Morphological markers for brain plasticity are still lacking and their findings are challenged by the extreme variability of cortical brain surface. Trying to overcome the "correspondence problem," we applied a landmark-free method (the generalized procrustes surface analysis (GPSA)) for investigating the shape variation of cortical surface in a group of 40 healthy volunteers (i.e., the practice group) subjected to daily motor training known as Quadrato motor training (QMT). QMT is a sensorimotor walking meditation that aims at balancing body, cognition, and emotion. More specifically, QMT requires coordination and attention and consists of moving in one of three possible directions on corners of a 50 x 50 cm2. Brain magnetic resonance images (MRIs) of practice group (acquired at baseline, as well as after 6 and 12 weeks of QMT), were 3D reconstructed and here compared with brain MRIs of six more volunteers never practicing the QMT (na & iuml;ve group). Cortical regions mostly affected by morphological variations were visualized on a 3D average color-scaled brain surface indicating from higher (red) to lower (blue) levels of variation. Cortical regions interested in most of the shape variations were as follows: (1) the supplementary motor cortex; (2) the inferior frontal gyrus (pars opercolaris) and the anterior insula; (3) the visual cortex; (4) the inferior parietal lobule (supramarginal gyrus and angular gyrus). Our results show that surface morphometric analysis (i.e., GPSA) can be applied to assess brain neuroplasticity processes, such as those stimulated by QMT.Morphological markers for brain plasticity are still lacking, and their findings are challenged by cortical brain surface variability. To overcome the "correspondence problem," we used a landmark-free method (generalized Procrustes surface analysis, GPSA) to investigate cortical surface shape variation in healthy volunteers practicing Quadrato motor training (QMT), a sensorimotor walking meditation. MRIs of the practice group (baseline, 6, and 12 weeks of QMT) were compared to non-practicing volunteers. Significant morphological variations were found in the supplementary motor cortex, inferior frontal gyrus, anterior insula, visual cortex, and inferior parietal lobule. Results show GPSA can assess neuroplasticity processes stimulated by QMT.image

Assessing brain neuroplasticity: Surface morphometric analysis of cortical changes induced by Quadrato motor training

Spani, F.
;
Mallio, C. A.;
2024-01-01

Abstract

Morphological markers for brain plasticity are still lacking and their findings are challenged by the extreme variability of cortical brain surface. Trying to overcome the "correspondence problem," we applied a landmark-free method (the generalized procrustes surface analysis (GPSA)) for investigating the shape variation of cortical surface in a group of 40 healthy volunteers (i.e., the practice group) subjected to daily motor training known as Quadrato motor training (QMT). QMT is a sensorimotor walking meditation that aims at balancing body, cognition, and emotion. More specifically, QMT requires coordination and attention and consists of moving in one of three possible directions on corners of a 50 x 50 cm2. Brain magnetic resonance images (MRIs) of practice group (acquired at baseline, as well as after 6 and 12 weeks of QMT), were 3D reconstructed and here compared with brain MRIs of six more volunteers never practicing the QMT (na & iuml;ve group). Cortical regions mostly affected by morphological variations were visualized on a 3D average color-scaled brain surface indicating from higher (red) to lower (blue) levels of variation. Cortical regions interested in most of the shape variations were as follows: (1) the supplementary motor cortex; (2) the inferior frontal gyrus (pars opercolaris) and the anterior insula; (3) the visual cortex; (4) the inferior parietal lobule (supramarginal gyrus and angular gyrus). Our results show that surface morphometric analysis (i.e., GPSA) can be applied to assess brain neuroplasticity processes, such as those stimulated by QMT.Morphological markers for brain plasticity are still lacking, and their findings are challenged by cortical brain surface variability. To overcome the "correspondence problem," we used a landmark-free method (generalized Procrustes surface analysis, GPSA) to investigate cortical surface shape variation in healthy volunteers practicing Quadrato motor training (QMT), a sensorimotor walking meditation. MRIs of the practice group (baseline, 6, and 12 weeks of QMT) were compared to non-practicing volunteers. Significant morphological variations were found in the supplementary motor cortex, inferior frontal gyrus, anterior insula, visual cortex, and inferior parietal lobule. Results show GPSA can assess neuroplasticity processes stimulated by QMT.image
2024
3D brain cortex; generalized procrustes surface analysis; magnetic resonance imaging; mindfulness; sensorimotor training; shape variation
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/20.500.12610/79648
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