[Vascular applications of interventional MRI]. / Vaskuläre Applikationen der interventionellen MRT.

The flow sensitivity inherent to the MR experiment allows for the non-invasive assessment of both the arterial and venous vasculature in any desired plane with good spatial resolution. Data can be acquired in a three-dimensional form, permitting reformating in any plane. In addition, MRI is capable of providing quantitative blood flow information with the use of phase-contrast flow-mapping techniques. Ultrafast gradient echo and echoplanar data acquisition strategies even permit imaging in near-real time. The availability of open MRI configurations now permits one to take advantage of the unique imaging features inherent to MR imaging for the purpose of guidance and control of various intravascular procedures. With the recent development of the MR tracking and MR profiling techniques, permitting visualization of guide-wires and catheters relative to their surroundings in the MR environment in real time, one of the last obstacles to 'Interventional MR angiography' has in effect been overcome. In addition, MR catheters can be modified to acquire high-resolution MR images of the vascular wall, thereby opening vast possibilities regarding characterization of atherosclerotic plaques. This review introduces the underlying techniques for catheter and guide-wire visualization in the MR environment, describes preliminary interventions in animals and humans and discusses the potential of intravascular MRI.

Radio-frequency-induced thermoablation: monitoring with T1-weighted and proton-frequency-shift MR imaging in an interventional 0.5-T environment.

PURPOSE: To evaluate the feasibility and accuracy of monitoring radio-frequency (RF) ablation with an open-configuration, 0.5-T magnetic resonance (MR) imager. MATERIALS AND METHODS: Thirty-six in vivo RF ablation experiments were performed in porcine paravertebral muscle (n = 24) and liver (n = 12). A 90 degrees C tip temperature was applied for 3-9 minutes. MR images were acquired after continuous or during intermittent RF application. Temperature changes were monitored as signal intensity and proton-frequency-shift (PFS) alterations in two T1-weighted gradient-echo sequences. An update image was obtained every 2.5 seconds (20/10 [repetition time msec/echo time [TE] msec]) or every 5.0 seconds (40/20). A color-coded subtraction technique enhanced the signal intensity and PFS changes. Macroscopic coagulation size was compared with MR image lesion size. RESULTS: The RF application mode had no significant effect on coagulation size in muscle or liver (P > .05). Twenty-two of 24 coagulative lesions in muscle and nine of 12 in liver were demonstrated with the PFS technique. Accuracy of lesion size determination depended on TE (TE = 20 msec, r = .95; TE = 10 msec, r = .78 [P < .01]). The T1-weighted technique depicted only six of 24 muscle and three of 12 liver lesion ablations. In the lesions depicted, macroscopic size was significantly underestimated (P < .001). CONCLUSION: PFS MR monitoring of RF effects in liver and muscle is feasible and accurate. The PFS technique outperformed the T1-weighted technique.

Active MR visualization of a vascular guidewire in vivo.

The purpose of this study was development of an actively visualized .035-inch vascular guidewire for use in MR-guided interventions. The guidewire was actively visualized by inclusion of a 6-cm-long radiofrequency coil in its tip. A high contrast outline of the distal tip of the guidewire was obtained by acquiring an image with the radiofrequency coil as the receiving antenna. The position of the guidewire relative to the surrounding anatomy was determined by overlaying the guidewire image on a previously acquired road map. The guidewire was evaluated in vivo in the abdominal vessels of a rabbit and swine at 1.5 T. The built-in radiofrequency coil delivered a high contrast signal over its full length, enabling visualization of the position and curvature of the tip of the guidewire. The ability to see the curvature of the guidewire over several centimeters significantly eased manipulation into targeted vessels and represents an important advance toward MR-guided vascular interventions.

Visualization of vascular guidewires using MR tracking.

MR tracking of a vascular guidewire sized for a .035-inch (.89-mm) catheter lumen was performed. The guidewire was actively tracked by incorporation of a miniature radiofrequency (RF) receive coil built into its tip. After in vitro validation, simultaneous tracking of the guidewire and a catheter was performed in the aortic and abdominal vessels of a swine at 1.5 T. The ability to track such a small device and the ability to simultaneously track multiple devices are significant steps towards vascular interventions under MR guidance.

