Friday, 7 may 2010

Gas-filled microbubbles have been shown as an MR susceptibility contrast agent; however, microbubble susceptibility effect is relatively weak when compared with other contrast agents. Studies have indicated that, by embedding magnetic nanoparticles, the magnetic susceptibility of the shell can be increased, thus enhancing the microbubble susceptibility effect. In this study, we further demonstrated the synergistic effect of gas core with iron oxide nanoparticles in achieving the overall microbubble susceptibility effect and characterized in vivo enhancements of microbubble susceptibility effects by entrapping iron oxide nanoparticles at 7 T, leading to the practical use of microbubbles as an intravascular MRI contrast agent.

Currently, positive contrast with superparamagnetic iron oxide nanoparticles (SPIOs) is limited to large particles within the static dephasing regime. We present a novel approach to generating positive contrast from SPIOs within the motional averaging regime. By simply adding a T2-weighted sequence prior to an inversion recovery sequence, we show a 30-fold improvement in contrast-to-noise ratio (CNR) over ordinary inversion recovery sequences. By taking advantage of the latest advances in nanotechnology, we expect an even greater improvement by making use of nanoparticles that have both T1 and T2 enhancement.

We propose a susceptibility tensor imaging (STI) technique to measure and quantify anisotropy of magnetic susceptibility. This technique relies on the measurement of resonance frequency offset at different orientations. We propose to characterize the orientation variation of susceptibility using an apparent susceptibility tensor. The susceptibility tensor can be decomposed into three eigenvalues (principle susceptibilities) and associated eigenvectors that are coordinate-system independent. We show that the principle susceptibilities offer strong contrast between gray and white matter while the eigenvectors provide orientation information of an underlying magnetic network. We believe that this network may further offer information of white matter fiber orientation.

MRI is routinely used for stereotactic guidance and surgical preparation for deep brain stimulation implantation. In preoperative MRI, a high contrast between midbrain nuclei and surrounding white matter is needed for more accurate electrode placement. Although conventional T2- and T2*-weighted imaging can be used for visualization of midbrain nuclei, a long TE value is needed and thus the scan time cannot be shortened. In this study, a 3D multi-echo steady-state free precession method is used to provide superior contrast at TE < 10ms. By further integrating SWI reconstruction and multi-echo SSFP, a direct and highly robust visualization of midbrain nuclei can be achieved.

Certain neurodegenerative diseases are associated with increased iron concentration in specified brain regions. To provide an up to date basis for validation of MR-based assessment of brain iron content, iron concentrations in selected grey and white matter regions of postmortem human brains were determined using inductively coupled plasma mass spectrometry (ICPMS) and compared to corresponding susceptibility weighted images (SWI). Measured iron concentrations were in good agreement in most brain regions with values published before. Visual comparison of the measured results with contrast in SWI showed that areas with high iron content correlate well with hypointense regions.

Development of new susceptibility-based contrast MR imaging biomarkers of angiogenesis (e.g. susceptibility-based blood volume and vessel size index) requires biophysical models that incorporate accurate representations of the brain tumor vasculature to establish an accurate relationship to the molecular basis of angiogenesis. We investigate the relationship between brain tumor angiogenesis and susceptibility-based contrast MRI by incorporating the de facto brain vasculature in a state-of-the-art computational model of MR image contrast called the finite perturber method (FPM). Our simulations show substantial signal differences between regions of tumor vascularity and normal brain while enabling to study the entire vascular network of a mouse brain at the same time.