Top-down specific preparatory activations for selective attention and perceptual expectations.

Proactive cognition brain models are mainstream nowadays. Within these, preparation is understood as an endogenous, top-down function that takes place prior to the actual perception of a stimulus and improves subsequent behavior. Neuroimaging has shown the existence of such preparatory activity separately in different cognitive domains, however no research to date has sought to uncover their potential similarities and differences. Two of these, often confounded in the literature, are Selective Attention (information relevance) and Perceptual Expectation (information probability). We used EEG to characterize the mechanisms that pre-activate specific contents in Attention and Expectation. In different blocks, participants were cued to the relevance or to the probability of target categories, faces vs. names, in a gender discrimination task. Multivariate Pattern (MVPA) and Representational Similarity Analyses (RSA) during the preparation window showed that both manipulations led to a significant, ramping-up prediction of the relevant or expected target category. However, classifiers trained with data from one condition did not generalize to the other, indicating the existence of unique anticipatory neural patterns. In addition, a Canonical Template Tracking procedure showed that there was stronger anticipatory perceptual reinstatement for relevance than for expectation blocks. Overall, the results indicate that preparation during attention and expectation acts through distinguishable neural mechanisms. These findings have important implications for current models of brain functioning, as they are a first step towards characterizing and dissociating the neural mechanisms involved in top-down anticipatory processing.

Proactive selective attention across competition contexts.

Selective attention is a cognitive function that helps filter out unwanted information. Theories such as the biased competition model (Desimone & Duncan, 1995) explain how attentional templates bias processing towards targets in contexts where multiple stimuli compete for resources. However, it is unclear how the anticipation of different levels of competition influences the nature of attentional templates, in a proactive fashion. In this study, we used electroencephalography (EEG) to investigate how the anticipated demands of attentional selection (either high or low stimuli competition contexts) modulate target-specific preparatory brain activity and its relationship with task performance. To do so, participants performed a sex/gender judgment task in a cue-target paradigm where, depending on the block, target and distractor stimuli appeared simultaneously (high competition) or sequentially (low competition). Multivariate Pattern Analysis (MVPA) showed that, in both competition contexts, there was a preactivation of the target category to select, with a ramping-up profile at the end of the preparatory interval. However, cross-classification showed no generalization across competition conditions, suggesting different preparatory formats. Notably, time-frequency analyses showed differences between anticipated competition demands, with higher theta band power for high than low competition, which mediated the impact of subsequent stimuli competition on behavioral performance. Overall, our results show that, whereas preactivation of the internal templates associated with the category to select are engaged in advance in high and low competition contexts, their underlying neural patterns differ. In addition, these codes could not be associated with theta power, suggesting that they reflect different preparatory processes. The implications of these findings are crucial to increase our understanding of the nature of top-down processes across different contexts.

MVPAlab: A machine learning decoding toolbox for multidimensional electroencephalography data.

BACKGROUND AND OBJECTIVE: The study of brain function has recently expanded from classical univariate to multivariate analyses. These multivariate, machine learning-based algorithms afford neuroscientists extracting more detailed and richer information from the data. However, the implementation of these procedures is usually challenging, especially for researchers with no coding experience. To address this problem, we have developed MVPAlab, a MATLAB-based, flexible decoding toolbox for multidimensional electroencephalography and magnetoencephalography data. METHODS: The MVPAlab Toolbox implements several machine learning algorithms to compute multivariate pattern analyses, cross-classification, temporal generalization matrices and feature and frequency contribution analyses. It also provides access to an extensive set of preprocessing routines for, among others, data normalization, data smoothing, dimensionality reduction and supertrial generation. To draw statistical inferences at the group level, MVPAlab includes a non-parametric cluster-based permutation approach. RESULTS: A sample electroencephalography dataset was compiled to test all the MVPAlab main functionalities. Significant clusters (p<0.01) were found for the proposed decoding analyses and different configurations, proving the software capability for discriminating between different experimental conditions. CONCLUSIONS: This toolbox has been designed to include an easy-to-use and intuitive graphic user interface and data representation software, which makes MVPAlab a very convenient tool for users with few or no previous coding experience. In addition, MVPAlab is not for beginners only, as it implements several high and low-level routines allowing more experienced users to design their own projects in a highly flexible manner.

Multivariate Pattern Analysis Techniques for Electroencephalography Data to Study Flanker Interference Effects.

A central challenge in cognitive neuroscience is to understand the neural mechanisms that underlie the capacity to control our behavior according to internal goals. Flanker tasks, which require responding to stimuli surrounded by distracters that trigger incompatible action tendencies, are frequently used to measure this conflict. Even though the interference generated in these situations has been broadly studied, multivariate analysis techniques can shed new light into the underlying neural mechanisms. The current study is an initial approximation to adapt an interference Flanker paradigm embedded in a Demand-Selection Task (DST) to a format that allows measuring concurrent high-density electroencephalography (EEG). We used multivariate pattern analysis (MVPA) to decode conflict-related electrophysiological markers associated with congruent or incongruent target events in a time-frequency resolved way. Our results replicate findings obtained with other analysis approaches and offer new information regarding the dynamics of the underlying mechanisms, which show signs of reinstantiation. Our findings, some of which could not have been obtained with classic analytical strategies, open novel avenues of research.

