OBJECTIVE: Magnetoencephalography (MEG) has a well-recognized weakness at detecting deeper brain activities. This paper proposes a novel algorithm for selective detection of deep sources by suppressing interference signals from superficial sources in MEG measurements. APPROACH: The proposed algorithm combines the beamspace preprocessing method with the dual signal space projection (DSSP) interference suppression method. A prerequisite of the proposed algorithm is prior knowledge of the location of the deep sources. The proposed algorithm first derives the basis vectors that span a local region just covering the locations of the deep sources. It then estimates the time-domain signal subspace of the superficial sources by using the projector composed of these basis vectors. Signals from the deep sources are extracted by projecting the row space of the data matrix onto the direction orthogonal to the signal subspace of the superficial sources. MAIN RESULTS: Compared with the previously proposed beamspace signal space separation (SSS) method, the proposed algorithm is capable of suppressing much stronger interference from superficial sources. This capability is demonstrated in our computer simulation as well as experiments using phantom data. SIGNIFICANCE: The proposed bDSSP algorithm can be a powerful tool in studies of physiological functions of midbrain and deep brain structures.
OBJECTIVE: Magnetoencephalography (MEG) has a well-recognized weakness at detecting deeper brain activities. This paper proposes a novel algorithm for selective detection of deep sources by suppressing interference signals from superficial sources in MEG measurements. APPROACH: The proposed algorithm combines the beamspace preprocessing method with the dual signal space projection (DSSP) interference suppression method. A prerequisite of the proposed algorithm is prior knowledge of the location of the deep sources. The proposed algorithm first derives the basis vectors that span a local region just covering the locations of the deep sources. It then estimates the time-domain signal subspace of the superficial sources by using the projector composed of these basis vectors. Signals from the deep sources are extracted by projecting the row space of the data matrix onto the direction orthogonal to the signal subspace of the superficial sources. MAIN RESULTS: Compared with the previously proposed beamspace signal space separation (SSS) method, the proposed algorithm is capable of suppressing much stronger interference from superficial sources. This capability is demonstrated in our computer simulation as well as experiments using phantom data. SIGNIFICANCE: The proposed bDSSP algorithm can be a powerful tool in studies of physiological functions of midbrain and deep brain structures.
Authors: Alberto Rodríguez-Rivera; Boris V Baryshnikov; Barry D Van Veen; Ronald T Wakai Journal: IEEE Trans Biomed Eng Date: 2006-03 Impact factor: 4.538
Authors: Ashwani Jha; Vladimir Litvak; Samu Taulu; Wesley Thevathasan; Jonathan A Hyam; Tom Foltynie; Patricia Limousin; Marko Bogdanovic; Ludvic Zrinzo; Alexander L Green; Tipu Z Aziz; Karl Friston; Peter Brown Journal: Cereb Cortex Date: 2016-11-22 Impact factor: 5.357