Multi-modal imaging of neural correlates of motor speed performance in the Trail Making Test

Camilleri, Julia; Grefkes, Christian; Amunts, Katrin; Eickhoff, Simon; Müller, Veronika; Reid, Andrew

doi:10.3389/fneur.2015.00219

Journal Article

FZJ-2015-06046

Multi-modal imaging of neural correlates of motor speed performance in the Trail Making Test

Camilleri, J. (Corresponding author) ; Reid, A.FZJ* ; Müller, V.FZJ* ; Grefkes, C.FZJ* ; Amunts, K.FZJ* ; Eickhoff, S.FZJ*

2015
Frontiers Research Foundation Lausanne

Frontiers in neurology 6, 219 (2015) [10.3389/fneur.2015.00219]

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Please use a persistent id in citations: http://hdl.handle.net/2128/9341 doi:10.3389/fneur.2015.00219

Abstract: The assessment of motor and executive functions following stroke or traumatic brain injury is a key aspect of impairment evaluation and used to guide further therapy. In clinical routine such assessments are largely dominated by pen-and-paper tests. While these provide standardized, reliable and ecologically valid measures of the individual level of functioning, rather little is yet known about their neurobiological underpinnings. Therefore, the aim of this study was to investigate brain regions and their associated networks that are related to upper extremity motor function, as quantified by the Motor Speed subtest of the Trail Making Test (TMT-MS). Whole brain voxel-based morphometry and whole brain tract-based spatial statistics were used to investigate the association between TMT-MS performance with gray matter volume (GMV) and white matter integrity respectively. While results demonstrated no relationship to local white-matter properties, we found a significant correlation between TMT-MS performance and GMV of the lower bank of the inferior frontal sulcus, a region associated with cognitive processing, as indicated by assessing its functional profile by the BrainMap database. Using this finding as a seed region, we further examined and compared networks as reflected by resting state connectivity, meta-analytic-connectivity modeling, structural covariance and probabilistic tractography. While differences between the different approaches were observed, all approaches converged on a network comprising regions that overlap with the multiple-demand network. Our data therefore indicates that performance may primarily depend on executive function, thus suggesting that motor speed in a more naturalistic setting should be more associated with executive rather than primary motor function. Moreover, results showed that while there were differences between the approaches, a convergence indicated that common networks can be revealed across highly divergent methods.

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