Magnetic Resonance Imaging at 3.0 Tesla: Challenges and Advantages in Clinical Neurological Imaging

Frayne, Richard; Goodyear, Bradley G.; Dickhoff, Peter; Lauzon, M. Louis; Sevick, Robert J.

doi:10.1097/01.rli.0000073442.88269.c9

Cited by 151 publications

(128 citation statements)

References 48 publications

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“…Changing the operating field from 1.5T to 3.0T theoretically results in a twofold gain in SNR, since magnetization increases with the square of the field strength while noise increases linearly [19]. However, prior studies examining changes in brain SNR from 1.5T to 3.0T have demonstrated increases in the range of 30-60% for T2-weighted fast-spin echo imaging [19], 28% for short-echo single-voxel stimulated echo acquisition mode (STEAM) spectroscopy [11], 23% for single-voxel PRESS spectroscopy [10], and 23-46% for long-echo 3D multivoxel spectroscopy [20].…”

Section: Discussionmentioning

confidence: 99%

Intramyocellular lipid quantification: comparison between 3.0- and 1.5-T 1H-MRS

Torriani

Thomas

Bredella

et al. 2007

Magnetic Resonance Imaging

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OBJECTIVE-To prospectively compare measurement precision of calf intramyocellular lipid (IMCL) quantification at 3.0T and 1.5T using 1 H magnetic resonance spectroscopy ( 1 H-MRS). MATERIALS AND METHODS-We examined the soleus and tibialis anterior (TA) muscles of 15 male adults [21-48 years of age, body mass index (BMI)=21.9-38.0 kg/m 2 ]. Each subject underwent 3.0T and 1.5T single-voxel short-echo-time point-resolved 1 H-MRS both at baseline and 31-day follow-up. The IMCL-methylene peak (1.3 ppm) was scaled to unsuppressed water peak (4.7 ppm) using the LCModel routine. Full width at half maximum (FWHM) and signal-to-noise ratios (SNR) of unsuppressed water peak were measured using jMRUI software. Measurement precision was tested by comparing interexamination coefficients of variation (CV) between different field strengths using Wilcoxon matched pairs rank test in all subjects. Overweight subjects (BMI>25 kg/ m 2 ) were analyzed separately to examine benefits of 3.0T acquisitions in subjects with increased adiposity.RESULTS-No significant difference between 3.0T and 1.5T was noted in CVs for IMCL of soleus (P=0.5). CVs of TA were significantly higher at 3.0T (P=0.02). SNR was significantly increased at 3.0T for soleus (64%, P<0.001) and TA (62%, P<0.001), however lower than the expected improvement of 100%. FWHM at 3.0T was significantly increased for soleus (19%, P<0.001) and TA (7%, P<0.01). Separate analysis of overweight subjects showed no significant difference between 3.0T and 1.5T CVs for IMCL of soleus (P=0.8) and TA (P=0.4). CONCLUSION-Using current technology, 1 H-MRS for IMCL at 3.0T did not improve measurement precision compared to 1.5T.

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Section: Discussionmentioning

confidence: 99%

Intramyocellular lipid quantification: comparison between 3.0- and 1.5-T 1H-MRS

Torriani

Thomas

Bredella

et al. 2007

Magnetic Resonance Imaging

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“…The advantages of shorter examination times for patients, radiologists, technicians and hospital administrators are obvious. Higher spatial resolution improves the matching of metabolic and anatomical information, enhancing the clinical value of 1 H-MRS [11].…”

Section: Spatial and Temporal Resolutionmentioning

confidence: 99%

“…In the last decade, with the approval of the US Food and Drug Administration for clinical use, MR systems at 3 T are proliferating, particularly at research centers [11]. With respect to the well-established MR technique at 1.5 T, switching to a higher field brings several advantages, such as an increased signal-to-noise ratio, with consequent enhanced spatial and temporal resolutions, and better spectral resolution, but also many limitations, such as installation issues, higher acoustic noise, device compatibility, system inhomogeneity, eddy current artifacts, misregistration errors, J-modulation anomalies, magnetic field instability and safety restrictions.…”

