J. Wieland scite author profile

Magnetic resonance (MR) spectroscopy and imaging experiments on humans were performed with a whole-body MR system at a static field of 4 tesla. Spectroscopic studies focussed on 1H, 13C, and 31P. Imaging of humans turned out to be possible, although below the optimum at this field. This holds especially for body imaging, since RF penetration effects and dielectric resonances influence the RF field homogeneity. Excellent volume selective proton spectra of the human cerebrum and cerebellum were obtained using the stimulated echo method. Natural abundance carbon spectra of the human calf were acquired both undecoupled and with narrowband decoupling, resolving the various triglyceride resonances. Broadband decoupling, however, would have violated SAR guidelines. Liver glycogen was detected on natural abundance 13C spectra.

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Pre-operative localized in vivo proton spectroscopy in cerebral tumors at 4.0 Tesla—First results

Langkowski

Wieland

Bomsdorf³

et al. 1989

Magnetic Resonance Imaging

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Sensitivity enhancement in whole‐body natural abundance ¹³C spectroscopy using ¹³C/¹H double‐resonance techniques at 4 tesla

Bomsdorf

Röschmann

Wieland

1991

Magnetic Resonance in Med

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In vivo 13C spectroscopy experiments were performed using a whole-body MR system at a static field of 4 T. The main goal of the investigations was to evaluate the sensitivity increase achievable by means of 13C/1H double-resonance techniques at 4 T. Spectra from subcutaneous fat as well as muscle glycogen from the lower leg were acquired using frequency selective proton decoupling and the polarization transfer method SINEPT. With respect to measurements on subcutaneous fat, polarization transfer turned out to be more efficient than selective decoupling. About a fourfold enhancement in spectral peak intensity for the C = C line doublet of the unsaturated fatty acid chain was obtained. Combining polarization transfer with decoupling yielded a factor of 6 in signal amplitude. In contrast to that, the signal enhancement observed in measurements on the glycogen C-1 resonance was only around twofold. The lower efficiency is explained by fast T2 relaxation of the proton transition. A T2 value of about 3 ms was derived from the experimental data. Acquisition times as low as 3 min were realized for normal level glycogen in human calf muscle, enabling a time resolution adequate for dynamic studies on muscle glycogen depletion. Aspects of RF power absorption in tissue and the generally higher efficiency make polarization transfer methods preferable to selective decoupling in whole-body 13C spectroscopy at 4 T.

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J. Wieland

Electronic structure of CoO, Li-doped CoO, andLiCoO2

Spectroscopy and imaging with a 4 tesla whole‐body mr system

Pre-operative localized in vivo proton spectroscopy in cerebral tumors at 4.0 Tesla—First results

Sensitivity enhancement in whole‐body natural abundance ¹³C spectroscopy using ¹³C/¹H double‐resonance techniques at 4 tesla

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About

J. Wieland

Electronic structure of CoO, Li-doped CoO, andLiCoO2

Spectroscopy and imaging with a 4 tesla whole‐body mr system

Pre-operative localized in vivo proton spectroscopy in cerebral tumors at 4.0 Tesla—First results

Sensitivity enhancement in whole‐body natural abundance 13C spectroscopy using 13C/1H double‐resonance techniques at 4 tesla

Contact Info

Product

Resources

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Sensitivity enhancement in whole‐body natural abundance ¹³C spectroscopy using ¹³C/¹H double‐resonance techniques at 4 tesla