There was a trend for the IR-TSE sequence to underestimate T1 in vivo. The sequence parameters for the IR-TSE and MPRAGE sequences were also optimized in terms of the signal-to-noise ratio (SNR) in the fitted T1. The optimal sequence for IR-TSE in terms of SNR in the fitted T1 was found to have five readouts at TIs of 120, 260, 563, 1,221, 2,647, 5,736 ms and TR of 7 s. The optimal pulse sequence for MPRAGE with readout flip angle = 8 degrees was found to have five readouts at TIs of 160, 398, 988, 2,455, and 6,102 ms and a TR of 9 s. Further optimization including the readout flip angle suggests that the flip angle should be increased, beyond levels that are acceptable in terms of power deposition and point-spread function.
Purpose: To determine if tissue magnetic susceptibility is a more direct marker of tissue iron content than other MR markers of iron. This study presents the first quantitative, in vivo measurements of the susceptibility of the substantia nigra in patients with Parkinson's disease. Materials and Methods:Nine patients and 11 controls were studied at 7 Tesla. Susceptibility maps were created by inverting the filtered phase maps associated with T2* weighted images.Results: On average, patients showed an increase in susceptibility of the pars compacta compared with controls, which correlates with the predicted increase in brain iron in Parkinson's disease. A rostral-caudal gradient in susceptibility was also observed in controls and patients. PARKINSON's DISEASE (PD) is a common neurodegenerative disease that is associated with dopaminergic cell loss in the substantia nigra (SN). In normal aging or Parkinson's disease, loss of these neurons occurs concurrently with the accumulation of iron, which acts as a nidus for neuronal damage, leading to free radical formation and lipid peroxidation (1). The pars compacta (PC), the medial sub region of the SN, has the greatest concentration of dopaminergic neurons in the SN.There have been several attempts to use MRI to study changes in the SN in PD. Anatomical differences within the borders of the SN have been studied in patients with PD, and an increased latero-medial contrast gradient has been detected (2,3). Reduced fractional anisotropy of water self diffusion, consistent with axonal loss, has also been observed in the SN of PD patients (4-6) and DTI has indicated changes in neuronal connectivity of the SN in patients with PD (3,7).However, most attempts to study PD with MRI have been based on the changes in iron homeostasis in the SN in PD, and the sensitivity of various MRI parameters to iron. In the SN there is a relatively inhomogeneous distribution of iron (8) in the form of ferritin and a heterogeneous distribution of iron within neuromelanin and hemosiderin, which will cause inhomogeneities in the magnetic field within a sample. The transverse relaxation rates, R2 and R2*, decrease with increasing iron concentration, due to spin dephasing in the microscopic field inhomogeneities induced in regions of heterogeneous iron distribution. R2 is sensitive to diffusion in the inhomogeneous magnetic field, whereas R2* is also sensitive to static dephasing in the inhomogeneous field. Increased R2 (9-12) and R2* (10) has been observed in the pars compacta of the SN of patients with PD, particularly on the most affected side. However, some studies do not detect this effect, possibly because the value of R2 measured will depend on the echo time interval in multiple spin-echo sequences, or on the echo time regimen explored in single spin echo sequences, due to the effects of diffusion and exchange. It has been proposed that the field dependence of R2 is a direct measure of ferritin, and using this it was suggested that early onset PD patients had an increase in ferritin in the S...
We investigated the extent to which a common neural mechanism is involved in task set-switching and response withholding, factors that are frequently confounded in task-switching and go/no-go paradigms. Subjects' brain activity was measured using event-related electrical potentials (ERPs) and event-related functional MRI (fMRI) neuroimaging in separate studies using the same cognitive paradigm. Subjects made compatible left/right keypress responses to left/right arrow stimuli of 1000 msec duration; they switched every two trials between responding at stimulus onset (GO task-green arrows) and stimulus offset (WAIT task-red arrows). With-holding an immediate response (WAIT vs. GO) elicited an enhancement of the frontal N2 ERP and lateral PFC activation of the right hemisphere, both previously associated with the "no-go" response, but only on switch trials. Task-switching (switch vs. nonswitch) was associated with frontal N2 amplification and right hemisphere ventrolateral PFC activation, but only for the WAIT task. The anterior cingulate cortex (ACC) was the only brain region to be activated for both types of task switch, but this activation was located more rostrally for the WAIT than for the GO switch trials. We conclude that the frontal N2 ERP and lateral PFC activation are not markers for withholding an immediate response or switching tasks per se, but are associated with switching into a response-suppression mode. Different regions within the ACC may be involved in two processes integral to task-switching: processing response conflict (rostral ACC) and overcoming prior response suppression (caudal ACC).
The transverse relaxation rate (R 2 ) of fresh human blood has been investigated at high and ultrahigh field, to characterize the R 2 dependency on blood sample oxygenation, hematocrit, and Carr-Purcell Meiboom-Gill sequence inter-echo spacing. Data were fitted to chemical exchange and diffusion models to assess their performance at different field strengths. The diffusion model gave a slightly superior fit at both field strengths, but the difference is unlikely to be relevant for the signal to noise ratio achieved in most in vivo experiments. Fitted model parameters were similar to those found in literature. Magn Reson Med 64:967-974,
The aim of this study was to optimise a pulse sequence for high-resolution imaging sensitive to the effects of conventional macromolecular magnetisation transfer (MT(m)) and nuclear Overhauser enhancement (NOE), and to use it to investigate variations in these parameters across the cerebral cortex. A high-spatial-resolution magnetisation transfer-prepared turbo field echo (MT-TFE) sequence was designed to have high sensitivity to MT(m) and NOE effects, whilst being robust to B0 and B1 inhomogeneities, and producing a good point spread function across the cortex. This was achieved by optimising the saturation and imaging components of the sequence using simulations based on the Bloch equations, including exchange and an image simulator. This was used to study variations in these parameters across the cortex. Using the sequence designed to be sensitive to NOE and MT(m), a variation in signals corresponding to a variation in MT(m) and NOE across the cortex, consistent with a reduction in myelination from the white matter surface to the pial surface of the cortex, was observed. In regions in which the stria was visible on T2*-weighted images, it could also be detected in signals sensitive to MT(m) and NOE. There was greater variation in signals sensitive to NOE, suggesting that the NOE signal is more sensitive to myelination. A sequence has been designed to image variations in MT(m) and NOE at high spatial resolution and has been used to investigate variations in contrast in these parameters across the cortex.
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