Section: Introductionmentioning

confidence: 99%

“…With respect to the well-established MR technique at 1.5 T, switching to a higher field brings several advantages, such as an increased signal-to-noise ratio, with consequent enhanced spatial and temporal resolutions, and better spectral resolution, but also many limitations, such as installation issues, higher acoustic noise, device compatibility, system inhomogeneity, eddy current artifacts, misregistration errors, J-modulation anomalies, magnetic field instability and safety restrictions. Some technical characteristics, such as changes in relaxation times, chemical shift and susceptibility, can have both benefits and disadvantages [11][12][13][14][15]. These limitations necessitating changes in technical devices and acquisition strategies have led to a debate about the usefulness of higher field strength in clinical settings [14][15][16][17][18][19][20].…”

Section: Introductionmentioning

confidence: 99%

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Proton MR spectroscopy of the brain at 3 T: an update

et al. 2007

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“…Theoretically, the signal-to-noise ratio (SNR) obtained by 3T MR imaging should be double that obtained at 1.5T, and the gain in SNR could be used to reduce scanning time or reduce the voxel size for high resolution images to less than one mm. 1,2 Numerous reports have documented the advantages of the 3T MR imaging system over the 1.5T system for morphological evaluation, functional imaging, and spectroscopy of the brain. 1,[3][4][5][6][7] However, in practice, the SNR increases but does not double, probably as a result of signal inhomogeneity or some artifacts, 1,2 and improved image quality at 3T is countered by drawbacks that include greater susceptibility eŠect, increased speciˆc absorption rate (SAR), and radiofrequency (RF)ˆeld inhomogeneity.…”

Section: Introductionmentioning

confidence: 99%

Visualization of Ovarian Tumors using 3T MR Imaging: Diagnostic Effectiveness and Difficulties

et al. 2012

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Purpose: We evaluated the diagnostic eŠectiveness of magnetic resonance (MR) imaging at 3 tesla to visualize ovarian tumors and problems associated with its use.Materials and Methods: From the records of 423 consecutive women who underwent pelvic MR imaging using a 3T system from April 2009 to June 2010, we analyzed 50 continuous cases of ovarian tumors proved by histopathology. We evaluated visualization of these tumors for image quality and artifacts using 5-point scales. For qualitative assessment, we scored overall image quality (1, poor, to 5, excellent), degree of conviction regarding the diagnosis (1, undiagnosable, to 5, diagnosable with high certainty), and 4 representative artifacts (penetrating, chemical shift, motion, and susceptibility artifact) (1, severe, to 5, little degradation). We also retrospectively reviewed the diagnostic features of the ovarian tumors and preoperative diagnostic accuracy. For quantitative assessment, we determined tumor size and ADC value.Results: Overall quality score was scored 4.9±0.5, and conviction regarding diagnosis was 4.9±0.3. Artifacts caused little degradation in most cases: penetrating, 4.8±0.5; chemical shift, 4.3±0.5; motion, 4.6±0.6; and susceptibility, 3.8±0.9. Preoperative diagnostic accuracy was 92z (sensitivity 94.7z, speciˆcity 90.3z). Mean tumor diameter was 88.3±61 mm. The mean ADC value was 1.04±0.3 in malignant tumors and 1.15±0.5 (×10 -6 mm 2 /s) in benign tumors.Conclusion: The quality of ovarian tumor images obtained with a 3T MR imaging system is adequate for diagnosis, with only slight degradation from penetrating or susceptibility artifacts.

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Magnetic Resonance Imaging at 3.0 Tesla: Challenges and Advantages in Clinical Neurological Imaging

Cited by 151 publications

References 48 publications

Intramyocellular lipid quantification: comparison between 3.0- and 1.5-T 1H-MRS

Intramyocellular lipid quantification: comparison between 3.0- and 1.5-T 1H-MRS

Proton MR spectroscopy of the brain at 3 T: an update

Visualization of Ovarian Tumors using 3T MR Imaging: Diagnostic Effectiveness and Difficulties

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