PURPOSE: To demonstrate that, when injecting an artificial reference signal for quantitation purposes, the real and artificial signals can be acquired separately, using a single radiofrequency (RF) channel, with no loss of fidelity. Conversion of MR signals to units of concentration can be simplified by injection of a precalibrated, artificial reference signal, or pseudo-signal. In previous implementations, the pseudo-signal was acquired simultaneously with the real signals arising from the sample and this requires a second, integrated RF channel. MATERIALS AND METHODS: We used in vivo spectroscopy and in vitro imaging measurements to test the validity of the separate acquisition method. RESULTS: There was very strong correlation (r = 0.94; P = 0.02) between the in vivo concentrations determined with separate and simultaneous acquisition methods. The in vitro measurements validated that the separate acquisition method compensates for differences in coil loading conditions as well as the simultaneous acquisition method. CONCLUSION: Separate acquisition eliminates the need for a second RF channel, which allows easier implementation at sites that have only one channel available, and relaxes the constraints on the number and amplitude of pseudo-signals. This flexibility can be exploited to increase the signal to noise ratio of the pseudo-signal and reduce variability when making the conversion to units of concentration.
PURPOSE: To demonstrate that, when injecting an artificial reference signal for quantitation purposes, the real and artificial signals can be acquired separately, using a single radiofrequency (RF) channel, with no loss of fidelity. Conversion of MR signals to units of concentration can be simplified by injection of a precalibrated, artificial reference signal, or pseudo-signal. In previous implementations, the pseudo-signal was acquired simultaneously with the real signals arising from the sample and this requires a second, integrated RF channel. MATERIALS AND METHODS: We used in vivo spectroscopy and in vitro imaging measurements to test the validity of the separate acquisition method. RESULTS: There was very strong correlation (r = 0.94; P = 0.02) between the in vivo concentrations determined with separate and simultaneous acquisition methods. The in vitro measurements validated that the separate acquisition method compensates for differences in coil loading conditions as well as the simultaneous acquisition method. CONCLUSION: Separate acquisition eliminates the need for a second RF channel, which allows easier implementation at sites that have only one channel available, and relaxes the constraints on the number and amplitude of pseudo-signals. This flexibility can be exploited to increase the signal to noise ratio of the pseudo-signal and reduce variability when making the conversion to units of concentration.
Authors: Steve Lane; Bob Boughtflower; Ian Mutton; Clare Paterson; Duncan Farrant; Nick Taylor; Zoe Blaxill; Carol Carmody; Phil Borman Journal: Anal Chem Date: 2005-07-15 Impact factor: 6.986
Authors: Beathe Sitter; Tone F Bathen; Trond E Singstad; Hans E Fjøsne; Steinar Lundgren; Jostein Halgunset; Ingrid S Gribbestad Journal: NMR Biomed Date: 2010-01-25 Impact factor: 4.044
Authors: Kenneth I Marro; Donghoon Lee; Eric G Shankland; Clinton M Mathis; Cecil E Hayes; Catherine E Amara; Martin J Kushmerick Journal: J Magn Reson Date: 2008-07-01 Impact factor: 2.229