Tibor Auer1, Renate Schweizer, Jens Frahm. 1. Biomedizinische NMR Forschungs GmbH am Max-Planck-Institut für biophysikalische Chemie, Am Fassberg 11, 37070 Göttingen, Germany. tauer@gwdg.de
Abstract
OBJECTIVES: Current thresholding strategies for the analysis of functional MRI (fMRI) datasets may suffer from specific limitations (e.g. with respect to the required smoothness) or lead to reduced performance for a low signal-to-noise ratio (SNR). Although a previously proposed two-threshold (TT) method offers a promising solution to these problems, the use of preset settings limits its performance. This work presents an optimised TT approach that estimates the required parameters in an iterative manner. METHODS: The iterative TT (iTT) method is compared with the original TT method, as well as other established voxel-based and cluster-based thresholding approaches and spatial mixture modelling (SMM) for both simulated data and fMRI of a hometown walking task at different experimental settings (spatial resolution, filtering and SNR). RESULTS: In general, the iTT method presents with remarkable sensitivity and good specificity that outperforms all conventional approaches tested except for SMM in a few cases. This also holds true for challenging conditions such as high spatial resolution, the absence of filtering, high noise level, or a low number of task repetitions. CONCLUSION: Thus, iTT emerges as a good candidate for both scientific fMRI studies at high spatial resolution and more routine applications for clinical purposes.
OBJECTIVES: Current thresholding strategies for the analysis of functional MRI (fMRI) datasets may suffer from specific limitations (e.g. with respect to the required smoothness) or lead to reduced performance for a low signal-to-noise ratio (SNR). Although a previously proposed two-threshold (TT) method offers a promising solution to these problems, the use of preset settings limits its performance. This work presents an optimised TT approach that estimates the required parameters in an iterative manner. METHODS: The iterative TT (iTT) method is compared with the original TT method, as well as other established voxel-based and cluster-based thresholding approaches and spatial mixture modelling (SMM) for both simulated data and fMRI of a hometown walking task at different experimental settings (spatial resolution, filtering and SNR). RESULTS: In general, the iTT method presents with remarkable sensitivity and good specificity that outperforms all conventional approaches tested except for SMM in a few cases. This also holds true for challenging conditions such as high spatial resolution, the absence of filtering, high noise level, or a low number of task repetitions. CONCLUSION: Thus, iTT emerges as a good candidate for both scientific fMRI studies at high spatial resolution and more routine applications for clinical purposes.
Authors: Tibor Auer; József Janszky; Attila Schwarcz; Tamás Dóczi; Anita Trauninger; Bálint Alkonyi; Sámuel Komoly; Zoltán Pfund Journal: Headache Date: 2009-02-11 Impact factor: 5.887
Authors: Tibor Auer; Katalin Veto; Tamás Dóczi; Sámuel Komoly; Vera Juhos; József Janszky; Attila Schwarcz Journal: Epileptic Disord Date: 2008-06 Impact factor: 1.819
Authors: A-L Wang; I Elman; S B Lowen; S J Blady; K G Lynch; J M Hyatt; C P O'Brien; D D Langleben Journal: Transl Psychiatry Date: 2015-03-17 Impact factor: 6.222
Authors: Marko Wilke; Samuel Groeschel; Anna Lorenzen; Sabine Rona; Martin U Schuhmann; Ulrike Ernemann; Ingeborg Krägeloh-Mann Journal: Ann Clin Transl Neurol Date: 2018-09-27 Impact factor: 4.511