PURPOSE: To evaluate the effect of varying spectral resolution on image quality of high spectral and spatial resolution (HiSS) images. MATERIALS AND METHODS: Eight women with suspicious breast lesions and six healthy volunteers were scanned using echo-planar spectroscopic imaging (EPSI) at 1.5 Tesla with 0.75- to 1-mm in-plane resolution and 2.3- to 2.6-Hz spectral resolution. Time domain data were truncated to obtain proton spectra in each voxel with varying (2.6-83.3 Hz) resolution. Images with intensity proportional to water signal peak heights were synthesized. Changes in water signal line shape following contrast injection were analyzed. RESULTS: Fat suppression is optimized at approximately 10-Hz spectral resolution and is significantly improved by removal of wings of the fat resonance. This was accomplished by subtracting a Lorentzian fit to the fat resonance from the proton spectrum. The water resonance is often inhomogeneously broadened, and very high spectral resolution is necessary to resolve individual components. High spectral resolution is required for optimal contrast in anatomic features with very high T(2)* (e.g., within a lesion) and for detection of often subtle effects of contrast agents on water signal line shape. CONCLUSION: Despite a trade-off between the spectral resolution and signal-to-noise ratio, it is beneficial to acquire data at the highest spectral resolution currently attainable at 1.5 Tesla. Copyright 2003 Wiley-Liss, Inc.
PURPOSE: To evaluate the effect of varying spectral resolution on image quality of high spectral and spatial resolution (HiSS) images. MATERIALS AND METHODS: Eight women with suspicious breast lesions and six healthy volunteers were scanned using echo-planar spectroscopic imaging (EPSI) at 1.5 Tesla with 0.75- to 1-mm in-plane resolution and 2.3- to 2.6-Hz spectral resolution. Time domain data were truncated to obtain proton spectra in each voxel with varying (2.6-83.3 Hz) resolution. Images with intensity proportional to water signal peak heights were synthesized. Changes in water signal line shape following contrast injection were analyzed. RESULTS:Fat suppression is optimized at approximately 10-Hz spectral resolution and is significantly improved by removal of wings of the fat resonance. This was accomplished by subtracting a Lorentzian fit to the fat resonance from the proton spectrum. The water resonance is often inhomogeneously broadened, and very high spectral resolution is necessary to resolve individual components. High spectral resolution is required for optimal contrast in anatomic features with very high T(2)* (e.g., within a lesion) and for detection of often subtle effects of contrast agents on water signal line shape. CONCLUSION: Despite a trade-off between the spectral resolution and signal-to-noise ratio, it is beneficial to acquire data at the highest spectral resolution currently attainable at 1.5 Tesla. Copyright 2003 Wiley-Liss, Inc.
Authors: Milica Medved; Xiaobing Fan; Hiroyuki Abe; Gillian M Newstead; Abbie M Wood; Akiko Shimauchi; Kirti Kulkarni; Marko K Ivancevic; Lorenzo L Pesce; Olufunmilayo I Olopade; Gregory S Karczmar Journal: Acad Radiol Date: 2011-10-01 Impact factor: 3.173
Authors: Hui Li; William A Weiss; Milica Medved; Hiroyuki Abe; Gillian M Newstead; Gregory S Karczmar; Maryellen L Giger Journal: J Med Imaging (Bellingham) Date: 2016-12-28
Authors: Elizabeth Hipp; Xiaobing Fan; Sanaz A Jansen; Erica J Markiewicz; James Vosicky; Gillian M Newstead; Suzanne D Conzen; Thomas Krausz; Gregory S Karczmar Journal: Med Phys Date: 2012-03 Impact factor: 4.071
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Authors: Milica Medved; Gillian M Newstead; Xiaobing Fan; Yiping P Du; Olufunmilayo I Olopade; Akiko Shimauchi; Marta A Zamora; Gregory S Karczmar Journal: Phys Med Biol Date: 2009-09-09 Impact factor: 3.609