ApoE2/2 mice (Figure 5B).Statistical AnalysisData are represented as the mean 6 standard deviation. Statistical analyses were performed using SPSS 17.0.2 (SPSS, Inc., Chicago, IL, USA). Statistical si.Llowing for plaque detection and vessel wall delineation (Figure 2C).Imaging of Contrast Agent UptakeThe aortic arches of ApoE2/2 mice (young and aged) were imaged with the retrospective-gated MRI protocol pre- and postinjection of a micellar T1 contrast agent. Throughout the cardiac cycle, 10 movie frames of 6 transversal slices were made (Figure 3A). Pre contrast agent injection, the plaque burden in the inner curvature of the aorta was difficult to discriminate from healthy vessel wall, with only slightly elevated CNR in the plaque (arrow in Figure 3B). After injection of Gd-containing micelles, a distinct hyperintensity was observed in the inner curvatures of the aortic arch and carotid arteries at the well-documented locations where atherosclerotic plaque is found in these ApoE2/2 mice (Figure 3C) [31]. The hyper enhancement was largest in the aged animals, but could be distinguished in the younger animals as well. The CNR values for these mice were determined after micelle injection for the images in the cardiac cycle with black blood (Figure 3A, frames 6?). Quantitative CNR values for the young and aged animals are summarized in Figure 3D. The CNR increased significantly after the injection of micelles in both groups, but both the CNR (Figure 3D1) and DCNR (Figure 3D2) of the aged animals were systematically higher than in the younger animals. We applied a similar imaging strategy to detect the contrast changes pre- and post-injection of an ultrasmall iron-oxide particle (USPIO). Because USPIOs induce large signal voids in the artery wall, the bright blood frames of the retrospective-gated CINE MRI were more suitable for CNR quantification (Figure 4A B). CNR (Figure 4C1) and DCNR (Figure 4C2) values became negative (hypointense) after injection of the contrast agent, and as for the micelles, the enhancement was more pronounced in the aged mice.HistologyAortic arches were frozen in Tissue TekH (Sakura Finetek Europe, Zoetermeer, The Netherlands) and cut into serial 5-mm sections. Sections were stained with hematoxylin and eosin for gross morphology and Oil Red O for lipid deposition as described previously [29], followed by bright-field microscopy. Lesion size was calculated from 8?0 consecutive H E stained sections of the aortic arch. Iron deposits were visualized using Perl’s Prussian blue staining. Presence of Gd-containing micelles was indirectly detected by staining of the DTPA chelate present in the micelles as recently described in den Adel et al. [30]. In short, sections were incubated overnight at room temperature with a rabbit polyclonal primary antibody against Gd-DTPA (1:20, BioPAL Inc). Goatanti-rabbit conjugate (1:200, DAKO) with normal goat serum diluted in PBS was incubated for 1 h at room temperature as secondary antibody. Biotin labelling was followed by development using black alkaline phosphatase (Vector Laboratories Inc., United Kingdom) and counterstaining was done with Mayer’s hematoxylin.Age Related Differences in Vessel Wall StiffnessAn increase in the diameter of the ascending aorta of the aged mice compared to the younger animals was observed both at endsystole and end-diastole (Figure 5A). A significant decrease of 46 in average maximal circumferential strain values was observed between 3 and 12-month-old ApoE2/2 mice (Figure 5B).Statistical AnalysisData are represented as the mean 6 standard deviation. Statistical analyses were performed using SPSS 17.0.2 (SPSS, Inc., Chicago, IL, USA). Statistical si.

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