Intravascular MR imaging of atherosclerotic plaque: ex vivo analysis of human femoral arteries with histologic correlation.

PURPOSE: To assess the potential role of intravascular magnetic resonance (MR) imaging with receiver coils mounted to an inflatable balloon in characterizing atherosclerotic plaque. MATERIALS AND METHODS: Twelve human harvested segmental femoral arteries with atherosclerotic changes were studied with a 5-F imaging balloon catheter equipped with a single-loop wire receiver coil. Imaging was performed with an open-configuration 0.5-T (n = 6) or a 1.5-T (n = 6) MR system, with T1- and T2-weighted sequences. Histologic analysis was the reference standard, and MR images were analyzed with regard to vessel wall thickness, plaque area, and components. RESULTS: Images acquired at 1.5 T were characterized by better in-plane resolution (117 x 104 microm). Resolution at 0.5 T (234 x 178 microm) was sufficient to discriminate the wall layers. On T2-weighted images, adventitia, media, and thickened intima could be discriminated. T1-weighted images did not permit differentiation between wall layers. There was good correlation between MR and histologic measurements of wall thickness (r = .97) and plaque area (r = .98). Plaque characterization was possible on T2-weighted images. Calcified plaque was identified as areas of low signal intensity (134 +/- 98) and could be differentiated from fibrous structures containing collagen (1,968 +/- 680) or fatty components (762 +/- 394). CONCLUSION: Intravascular MR imaging on the basis of the balloon catheter design enables differentiation of wall layers and plaque components.

[The differentiation of adrenal gland tumors: an improvement in accuracy by a combination of fat-sensitive, T2-weighted and contrast-enhanced MR sequences]. / Differenzierung von Nebennierentumoren: Verbesserung der Treffsicherheit durch Kombination fettsensitiver, T2-gewichteter und kontrastmittelverstärkter MR-Sequenzen.

PURPOSE: To determine the diagnostic value of 3 MR sequences for the diagnosis of adrenal tumors. MATERIAL AND METHODS: Retrospective analysis of 32 adrenal tumors (10 malignant, 15 adenomas, 5 inflammatory, 2 phaeochromocytomas) examined by MRT (1.5 T) using T2 turbo spin echo, chemical shift imaging and dynamic contrast-enhanced gradient echo sequences. RESULTS: Differentiation between malignant and benign adrenal tumours by means of T2-weighted sequences, chemical shift imaging and dynamic contrast-enhanced sequences achieved a sensitivity/specificity of 90%/73%, 100%/68% and 90%86%. Accuracy was 78%, 78% and 87%. By combining the three procedures, sensitivity/specificity/accuracy was improved to 100%/91%/94%. CONCLUSION: To differentiate adrenal lesions, the following procedures are recommended: demonstration of fat by chemical shift imaging is indicative of an adenoma. In the absence of any lipid content, T2-weighted and dynamic contrast-enhanced sequences can demonstrate inflammatory lesions.

[Intravascular MR imaging: the first in-vivo experiences in an animal arteriosclerosis model]. / Intravaskuläre MR-Bildgebung: erste in-vivo-Erfahrungen in einem Arteriosklerose-Tiermodell.

PURPOSE: To evaluate intravascular MR imaging in normal New Zealand rabbits and hereditary hyperlipidaemic Watanabe rabbits (WHHL) with histological correlation. MATERIAL AND METHODS: The suprarenal abdominal aortas of two normal and two WHHL rabbits were examined by conventional angiography, high resolution MRT with a surface coil and intravascular MRT in a 1.5 T system. The intravascular reception coil consisted of a copper wire loop built into the balloon of an angioplasty catheter. The findings were correlated with histological examinations. RESULTS: Excellent spin echo images with a resolution of 78 x 156 microns were obtained in less than 4 minutes. The arteriosclerotic changes in the vessels of the WHHL rabbits could not be recognised angiographically. High resolution MRT with surface coils showed mural thickening but a detailed demonstration of arteriosclerotic lesions was possible only by means of high resolution intravascular imaging. There was good histological correlation. CONCLUSION: Arteriosclerotic lesions can be demonstrated in vivo by high resolution intravascular imaging.