PURPOSE: Several parallel transmit MRI techniques require knowledge of the transmit radiofrequency field profiles (B1 (+) ). During the past years, various methods have been developed to acquire this information. Often, these methods suffer from long measurement times and produce maps exhibiting regions with poor signal-to-noise ratio and artifacts. In this article, a model-based reconstruction procedure is introduced that improves the robustness of B1 (+) mapping. THEORY AND METHODS: The missing information from undersampled B1 (+) maps and the regions of poor signal to noise ratio are reconstructed through projection into the space of spherical functions that arise naturally from the solution of the Helmholtz equations in the spherical coordinate system. RESULTS: As a result, B1 (+) data over a limited range of the field of view/volume is sufficient to reconstruct the B1 (+) over the full spatial domain in a fast and robust way. The same model is exploited to filter the noise of the measured maps. Results from simulations and in vivo measurements confirm the validity of the proposed method. CONCLUSION: A spherical functions model can well approximate the magnetic fields inside the body with few basis terms. Exploiting this compression capability, B1 (+) maps are reconstructed in regions of unknown or corrupted values.
PURPOSE: Several parallel transmit MRI techniques require knowledge of the transmit radiofrequency field profiles (B1 (+) ). During the past years, various methods have been developed to acquire this information. Often, these methods suffer from long measurement times and produce maps exhibiting regions with poor signal-to-noise ratio and artifacts. In this article, a model-based reconstruction procedure is introduced that improves the robustness of B1 (+) mapping. THEORY AND METHODS: The missing information from undersampled B1 (+) maps and the regions of poor signal to noise ratio are reconstructed through projection into the space of spherical functions that arise naturally from the solution of the Helmholtz equations in the spherical coordinate system. RESULTS: As a result, B1 (+) data over a limited range of the field of view/volume is sufficient to reconstruct the B1 (+) over the full spatial domain in a fast and robust way. The same model is exploited to filter the noise of the measured maps. Results from simulations and in vivo measurements confirm the validity of the proposed method. CONCLUSION: A spherical functions model can well approximate the magnetic fields inside the body with few basis terms. Exploiting this compression capability, B1 (+) maps are reconstructed in regions of unknown or corrupted values.
Authors: Xiaoping Wu; Sebastian Schmitter; Edward J Auerbach; Kâmil Uğurbil; Pierre-François Van de Moortele Journal: Magn Reson Med Date: 2015-05-20 Impact factor: 4.668
Authors: Steven Kecskemeti; Alexey Samsonov; Samuel A Hurley; Douglas C Dean; Aaron Field; Andrew L Alexander Journal: Magn Reson Med Date: 2015-04-17 Impact factor: 4.668
Authors: Janot P Tokaya; Alexander J E Raaijmakers; Peter R Luijten; Cornelis A T van den Berg Journal: Magn Reson Med Date: 2018-04-24 Impact factor: 4.668
Authors: Janot P Tokaya; Alexander J E Raaijmakers; Peter R Luijten; Alessandro Sbrizzi; Cornelis A T van den Berg Journal: Magn Reson Med Date: 2019-10-21 Impact factor: 4.668