Functional and Structural Correlates of Motor Speed in the Cerebellar Anterior Lobe

Reach movements are characterized by multiple kinematic variables that can change with age or due to medical conditions such as movement disorders. While the neural control of reach direction is well investigated, the elements of the neural network regulating speed (the nondirectional component of velocity) remain uncertain. Here, we used a custom made magnetic resonance (MR)‐compatible arm movement tracking system to capture the real kinematics of the arm movements while measuring brain activation with functional magnetic resonance imaging to reveal areas in the human brain in which BOLD‐activation covaries with the speed of arm movements. We found significant activation in multiple cortical and subcortical brain regions positively correlated with endpoint (wrist) speed (speed‐related activation), including contralateral premotor cortex (PMC), supplementary motor area (SMA), thalamus (putative VL/VA nuclei), and bilateral putamen. The hand and arm regions of primary sensorimotor cortex (SMC) and a posterior region of thalamus were significantly activated by reach movements but showed a more binary response characteristics (movement present or absent) than with continuously varying speed. Moreover, a subregion of contralateral SMA also showed binary movement activation but no speed‐related BOLD‐activation. Effect size analysis revealed bilateral putamen as the most speed‐specific region among the speed‐related clusters whereas primary SMC showed the strongest specificity for movement versus non‐movement discrimination, independent of speed variations. The results reveal a network of multiple cortical and subcortical brain regions that are involved in speed regulation among which putamen, anterior thalamus, and PMC show highest specificity to speed, suggesting a basal‐ganglia‐thalamo‐cortical loop for speed regulation.

Section: Brain Regions With Movement-related Activation Irrespectivmentioning

confidence: 83%

Cortical and subcortical areas involved in the regulation of reach movement speed in the human brain: An fMRI study

Shirinbayan

Dreyer

Rieger

2018

“…In this study, the greater cerebellum GMV was specifically located in the lobules IV-V of the cerebellum and the IV-V vermian lobules in the anterior cerebellum lobe. These areas represent the arms, hands, and feet (Buckner, Krienen, Castellanos, Diaz, & Yeo, 2011;Manni & Petrosini, 2004) and are especially involved in motor execution, synchronization, coordination, control, and prediction (Cerasa et al, 2017;Koziol et al, 2014;Stoodley & Schmahmann, 2010;Wenzel, Taubert, Ragert, Krug, & Villringer, 2014). In addition, the GMV expansion in the athlete group extended to the bilateral lingual gyrus, PCC, and PCUN, which played important roles in visual attention.…”

Section: Gmv Differences Between Athletes and Controlsmentioning

confidence: 99%

Adaptation of brain functional stream architecture in athletes with fast demands of sensorimotor integration

Gao

et al. 2018

Training‐induced neuroplasticity has been described in athletes' population. However, it remains largely unknown how regular training and sports proficiency modifies neuronal circuits in the human brain. In this study, we used voxel‐based morphometry and stepwise functional connectivity (SFC) analyses to uncover connectivity changes in the functional stream architecture in student‐athletes at early stages of sensorimotor skill training. Thirty‐two second‐year student‐athletes whose major was little‐ball sports and thirty‐four nonathlete controls were recruited for the study. We found that athletes showed greater gray matter volume in the right sensorimotor area, the limbic lobe, and the anterior lobe of the cerebellum. Furthermore, SFC analysis demonstrated that athletes displayed significantly smaller optimal connectivity distance from those seed regions to the dorsal attention network (DAN) and larger optimal connectivity distance to the default mode network (DMN) compared to controls. The Attention Network Test showed that the reaction time of the orienting attention subnetwork was positively correlated with SFC between the seeds and the DAN, while negatively correlated with SFC between the seeds and the DMN. Our findings suggest that neuroplastic adaptations on functional connectivity streams after motor skill training may enable novel information flow from specific areas of the cortex toward distributed networks such as the DAN and the DMN. This could potentially regulate the focus of external and internal attention synchronously in athletes, and consequently accelerate the reaction time of orienting attention in athletes.

“…Third, movement speed (and not movement amplitude or directional-change), positively correlates with cerebellar activity in human imaging studies [Lewis et al, 2003;Turner et al, 1998;Wenzel et al, 2014]. Fourth, there is even evidence for perceptual sensitivity to speed in the cerebellum, as cerebellar patients show impairments in making perceptual judgments regarding the speed of moving visual stimuli but not their position [Ivry and Diener, 1991].…”

Section: Discussionmentioning

confidence: 99%

“…Second, the average firing rate and modulation depth of cerebellar cells more frequently increases rather than decreases with faster speed [Roitman et al, ], a property which may be expected to be reflected in positive modulation of the fMRI signal. Third, movement speed (and not movement amplitude or directional‐change), positively correlates with cerebellar activity in human imaging studies [Lewis et al, ; Turner et al, ; Wenzel et al, ]. Fourth, there is even evidence for perceptual sensitivity to speed in the cerebellum, as cerebellar patients show impairments in making perceptual judgments regarding the speed of moving visual stimuli but not their position [Ivry and Diener, ].…”

Section: Discussionmentioning

confidence: 99%

Preferential encoding of movement amplitude and speed in the primary motor cortex and cerebellum

Stark‐Inbar

Dayan

2017

Voluntary movements require control of multiple kinematic parameters, a task carried out by a distributed brain architecture. However, it remains unclear whether regions along the motor system encode single, or rather a mixture of, kinematic parameters during action execution. Here, rapid event-related functional magnetic resonance imaging was used to differentiate brain activity along the motor system during the encoding of movement amplitude, duration, and speed. We present cumulative evidence supporting preferential encoding of kinematic parameters along the motor system, based on blood-oxygenation-level dependent signal recorded in a well-controlled single-joint wrist-flexion task. Whereas activity in the left primary motor cortex (M1) showed preferential encoding of movement amplitude, the anterior lobe of the right cerebellum (primarily lobule V) showed preferential encoding of movement speed. Conversely, activity in the left supplementary motor area (SMA), basal ganglia (putamen), and anterior intraparietal sulcus was not preferentially modulated by any specific parameter. We found no preference in peak activation for duration encoding in any of the tested regions. Electromyographic data was mainly modulated by movement amplitude, restricting the distinction between amplitude and muscle force encoding. Together, these results suggest that during single-joint movements, distinct kinematic parameters are controlled by largely distinct brain-regions that work together to produce and control precise movements. Hum Brain Mapp 38:5970-5986, 2017. © 2017 Wiley Periodicals, Inc.