RESUMEN
Spectrometers make use of D/A converters to generate RF and gradient shapes. This paper examines by exact simulations the time and amplitude digitization effects, inherent to the use of D/A converters, on the performance of amplitude modulated (AM) frequency selective RF pulses. By making use of Fourier theory and the small tip angle approximation, an approximate model of these effects on the magnetization slice profiles is derived and verified for several pulse types by computer simulations. This approximate model will be used to derive requirements for D/A converters with respect to spatial localization. The dynamics of the spin system allows pulse width modulation (PWM) as an alternative to AM for pulse envelope encoding. The effects of PWM on the slice profile are examined and compared with conventional AM pulses. It is shown by simulation and measurement that adiabatic PWM pulses can be found. In contrast to AM modulated adiabatic pulses, adiabatic PWM pulses have side bands with the same slice quality as the main slice and might therefore be useful as multislice selective pulses.
Asunto(s)
Espectroscopía de Resonancia Magnética , MagnetismoRESUMEN
A fast and flexible time domain iterative fitting procedure that can be used to fit free induction decays as well as echo-like signals is described. Damping constants of the first and second part of the echo do not have to be identical. Prior knowledge can be used to diminish the number of parameters to be fitted, which results in an improved accuracy. It is shown how prior knowledge is mathematically incorporated in the Gauss-Newton method. From proton NMR measurements of model solutions actual prior knowledge is extracted. With this knowledge relative concentrations are determined from a mixture of metabolites. The fitted results agree with the true values within the margins of the noise. After some minor changes the same prior knowledge was successfully used to analyze a series of in vivo rat brain measurements.
Asunto(s)
Espectroscopía de Resonancia Magnética/métodos , Matemática , Modelos TeóricosRESUMEN
Several multiple quantum editing techniques for in vivo proton NMR are discussed and compared using simulated and experimental data. Extensions of these techniques for improved editing are given. Relative S/N ratios, modulation characteristics, metabolite selectivity, B0 and B1 inhomogeneity and motion effects are considered. Frequency selective read pulses can be used for signal enhancement and lipid suppression. Extra suppression of undesired signals can be obtained with a two-shot t1 cycle which gives good results for both the zero and double quantum sequences. These sequences give at most 50% signal intensity and lipid suppression factors of ca 2000 and 7000, respectively. A sequence which selects zero and double quantum coherences yields 100% signal intensity but only gives a good lipid suppression factor (7000) in combination with phase cycling. It is shown that the multiple quantum modulation can be used to obtain specific metabolite editing. Corrections can be made for the effects of B0 inhomogeneity on the multiple quantum coherences; B1 inhomogeneity affects the investigated multiple quantum sequences in about the same way and decreases the volume of interest. In vivo measurements show the good performance of the proposed zero and double quantum sequences for lactate.