PURPOSE: To obtain T2 * and T2 -weighted images as well as quantitative T2 * , T2 , and susceptibility maps with a novel, silent 3D imaging method, which combines zero-echo-time (ZTE) imaging with gradient- and spin-echo BURST encoding. METHODS: After a segment of standard ZTE encoding with multiple 3D radial k-space spokes, the direction of traversing k-space is reversed while excitation is switched off. This recalls gradient echoes for each spoke/excitation. This results in multiple images: one FID image from ZTE and multiple BURST echo images at different echo times weighted by a T2 * decay. By adding a pair of 180° pulses with an appropriate wait period, it is also possible to obtain spin echoes, leading to T2 -weighted images. Data is reconstructed using standard 3D gridding and Fourier transformation. In vivo feasibility was demonstrated by imaging the brain of multiple healthy volunteers. RESULTS: It is possible to acquire high-quality T2 * - and T2 -weighted brain images in a silent manner. From images acquired with gradient-echo ZTE-BURST, it is possible to extract quantitative T2 * and magnetic susceptibility maps, whereas the spin echo version yields T2 maps. CONCLUSION: ZTE combined with BURST enables silent acquisition of T2 * - and T2 -weighted images with good image quality.
PURPOSE: To obtain T2 * and T2 -weighted images as well as quantitative T2 * , T2 , and susceptibility maps with a novel, silent 3D imaging method, which combines zero-echo-time (ZTE) imaging with gradient- and spin-echo BURST encoding. METHODS: After a segment of standard ZTE encoding with multiple 3D radial k-space spokes, the direction of traversing k-space is reversed while excitation is switched off. This recalls gradient echoes for each spoke/excitation. This results in multiple images: one FID image from ZTE and multiple BURST echo images at different echo times weighted by a T2 * decay. By adding a pair of 180° pulses with an appropriate wait period, it is also possible to obtain spin echoes, leading to T2 -weighted images. Data is reconstructed using standard 3D gridding and Fourier transformation. In vivo feasibility was demonstrated by imaging the brain of multiple healthy volunteers. RESULTS: It is possible to acquire high-quality T2 * - and T2 -weighted brain images in a silent manner. From images acquired with gradient-echo ZTE-BURST, it is possible to extract quantitative T2 * and magnetic susceptibility maps, whereas the spin echo version yields T2 maps. CONCLUSION: ZTE combined with BURST enables silent acquisition of T2 * - and T2 -weighted images with good image quality.