Visuomotor brain network activation and functional connectivity among individuals with autism spectrum disorder

ABSTRACTSensorimotor abnormalities are common in autism spectrum disorder (ASD) and predictive of functional outcomes, though their neural underpinnings remain poorly understood. Using functional magnetic resonance imaging (fMRI), we examined both brain activation and functional connectivity during visuomotor behavior in 27 individuals with ASD and 30 typically developing (TD) controls (ages 9-35 years). Participants maintained a constant grip force while receiving visual feedback at three different visual gain levels. Relative to controls, ASD participants showed increased force variability, especially at high gain, and reduced entropy. Brain activation was greater in individuals with ASD than controls in supplementary motor area, bilateral superior parietal lobules, and left middle frontal gyrus at high gain. During motor action, functional connectivity was reduced between parietal-premotor and parietal-putamen in individuals with ASD compared to controls. Individuals with ASD also showed greater age-associated increases in functional connectivity between cerebellum and visual, motor, and prefrontal cortical areas relative to controls. These results indicate that visuomotor deficits in ASD are associated with atypical activation and functional connectivity of posterior parietal, premotor, and striatal circuits involved in translating sensory feedback information into precision motor behaviors, and that functional connectivity of cerebellar-cortical sensorimotor and non-sensorimotor networks show delayed maturation.HIGHLIGHTSIndividuals with ASD show impaired precision manual force control, especially when visual feedback is magnifiedVisuomotor deficits in ASD are associated with increased activity in frontal and parietal cortex and reduced parietal-frontal and parietal-putamen functional connectivityVisuomotor-dependent functional connectivity of cerebellum with visual, motor, and prefrontal cortices shows atypical age-associated trajectories in ASD

Active vision at the foveal scale in the primate superior colliculus

The primate superior colliculus (SC) has recently been shown to possess both a large foveal representation as well as a varied visual processing repertoire. This structure is also known to contribute to eye movement generation. Here we describe our current understanding of how SC visual and movement-related signals interact within the realm of small eye movements associated with the foveal scale of visuomotor behavior. Within the SC's foveal representation, there is a full spectrum of visual, visual-motor, and motor-related discharge for fixational eye movements. Moreover, a substantial number of neurons only emit movement-related discharge when microsaccades are visually-guided, but not when similar movements are generated towards a blank. This represents a particularly striking example of integrating vision and action at the foveal scale. Beyond that, SC visual responses themselves are strongly modulated, and in multiple ways, by the occurrence of small eye movements. Intriguingly, this impact can extend to eccentricities well beyond the fovea, causing both sensitivity enhancement and suppression in the periphery. Because of large foveal magnification of neural tissue, such long-range eccentricity effects are neurally warped into smaller differences in anatomical space, providing a structural means for linking peripheral and foveal visual modulations around fixational eye movements. Finally, even the retinal-image visual flows associated with tiny fixational eye movements are signaled fairly faithfully by peripheral SC neurons with relatively large receptive fields. These results demonstrate how studying active vision at the foveal scale represents an opportunity for understanding primate vision during natural behaviors involving ever-present foveating eye movements.

Effect of Visuo-Motor Behavior Rehearsal on enhancing Mental Toughness of Soccer Players

The present study aimed to evaluate the effect of six weeks of Visuomotor Behavior Rehearsal on Enhancing Mental Toughness of Soccer Players. For the purpose of study forty (n=40) soccer players in the age groups of 17 to 21 years belong to Th. Birchandra Singh Football Academy (TBSFA), Imphal West, Manipur were selected. Subjects were divided into Treatment and controlled group (20 players in each group). The data was collected through the administration of the Psychological Performance Inventory (PPI) by James E. Loehr (1996) containing 42 items. To find out the significant effect of the Psychological Skills Training Program on Selected Psychological Variables of Soccer Players, MANOVA for psychological variables was used and the level of significance was set at 0.05. The findings of the study revealed that there was a significant effect of soccer players on those who underwent the PST program as compared to the players in the controlled group.

Common properties of visually-guided saccadic behavior and bottom-up attention in marmoset, macaque, and human

The saccade is a stereotypic behavior whose investigation improves our understanding of how primate brains implement precise motor control. Furthermore, saccades offer an important window into the cognitive and attentional state of the brain. Historically, saccade studies have largely relied on macaque. However, the cortical network giving rise to the saccadic command is difficult to study in macaque because relevant cortical areas lie in sulci and are difficult to access. Recently, a New World monkey – the marmoset – has garnered attention as an attractive alternative to macaque because of its smooth cortical surface, its smaller body, and its amenability to transgenic technology. However, adoption of marmoset for oculomotor research has been limited due to a lack of in-depth descriptions of marmoset saccade kinematics and their ability to perform psychophysical and cognitive tasks. Here, we directly compare free-viewing and visually-guided behavior of marmoset, macaque, and human engaged in identical tasks under similar conditions. In video free-viewing task, all species exhibited qualitatively similar saccade kinematics including saccade main sequence up to 25° in amplitude. Furthermore, the conventional bottom-up saliency model predicted gaze targets at similar rates for all species. We further verified their visually-guided behavior by training them with step and gap saccade tasks. All species showed similar gap effect and express saccades in the gap paradigm. Our results suggest that the three species have similar natural and task-guided visuomotor behavior. The marmoset can be trained on saccadic tasks and thus can serve as a model for oculomotor, attention, and cognitive research.New & noteworthyWe directly compared the results of video free-viewing task and visually-guided saccade tasks (step and gap) among three different species: the marmoset, macaque and human. We found that all species exhibit qualitatively similar saccadic behavior and bottom-up saliency albeit with small differences. Our results suggest that the marmoset possesses similar neural mechanisms to macaque and human for saccadic control, and it is an appropriate model animal to study neural mechanisms for active vision and attention.

Is there an Intrinsic Relationship between LFP Beta Oscillation Amplitude and Firing Rate of Individual Neurons in Macaque Motor Cortex?

The properties of motor cortical local field potential (LFP) beta oscillations have been extensively studied. Their relationship to the local neuronal spiking activity was also addressed. Yet, whether there is an intrinsic relationship between the amplitude of beta oscillations and the firing rate of individual neurons remains controversial. Some studies suggest a mapping of spike rate onto beta amplitude, while others find no systematic relationship. To help resolve this controversy, we quantified in macaque motor cortex the correlation between beta amplitude and neuronal spike count during visuomotor behavior. First, in an analysis termed “task-related correlation”, single-trial data obtained across all trial epochs were included. These correlations were significant in up to 32% of cases and often strong. However, a trial-shuffling control analysis recombining beta amplitudes and spike counts from different trials revealed these task-related correlations to reflect systematic, yet independent, modulations of the 2 signals with the task. Second, in an analysis termed “trial-by-trial correlation”, only data from fixed trial epochs were included, and correlations were calculated across trials. Trial-by-trial correlations were weak and rarely significant. We conclude that there is no intrinsic relationship between the firing rate of individual neurons and LFP beta oscillation amplitude in macaque motor cortex.