Roberta Kriegl1, Jean-Christophe Ginefri, Marie Poirier-Quinot, Luc Darrasse, Sigrun Goluch, Andre Kuehne, Ewald Moser, Elmar Laistler. 1. Laboratoire d'Imagerie par Résonance Magnétique Médicale et Multi-Modalités (IR4M), UMR8081 Univ Paris-Sud - CNRS, Orsay, France; Center for Medical Physics and Biomedical Engineering, Medical University of Vienna, Währinger Gürtel 18-20, 1090, Vienna, Austria; MR Centre of Excellence, Medical University of Vienna, Lazarettgasse 14, 1090, Vienna, Austria.
Abstract
PURPOSE: This article presents a novel inductive decoupling technique for form-fitting coil arrays of monolithic transmission line resonators, which target biomedical applications requiring high signal-to-noise ratio over a large field of view to image anatomical structures varying in size and shape from patient to patient. METHODS: Individual transmission line resonator elements are mutually decoupled using magnetic flux sharing by overlapping annexes. This decoupling technique was evaluated by electromagnetic simulations and bench measurements for two- and four-element arrays, comparing single- and double-gap transmission line resonator designs, combined either with a basic capacitive matching scheme or inductive pickup loop matching. The best performing array was used in 7T MRI experiments demonstrating its form-fitting ability and parallel imaging potential. RESULTS: The inductively matched double-gap transmission line resonator array provided the best decoupling efficiency in simulations and bench measurements (<-15 dB). The decoupling and parallel imaging performance proved robust against mechanical deformation of the array. CONCLUSION: The presented decoupling technique combines the robustness of conventional overlap decoupling regarding coil loading and operating frequency with the extended field of view of nonoverlapped coils. While demonstrated on four-element arrays, it can be easily expanded to fabricate readily decoupled form-fitting 2D arrays with an arbitrary number of elements in a single etching process.
PURPOSE: This article presents a novel inductive decoupling technique for form-fitting coil arrays of monolithic transmission line resonators, which target biomedical applications requiring high signal-to-noise ratio over a large field of view to image anatomical structures varying in size and shape from patient to patient. METHODS: Individual transmission line resonator elements are mutually decoupled using magnetic flux sharing by overlapping annexes. This decoupling technique was evaluated by electromagnetic simulations and bench measurements for two- and four-element arrays, comparing single- and double-gap transmission line resonator designs, combined either with a basic capacitive matching scheme or inductive pickup loop matching. The best performing array was used in 7T MRI experiments demonstrating its form-fitting ability and parallel imaging potential. RESULTS: The inductively matched double-gap transmission line resonator array provided the best decoupling efficiency in simulations and bench measurements (<-15 dB). The decoupling and parallel imaging performance proved robust against mechanical deformation of the array. CONCLUSION: The presented decoupling technique combines the robustness of conventional overlap decoupling regarding coil loading and operating frequency with the extended field of view of nonoverlapped coils. While demonstrated on four-element arrays, it can be easily expanded to fabricate readily decoupled form-fitting 2D arrays with an arbitrary number of elements in a single etching process.
Authors: Bei Zhang; Bili Wang; Justin Ho; Shota Hodono; Christopher Burke; Riccardo Lattanzi; Markus Vester; Robert Rehner; Daniel Sodickson; Ryan Brown; Martijn Cloos Journal: Magn Reson Med Date: 2021-12-31 Impact factor: 4.668
Authors: Elmar Laistler; Barbara Dymerska; Jürgen Sieg; Sigrun Goluch; Roberta Frass-Kriegl; Andre Kuehne; Ewald Moser Journal: Magn Reson Med Date: 2017-03-10 Impact factor: 4.668
Authors: Roberta Frass-Kriegl; Lucia Isabel Navarro de Lara; Michael Pichler; Jürgen Sieg; Ewald Moser; Christian Windischberger; Elmar Laistler Journal: PLoS One Date: 2018-11-01 Impact factor: 3.240