Alterations in white matter microstructure are associated with goal‐directed upper‐limb movement segmentation in children born extremely preterm

Altered white matter microstructure is commonly found in children born preterm (PT), especially those born at an extremely low gestational age (GA). These children also commonly show disturbed motor function. This study explores the relation between white matter alterations and upper‐limb movement s...

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Bibliographic Details
Published in:Human brain mapping 2017-10, Vol.38 (10), p.5051-5068
Main Authors: Lenfeldt, Niklas, Johansson, Anna‐Maria, Domellöf, Erik, Riklund, Katrine, Rönnqvist, Louise
Format: Article
Language:English
Subjects:
anisotropy
Arm
Attention deficit hyperactivity disorder
Biomechanical Phenomena
Brain
Cerebral hemispheres
Child
Children
Corpus callosum
corticospinal
Diffusion Tensor Imaging
Elbow
Elbow (anatomy)
Female
Functional Laterality
Gestational age
Girls
Goals
Humans
Image segmentation
Imaging, Three-Dimensional
Infant, Extremely Premature - physiology
internal capsule
laterality
Magnetic resonance imaging
Male
Microstructure
Motor Activity - physiology
Motor task performance
Movement Disorders - diagnostic imaging
Movement Disorders - etiology
Movement Disorders - pathology
Movement Disorders - physiopathology
movement segmentation
Neuroimaging
Pediatrics
pediatrik
Psychology
psykologi
Pyramidal tracts
radiologi
Radiology
sensorimotor
Sensorimotor system
Substantia alba
Upper Extremity - physiology
White Matter - diagnostic imaging
White Matter - pathology
Wrist
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Summary:Altered white matter microstructure is commonly found in children born preterm (PT), especially those born at an extremely low gestational age (GA). These children also commonly show disturbed motor function. This study explores the relation between white matter alterations and upper‐limb movement segmentation in 41 children born PT (19 girls), and 41 children born at term (18 girls) at 8 years. The PT group was subdivided into extremely PT (E‐PT; GA = 25–27 weeks, N = 10), very PT (V‐PT; GA = 28–32 weeks, N = 13), and moderately PT (M‐PT; GA = 33–35 weeks, N = 18). Arm/hand preference (preferred/non‐preferred) was determined through object interactions and the brain hemispheres were designated accordingly. White matter alterations were assessed using diffusion tensor imaging in nine areas, and movement segmentation of the body‐parts head, shoulder, elbow, and wrist were registered during a unimanual goal‐directed task. Increased movement segmentation was demonstrated consistently on the preferred side in the E‐PT group compared with the term born group. Also compared with the term born peers, the E‐PT group demonstrated reduced fractional anisotropy (FA) in the cerebral peduncle (targeting the corticospinal tract) in the hemisphere on the non‐preferred side and in the splenium of corpus callosum. In contrast, in the anterior internal capsule on the preferred side, the E‐PT group had increased FA. Lower FA in the cerebral peduncle, but higher FA in the anterior internal capsule, was associated with increased movement segmentation across body‐parts in a contralateral manner. The results suggest that impaired development of sensorimotor tracts in E‐PT children could explain a sub‐optimal spatiotemporal organization of upper‐limb movements. Hum Brain Mapp 38:5051–5068, 2017. © 2017 Wiley Periodicals, Inc.
ISSN:1065-9471
1097-0193
1097-0193
DOI:10.1002/hbm.23714