Motion Artifact Compensation in 1H Spectroscopic Imaging by Signal Tracking

## Abstract The measurement of intramyocellular lipid (IMCL) using in vivo ^1^H MRS is important for better understanding muscle physiology. However, the accurate measurement of IMCL in muscle adjacent to subcutaneous fat (SF) and bone marrow (BM) is often hampered by contaminations from the fat. I

## Abstract Different approaches are being explored for the noninvasive observation of myocardial lipids in the human heart by __in vivo__ ^1^H NMR spectroscopy. One approach is to measure cardiac lipids using a combination of volume selection and 2D gradient phase encoding. From these data sets li

## Abstract We introduce a fast and robust spatial‐spectral encoding method, which enables acquisition of high resolution short echo time (13 ms) proton spectroscopic images from human brain with acquisition times as short as 64 s when using surface coils. The encoding scheme, which was implemented

## Abstract Patients with intracranial tumors (gliomas) were examined by means of localized water‐suppressed ^1^H NMR single volume spectroscopy and spectroscopic imaging. The ^1^H NMR spectra of the tumors exhibit signal intensities of the N‐acetyl aspartate, choline compounds, and creatine plus p

## Abstract Long echo time (272 ms) ^1^H magnetic resonance spectro‐scopic imaging was used to measure the relative magnitudes of the N‐acetylaspartate (NAA) signal in a variety of anatomically defined brain structures (centrum semiovale, thalamus, medial frontal cortex, and genu of the corpus call