Correlation MRI/ultrastructure in cerebral ischemic lesions: application to the interpretation of cortical layered areas.

The origin and fate of cortical ischemic lesions, showing a stratified appearance at in vivo MRI-examination, was studied on rats in which a focal brain ischemia was induced by occlusion of the middle cerebral artery. One week after ischemia induction, six rats were selected in which three layers of different intensity were visible in the lesioned cortex. Two animals were sacrificed and studied by histology and electron microscopy. The external hyperintense layer was composed of pial and lesioned nervous tissue, the intermediate of degenerating nervous tissue in which an accumulation of macrophages was found, the deepest of edematous nerve tissue without a marked accumulation of macrophages. The remaining rats underwent further MRI examinations showing that, in the lesioned areas, cerebral blood volume was 14-69% lower than the contralateral healthy cortex. At histological and ultrastructural examination, a large part of the lesion was occupied by enlarged pial tissue and marginal glia. A dilatation of the ventricular cavity and cystic structures were also visible. In three animals an increase of the transverse diameter of the caudo-putamen ipsilateral to the lesion was found. The study suggests that the layered appearance is mainly due to an accumulation of macrophages in the intermediate layer and that several processes contribute to the occlusion of the space created by the removal of the necrotic tissue in stratified ischemic lesions (i.e. expansion of the pial tissue, thickening of the marginal glia; expansion of the caudo-putamen, enlargement of the ventricular cavity and development of cystic structures).

Delayed muscle injuries in arterial insufficiency: contrast-enhanced MR imaging and 31P spectroscopy in rats.

PURPOSE: To evaluate whether the vascular system resulting from an arterial lesion shows differences in permeability to a tracer with respect to the normal vascular system and whether eventual differences are maintained for long periods. MATERIALS AND METHODS: Permanent ischemia was induced in rats with femoral arterial removal, and magnetic resonance (MR) imaging was performed after 1, 7, 14, and 90 days. Gadopentetate dimeglumine was injected, and the kinetics of its penetration in the leg were studied. Phosphorus 31 spectroscopy was performed to determine the bioenergetic characteristics of the gastrocnemius muscle at rest and stimulation. Ischemic muscles were then processed for electron microscopy. RESULTS: After ischemia induction, a hyperintense area that progressively decreased was present on T2-weighted images. Gadopentetate dimeglumine improved the signal intensity of the area. Three months after arterial occlusion, the contrast-enhanced images still showed microvessels highly permeable to the tracers. Spectroscopic data revealed that 3 months after arterial removal, the bioenergetic reserve of the gastrocnemius muscle was reduced, suggesting that the contrast-enhanced MR imaging-visible area is functionally relevant. Ultrastructural examination revealed persistent muscle damage and signs of chronic microangiopathy. CONCLUSION: After ischemia induction, the restitutio ad integrum is not complete, and delayed muscle injuries can result from arterial insufficiency.

Regional cerebral blood volume mapping after ischemic lesions.

The possible persistence of a microvascular deficit at long time intervals after cerebral ischemia induction is not well established. In rats, we have generated in vivo maps of the regional cerebral blood volume (rCBV) at different time intervals after middle cerebral artery occlusion (MCAo) with the aim to evaluate the persistence of a rCBV deficit in the damaged area or in the surrounding regions. The rats were examined by magnetic resonance imaging (MRI) at different time intervals, starting from the first day until three months after ischemia and postmortem histological and ultrastructural correlation was obtained. All MRI experiments were carried out using an imager-spectrometer equipped with a 4.7 Tesla magnet. To produce the susceptibility-weighted rCBV images, a suspension of superparamagnetic iron oxide nanoparticles (AMI-25) was injected to the rat. In a control group (nonoperated or sham-operated rats), a symmetrical distribution of rCBV values was found between the two hemispheres (differences between left and right cortex below 8%). In the rats with MCAo an evident vascular asymmetry was found 24 h after ischemia (differences between left and right ranging from 22 and 77%) and reduced rCBV values were evident in the ischemic areas. In a time range following the 15th day most of the rats showed a complete recovery of the lesion while only four animals still had a small residual lesion, as probed by T2-weighted (T2W) images. In three of these four cases, the reduction of rCBV in the ipsilateral cortex with respect to the contralateral was greater than 20%. Correlation was found (Y > 0.8) between late rCBV measurement and the initial volume of the lesion (hyperintense region in T2W images). The postmortem measurements correlate much better with the rCBV data than with the T2W ones. In conclusion, the present work demonstrates that cortical lesions may result in a deficit of rCBV for long periods and that a mismatch between T2w and rCBV data can be present during the repair process.

Comparison of results of scanning electron microscopy and magnetic resonance imaging before and after administration of a radiographic contrast agent in the tendon of the deep digital flexor muscle obtained from horse cadavers.

OBJECTIVE: To analyze the tendon of the deep digital flexor (TDDF) muscle of the forelimb in horses by use of a contrast radiographic agent (gadopentate dimeglumine [Gd-DTPA/Dimeg]) and magnetic resonance imaging (MRI) and to determine the concentration of water protons in the tendons by use of MRI. SAMPLE POPULATION: 8 TDDF harvested from the forelimbs of 6 horse cadavers. PROCEDURE: Examinations were performed on the same portion of each tendon. Tendons were examined by use of two techniques: MRI before and after treatment with Gd-DTPA/Dimeg as well as scanning electron microscopy. RESULTS: Tendons did not have detectable signal intensity on MRI before treatment with Gd-DTPA/Dimeg; however, intravascular injection of Gd-DTPA/Dimeg allowed evaluation of the internal structure of the tendons Scanning electron microscopy images correlated well with images obtained by use of MRI before and after administration of Gd-DTPA/Dimeg. Localized spectra revealed the concentration of water protons in the TDDF. CONCLUSIONS AND CLINICAL RELEVANCE: The techniques used in this study provided information about internal organization of the TDDF in horses. Analysis of results revealed that the best technique involved vascular injection of contrast medium. Results of MRI correlated well with results for scanning electron microscopy. After administration of Gd-DTPA/Dimeg, MRI provided additional information about tendon morphologic characteristics. This technique may be of value for examination of tendons in lame horses.

Use of magnetic resonance imaging for diagnosis of a spinal tumor in a cat.

Magnetic resonance imaging was used to identify a spinal mass at the level of the 6th-7th cervical vertebral body in a cat. The MRI images were most consistent with the presence of an intradural, extramedullary meningioma that was confirmed by subsequent histological examination.