Movimiento escapular, distancia acromiohumeral, rango y fuerza rotacional glenohumeral en deportistas femeninas de handball de élite / Scapular motion, acromiohumeral distance, range and glenohumeral rotational strength in elite female handball athletes

Antecedentes: El handball es un deporte "overhead" que expone al hombro a demandas elevadas de carga durante la práctica, lo que puede llevar a esta articulación a sufrir adaptaciones específicas. La comprensión de estas adaptaciones es importante y puede ayudar a los clínicos a crear protocolos de prevención y a desarrollar programas de condicionamiento y rehabilitación para esta población. Objetivos: Generar un perfil descriptivo de:1) movimiento escapular durante la elevación y descenso de la extremidad superior en el plano escapular, 2) distancia acromiohumeral y 3) rango de movimiento y fuerza rotacional glenohumeral en deportistas femeninas de handball de élite. Métodos: Se realizo un estudio transversal observacional y descriptivo en 23 jugadoras (Edad = 22±4.3 años; Años de practica 9.7±3.5) de handball de élite, libres de dolor. Se valoró el movimiento escapular bilateral durante la elevación y el descenso del brazo, la distancia acromiohumeral durante la abducción activa y pasiva, y el rango de movimiento articular y la fuerza rotacional GH en rotación interna y externa. Se describen estas variables, comparándolas entre ambos brazos, y entre los grupos formados en función del déficit de rotación interna GH. Resultados: No se detectaron diferencias significativas en el movimiento escapular 3D ni en la distancia acromiohumeral entre los brazos. Se observó una disminución del rango de rotación interna (Diferencia Media (DM)= -11.09°; Intervalo Confianza 95% (IC)= -17.70,-4.47) y un incremento del rango de rotación externa (DM= 12.82°; IC= 6.07°,19.58°) en el hombro dominante. El torque rotacional GH en rotación externa fue mayor (DM= 0.36 Nm/kg; IC=-0.008 Nm/kg, -0.81Nm/kg) en el hombro dominante. Las participantes con déficit de rotación interna mostraron mayores rangos de rotación superior y tilt posterior escapular durante la elevación, mayor distancia acromiohumeral en reposo y mayor disminución de esta durante la elevación de la extremidad Conclusión: Los resultados sugieren que no existen diferencias en el movimiento escapular durante la elevación y descenso de la extremidad superior, ni en la distancia acromiohumeral en las diferentes posiciones de elevación GH activa y pasiva entre el brazo dominante y no dominante de las deportistas femeninas de handball de élite. Los hallazgos indican que el brazo lanzador de estas deportistas presenta diferencias en el rango rotacional y en la fuerza, que podrían representar un factor de riesgo lesional, siendo detectables en el ambiente clínico. Las deportistas que presentan GIRD, muestran mayor movimiento escapular 3D durante la elevación, mayor DAH en reposo y mayor disminución de esta durante la elevación de la ES

Background: Handball is an overhead sport that exposes the shoulder to high demands of load during the practice, which may lead this joint to sport-specific adaptions. Understanding these adaptions is important and may help clinicians to create preventive protocols and further develop conditioning and rehabilitation program to this population. Objectives: To generate a descriptive profile of:1) scapular motion during upper extremity raising and lowering along the scapular plane, 2) acromiohumeral distance, and 3) GH rotational range of motion and rotational strength in elite female handball athletes. Methods: This is observational and descriptive cross-sectional study. Twenty-three (22±4.3 years and 9.7±3.5 years of practice) pain free elite female handball players were assessed. Outcome measures included bilateral 3D scapular movement during raising and lowering of the arm, acromiohumeral distance during passive and active abduction, GH range of motion of internal and external rotation, and strength of the internal and external rotators. These variables were described by comparing them between both arms, and among the groups according to the GH internal rotation deficit. Results: No significant differences were detected in 3D scapular motion or acromiohumeral distance between the arms. A decrease in internal rotation range of motion (Mean Difference (MD) =-11.09°;95% Confidence Interval (CI)= -17.70°, -4.47°) and an increase in external rotation range of motion (MD= 12.82°; CI=6.07°, 19.58°) and in GH rotational torque in external rotation (MD=0.36 Nm/kg; CI=-0.008Nm/kg, -0.81Nm/kg) were observed in the dominant shoulder. Participants with internal rotation deficit showed greater ranges of superior rotation and scapular posterior tilt during raising, greater acromiohumeral distance at rest and greater decrease of this during limb elevation. Conclusion: The findings suggest there are no differences in in the scapular movement during upper extremity raising and lowering along the scapular plane, nor in the acromiohumeral distance during passive and active GH between the dominant and non-dominant arm of elite female handball athletes. The findings indicate that there are differences in rotational range of motion and strength between both arms, which could represent an injury risk factor, being detectable in the clinical sports environment. Participants with internal rotation deficit showed greater scapular 3D movement, greater DAH at rest and greater decrease of it during arm elevation