Design and construction of a gradient coil for high resolution marmoset imaging.

A gradient coil with integrated second and third order shims has been designed and constructed for use inside an actively shielded 310 mm horizontal bore 9.4 T small animal MRI. An extension of the boundary element method, to minimise the power deposited in conducting surfaces, was used to design the gradients, and a boundary element method with a constraint on mutual inductance was used to design the shims. The gradient coil allows for improved imaging performance and was optimized for an imaging region appropriate for marmoset imaging studies. Efficiencies of 1.5 mT m-1 A-1 were achieved in a 15 cm wide bore while maintaining gradient uniformity ≤5% over the 8 cm region of interest. Two new cooling methods were implemented which allowed the gradient coil to operate at 100 A RMS, 25 % of max current with a temperature rise below 30 C.

Increased deep gray matter iron is present in clinically isolated syndromes.

OBJECTIVE: Abnormal iron accumulation in MS has been known for decades, however it remains to be established whether iron reflects a cause or epiphenomenon of pathology. The objective of the present study is to determine if iron is increased in the brains of patients with clinically isolated syndromes (CIS) suggestive of early MS. METHODS: Twenty-two patients with a CIS and 16 age- and sex-matched controls underwent 3T MRI studies. Differences in R2*, a metric of iron concentration, were assessed for all voxels throughout the brain. Similar clusters of significant differences were grouped, wherein mean R2* was regressed against a number of parameters, including extended disability status scale (EDSS), age, disease duration, and internal jugular vein (IJV) cross-sectional area (CSA), as measured from magnetic resonance time-of-flight venograms. RESULTS: Patients had significantly increased R2* in globus pallidus, thalamus, right pulvinar, and cortical areas. Thalamic R2* correlated positively with EDSS. Decreased white matter R2* was detected at various positions in the patient group average. No correlations were found between any changes in R2* and IJV CSA. INTERPRETATION: Iron is increased in CIS in deep gray matter, suggesting this iron accumulation, well-known in definite MS, occurs early in the disease course. Increases in thalamic iron are associated with worsened clinical status. Decreased white matter R2* may be interpreted as diffuse damage to normal appearing white matter, not often reported in CIS. Observations do not support a role for venous abnormalities in either iron accumulation or white matter damage.

Signal displacement in spiral-in acquisitions: simulations and implications for imaging in SFG regions.

Susceptibility field gradients (SFGs) cause problems for functional magnetic resonance imaging (fMRI) in regions like the orbital frontal lobes, leading to signal loss and image artifacts (signal displacement and "pile-up"). Pulse sequences with spiral-in k-space trajectories are often used when acquiring fMRI in SFG regions such as inferior/medial temporal cortex because it is believed that they have improved signal recovery and decreased signal displacement properties. Previously postulated theories explain differing reasons why spiral-in appears to perform better than spiral-out; however it is clear that multiple mechanisms are occurring in parallel. This study explores differences in spiral-in and spiral-out images using human and phantom empirical data, as well as simulations consistent with the phantom model. Using image simulations, the displacement of signal was characterized using point spread functions (PSFs) and target maps, the latter of which are conceptually inverse PSFs describing which spatial locations contribute signal to a particular voxel. The magnitude of both PSFs and target maps was found to be identical for spiral-out and spiral-in acquisitions, with signal in target maps being displaced from distant regions in both cases. However, differences in the phase of the signal displacement patterns that consequently lead to changes in the intervoxel phase coherence were found to be a significant mechanism explaining differences between the spiral sequences. The results demonstrate that spiral-in trajectories do preserve more total signal in SFG regions than spiral-out; however, spiral-in does not in fact exhibit decreased signal displacement. Given that this signal can be displaced by significant distances, its recovery may not be preferable for all fMRI applications.