In vivo nuclear magnetic resonance chemical shift imaging by selective irradiation.

NMR images of preselected chemically shifted species can be obtained by selective irradiation of the remainder of the NMR chemical shift spectrum prior to application of a conventional NMR imaging sequence. The chemical-selective irradiation consists of narrow-bandwidth pi/2 or saturation radio-frequency pulses applied in the absence of imaging gradients. The technique permits substantial reductions in scan and reconstruction times over standard three- and four-dimensional Fourier transform chemical-shift-imaging methods, when images of few spectral peaks are desired. It is also suitable for the elimination of chemical shift artifacts in conventional high-field NMR imaging. In vivo applications of the technique to the head and limbs in a 1.5-T magnetic field yield 1H H2O and -CH2-images, with little detectable -CH2- in muscle and brain.

Anatomy and metabolism of the normal human brain studied by magnetic resonance at 1.5 Tesla.

Proton magnetic resonance (MR) images were obtained of the human head in magnetic fields as high as 1.5 Tesla (T) using slotted resonator high radio-frequency (RF) detection coils. The images showed no RF field penetration problems and exhibited an 11 (+/- 1)-fold improvement in signal-to-noise ratio over a .12-T imaging system. The first localized phosphorus 31, carbon 13, and proton MR chemical shift spectra recorded with surface coils from the head and body in the same instrument showed relative concentrations of phosphorus metabolites, triglycerides, and, when correlated with proton images, negligible lipid (-CH2-) signal from brain tissue on the time scale of the imaging experiment. Sugar phosphate and phosphodiester concentrations were significantly elevated in the head compared with muscle. This method should allow the combined assessment of anatomy, metabolism, and biochemistry in both the normal and diseased brain.

Nuclear magnetic resonance imaging: contrast-to-noise ratio as a function of strength of magnetic field.

The choice of the strength of the magnetic field for an imaging system based on the nuclear magnetic resonance of hydrogen is considered. It is shown by an analysis based on in vitro data that the quality, or contrast-to-noise ratio, of images based on T1 or T2 discrimination increases with field up to 1.5-2 T. After a brief discussion of potential high-field limitations, results are presented which show that images of the human head with excellent anatomic detail can be produced at 1.5 T or 64 MHz.

Head and body imaging by hydrogen nuclear magnetic resonance.

A hydrogen (1H) nuclear magnetic resonance (NMR) imaging study of the normal head, thorax, and limbs is reported. The images are 10 to 15 mm thick transverse slices obtained in 2 to 4 min using a two-dimensional Fourier transform technique. Spatial resolution in the imaging plane is about 2 mm, enabling the optic nerve and many small blood vessels to be observed. Thorax scans show details of the cardiac chambers, aorta wall, and lungs without artefacts arising from physiological motion.

CT of the lumbosacral spine: importance of tomographic planes parallel to vertebral end plate.

An experimental computer program capable of reformatting stored display data from a CT scanner into true cross-sectional images of the spine has been clinically tested over a 1 year period. With this program, tomographic planes exactly parallel to the vertebral end plate can be imaged at the lumbosacral level even in patients who are markedly rotated or have scoliotic deformities. The reformatted image planes are tilted in the dorsoventral and mediolateral directions to compensate for lordosis or scoliosis. The reformatting can also produce images in coronal and sagittal planes on axes other than true horizontal or vertical. The program has been used in the examination of 269 spines and has been found to be valuable in demonstrating the spinal canal and the intervertebral foramina.